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High school students took part in LSR summer internship  

The Laboratory for Space Research (LSR) internship program at The University of Hong Kong(HKU) has grown organically and rapidly since its inception in 2016, with its first two interns reaching capacity today at seventeen. Fifty-two interns have been hosted since 2016 for periods of between two to three weeks and three months. Interns come not just from local international schools, HKU and local universities, but also from overseas (e.g. India, USA, Singapore, Spain).  This year, LSR has hosted six undergraduate students from HKU, three overseas students from the University of Chicago who attended remotely, as well as eight high school students from various top local schools.    Jenny JIANG from St. Paul's Convent School was one of the LSR interns and had been working on excitation of planetary nebulae under the supervision of Professor Quentin PARKER, the Director of LSR. She said, "These beautiful glowing clouds are an important phase in the stellar evolution of an intermediate-mass star such as our sun. I've learnt to use techniques such as spectroscopy and data analysis to obtain results. It introduced me to the field of astronomy." LSR provides wonderful guidance and resources to all its members that aid their research. Jenny said she very much enjoyed the intellectual community and the experience this summer strengthened her aspiration to pursue a research career, "I'm grateful that Professor Parker and LSR accept high school students as interns - very rare for any research laboratory, so this is a valuable opportunity for high school students like myself to get a taste of the academic realm," Jenny remarked.  LSR internship does not cater just to physics major but has also accepted students from computing and engineering as befits the interdisciplinary nature of the LSR. Student projects cover computer simulations and aerospace design (for CubeSats and Mars rover drills), late-stage stellar evolution and high-energy astrophysics. The robust internship program of LSR not only serves as a valuable KE and community service but also offers short-term support to the research staff.  Click here to learn more about Laboratory of Space Research.     

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HKU Physicists and collaborators co-observe a higher-dimensional topological state with metamaterials

Linked Weyl surfaces, a novel type of topological phase that exists in five-dimensional space, were experimentally observed for the first time by a team led by Professor Shuang ZHANG from the Department of Physics at The University of Hong Kong(HKU). The work provides a unique platform for exploring various topological phases, the transition between them, and the corresponding boundary effects in five dimensions. Why topology and Weyl surfaces matter? In geometry, topology concerns the global features of a shape, independent of the details - a famous example being that a coffee mug and a donught-shaped ring (torus) are topologically equivalent because they can be continuously transformed into each other without experiencing dramatic changes, e.g. opening holes, tearing, gluing, etc. The principle of topology has been successfully applied to physical systems and has led to the discovery of many intriguing phenomena, such as quantum Hall effect and robust one-way surface wave propagation without any backscattering. Topological physics also holds promise for novel devices and applications in both electronics and photonics, e.g large-scale topological quantum computation and topological laser. Among various topological physical systems, Weyl point, a massless state with linear dispersion along with all three directions, has received special attention as it serves as a kind of source of band topology. Weyl particles were first predicted by German physicist Hermann Weyl in 1929, but they have not been found as fundamental particles. Weyl points were proposed to exist in certain material systems in the form of quasiparticles in recent years, and they were observed experimentally in 2015. Weyl points are the 3D counterparts of the famous Dirac points found in graphene - a two-dimensional system consisting of a single layer of graphite. The extension of Weyl points from 3D to higher dimensions is expected to introduce more complicated and intriguing topological phenomena, e.g. high-dimensional quantum Hall effect. Specifically, its generalisation to five dimensions leads to two possible configurations - Yang monopoles and linked Weyl surfaces. Yang monopoles, first proposed by Professor Chen-Ning YANG in 1978, are isolated points in the 5D momentum space, which serve as sources of non-abelian Berry curvature. Recently there have been demonstrations of Yang monopoles in purely synthetic dimensions. However, until now, there has been no experimental observation of Weyl surfaces, whose linking behaviour serves as a direct signature of the second Chern number. Observing complicated topological phase through experiment Together with collaborators from Jilin University, HKUST and Tsinghua University, Zhang’s group designed and realised systems possessing linked Weyl surfaces based on metamaterials   -  artificially engineered photonic structures that exhibit exotic optical properties, including negative refraction and invisibility cloaks. The authors constructed a 5D physical system by combining the three real momenta and two additional synthetic dimensions provided by an exotic electromagnetic property of metamaterials called bianisotropy. The designed metamaterial consists of a delicate arrangement of metallic helices of different handednesses. By carefully engineering the geometry and orientation of each helix, it is possible to finely tune the structure to realise controllable synthetic momenta. By further adding some perturbations to the system to lower the symmetry of the structure, one can bring the interesting linking properties of the Weyl surfaces to the three-dimensional real momentum space, which can be directly observed in the experiment. Depending on the type of perturbations, the linked Weyl surfaces can be manifested as a point enclosed by a sphere, two points separated by a plane, or linking between two rings in the three-dimensional subspace, as shown in the figure. This linking represents the second Chern number that is not present in their lower dimensional counterparts. The authors further observed the key signature of this unusual topological phase   -  the presence of a 1D Weyl arc at the 4D boundary of the 5D system. What are the impacts and what’s next? This work opens doors to the investigation of various topological phases in higher dimensions. From the perspective of fundamental physics, it provides a unified view of different topological phases in lower dimensions, such as Weyl points, nodal lines, and Dirac points; for device applications, by taking designing parameters as additional synthetic dimensions, it leverages the concept of higher-dimension topology to control the propagation of electromagnetic waves in artificially engineered photonic media, e.g. realising robust integrated photonic circuits for optical information processing that is immune to scattering loss. The synthetic platform also brings various artificial gauge fields and pseudo magnetic fields into topological photonics. In addition to the chiral zeroth Landau levels, other elusive phenomena, including quantum oscillation, wormhole effect, and other effects arising from non-abelian gauge fields, can be explored in the photonic metamaterial systems. By introducing pseudo electric field, i.e., spatial-dependent frequency responses, high-dimensional chiral anomaly could also be designed. “Our work serves as the first experimental observation of the linking of Weyl surfaces and surface Weyl arcs in five-dimensional space,” said Professor Zhang. “Making use of the design flexibility and tunability of metamaterials, it will usher in a new era of higher-dimensional topological phase exploration.”   The research paper was recently published in the renowned journal Science. Details of the paper: Linked Weyl surfaces and Weyl arcs in photonic metamaterials. Shaojie Ma, Yangang Bi, Qinghua Guo, Biao Yang, Oubo You, Jing Feng, Hong-Bo Sun, Shuang Zhang. Vol. 373, Issue 6554, pp. 572-576. The journal paper can be accessed here. 

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Honoring staff members with outstanding performance in research, teaching and knowledge exchange (KE)

HKU Science has long committed to advancing the excellence of research and teaching, as well as promoting knowledge transfer. We are pleased to announce that many of our members are recognised for their efforts and  dedication in different areas for the past year.   The Faculty has set up awards to recognise the outstanding performance of members in the Faculty. The Award for Teaching Excellence, Award for Teaching Innovations in E-learning and Excellence Teaching Assistant Award are established to recognise excellence in teaching in the Faculty, while the Award for Outstanding Professional Services Staff is to recognise, reward and promote excellent performance among professional services staff.   Other recognition includes the Faculty Knowledge Exchange (KE) Award, which honours dedicated Faculty member with outstanding KE accomplishment in his or her own area. We also have Faculty-based Research Output Prize that accords recognition to an author (or team of authors) of a single piece of research output published.   Please join us to share the joy of the following recipients:   University Awards Research Output Prize 2020  Dr Louise A ASHTON, Assistant Professor, School of Biological Sciences   Faculty Knowledge Exchange (KE) Award 2021 Professor Hongzhe SUN, Norman and Cecilia Yip Professorship in Bioinorganic Chemistry & Professor: Chair of Chemistry, Department of Chemistry   Faculty Awards Award for Teaching Excellence 2020-2021 Dr Rachel K W LUI, Senior Lecturer, Faculty of Science   Award for Teaching Innovations in E-learning 2020-2021 Professor Pauline CHIU, Professor, Department of Chemistry   Excellent Teaching Assistant Awards 2020-2021 Mr Abdullah Nawabjan SHAIK, PhD Student, School of Biological Sciences Mr Thomas H T WONG, MPhil Student, Department of Physics   Award for Outstanding Professional Services Staff 2020-2021 Mr Man Fai LEE, Senior Clerk, Faculty of Science   Congratulations to them all!

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Five young scientists awarded the National Excellent Young Scientists Fund 2021

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HKU Science welcomes HKDSE high achievers to our full spectrum of programmes

The Faculty of Science is pleased to announce that our new first-class double degree programme 6688 Science Master Class (SMC) is doing exceptionally well in attracting high DSE performers into our programme, according to the 2021 Joint University Programmes Admissions System (JUPAS) Main Round offer results just released, with a median admissions score of around 40 for the best 6 subjects attained by the 17 admitted students, ranking the 8th out of the 43 HKU programmes.  The 6224 Bachelor of Arts and Sciences in Applied Artificial Intelligence (BASc(AppliedAI)), another elite programme co-offered by the Faculty, remains one of the top programmes in the community. Twelve students with a median admissions score of 36 for the best 6 subjects opted for the AI programme in HKU. The Dean of Science (Interim), Professor Vivian YAM extends her warmest welcome to all our newly admitted students. She attributes the encouraging admissions results to the programmes that have been designed to address the specific needs of talented students. “We understand the learning pace and needs of highly able students might be different. The SMC programme is designed to help students with high research aspirations to achieve their scholastic potential in science, allowing them to learn from renowned scientists in the Faculty, get to know the frontiers of scientific research, and most importantly, immerse themselves in an authentic research environment in the early years of their study,” said Professor Yam. “We thank our students for their interest in the programme. We will try our best to provide a good experience for their study.”   As Hong Kong’s role as a premier innovation hub in Asia becomes increasingly important and with the booming AI industry, Professor Yam emphasises that the AI applications in diverse areas highlighted in the BASc(AppliedAI) Programme would help students to develop their intellectual capacity essential to meeting new challenges. “In this digital era, the limitless power of AI impacts all aspects of our lives. We hope with the concerted efforts of our top-notch researchers, we are able to inspire the next generation of AI professionals,” she remarked.   “Though the SMC and BASc(Applied AI) programmes cater to supporting the growth of elite undergraduates, all our science programmes are internationally competitive and are designed to nurture our students to their fullest potentials,” Professor Yam added. 

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HKU Ecologists study the buffering effects of forests on climate change impacts on insect communities, revealing the importance of forest regeneration

The understanding of long-term responses of the fauna and flora in a world highly modified by deforestation, biological invasions or climate changes is paramount to develop the best conservation strategies. In tropical and subtropical regions, old datasets and specimens are scarce, limiting the monitoring of sites over time and thus informing the best strategies for the protection of biodiversity. A team of scientists from the Insect Biodiversity and Biogeography Laboratory of the Research Division from Ecology and Biodiversity and the School of Biological Sciences at The University of Hong Kong (HKU), along with colleagues in the UK and the USA, has studied long-term changes in species richness and composition of ants across different habitats in Hong Kong. Their results reveal the importance of forest regeneration in mitigating the increasing effects of extreme hot events for species survival, while temperature-mediated species turnover has been found for species living within open habitats. Digging up treasure from old datasets In this new study, the authors studied the species richness and composition of ants at 47 sites in country parks across a >20 years’ period of forest regeneration. The ants were first collected in the mid-1990 by Dr John FELLOWES, an Honorary Assistant Professor of HKU Kadoorie Institute, nearly 20 years ago, who cleverly kept the specimens in a collection here in Hong Kong. Twenty-five years later, the research team used a similar sampling protocol for collecting ants at the sites defined by Dr Fellowes, and re-examined the specimens collected in the 90’s to confirm species identifications. The results then highlight the importance of secondary forests in buffering temperature impacts on subtropical ants, while in open habitats, such as grassland and shrubland, high temperatures became more important over time in explaining which ant species would be present at a particular site.  Overall, average body size of species in open habitats and in forests with low canopy cover became smaller over time, suggesting that large-body ant species were more susceptible to increased temperature. This then could have consequences on the functioning of ecosystems as large ant species may contribute disproportionally to particular ecological functions, such as decomposition processes.  “Over the past decades, extreme hot days (> 33oC) have been experienced more often and for longer period of time. Unfortunately, this may also impact local wildlife, threatening the survival of many species, especially for groups like insects unable to directly regulate their body temperature. Our research investigated how we could mitigate such adverse impacts.” Dr Benoit GUÉNARD, Head of the Insect Biodiversity and Biogeography Laboratory mentioned. He further adds: “Ants are particularly interesting to understand how habitat modifications and changes in climate may impact local biodiversity. Because of their social organisation, they invest important efforts and energy in building nests, making them almost sessile like plants, and thus enduring the local conditions, contrary to many other solitary organisms which can move more easily between different habitat patches. Thanks to standardised sampling methods and specimens’ collection, we can thus monitor how their diversity and species composition evolve over time as environmental conditions change at a particular site”. The deforested landscape is now commonly seen in tropical Asia, where forest logging rates are among the highest in the world. The combination of deforestation and climate change have raised the temperatures to some abnormally high levels, so mitigating the increasing heat on biodiversity is urgently required. Here, the new results reinforce the importance of maintaining or increasing forest coverage and age, as the canopy that develops in older forests increases the benefits of its temperature buffering role for species living underneath. Hong Kong country parks provide a unique opportunity to safeguard natural forests and allow them to regrow, but also a rare chance to examine this process on animal communities. The finding of this study highlight the vital role of mature forests in mitigating the extreme heat as well as establishing protected areas that provide time for forests to regenerate. Specimen preservation- the importance of a natural museum for our biodiversity The study also highlights the importance of specimen collections to assess changes in biodiversity over time and space. Access to specimen collections of earlier samplings is often difficult if not impossible due to a lack of specimen preservation, leading to the potentially incorrect assumption that past species lists are accurate.   In this study, the authors accessed and re-identified specimens from the historical baseline collected by Dr John Fellowes in the 1990s, previously stored in the Kadoorie Farm and Botanic Garden and now within the Hong Kong Biodiversity Museum. This allowed for consistency in the species identity between the two periods and a detailed account for taxonomic updates over time. This type of research assessing changes over time would not be possible for groups like insects if access to specimen collection was not available, demonstrating the importance of natural museum collections in the preservation of specimens and in the opening of a temporal window on biodiversity. The paper of the above study was published as an accepted article in the journal Ecological Monographs on July 16th 2021. The journal paper can be accessed from here.  Dr John Fellowes, one of the co-authors of the study, carrying out ant inventory during the mid-1990s. Photo credit: Kadoorie Farm & Botanic Garden. Secondary forest in the Lantau North Country Park, buffering temperature impacts on understory wildlife. Photo credit: Insect Biodiversity and Biogeography Laboratory. Ms Ying LUO and Mr Chase Liu Wei WANG from the Insect Biodiversity and Biogeography Laboratory resampling ants in a shrubland in 2010s. Photo credit: Insect Biodiversity and Biogeography Laboratory. Specimens collection preserved within museum collections are essential components to establish rigorous baseline and monitor changes of biodiversity. Here are ant specimens preserved at the Hong Kong Biodiversity Museum. Photo credit: Hong Kong Biodiversity Museum.  

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HKU geologists discover that the NASA rover has been exploring surface sediments, not lake deposits for last eight years

In 2012, NASA landed the rover Curiosity in the Gale crater on Mars because the crater was thought by many scientists to be the site of an ancient lake on Mars more than 3 billion years ago. Since that time, the rover has been driving along, carrying out geological analyses with its suite of instruments for over 3,190 sols (martian days, equivalent to 3278 earth days). After analysing the data, researchers from Department of Earth Sciences, the Faculty of Science at HKU, have proposed that the sediments measured by the rover during most of the mission did not actually form in a lake.   The researcher team suggested that the large mound of sedimentary rocks explored and analysed for the last eight years actually represent sand and silt deposited as air-fall from the atmosphere and reworked by the wind. The alteration minerals formed by the interaction between water and the sand did not occur in a lake setting. The “wet” environment, they propose, actually represents weathering similar to soil formation under rainfall in an ancient atmosphere that was very different from the present one.   The discovery was published recently in Science Advances in a paper led by research postgraduate student Jiacheng LIU, his advisor Associate Professor Dr Joe MICHALSKI, and co-author Professor Mei Fu ZHOU, all of whom are affiliated with the Department of Earth Sciences. The researchers used chemistry measurements and x-ray diffraction (XRD) measurements, in addition to images of rock textures, to reveal how compositional trends in the rocks relate to geological processes.   “Jiacheng has demonstrated some very important chemical patterns in the rocks, which cannot be explained in the context of a lake environment,” said Dr Michalski. “The key point is that some elements are mobile, or easy to dissolve in water, and some elements are immobile, or in other words, they stay in the rocks. Whether an element is mobile or immobile depends not only on the type of element but also on the properties of the fluid. Was the fluid acidic, saline, oxidising etc. Jiacheng’s results show that immobile elements are correlated with each other, and strongly enriched at higher elevations in the rock profile. This points toward top-down weathering as you see in soils. Further, he shows that iron is depleted as weathering increases, which means that the atmosphere at the time was reducing on ancient Mars, not oxidising like it is on the modern day, rusted planet.”   Understanding how the Martian atmosphere, and the surface environment as a whole, evolved is important for the exploration for possible life on Mars, as well as our understanding of how Earth may have changed during its early history. “Obviously, studying Mars is extremely difficult, and the integration of creative and technologically advanced methodologies are necessary. Liu and co-authors have made intriguing observations via the utilisation of remote sensing techniques to understand the chemical composition of ancient sediments that inform on their early development. Their data present challenges to existing hypotheses for both the depositional environment of these unique rock formations and the atmospheric conditions that they formed under - specifically, the authors show evidence for weathering processes under a reducing atmosphere in a subareal environment similar to a desert, rather than formation in an aqueous lake environment. Indeed, this work will inspire new and exciting directions for future research.” Assistant Professor from Department of Earth Science Dr Ryan McKenzie added.   China successfully landed its first lander, Zhurong, on Mars in May this year. Zhurong is currently roving the plains of Utopia Planitia, exploring mineralogical and chemical clues to recent climate change. China is also planning a sample return mission likely to occur at the end of this decade. About the research team at HKU: The Department of Earth Sciences, Research Division for Earth and Planetary Science and the Laboratory for Space Research specialise in the applications of traditional Earth and environmental science techniques and skills for modern space science challenges. Dr Joe Michalski operates the Planetary Spectroscopy and Mineralogy Laboratory at HKU, and is the Deputy Director of the Laboratory for Space Research.  

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HKU alumna from the School of Biological Sciences won fellowship to study nutrient sharing in symbioses

A proposed research initiated by Former PhD student Dr Inga Elizabeth Conti-Jerpe School of Biological Sciences at HKU class of 2019, was awarded a prestigious Plant Genome Postdoctoral Research Fellowship from the National Science Foundation of USA. The proposed research will investigate the traits and underpinning genetics that modulate nutrient exchange between symbiotic partners at the University of California, Berkeley. Symbiotic relationships in which two organisms share nutrients are prevalent across the tree of life.  Most plants, for example, associate with soil fungi that provide nutrients that the plant cannot assimilate independently. In exchange, the plant provides the fungi with sugars produced through photosynthesis. These mutually beneficial relationships exist in other lifeforms, including marine invertebrates (corals, jellyfish, clams, sea slugs, and flatworms) associate with algae, and lichens, which are comprised of an algae and fungus living together. By coupling their nutrition, these partners thrive in nutrient-poor environments and provide the foundation for critical ecosystems such as forests and coral reefs. Dr Conti-Jerpe proposed to apply a new technique she developed during her PhD that uses stable isotope analysis to quantify nutrient sharing in symbioses. She will use this method to measure nutrient exchange in a diversity of marine invertebrates, plants, and lichens to determine if certain traits are adaptations for more or less sharing. “We see the same set of traits over and over again in symbioses that evolved independently,” says Dr Conti-Jerpe. “I want to understand if these traits are adaptations for varying functionality of the symbiosis.” Dr Conti-Jerpe’s proposed research will take this one step further by investigating gene expression in a flexible symbiosis. “I realised that some tree species are able to form symbioses with two different types of soil fungi: those that form a sheath around the plants’ roots and those that actually penetrate the root cell wall. This struck me as a great system for manipulating one functional trait of the symbiosis: how physically intertwined the two partners are.” By manipulating the fungi associated with grey alder tree seedlings and comparing genes expressed in each scenario, Dr Conti-Jerpe can identify genes involved in the establishment and maintenance of symbiotic relationships. “I’m excited to use both stable isotope analysis and advanced genetic techniques to understand symbioses,” says Dr Conti-Jerpe. “Combining these technologies has huge potential, and I’m thrilled by the opportunity to add molecular tools to my toolkit.” Click here to learn more about the NSF project Abstract.   

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Restoring Hong Kong’s Whale’ Campaign

Riding on the re-opening of the Swire Institute of Marine Science (SWIMS), Faculty of Science of The University of Hong Kong(HKU) on 28th July, 2021, the institute also launches the ‘Restoring Hong Kong’s Whale’ Campaign on the same day, to restore the fin whale skeleton, the symbol of marine conservation that has been sitting on the shore at Cape d’Aguilar beside SWIMS for 3 decades, in the hope of revitalising the icon and appealing for support to educational activities.  A baby whale lost its mother in the sea In the summer of 1955, a baby Fin whale was discovered in Hong Kong waters. It was first seen floating among the pilings under Ming Shan Wharf in Victoria Harbour. The young male was, sadly, separated from its mother while migrating north from the South China Sea and was slowly starving. After marine police euthanised the whale, it was towed to Aberdeen where it was processed by HKU zoologists. The skeleton was preserved and displayed across several buildings on the HKU campus, out of sight of the sea, for the following 35 years. To help return the whale to the seashore, the skeleton underwent a year-long reconstruction and was found a new home on the shores of Cape d’Aguilar next to the newly established Swire Marine Laboratory in 1991, overlooking the South China Sea since then. Storm Damage Unfortunately, the Hong Kong’s whale suffered major damage during 2018’s super typhoon, Mangkhut, which ravaged Hong Kong with 170 km/hr wind gusts for over two days. The supportive structures connecting the bones were bent by the storm’s incessant winds, causing many of the ribs to crack, the lower right jawbone was dislodged and the left hip bone blown away. After the storm, despite remedial efforts, the whale continues to deteriorate on the exposed, sun baked rocks of Cape d’Aguilar. The Whale’s Rebirth With the reopening of SWIMS, Hong Kong’s whale will undergo its first restoration initiative in twenty years and be re-born as a symbol for marine conservation. The original bones will be preserved in the SWIMS biodiversity collection while new bones of 1:1 size designed to withstand typhoon winds, salt spray, and Hong Kong’s hot summer sun for many years will be 3D printed using state of the art technology. The campaign aims to support the recreation of the whale skeleton, as a figurehead for SWIMS research and education efforts to conserve Hong Kong’s marine environment. As such, the whale will be named to celebrate its ‘re-birth’.  Restoration Campaign  This ‘Restoring Hong Kong's Whale’ campaign focuses on raising funds to restore this icon of Hong Kong back to its original glory, to contribute towards marine conservation in Hong Kong and to support outreach activities at SWIMS. Donors can get a chance to vote for their favourite name for the baby whale, which will be remembered generations from now. To show the sincere gratitude of HKU and SWIMS, a small-scale 3D printed replica of the whale will be given to donors with contributions of HK$8,000 or above. Souvenirs will be offered while stock lasts.  Click here to donate.     The dead whale was tied onto the Research Vessel Alister Hardy and towed to Aberdeen on April 12, 1955. Photo credit: Spectrum, No. 4, May 1955 Using a high tide the next day, the whale was beached in front of the Government Fisheries Division’s Headquarters in Aberdeen where it was measured and dissected by HKU scientists. Photo credit: Spectrum, No. 4, May 1955 After years housed indoors at HKU campus, academics from various departments worked to rebuild the skeleton and take it back to the sea. SWIMS has been the whale’s steward since it first moved there in the 1990s. Whale bone before damage.  Photo credit: Dr Jacky Ip The damaged skeletal display of the whale after being ravaged by super typhoon Mangkhut in September 2018.  

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HKU Science celebrates the opening of the expansion of the Swire Institute of Marine Science and launches the ‘Restoring Hong Kong’s Whale’ Campaign to revitalise marine conservation icon

Video Highlights  A Plaque Unveiling and Opening Ceremony took place on July 28, 2021 at the Swire Institute of Marine Science (SWIMS), Faculty of Science of The University of Hong Kong (HKU), at Cape d’Aguilar Marine Reserve, celebrating the opening of SWIMS’ expansion and marking the beginning of a new era in marine research. Riding on its re-opening, SWIMS also launches the ‘Restoring Hong Kong’s Whale’ Campaign to restore the fin whale skeleton, the symbol of marine conservation that has been sitting on the shore beside SWIMS for 3 decades, in the hope of revitalising the icon and appealing for support to educational activities. Since its inception in 1990, SWIMS has long been a premier marine centre driving our understanding of coastal marine ecosystems in Hong Kong and surrounding regions. Whilst earlier research relied on more field-based approaches, recent technologies have revolutionized marine biology and the new expansion. Three decades since its launch, it comes at an opportune time for SWIMS to modernise and expand its research capacity to provide HKU researchers with state-of-the art facilities. At the ceremony, President and Vice-Chancellor of HKU Professor Xiang Zhang expressed his heartfelt gratitude to The Swire Group Charitable Trust (Swire Trust) for its continued and committed support of SWIMS research in marine conservation. “The expansion of SWIMS coincides with the University’s development blueprint of building an innovative knowledge hub and redefining the world. This transformative vision, the expansion, and new state-of-the-art facilities will help SWIMS achieve its goal of conserving our rich marine biodiversity to build a sustainable coastal ecosystem. The newly expanded SWIMS will become one of the most iconic landmarks of HKU and I look forward to its great success.” Mr Merlin Swire, Chairman of Swire Pacific Limited, said: “I congratulate HKU and the Faculty of Science on this wonderful new expansion to SWIMS. Swire has a long history of supporting HKU, and our support for SWIMS has been a highlight of that enduring partnership. When Swire first sponsored the establishment of the SWIMS facility here at Cape d’Aguilar in 1990, we hoped to make a positive contribution to protecting Hong Kong’s unique marine habitat by supporting scientific research and education. In the thirty years since then, SWIMS has gone from strength to strength, establishing itself as one of the leading marine research institutes in the region, dedicated to protecting and sustaining the coastal ecosystem. This new extension will facilitate even closer collaboration with international research organisations, bringing a global perspective on local loss of biodiversity, including the effects of climate change, as well as offering more opportunities for outreach and education. We are proud to have played a part in opening up this exciting new chapter for SWIMS.” Dean of HKU Science Professor Matthew Evans echoed that Hong Kong, as a coastal metropolis strategically situated at the heart of Asia, is a vital hub to drive research in marine science. “Our newly set up marine biodiversity centre will soon establish an extensive physical and electronic reference base of Hong Kong’s marine life, which will be of use to scientists, government departments, NGOs and environmental institutions,” said Professor Evans. “The new facility will also introduce local citizens and students to the diversity of amazing sea life through its proposed outreach and knowledge transfer programmes.” About the expansion and new facilities Forming an L-shape with the existing main building, the expansion and renovation will comprise a molecular laboratory, biodiversity centre and both indoor and outdoor seawater aquaria, providing state-of-the-art facilities for its growing body of new staff and research students. “Through the addition of new facilities, SWIMS will be able to host more researchers from around the world and maintain its leading role in marine science research, while also catering to the growing interest in local marine ecology and biodiversity being developed by citizens in Hong Kong,” said Professor Gray A Williams, Director of SWIMS. About the Swire Institute of Marine Science The Swire Institute of Marine Science (SWIMS), originally named the Swire Marine Laboratory, was established in 1990 and is located at Cape d’Aguilar as an off-campus facility of HKU’s Faculty of Science. SWIMS facilitates and enhances interdisciplinary research, with its major research focus on coastal marine systems and their biodiversity and ecology, particularly in relation to the themes of habitat destruction and restoration; global change and adaptation; and overexploitation and sustainability. It currently has around 75 scientists conducting active research, including many which stay in its accommodation on the cliffs overlooking SWIMS, and has recently received funding from the Swire Group Charitable Trust, the Faculty of Science, the University, and the HKSAR Government to expand its facilities to enhance its vibrant research environment. Website of SWIMS: https://www.swims.hku.hk The Swire Institute of Marine Science (SWIMS) is an off-campus research and education facility under HKU Science. The Cape d’Aguilar Marine Reserve, Hong Kong’s only marine reserve where the Swire Institute of Marine Science (SWIMS) is located, is rich in biodiversity. The Re-opening Ceremony of the Swire Institute of Marine Science took place yesterday (July 28) at Cape d’Aguilar Marine Reserve.The officiating guests gathered to unveil the plaque for SWIMS’ expansion. From the left: Professor Gray A Williams, Director of SWIMS, HKU; Mr Merlin Swire, Chairman of Swire Pacific Limited; Professor Xiang Zhang,  President and Vice-Chancellor of HKU; Professor Matthew R Evans, Dean of Science, HKU. Replica of whale skeleton produced by 3D printing was presented to officiating guest Mr Merlin Swire, Chairman of Swire Pacific Limited, by Professor Matthew R Evans, Dean of Science, HKU. Professor Xiang Zhang,  President and Vice-Chancellor of HKU was interacting with the researchers while visiting the Biodiversity Centre.  Director of SWIMS Professor Gray A Williams introducing the mission of the ‘Restoring Hong Kong's Whale’ campaign, which focuses on raising funds to restore the icon of marine conservation in Hong Kong and to support outreach activities at SWIMS.  Molecular Laboratory - What used to be staff offices and storage space has been converted into a brand new, state of the art molecular lab. It provides a highly sterilised and dry environment for extracting DNA of specimens and performing downstream molecular analysis using advanced equipment. Biodiversity Centre - As part of the new structure, the centre will be a multipurpose space for public outreach and community engagement, a classroom for visiting school groups, and a library which houses the SWIMS museum specimen collection. The specimen collection mostly collected from Hong Kong, which will continue to be used for research purposes. Aquarium - Expanded from the existing structure, containing approximately 50-60 individual tanks in different dimensions to accommodate species of different sizes. The aquarium is designed specifically in a controlled environment where lighting and temperature are adjustable for manipulating a day cycle that simulates an environment according to the needs of different species. The Wet Lab - Associated with the Aquarium, it is designed to perform physiological measurement and dissection of specimens.    To visit the photo gallery, please click here!

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HKU Ecologist applied a novel statistical method to analysing causal inference and revealed importance of climate change in controlling deep-sea biodiversity

Which of temperature or food is more important for the richness of deep-sea animals? Dr Moriaki YASUHARA from the School of Biological Sciences, the Research Division for Ecology & Biodiversity, and The Swire Institute of Marine Science, The University of Hong Kong (HKU), in collaborating with Hideyuki DOI from University of Hyogo and Masayuki USHIO from Kyoto University, used long-term fossil dataset and novel statistical method to detect causality and found climate control of deep-sea biodiversity. Deep-sea cover >90 % of the ocean. So, understanding biodiversity drivers in deep-sea is critically important to project future changes in the function of Earth's ocean system. Recently, two main factors of the deep-sea biodiversity control have been actively debated, which are (1) food supply via marine snow (aka sinking particulate organic carbon originated from surface primary production) that is the main food source for deep-sea animals (given no sun light penetration and so no phytoplankton production in deep sea); and (2) climate-driven deep-sea temperature change. These two hypotheses of marine-snow or temperature control of deep-sea biodiversity are difficult to be fully tested by traditional modelling framework because the environment-diversity relationship that facilitates deep-sea biodiversity can be complex. The research, published in Biology Letters, used long-term fossil records from sediment cores and recently developed statistical method that can detect causality in a complex system instead of simple correlation (degree of linear relationship between two variables) to address this issue of marine-snow or temperature control of deep-sea biodiversity. The research team used benthic foraminifera (small shelled protist) as indication for the deep-sea fossil biodiversity time series and applied Convergent Cross Mapping (CCM) for the causality detection, and the results detected causality of temperature on deep-sea biodiversity but not of marine snow, which is supporting evidence that climate change affected long-term changes in deep-sea biodiversity. This temperature-diversity relationship detected indicates that ongoing and future human-induced climate change may affect deep-sea ecosystems via changes in global deep-water circulation rather than those in surface primary production. However, their study is based on a relatively limited number of data, and we need further comprehensive studies with better spatial and temporal coverage to confirm the generality of this conclusion.  In addition, this study is the first application of the causal inference method, CCM, to deep-sea long-term fossil time series from sediment cores. They successfully showed that this framework of using CCM on diversity time series can applicable not only to relatively short ecological-biological time series, but also long paleontological-paleoclimatological time series broadly.  "It's a long term debate which of temperature or marine snow is the main driver of deep-sea biodiversity. Our new causality analysis result is the strong support for the temperature hypothesis. ” co-lead author Moriaki Yasuhara concluded. About the journal paper: Citation: Hideyuki Doi, Moriaki Yasuhara, Masayuki Ushio (2021) Causal analysis of the temperature impact on deep-sea biodiversity. Biology Letters. The journal paper can be accessed from here:  For more information about Dr Moriaki Yasuhara’s research, please visit here.         

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Marine ecologists reveal mangroves might be threatened by low functional diversity of invertebrates

Mangrove forests were once dominant in the tropics but have recently been disappearing at alarming rates worldwide. Although this threatened ecosystem supports a broad range of specialised invertebrates, little is known about the impact of mangrove deforestation on the functional diversity and resilience of these resident fauna. The International Day for the Conservation of the Mangrove Ecosystem (also known as the World Mangrove Day), declared by UNESCO and celebrated every year on 26th July, aims to raise awareness on the importance of mangrove ecosystems. Mangroves are more than just trees, together they form a unique, special and vulnerable habitat. Their ecological functioning depends upon the mutual relationships between their floral and faunal components, and there is no viable mangrove forest without a healthy community of invertebrates sustaining it. To address this question, which is crucial in order to manage pristine mangroves and rehabilitate degraded ones, Dr Stefano CANNICCI (Associate Director of the Swire Institute of Marine Science and Associate Professor from the Research Division for Ecology & Biodiversity, The University of Hong Kong), along with Professor Joe Shing Yip LEE (Professor and Director, Simon FS Li Marine Science Laboratory, School of Life Sciences, The Chinese University of Hong Kong) and their colleagues compiled a dataset of 209 crustacean and 155 mollusc species from 16 mangrove forests around the world. They found that mangroves, when compared with other ecosystems, are among those with the lowest functional redundancy among resident fauna recorded to date, which suggests that these coastal vegetations are one of the most precarious ecosystems in the world in the face of the recent anthropogenic changes. Thus, a high functional redundancy is a sort of ‘ecological insurance’ for a given forest, since if one species is lost, another can fulfil its function, ultimately keeping the ecosystem viable. Diversity: The key to survival The authors classified these species into 64 functional entities based on unique combinations of three functional traits: feeding habits, behavioural traits potentially affecting ecosystem characteristics, and micro-habitat. More than 60% of the locations showed no functional redundancy, i.e., most of the functional entities at those locations consisted of only one species, with the notable exceptions being locations in South America, the eastern Indian Ocean and the western Pacific Ocean. On average, 57% of the functional entities are performed by a single species, suggesting that even a modest local loss of invertebrate diversity could have significant negative consequences for mangrove functionality and resilience, because invertebrates are crucial for the mangrove nutrient cycling and for oxygen provision to the tree roots and these functions will be lost with a decrease in functional diversity. Moreover, the low functional diversity of the resident invertebrates indicates that mangroves are among the most vulnerable ecosystems on the planet. Nonetheless, some small mangrove patches, such as those in Hong Kong and Mozambique, harbor multifunctional invertebrate assemblages that may serve as biodiversity reservoirs, which could prove critical for future conservation efforts. Mangrove trees can be replanted but the local invertebrate fauna needs to naturally recruit the newly replanted sites. Without faunal recruitment, mangrove will not be able to develop, due to the lack of nutrients and oxygen in the soil. By contrast, some large forests, such as those in Cameroon, were characterised by low invertebrate functional diversity. Taken together, the findings suggest that faunal functional diversity may be a better measure of mangrove resilience than the conventional indicator of forest size. One of the most important messages to take away from this study is that, although the mangroves in Hong Kong are very small, they are very diverse, and they are still home for a lot of species, which perform multiple functions in the environment. Therefore, the mangroves in Hong Kong are the last pristine, and natural mangroves in the Pearl River Delta, and they could be sources of populations that can re-populate mangroves even in mainland China. According to the authors, studying the functional diversity of the resident faunal assemblages is crucial for assessing the vulnerability of mangrove forests to environmental change and for designing effective management, conservation, and restoration plans. At present, the health and resilience of mangrove forests around the world are assessed through their overall increase in area. This approach, however, does not consider the real viability and functionality of those forests. A mangrove forest is not just a group of trees, but a complex ecosystem also built upon healthy faunal communities and on the interaction between such communities and the trees. Mangrove management and rehabilitation projects need to take into account not just the increase in size of a mangrove, but also the stability and redundancy of its faunal component. The findings were recently published in The Proceedings of the National Academy of Sciences (PNAS), the official journal of the National Academy of Sciences (NAS).  The journal paper can be accessed from here.    Invertebrate animals influence many ecological functions of mangrove forests, like the change in surface topography caused by the mounds of burrowing crustaceans at Sam A Chung, located in the northeastern part of Hong Kong. Photo credit: Joe S Y Lee A large number of crabs, such as this Metopograpsus frontalis, find food and shelter in mangrove forests. Photo credit: Stefano Cannicci Large crabs, such as Chiromantes haematocheir, constantly rework the sediment, providing nutrients and oxygen to the mangrove trees. Photo credit: Stefano Cannicci The local mangrove clam Geloina expansa is a filter-feeder but occupies the high-intertidal region of the mangrove forest where tidal inundation is infrequent. This clam has the amazing ability to remain alive for weeks out of water. Photo credit: Joe S Y Lee  

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Three academics from the Faculty of Science have been selected for Research Grants Council’s Senior Research Fellow Scheme and Research Fellow Scheme

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Sweeteners in common food: HKU-led research revealed hidden sources of non-nutritive and low-calorie sweeteners in pre-packaged foods in Hong Kong

Excessive intake of free sugars, defined by the World Health Organization (WHO) as “all monosaccharides (e.g. glucose and fructose) and disaccharides (e.g. sucrose) added to foods by the manufacturer, cook or consumer, plus the sugars that are naturally present in honey, syrups and fruit juices”, has been associated with many health problems, including obesity. Hence in a bid to curb the rise in the obesity epidemic, the WHO has released a new set of free sugar intake guidelines for adults and children in March 2015, which recommended a maximum intake of free sugars to less than 10% of total energy intake (e.g. ~50 g for a 2000 kcal /day diet); with a conditional recommendation of below 5% total energy intake. Since the release of the WHO guidelines, food manufacturers have been working voluntarily or under the government’s request to reduce the sugar content of their products. One way in doing so without significantly altering the taste profile of the reformulated products is to replace sugars with non-nutritive sweeteners (NNS) or low-calorie sweeteners (LCS), also known as sugar substitutes. Sugar substitutes are compounds that will provide the sweet sensation when consumed, but less calories for the same level of sweetness delivered. Commonly known examples of sugar substitutes include aspartame, stevia and sugar alcohols, in which, aspartame is synthetic while stevia and most sugar alcohols are both natural. Surprising food that contains sweeteners It is considered safe if the consumption of sugar substitute is under the acceptable daily intake (ADI), although some side effects may be present, e.g. laxative effect for sugar alcohols. However, a recent study led by Assistant Professor Dr Jimmy Chun Yu LOUIE, and BSc (Food and Nutritional Sciences major) graduate Mr Billy Yin Sing O, both from the Research Division for Molecular & Cell Biology of The University of Hong Kong (HKU) audited the use of sugar substitutes in ~20,000 pre-packaged foods in Hong Kong, and found that sugar substitutes are present in much more types of products than the risk assessment modelling designed by the Centre for Food Safety assumed. This audit is the first-of-its-kind in Hong Kong. The team examined 20 different types (see note 1) of NNSs and LCSs, of the 12 NNSs examined, 10 were found and 2 were not found; of the 8 LCSs examined, all were found. The study revealed that sugar substitutes are not only used in low-calorie/diet products, but also in regular products. Even more surprising is the discovery that a sizable proportion (15-20%) of savoury snacks such as potato chips and extruded snacks also contained at least one non-nutritive or low-calorie sweeteners in their formulation. Also, Asian prepackaged foods were more likely to contain NNSs/LCSs (10.1%) compared with those from other regions. The study suggests that the popularity of using sugar substitute in common food products may increase the risk of going above the limit of ADI. For example, a person has to drink 14 cans of diet coke to go above the ADI if he only consumed aspartame in diet coke, but now aspartame may also be found in many other common food products, therefore the risk of going above the ADI is higher, which may increase the potential risk for health problem. Potential impact is still uncertain Results of this study echo the findings of similar studies in other countries (see note 2) that the use of non-nutritive and low-calorie sweeteners has become increasingly common, and had extended beyond low-calorie/diet products. That could be a public health concern due to their higher consumption frequencies than “diet” products and suggests the current risk assessment modelling is likely to underestimate the population’s exposures to non-nutritive and low-calorie sweeteners. Consumers should be better educated on label reading (see note 3) to assist them in making informed choices. “Until more prominent labelling schemes, e.g. front of package warning labels are put in place, consumers should actively look out for the names and/or E-codes of sugar substitutes on the ingredients list of pre-packaged products to identify these hidden sugar substitutes,” said Dr Louie. Sugar substitutes Information Proportion of audited products containing it Sucralose E955 A chemically modified form of sucrose which is non-digestible and non-absorbable by humans, thus providing 0 calories. Commonly sold under the brand Splenda®. It’s about 300-1000 times sweeter than sucrose. 1.9% Acesulfame K E950 A heat stable synthetic sugar substitute which is zero calorie. It has a slightly bitter aftertaste; and is about 200 times sweeter than sucrose. 1.6% Aspartame E951 Aspartame is a synthetic compound which contains two amino acids, namely aspartic acid and phenylalanine, joint together as a methyl ester. In the body it is broken down into its constituent amino acids and a methanol molecule, and hence technically is provides 4 kcal/g. But since it’s about 200 times sweeter than sucrose, with the amount typically used the caloric contribution is negligible. 1.3% Stevia E960 Stevia, also known as steviol glycosides, is a natural sugar substitute derived from the stevia plant. It is not metabolized by the human body and hence provides 0 calories. It’s about 200 times sweeter than sucrose. 1.0% Sorbitol E420 It is a sugar alcohol which is about 60% as sweet as sucrose. It provides ~2.6 calorie per gram and is metabolized slowly compared with sucrose. 2.9% Maltitol E965 It is a sugar alcohol which provides ~2.5 calorie per gram for similar amount of sweetness (75-90%) as sucrose, and hence is used to replace sucrose in food products. 0.6% Some sugar substitutes examined in the research   Categories most likely to contain sugar substitutes. Assistant Professor Dr Jimmy Chun Yu LOUIE(on the left), and BSc graduate Mr Billy Yin Sing O from Research Division for Molecular & Cell Biology from HKU Science.   Note 1. The Artificial NNSs examined in the study include: E950, E969, E956, E951, E962, E952, E954, E955, E961, E959. Natural NNSs include E960 and E957. All LCSs examined could be considered natural. Note 2. Relevant studies from other countries: Types and Amounts of Nonnutritive Sweeteners Purchased by US Households: A Comparison of 2002 and 2018 Nielsen Homescan Purchases Non-Nutritive Sweeteners in the Packaged Food Supply-An Assessment across 4 Countries The major types of added sugars and non-nutritive sweeteners in a sample of Australian packaged foods Note 3.The Centre for Food Safety of Hong Kong has published “The Consumer Guide to Food Additives” which contains a list of the names and E-codes of sugar substitutes permitted for use in Hong Kong.  The journal paper can be accessed from here .

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HKU Team Paves the Way for Learning what Ancient Birds Ate

The diet of animals is an important part of understanding how they behave and what roles they play in the world. This is more difficult to know in fossil animals because they rarely preserve all of the information we would need. Reconstructing the diet of fossil birds has been especially hard as they have small, fragile bodies that are challenging to preserve. Our current knowledge of fossil bird diet heavily relies on rare instances where food was preserved inside their fossilised bodies. Of the over 150 species of birds currently known from the Mesozoic Era, the period of Earth’s history when dinosaurs ruled the Earth, only 7 species have any sort of food preserved in their stomachs (Fig. 1). HKU PhD student Case Vincent MILLER and his supervisor Research Assistant Professor & Assistant Dean (e-learning) Dr Michael PITTMAN (Vertebrate Palaeontology Laboratory, Research Division for Earth and Planetary Science & Department of Earth Sciences) want to change this. The duo reviewed more than 1,000 publications on animal diet, with a special focus on birds and non-avian dinosaurs, while also incorporating innovations from other fields including medicine and materials science. In the end, they produced a framework of seven techniques to combine for determining fossil bird diet (Fig. 2). Dr Pittman notes, “As a scientist, it is risky to rely on only a single line of evidence. It’s when you find several that agree that you can better support your conclusions.” Very little quantitative work has been done on fossil bird diet, the team reports, but in the review they identified some fossil birds with previously-unrecognised agreement on their diet. The first is Shenqiornis, an Early Cretaceous enantiornithine “opposite bird” from northern China. The shape of its claws and the mechanics of its jaws (Fig. 3) point to it being a carnivore. The second is Confuciusornis (Fig. 4), one of the first beaked fossil birds, which is known from hundreds of specimens from the Early Cretaceous of northern China. Two different mechanical metrics of its jaw, including one Miller and Pittman studied last year (see note 1), found it suited for eating plants. The duo note that the diet of the earliest undisputed bird, Archaeopteryx, is still uncertain despite several quantitative studies looking at it. The studies contradict one another, which may mean that different individuals of Archaeopteryx ate different things. The team’s next goal is to apply their framework to groups of fossil birds whose diets remain unstudied. “When I started my PhD, I planned on studying the diet of obscure bird groups that scientists still hadn’t figured out,” Miller said. “But to my surprise, scientists hadn’t figured out the diet of most fossil birds! I’ve identified several families of Mesozoic birds with interesting dietary hypotheses to test during my PhD. Preliminary application of our framework to one of those families managed to narrow their diet possibilities from five down to two, and increase the number of known fossil bird diets by almost 20%. To anyone interested in the ecology of Mesozoic birds and the origins of today’s bird diversity, I would say the future looks very bright.” Simplified family tree of birds. All seven fossil birds with meals fossilised in their stomachs are colour coded. The other 150+ named species of Mesozoic birds do not preserve any meals. Image credit: Case Vincent Miller & Michael Pittman, silhouettes from phylopic.org   Simplified version of the framework proposed by Miller & Pittman. From left to right: name of the technique, brief description, and what it can tell about diet. See Figure 8 of the published paper for a more detailed version. Image credit: Case Vincent Miller & Michael Pittman   Evidence of carnivory in the enantiornithine bird Shenqiornis. The skull (left) is adapted to close quickly and catch fast-moving prey. The foot claws (right) are curved and adapted for holding struggling prey. Image credit: Case Vincent Miller & Michael Pittman.   The paper is published in Biological Reviews and can be accessed here .  

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HKU biologists identify and demonstrate a naturally abundant venom peptide from ants that activates a previously unknown pseudo allergic pathway, unravelling a novel immunomodulatory pathway of MRGPRX2

Ants are omnipresent, and we often get blisters after an ant bite. But do you know the molecular mechanism behind it? A research team led by Professor Billy K C CHOW from the Research Division for Molecular and Cell Biology, Faculty of Science, the University of Hong Kong (HKU), in collaboration with Dr Jerome LEPRINCE from The Institut national de la santé et de la recherche médicale (INSERM) and Professor Michel TREILHOU from the Institut National Universitaire Champollion in France, have identified and demonstrated a novel small peptide isolated from the ant venom can initiate an immune pathway via a pseudo-allergic receptor MRGPRX2. The study has recently been published in a top journal in Allergy – The Journal of Allergy and Clinical Immunology. Allergy is a common undesirable immune response for most people, and are often caused by allergens such as food, pollen, drugs, mites, bites and stings from venomous insects etc. When an allergic reaction happens, mast cells that line the body surfaces alert the immune system by releasing cytokines. Thus, other immune cells are recruited to the infected area to clear the allergens. There are two kinds of allergic reaction: allergic and pseudo allergic reactions. Allergic reactions are triggered when allergens bind to the high-affinity IgE receptor on mast cells, whereas the pseudo allergic reactions are majorly triggered when allergens bind to MRGPRX2 on mast cells. Therefore, different medical treatments are required to contain them. Recently, the discovery of IgE and MRGPRX2 expressed receptors in mast cells has helped us to understand the root cause of most allergic and pseudo allergic reactions. However, functional characterisation of MRGPRX2 is very limited since it has not got much attention in the allergic field as a pseudo allergic receptor until recently, whereas the former is very well studied. The function of MRGPRX2, other than being a pseudo allergic receptor, is largely unknown and yet to be explored. For instance, pseudo allergic reactions can be induced by various FDA approved drugs. So, understanding this pseudo allergic mechanisms will help in developing drugs without side effects. In addition, understanding of pseudo allergic reactions will also help in developing antagonists that would minimise clinically relevant MRGPRX2 mediated allergic reactions such as rosacea or red man syndrome. Through concerted efforts, our research team identifies and demonstrates a naturally abundant venom peptide from ants that activates a previously unknown pseudo allergic pathway, which in turn, help to discover other function of MRGPRX2, sheding light on the non-pseudo allergic function of MRGPRX2. Research background Insect venoms are biochemical arsenals developed by animals to defend themselves. Interestingly, arthropods contain the maximum number of species capable of making venoms that can produce biological effects in our body. Particularly, ants are the most dominant and diversified species with more than 14,700 known species and the biggest biomass in most territorial ecosystems. Therefore, Insect venoms are very important resources for us containing a treasure of biologically active chemicals, peptides and proteins. For instance, Purotoxin-1 (PT1), Apamin and Bicarinalin are bioactive peptides isolated from various insect venoms that are known to play a role in inflammatory pain, antimicrobial effects and cytotoxic effects against cancer cells. P17 is a short host defence peptide isolated from the venom of an ant Tetramorium bicarinatum. We have recently demonstrated its involvement in our body defence system via interacting with an unknown receptor to activate the immune system to kill the fungal infection in mice lungs. P17, therefore can be exploited as a therapeutic peptide for inflammatory disorders or cancer and pseudo allergic reactions. In this study, after screening almost the entire human G protein-coupled receptor repertoire, we have successfully identified a specific human receptor or Mas-related G protein–coupled receptor-X2 (MRGPRX2) that is responsible for interacting with P17 to carry out its activity. Key findings The research team has extensively worked on identifying a lock (GPCR) for a key (P17) by trying about 400 locks for a single key and eventually identified the GPCR for P17. In addition, we also demonstrated the molecular pathways of P17-MRGPRX2 mediated activation of mast cells, an immune cell that is responsible for the allergic reaction. Upon deorphanising of P17, we then used computational approaches to find the important amino acids (ridges in the key) that are important for the binding of the venom peptide with its receptor - like a key ridge in the key for a lock. Our team then uncovered a novel pathway for this receptor. We showed P17 induces infiltration of monocytes at the injected site by activating MRGPRX2. The effect is quite similar to an ant bite in humans. Once the ant bites you, you will have blisters/swelling, which indicates the immune cell infiltration at the bite site to remove the ant venom. Usually, our body detects the external substances (arrows in the diagram) via receptors (targets) and act upon those external substances to clear them out. In this scenario, P17 is the arrow detected by MRGPRX2 of mast cells to recruit monocytes and differentiates them into macrophages to engulf and clear the pathogens. To the best of our knowledge, we demonstrated for the first time that MRGPRX2 mediated activation of mast cell could recruit human monocyte and differentiate them into macrophages. This study shows a novel immunomodulatory effect of MRGPRX2 and suggests that it is a vital receptor in innate immunity. Societal impact of the findings Firstly, a novel immunomodulatory pathway of MRGPRX2 has been demonstrated, which could enhance the overall understanding of the receptor function among the scientific community. Additionally, Macrophages are specialised cells involved in the detection, phagocytosis and destruction of bacteria and other harmful organisms. Thus, using this novel information, we can design new analogues that are agonists or antagonists of MRGPRX2 to modify our immune response to deal with host defence, allergic or other immune diseases. “We demonstrated that peptides isolated from venoms can be used to modulate immune responses and these peptides are abundant in nature. One key message we should take from this finding is biodiversity is one of the greatest treasure we have and we just have to use them wisely,” says Professor Chow. “Our findings are evident that novel scientific innovations come from observing the nature. Ant bite leads to immune cell infiltration, so we just isolated the peptide that recruits the immune cells that can be beneficial,” says Dr Duraisamy.  Besides, the HKU team’s laboratory has established a platform for translating basic biology into novel drug discoveries as we already have filed a patent for the design and synthesis of a group of drugs with high efficacies to translate them into societal impact. Using this novel pathway we could eventually tweak it a bit to our benefit to kill off pathogens during infection. Schematic diagram depicting the overall pathway involved in MRGPRX2 mediated monocyte recruitment and differentiation. Research Team: The research was conducted by the team led by Professor Billy KC CHOW from the Research Division for Molecular and Cell Biology. Dr Karthi DURAISAMY from Professor Chow’s group is the first author of the paper, while Dr Jérôme LEPRINCE is the co-corresponding author of the paper. Professor Michel TREILOU, Dr Elsa BONNAFÉ, Dr Kailash SINGH, Mr Benjamin LEFRANC and Mr Mukesh KUMAR contributed to the research. The research has been supported by various grants from the Research Grants Council of Hong Kong and European Regional Development Fund. This work was supported by HK government RGC Grant GRF 1711320 and 17111421, NSFC/RGC and HKU seed fund for basic research 201910159222 to BKCC. Institut National de la Santé et de la Recherche Médicale (Inserm), the Normandy University (Rouen), the Region Normandy, the European Union (PHEDERCPG and 3R projects) and Europe gets involved in Normandy with European Regional Development Fund (ERDF) to JL. About Professor Chow: Professor Billy KC Chow focuses on novel therapeutic molecules for the treatment of major critical diseases that involves GPCRs. Using his years of experience in basic research, he has founded a start-up company PhrmaSec Ltd, which aims to translate basic research into major societal impact.  His expertise lies in GPCRs in general with GPCR physiological functions, and target receptor identification and their molecular mechanisms of novel bioactive agents. Click here for more information about Professor Chow and his research group: The research paper can be accessed from here.     

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HKU Ecologists develop a novel forensic tool detecting laundering of critically endangered cockatoos

It is possible that some of the Yellow-crested Cockatoos for sale in the bird market could have been taken from Hong Kong’s free-flying population of cockatoos. Photo courtesy of Astrid Andersson Ecologists from the Conservation Forensics Laboratory of the Research Division for Ecology and Biodiversity at The University of Hong Kong (HKU) have applied stable isotope techniques to determine whether birds in the pet trade are captive or wild-caught, a key piece of evidence required in many cases to determine whether a trade is legal or not. They have applied this technique to the yellow-crested cockatoo (Cacatua sulphurea, YCC), a critically endangered species from Indonesia/Timor-Leste with a global population of fewer than 2,500, according to the International Union for the Conservation of Nature (IUCN). Threatened by overexploitation for the pet trade, Hong Kong has a sizeable population of 150-200 individuals which was established through the release of birds transported here as pets.  There is a global ban on trapping and international trade of wild-caught YCCs; the species has been listed on Appendix I of the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES) since 2005. In Hong Kong, it is legal in some cases to sell captive-bred birds, however it is difficult to differentiate a wild-caught from a captive-bred cockatoo just by eye - which means illegally caught YCCs can be laundered in the legal market by claiming they have been bred in captivity. Yellow-crested cockatoos are commonly sold as pets in Hong Kong. Dr Astrid ANDERSSON from the Conservation Forensics Laboratory conducted a market survey at Yuen Po Street bird market in Mong Kok from 2017-2018 and observed 33 unique individual YCCs for sale during this period, more than have officially been imported to Hong Kong since 2005 (10 individuals). These birds could have been bred by home breeders (which is a legal grey area in Hong Kong), trafficked from abroad (illegal) or taken from Hong Kong's free-flying, introduced population of YCCs (illegal). In order to determine whether birds in trade are legal or not, there is a need for a method for determining whether an individual is sourced from the wild or captive-bred.  Under the supervision of Dr Caroline DINGLE, Director of Conservation Forensics Laboratory, Dr ANDERSSON conducted stable isotope analysis(SIA) and compound-specific stable isotope analysis(CSIA) on feathers from Hong Kong's wild YCC population and on feathers from pet cockatoos owned by private individuals to see if differences in the diet of captive and wild birds were reflected in carbon and nitrogen values. The team applied two novel forensic tools: stable isotope analysis (SIA) as the basic first step and compound-specific stable isotope (CSIA), which analyzes isotope values associated with specific amino acids, as the advanced second step. They found that both stable carbon and nitrogen isotope values differed significantly between wild and captive cockatoos, indicating consumption of different plant and protein types in their diets. They also found that the isotopes associated with six amino acids differed significantly - with valine being the most informative. Enforcement officials could apply this test in the future to determine whether a cockatoo has been raised in the wild or in captivity.  "Legal wildlife trade creates opportunities for the sale of illegally procured wildlife since it is difficult to discern legal from laundered items. This problem is common across many wildlife trade areas - exotic pets, ornaments, seafood - and involves a variety of taxa. Our results show that SIA, together with CSIA, presents a powerful tool for government authorities in their efforts to regulate wildlife trade," says Astrid Andersson, the first author of the study.  "The successful and novel application of CSIA as a secondary validation step to increase the accuracy of SIA for detecting wild vs captive individuals is promising and adds to the growing volume of research that demonstrates the applicability of stable isotope techniques in wildlife forensics. While more work needs to be done to validate SIA as a robust forensic test, the results from this study show that this is a promising avenue for continued research," adds Dr Caroline Dingle. The journal paper can be accessed from here.   

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Songbirds like it sweet! A research co-developed by HKU Evolutionary Biologist found that Songbird ancestors evolved a new way to taste sugar

A New Holland honeyeater (Phylidonyris novaehollandiae) perched on a banksia in Western Australia. Photograph by Gerald Allen (Macaulay Library 340326621). Humans can easily identify sweet-tasting foods - and with pleasure. However, many carnivorous animals lack this ability, and whether birds, descendants of meat-eating dinosaurs, can taste sweet was previously unclear. An international team of researchers led by Max Planck Institute for Ornithology including Dr Simon SIN from Research Division for Ecology and Biodiversity, The University of Hong Kong (HKU), has now shown that songbirds, a group containing over 4,000 species, can sense sweetness regardless of their primary diets. The study highlights a specific event in the songbird ancestors that allowed their umami (savoury) taste receptor to recognise sugar. This ability has been conserved in the songbird lineage, influencing the diet of nearly half of all birds living today. Bitter, salty, sweet, sour and umami are the five basic tastes that we humans perceive. The sense of taste has an enormous influence on our diet - what we think tastes good often ends up on our plates. The rest of the animal kingdom is no different, as taste reliably helps to distinguish what is nutritious from what is poisonous. But what exactly do other animals taste? It is well known that the sweet taste receptor is widespread among mammals. Birds, however, descend from carnivorous dinosaurs and lack an essential subunit of this receptor - presumably leaving most unable to detect sugar. The only known exception are the hummingbirds, who re-purposed their umami taste receptor to recognise carbohydrates. But are all other birds unable to taste sugars? First, the researchers from the international team systematically studied the diets of birds. Certain songbird lineages, such as sunbirds, sugarbirds, and honeycreepers, are known to regularly consume large quantities of nectar. However, the team found an above-average number of other songbird species across the entire radiation that occasionally consume nectar or fruit. "This was the first hint that we should concentrate on a range of songbirds, not only the nectar-specialised ones when searching for the origins of avian sweet taste," explains Dr Maude BALDWIN, an evolutionary biologist from the Max Planck Institute for Ornithology who led the research. Indeed, their behavioural experiments showed that both a nectar specialist as well as a grain-eating songbird preferred sugar water to regular water. The researchers dug deeper and found that the umami receptors of nectar specialist honeyeaters, as well as those of other songbirds with varying diets, also respond to sugar. They concluded that songbirds really do sense sweetness and, like hummingbirds, use the umami receptor to do so. To identify the origin of this ability, the researchers reconstructed ancestral umami receptors at different locations on the songbird family tree. It turned out that the early ancestors of songbirds evolved the ability to sense sugar, even before they radiated out of Australia and spread across the planet. "We were very surprised by this result. Sweet perception emerged very early within the songbird radiation and then persisted even in species that do not rely primarily on sugary food," says Dr Baldwin. In addition to the timing of the sensory change, the researchers were able to uncover its molecular basis. By comparing the sugar-indifferent and sugar-responding receptor sequences, they identified the modifications enabling sweet perception. Interestingly, these exact changes coincide only slightly with those seen in the distantly-related hummingbirds, even though similar areas of the receptor are modified. So, over evolutionary time, these distant bird groups converged on the same solution of re-purposing their umami taste receptors to sense sugar. However, each group modified the receptors in distinct ways to achieve the same outcome. "It is intriguing that hummingbirds and songbirds convergently evolved to taste sugar, but via different ways. This is an important study that shows how different evolutionary pathways could lead to the same adaptation," says Dr Sin. The journal paper can be accessed here.  (This article was derived from the press release originated by Max Planck Institute for Ornithology)

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HKU Chemist Professor CHE Chi Ming being awarded of the Silver Bauhinia Star

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From flat screen to nature via birding: HKU Ecologist and the Hong Kong Bird Watching Society jointly developed a Mobile App "HKBirds: Birds of Hong Kong", facilitating a bird-watching learning platform

Red-whiskered Bulbul, a common and widely distributed Hong Kong resident usually seen in woodland, open country and urban areas.                                              Photo credit: Hong Kong Bird Watching Society Nowadays, citizens often stick to the flat screens of mobile phones. To reconnect people in the city with nature through their mobile devices, the School of Biological Sciences of The University of Hong Kong (HKU) and the Hong Kong Bird Watching Society jointly developed the iOS app "HKBirds: Birds of Hong Kong". The app facilitates observation, identification, recording and sharing of bird records at anytime and anywhere. It encourages users to observe and reconnect with nature, raises public awareness on biodiversity and enhances appreciation of nature. The app is available for free download worldwide and acts as a field guide for the birds of Hong Kong. Mr LAU Wai Man, Chairman of Hong Kong Bird Watching Society said, "This mobile application records over 40% (240 species) of the birds in Hong Kong. It provides detailed information, including characteristics, habitats, conservation status, bird calls, etc. The public can also systematically record their observations in the app, which makes this app a comprehensive learning platform." The project coordinator, Dr Billy HAU from HKU School of Biological Sciences added, "Urban populations have been growing fast worldwide. Apart from protecting biodiversity in the natural environments, promoting biodiversity conservation in urban environments has become a global trend in recent years. This app facilitates Hong Kong people to learn more about the diverse bird fauna of Hong Kong and enables knowledge exchange." “HKBirds: Birds of Hong Kong” is a Mobile App under the project titled "From Flat Screen to Nature via Birding", which is supported by HKU Knowledge Exchange Fund. Technical support of the Mobile App is provided by HKU Department of Computer Science. The Mobile App can be downloaded from here Home page of "HKBirds: Birds of Hong Kong" can be access from here   Information of over 240 bird species are available in the app, covering most of the common species found in Hong Kong. The App provides detailed information about each bird species, including size, characteristics, habitats, conservation status and bird calls to assist learning. The public can systematically record their observations and birding experience in the app.      

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Hong Kong-based space expert Professor Quentin Parker Welcomed the new horizons for humanity in space

      2021 is a dreamy year for China. On the 17th June 2021, China's Shenzhou-12 spaceship launched and delivered the first crew to the Tianhe module, the first module of the Tiangong space station and China's first self-developed space station. Having plans to launch more missions, China targets to complete its space station by the end of 2022.  As a Hong Kong-based space expert, Professor Quentin PARKER, Director of Laboratory for Space Research at HKU,  is delighted to see increasing role of China in space mission. In his recent media interview, he said to SCMP: "China has clearly demonstrated that it has the technical capacity to launch very sophisticated missions, and it is getting more sophisticated and technically accomplished."   Professor Parker stressed that he welcomed the new horizons for humanity in space and appreciated China’s positive attitude and willingness to open up its own space station for international experiments and countries all around. "We care most about trying to move the frontiers of science forward through discoveries. And we believe that if you're collaborating, any kind of collaboration is good," he added.  Being impressed by the capacity of China, he also expressed his excitement about this "space competition". "I am excited. It's not every day that anybody puts up a new space station," said Professor Parker in another interview with CBS. "They really are serious, I believe, in wanting to emerge as a very senior science power for the benefit of all mankind, not just China."               Media Highlights  頭條日報 港大首推中學生「太空計畫」28-Jun-2021 China Plus:  Podcast: What's driving China's space exploration?25-Jun-2021 China Daily:  Scientists hail HK's role in space missions24-Jun-2021 RTHK: China’s manned space mission 18-Jun-2021 South China Morning Post:  Podcast: Building China's new space station, Beijing's moon base plans and its growing space industry24-Jun-2021 Ahead of Chinese space station mission, a call for more collaboration17-Jun-2021 Meet the astronauts set to blast off on first Chinese space station mission17-Jun-2021 CBS News: Will China's fast pace in the space race fuel U.S. ambitions? 17-Jun-2021          

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PhD Candidate from School of Biological Sciences won the Constance Boone Award for best student presentation at American Malacological Society

Kanmani Chandra RAJAN, a PhD Candidate Dr Thiyagarajan Vengatesen at The Swire Institute of Marine Science(SWIMS), Research Division for Ecology and Biodiversity and School of Biological Sciences, has won a Constance Boone Award for best student presentation at American Malacological Society virtual annual meeting 2021 on June 18, 2021, the presentation is mainly based on her research journal "Molecular adaptation of molluscan biomineralisation to high-CO2 oceans - The known and the unknown." and "Oyster biomineralization under ocean acidification: From genes to shell". Students’ oral and poster contributions are evaluated based on the clarity of the presentation and the abstract, scientific merit, and the student’s ability to answer questions concerning the presentation. Ms Rajan was also the winner of  the "Online People’s Choice Award" of the HKU Three Minute Thesis (3MT) Competition in 2020. for her thesis “How to Save Oysters from Ocean Acidification?”, which gave a general overview of her PhD research, you may review her 3MT presentation from here.  The Constance Boone Award For Best Student Presentation is named for the late Constance Boone, a past president of American Malacological Society, who was also the past president of the Houston Conchological Society, co-editor of Texas Conchologist. Constance Boone was a long-time associate in the Malacology Department of the Houston Museum of Natural Science, a strong supporter of students, and was a vital force in American Malacology.          

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HKU scientists reveal silver-based antimicrobials can be utilised as antibiotic adjuvants to combat antibiotic resistant Staphylococcus aureus

A research team led by Professor Hongzhe SUN, Norman & Cecilia Yip Professor in Bioinorganic Chemistry and Chair Professor from Research Divison for Chemistry and Department of Chemistry, Faculty of Science, in collaboration with Dr Richard Yi-Ysun KAO, Associate Professor from the Department of Microbiology, Li Ka Shing Faculty of Medicine, and Dr Aixin YAN, Associate Professor from School of Biological Sciences, The University of Hong Kong (HKU), discovers that silver (Ag)-based antimicrobials can effectively combat antibiotic resistant Staphylococcus aureus by targeting multiple biological pathways via functional disruption of key proteins and can be further exploited to enhance the efficacy of conventional antibiotics as well as to resensitize methicillin-resistant Staphylococcus aureus (MRSA) to antibiotics. The study resolves the long-standing question of the molecular targets of silver in Staphylococcus aureus and offers insights into the sustainable bacterial susceptibility of silver, providing a new approach for combating antimicrobial resistance. The ground-breaking findings are now published in a leading multidisciplinary science journal, Nature Communications. Background Antibiotics are medicines designed to kill bacteria and treat bacterial infections. Antibiotic resistance occurs when bacteria adjust in response to the misuse or overuse of these medicines, and it has become one of the biggest public health challenges in this era. At least 2.8 million people get an antibiotic-resistant infection annually in the US, and more than 35,000 people die from it. Staphylococcus aureus, a round-shaped Gram-positive bacterium, is a dangerous and versatile pathogen for humans and is estimated that approximately 30% of the human population are asymptomatic nasal and long-term carriers. Staphylococcus is the causative agent of a variety of diseases, such as skin infection, food poisoning, bone/joint infection, and bacteremia, ranging from subacute superficial skin infection to life-threatening septicemia. The rise in incidence has been accompanied by an increase in antibiotic-resistant strains, especially MRSA. Moreover, the outbreak of the Coronavirus Disease 2019 (COVID-19) pandemic may further increase antimicrobial resistance due to the heavy use of antibiotics to treat patients infected with Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-COV-2). Given the rapid emergence of drug-resistant Staphylococcus aureus but a lack of antibiotic-development pipeline, alternative strategies are urgently needed to combat antibiotic-resistant Staphylococcus aureus. Key findings Metal ions have been historically used as antimicrobial agents owing to their inherent broad-spectrum antimicrobial properties and less chance of resistance. There is a growing interest in revitalizing metal-based compounds as promising alternatives to tackle the antimicrobial resistance crisis. Silver ions (Ag+) and silver nanoparticles (AgNPs) have been used as antimicrobial agents for centuries and are still being widely used in the healthcare and food industry. Previously, the team has built a technical platform named LC-GE-ICP-MS to systematically identify Ag+-proteome in Escherichia coli and developed a strategy named metabolome reprogramming to enhance the efficacy of antibacterial metallodrugs (PLoS Biol., 2019, 17, e3000292; Chem. Sci., 2019, 10, 7193-7199; Chem. Sci., 2020, 11, 11714-11719). In this study, using the customized approach of LC-GE-ICP-MS, the team successfully separated and identified 38 authentic Ag+-binding proteins (Ag+-proteome) in Staphylococcus aureus at the whole-cell scale. In combination with bioinformatics analysis and systematic biochemical characterization, they demonstrate that Ag+ exploits a shotgun action through targeting multiple proteins, thus interfering with multiple pathways, including glycolysis, oxidative pentose phosphate pathway (oxPPP), and reactive oxygen species (ROS) stress defence system, to exert its bactericidal effect against Staphylococcus aureus. Further studies unveiled that oxPPP served as a vital pathway targeted by Ag+ in Staphylococcus aureus, with 6PGDH identified as the key enzyme involved in the inhibitory effects of Ag+ against Staphylococcus aureus. They resolved the first crystal structures of 6PGDH from Staphylococcus aureus both in substrate-bound and Ag-bound forms and revealed that Ag+ abolished the enzymatic activity of 6PGDH through targeting Histidine 185 in the active site and morphing its catalytic pocket. This study resolves the long-standing question on the molecular targets and mode of action of silver against Staphylococcus aureus. Such a unique mode of action of silver via targeting multiple pathways confers the inability to select silver-resistant Staphylococcu aureus and endows it with the sustainable efficacy against Staphylococcus aureus. Based on the uncovered molecular mechanism, they further demonstrate that Ag+/AgNP can potentiate the efficacy of a broad range of antibiotics, resensitize MRSA to antibiotics, and slow down the evolution of antibiotic resistance in Staphylococcus aureus. Therefore, a combination of antibiotics with silver or other metal-based compounds or nanomaterials could serve as a promising strategy to suppress the selection effects of antibiotics, thus preventing the occurrence of primary antibiotic resistance and extending the lifespan of conventional antibiotics to relieve the current crisis of antibiotic resistance. About the research team The research was conducted by a team led by Professor Hongzhe SUN, Norman & Cecilia Yip Professor in Bioinorganic Chemistry and Chair Professor of Department of Chemistry. Dr Haibo WANG is the first author. Other scientists contributing to the research include Dr Richard Yi-Ysun KAO, Associate Professor (Microbiology), Dr Aixin YAN, Associate Professor (Biological Sciences), Dr Hongyan LI, Senior Research Assistant (Chemistry), Dr Minji WANG, Associate Professor (Chemistry, East China Normal University), Dr Xiaohan XU, PhD student (Chemistry), Dr Peng GAO, Research Assistant Professor (Microbiology), Dr Zeling XU, Associate Professor (South China Agricultural University), and Dr Qi ZHANG (Chemistry). The work was supported by the Research Grants Council of Hong Kong, Health and Medical Research Fund and Seed Fund for Basic Research. About Professor Hongzhe SUN Professor Hongzhe SUN is the Norman & Cecilia Yip Professor in Bioinorganic Chemistry and Chair Professor from Research Division for Chemistry and Department of Chemistry at HKU. His research focuses on metalloproteins, the discovery of antimicrobial agents, and inorganic chemical biology. Professor Sun has published a series of well-recognized work in overcoming antimicrobial resistance against superbugs, developing anti-coronavirus agent, and understanding the functions of metalloproteins.  More information about Professor Hongzhe SUN and his research group can be found from their group’s webpage: http://www.bioinorg-chem.hku.hk About the research paper: https://www.nature.com/articles/s41467-021-23659-y (a) Exploration of Ag+-binding proteins in the soluble fraction of S. aureus with LC-GE-ICP-MS. (b) The overall structure of Ag-bound 6PGDH. (c) Silver coordination sites in 6PGDH and silver cluster composed of four adjacent Ag ions. (d) Diagram showing that Ag+ kills S. aureus by targeting multiple essential pathways. (e) Isobolograms of the combination of conventional antibiotics and Ag+ against S. aureus Newman. (f) Resistance acquisition curves during serial passage with the subinhibitory concentration of ampicillin or combination of ampicillin and Ag+ against S. aureus Newman.

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HKU first-year physics PhD student obtained the Higgs mode via dimensional crossover in quantum magnets which reveals importance of dimensions in many-body systems

In 2013, François ENGLERT and Peter HIGGS won the Nobel Prize in Physics for the theoretical discovery of a mechanism that contributes to our understanding of the origin of mass of subatomic particles, which was confirmed through the discovery of the predicted fundamental particle by the A Toroidal LHC Apparatus (ATLAS) and the Compact Muon Solenoid (CMS) experiments at The European Organization for Nuclear Research (CERN)'s Large Hadron Collider in 2012. The Higgs mode or the Anderson-Higgs mechanism (named after another Nobel Laureate Philip W ANDERSON), has widespread influence in our current understanding of the physical law for mass ranging from particle physics - the elusive “God particle” Higgs boson discovered in 2012 to the more familiar and important phenomena of superconductors and magnets in condensed matter physics and quantum material research. The Higgs mode, together with the Goldstone mode, is caused by the spontaneous breaking of continuous symmetries in the various quantum material systems. However, different from the Goldstone mode, which has been widely observed via neutron scattering and nuclear magnetic resonance spectroscopies in quantum magnets or superconductors, the observation of the Higgs mode in the material is much more challenging due to its usual overdamping, which is also the property in its particle physics cousin – the elusive Higgs boson. In order to weaken these damping, two paths have been suggested from the theoretical side, through (1) quantum critical points and (2) dimensional crossover from high dimensions to lower ones. For (1), people have achieved several remarkable results, whereas there are few successes in (2). To fulfil this knowledge gap, from 2020 Mr Chengkang ZHOU, then a first-year PhD student, Dr Zheng YAN and Dr Zi Yang MENG from the Research Division for Physics and Astronomy of The University of Hong Kong(HKU), designed a dimensional crossover setting via coupled spin chains. They applied the quantum Monte Carlo (QMC) simulation to investigate the excitation spectra of the problem. Teamed up Dr Hanqing WU from the Sun Yat-Sen University, Professor Kai SUN from the University of Michigan, and Professor Oleg A STARYKH from The University of Utah, they observed three different kinds of collective excitation in the quasi-1D limit, including the Goldstone mode, the Higgs mode and the scalar mode. By combining numerical and analytic analyses, they successfully explained these excitations, and in particular, revealed the clear presence of the Higgs mode in the quasi-1D quantum magnetic systems. All these results not only can help us find out the key model parameters of the material but also show us a picture of how dimension matters in the condensed material. These research finding has recently been published in one of the most prestigious journals in the field of physics – Physical Review Letters. Background The quantum materials have been embedded in our daily life, such as various electronic components, computer chips, and solar panels. With the fast development of science and technology, the understanding and manipulation of the quantum many-body interactions in the materials are playing a more and more important role. Such a tendency has already shown its first sign. For example, the 2D quantum moiré materials, such as the magic angle twisted bilayer graphene, have attracted much attention and show their novel performance in realising superconductivity in Carbon-based instead of the traditional silicon-based materials. Moreover, quantum computer tech, which is based on the theory of superconductivity and even topology is rapidly developing to build more efficient computer chips beyond Moore’s law. Along with these efforts, the research on quantum magnets is one of the most important objects, in which the detection of the Higgs mode and the Goldstone modes can reveal the underlying model parameters of the material. However, since the interaction of billions of electrons must be considered, it is hard to point out a clear picture of several quantum many-body systems via quantum mechanics directly. Therefore, numerical methods, such as the QMC simulation, have become useful techs to study quantum many-body systems. These numerical methods can tell us useful information and properties of quantum many-body systems and show the micro mechanism of these systems. This information would stimulate the development of the theory as well as guiding the experimental design, which would help the scientists and engineers to find out more novel quantum materials and components. The Higgs mode via dimensional crossover To study the micro mechanism in quantum many-body systems, numerical physicists usually come up with a simple model based on theoretical understanding and experimental data. Then, they apply numerical simulation methods to study the model in reasonable parameters region. Such a research procedure has been used in the investigation of the Higgs mode in the quantum magnets, yet its observation is still challenging due to its usual overdamping feature. From the quantum-theoretical side, scientists have suggested two paths. The first is through the quantum critical point. On this path, there are several remarkable results, including the signal of the Higgs mode has been observed in C9H18N2CuBr4 . But the second path, which is though the dimensional crossover towards 1D, is still full of blank and calling for more study, partly because it is hard to find out a quantum many-body system with dimensional reduction. Such a dimensional reduction weakens the long-range order of the system and, therefore, inhibits the Higgs mode’s overdamping feature. The research team from The University of Hong Kong, the Sun Yat-Sen University, the University of Michigan and The University of Utah managed to fulfil these blanks by numerically simulating a dimensional-crossover quantum spin model, coupled spin chains (see Figure 1). Image 1. Coupled spin chains with nearest-neighbour spin intrachain interaction (solid black line) and interchain interaction (red dashed line). The research team came up with coupled spin chains model by introducing the interchain interaction. By reducing the strength of these interchain interactions (changing the value of J⊥  in Figure 1 towards 0), the model would change from a 2D system to a quasi-1D system. The research team used the QMC method simulating the model and developed an effective method to measure the spin- and the bond- correlation functions. They not only observed the Higgs mode via a dimensional crossover but also find the scalar mode, which is predicted by the sine-Gordon theory. These results make coupled spin chains an attractive candidate system for studying collective quantum dynamics theoretically and experimentally. The Higgs mode and the scalar mode spectrum With the help of the Tianhe- II and III supercomputers, the research team study the coupled spin chains in the quasi-1D limit and observed the evolution of the spectrum of Goldstone mode(Figure 2 (g) and (k)), the Higgs mode(Figure 2 (h) and (l)), and the scalar mode(Figure 2 (f) and (j)). Figure 2 shows the obtained spectra from the QMC simulations, where the blue dashed line represents the dispersion relation according to the combination of the mean-field theory and the sin-Gordon theory model. As one can see in Figure 2, the numerical results fit well with the theory prediction, which means the research team has managed to catch the signal of the Higgs mode. These signal is very helpful to design corresponding experiments to observe the Higgs mode via a dimensional crossover, like neutron scattering and nuclear magnetic resonance spectroscopy. Such exciting results also will contribute to our understanding of the Higgs mode in dimensional reduction. Image 2. The spectra of the Goldstone mode, the Higgs mode, and the scalar mode changes with the coupled spin chains that tends to a quasi-1D limit. The first and the third columns are for the Goldstone mode. The second tells the scalar mode while the fourth is the Higgs mode. Image 3. Frequency dependence of the spectrum of the Higgs mode (b) and the scalar mode (a) evolve with the dimension reduction. In this dimensional reduction, a sharp peak is emerging, which means the signal of the scalar mode and the Higgs mode becomes stronger. In order to describe the emergence of the Higgs mode and scalar mode, the research team also plotted out the frequency dependence of them (see Figure 3), where g is a factor telling how close the model to the quasi-1D is. When g=1, the coupled spin chains are in a 2D system, and with g=0, the coupled spin chains are in a 1D system. By comparing the frequency dependence of the spectrum with different g, one can find a sharp peak emerging as g reduces, which means the signals of the Higgs mode and the scalar mode are becoming stronger and stronger. The novel physics phenomenon via dimensional crossover In the framework of modern physics, symmetry and dimension are two of the most important factors that determine the properties of quantum many-body physics. And the phenomenon caused by dimension reduction is a key topic in quantum magnetic systems. The finding of the research team provided an attractive model and data support, which help us to understand what an essential role that the dimension plays in our world and stimulate the development of the next-generation quantum material and components. About the team Mr Chengkang Zhou is a PhD student in physics, under the supervision of Dr Zi Yang Meng. The work was supported by the Research Grants Council of HKSAR, the Areas of Excellence “2D Materials Research: Fundamentals Towards Emerging Technologies”, and we thank the Computational Initiative at the Faculty of Science and the Information Technology Services at The University of Hong Kong and the National Supercomputer Centers in Guangzhou and Tianjin for their technical support and providing generous HPC resources that have contributed to the research results reported within this paper.   The journal paper can be accessed from here.    

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A fiery past sheds new light on the future of global climate change, ice core samples reveal significant smoke aerosols in the pre-industrial Southern Hemisphere

Centuries-old smoke particles preserved in the ice reveal a fiery past in the Southern Hemisphere and shed new light on the future impacts of global climate change, according to a research led by Harvard University and a group of international researchers from the Desert Research Institute in Nevada and The University of Hong Kong, etc. recently published in Science Advances. “Up till now, the magnitude of past fire activity, and thus the amount of smoke in the preindustrial atmosphere, has not been well characterised,” said Pengfei LIU, a former graduate student and postdoctoral fellow at the Harvard John A Paulson School of Engineering and Applied Sciences (SEAS) and first author of the paper. “These results have importance for understanding the evolution of climate change from the 1750s until today, and for predicting future climate.” One of the biggest uncertainties when it comes to predicting the future impacts of climate change is how fast surface temperatures will rise in response to increases in greenhouse gases. Predicting these temperatures is complicated since it involves the calculation of competing warming and cooling effects in the atmosphere. Greenhouse gases trap heat and warm the planet’s surface while aerosol particles in the atmosphere from volcanoes, fires and other combustion cool the planet by blocking sunlight or seeding cloud cover. Understanding how sensitive surface temperature is to each of these effects and how they interact is critical to predicting the future impact of climate change. Many of today’s climate models rely on past levels of greenhouse gasses and aerosols to validate their predictions for the future. But there’s a problem: While pre-industrial levels of greenhouse gasses are well documented, the amount of smoke aerosols in the preindustrial atmosphere is not.  To model smoke in the pre-industrial Southern Hemisphere, the research team looked to Antarctica, where the ice trapped smoke particles emitted from fires in Australia, Africa and South America. Ice core scientists and co-authors of the study, Joseph MCCONNELL and Nathan CHELLMAN from the Desert Research Institute in Nevada, measured soot, a key component of smoke, deposited in an array of 14 ice cores from across the continent, many provided by international collaborators. “Soot deposited in glacier ice directly reflects past atmospheric concentrations so well-dated ice cores provide the most reliable long-term records,” said McConnell.     What they found was unexpected. “While most studies have assumed less fire took place in the preindustrial era, the ice cores suggested a much fierier past, at least in the Southern Hemisphere,” said Loretta MICKLEY, Senior Research Fellow in Chemistry-Climate Interactions at SEAS and senior author of the paper. To account for these levels of smoke, the researchers ran computer simulations that account for both wildfires and the burning practices of indigenous people. “The computer simulations of fire show that the atmosphere of the Southern Hemisphere could have been very smoky in the century before the Industrial Revolution. Soot concentrations in the atmosphere were up to four times greater than previous studies suggested. Most of this was caused by widespread and regular burning practiced by indigenous peoples in the pre-colonial period,” said Jed KAPLAN, Associate Professor from the Research Division of Earth & Planetary Science at The University of Hong Kong and co-author of the study. This result agrees with the ice core records that also show that soot was abundant before the start of the industrial era and has remained relatively constant through the 20th century. The modelling suggests that as land use changes decreased fire activity, emissions from industry increased.   What does this finding mean for future surface temperatures? By underestimating the cooling effect of smoke particles in the pre-industrial world, climate models might have over-estimated the warming effect of carbon dioxide and other greenhouse gasses in order to account for the observed increases in surface temperatures. “Climate scientists have known that the most recent generation of climate models have been over-estimating surface temperature sensitivity to greenhouse gasses, but we haven’t known why or by how much,” said Liu. “This research offers a possible explanation.” “Clearly the world is warming but the key question is how fast will it warm as greenhouse gas emissions continue to rise. This research allows us to refine our predictions moving forward,” said Mickley. Other co-authors include Yang Li, Monica Arienzo, John Kodros, Jeffrey Pierce, Michael Sigl, Johannes Freitag, Robert Mulvaney and Mark Curran. It was funded by the US National Science Foundation’s Geosciences Directorate under grants AGS-1702814 and 1702830, with additional support from 0538416, 0538427, and 0839093. The research paper can be accessed from here. Note: This article is adapted from the press release prepared by Leah BURROWS from Harvard John A Paulson School of Engineering and Applied Sciences.     

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Research Assessment Exercise (RAE) 2020 affirms HKU Science’s world-leading research positions

We are pleased to announce the encouraging results of HKU Science’s performance in the latest Research Assessment Exercise (RAE) 2020 published on May 24, 2021. Among the five Units of Assessment (UoA) to which HKU Science submitted, under the Panels of Physical Sciences and Biology, we outperform other local universities and achieve the highest percentage of 4* ratings in three UoAs including Chemistry, Earth Sciences and other Physical Sciences, and Mathematics and Statistics, affirming our world-leading position in the aforementioned fields (37% of all research submitted by the Faculty was judged to be world-leading (4*) by the RAE panel). Overall, 83% of the research submissions by HKU Science’s 118 eligible staff is rated as world-leading (4*) or internationally excellent (3*), this is compared to the Hong Kong-wide figure of 78% for science disciplines that we submitted (Chemistry 99% (sector 92%), Physics and Astronomy 95% (sector 91%), Earth Sciences and Other Physical Sciences 85% (sector 77%), Mathematics and Statistics 82% (sector 77%) and Biological sciences 62% (sector 61%)).     Dean of Science Professor Matthew EVANS was delighted to see the result of RAE recognising our exceptional standing in terms of research output, impact and environment. “We have retained top spot in Hong Kong in the UoAs where we had first place in 2014 and we have seen large improvements in the others. I want to thank everyone involved with getting the RAE done and congratulate you all, thank you for your hard work. The gains are very welcome,” he remarked. The Faculty will continue to strive for even greater achievements in our research endeavours in the years ahead.    The RAE 2020 is part of the University Grants Committee (UGC)'s ongoing efforts to assess the performance of the UGC-funded universities in research. It is a criterion-referenced assessment exercise against agreed quality levels as defined by international standards, covering research outputs completed during October 2013 to September 2019. About 16,000 research outputs involving some 4,200 eligible academic staff, 340 research impact case studies and 190 research environment submissions were assessed in this exercise. About 70% of the research projects assessed were judged by international experts to be "internationally excellent" or above – 25% being "world leading" and 45% "internationally excellent". Details of the RAE 2020 results can be found here.  

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Translational Research Series: Coastal groundwater - Its implications for the environment, engineering, and water resources

Professor Jimmy Jiujiu JIAO Professor of Research Division for Earth and Planetary Science   There has been a change in the research culture towards translational research. Generating some societal impacts is a nice bonus to us, however, I still appreciate the research freedom that allows individuals to choose research topics that are scientifically fundamental.   Coastal cities are home to roughly 25% of the world’s population and are rapidly growing. Hence coastal groundwater is vital because of its resource, environmental, and engineering implications. HKU’s Hydrogeology Research Group (HRG), led by Professor JIAO, has researched the impact of land reclamation on groundwater. This work has provided a theoretical framework leading to globally adopted practical guidance. The HRG’s findings on offshore groundwater have been used to understand the connection between submarine groundwater discharge (SGD) and red tides, prompting the Hong Kong government to reduce groundwater-induced nutrient sources to better manage the redtide problem. The findings have also helped to identify cost-effective, reliable groundwater resources in Singapore and to reduce the adverse engineering and environmental impacts of land reclamation in Sri Lanka and China. These findings and experiences are valuable to other coastal countries. Professor Jiao has been advising government departments and private organisations in Australia, Bahrain, Philippines, Malaysia and Singapore, to offer consultancy or expert opinions on their coastal land reclamation projects. As lots of large national-scale projects are happening in China, Professor Jiao has recently been appointed as a member of the Expert Advisory Committee of Water Resources Assessment, China Geological Survey (CGS), Chinese Research Academy of Environmental Sciences (CRAES), and Ministry of Ecology and Environment, to provide expert opinions. He has also conducted contract research with the Shenzhen Government and offered expert opinions on urban groundwater problems for Shanghai. As a scientist, Professor Jiao thinks that the primary purpose of research is to address scientific curiosity. “There has been a change in the research culture towards translational research. Generating some societal impacts is a nice bonus to us, however, I still appreciate the research freedom that allows individuals to choose research topics that are scientifically fundamental.“  

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Translational Research Series: A cultural, behavioural, and regulation campaign against light pollution: from Hong Kong to the world

Dr Jason Chun Shing PUN Principal Lecturer of Research Division for Physics and Astronomy   I am happy to see this translational research exert a considerable influence on how we perceive and what we do against light pollution, and I am glad that the society has committed to stop abusing the use of outdoor lighting, and to limit its adverse effects to the environment.”   Light pollution is a form of environmental degradation caused by inappropriate or excessive use of artificial outdoor lighting that not only wastes energy, money and valuable earth resources, but also has negative impacts on our ecological systems and possibly our health. Dr Jason PUN from the Research Division for Physics and Astronomy and his team underpinned a long-term cultural, behavioural, and regulation movement against light pollution, that combines rigorous scientific research to promote public awareness of the damages caused by light pollution to the natural environment. Their study supported the Hong Kong government‘s Charter on External Lighting, through which more than 4,800 organisations pledged to turn off lighting at night. The research technique used in Hong Kong has now been applied in 16 countries/ regions, spreading the message of dark sky preservation worldwide, influencing policy decisions and securing a range of environmental and health benefits. The research findings are also applied for policy-making, as Dr Pun is serving as a member of the ”Working Group on External Lighting”, an official government body to review the effectiveness of the Charter and to study how to further regulate external lighting. This represents the strongest commitment ever from the government to reduce the negative impacts of light pollution. After striving on the issue for 18 years, Dr Pun said he finally sees a significant change in how people think of light pollution. ”I can see people's attitude changing over time. People are no longer asking whether we should reduce light pollution, but how fast and better we can adopt a smarter lighting in the city. I am happy to see this translational research exert a considerable influence on how we perceive and what we do against light pollution, and I am glad that the society has committed to stop abusing the use of outdoor lighting, and to limit its adverse effects to the environment.”   The appearance of the montior.  Click here to visit the bilingual website set up by the team for educating the public on light pollution. Click here to visit the Outdoor Lighting Directory that displays public-contributed examples of good and poor lighting fixtures.

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Translational Research Series: Developing a novel therapeutic molecule into an anti-hypertensive drug

Professor Billy Kwok Chong CHOW Chair of Endocrinology, Research Division for Molecular and Cell Biology   I find beauty in science. The real essence of science is to find a way to mould and translate them into something extraordinary to face the problems in the real world.   Hypertension is known as the silent killer and is the leading preventable cause of premature deaths worldwide. It is clinically shown to dramatically increase the risk of life-threatening diseases such as heart disease, heart attack, stroke, heart failure, peripheral arterial diseases, aortic aneurysms, kidney disease, and vascular dementia, etc. It is estimated that about 1.56 billion people will suffer from hypertension by 2025. Despite the wide range of drugs available for treating hypertension, at least 10% of patients are resistant to all conventional drugs, a condition known as resistant hypertension. Professor Billy CHOW from the Research Division for Molecular and Cell Biology, has founded a start-up company PhrmaSec Ltd. HK, focusing on the discovery of novel therapeutic molecules for the treatment of some major critical diseases. Using G Protein-Coupled Receptors (GPCRs) as targets, his team was able to discover a small molecule allosteric modulator of the human secretin receptor, developing the novel small molecule “KSD179019” into an anti-hypertensive drug to address the continually expanding hypertensive population. GPCRs are the targets of more than half of the approved drugs in the market. This tells us the importance of these cell surface receptors in normal physiology as well as the development of pathophysiological conditions in humans. Based on the resolved structure of specific GPCR, the team has developed an in-silico based technology to screen small compound modulators, allowing initial molecular dynamic simulations to simulate atomic interactions between the ligand and receptor in real-time. The data generated are subsequently translated into identifications of pharmacophore of the receptor and small compound modulators that interact with the receptor. As the KSD179019 discovered by Professor Chow’s laboratory targets a new mechanism, it has the potential to be used for the therapeutical treatment of patients resistant to conventional drugs. The main advantages of this drug are: it is inexpensive to synthesise, it is safe since it possesses minimal acute and chronic toxicity according to OECD guidelines, and it significantly lowers blood pressure for a much longer 60-hour window in the hypertensive rat model. With this scientific advancement, the start-up has filed a patent and obtained an exclusive license from HKU to develop and market this drug. Professor Chow said there is no other time like today for researchers to be more responsible than ever to bring their innovation to the public. “If you are in basic biology research, then it is your utmost responsibility to translate your novel innovation for the betterment and health gain of the society that you live in,” he remarked. “I find beauty in science. The real essence of science is to find a way to mould and translate them into something extraordinary to face the problems in the real world.”

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Translational Research Series: Tracing DNA evidence in kinship determination and criminal investigations by user-friendly statistical software

Professor Tony Wing Kam FUNG Chair of Statistics, Research Division for Mathetatical and Statistical Science   The goal of my project is to develop sophisticated statistical methodology and to provide user-friendly software for practitioners such as forensic scientists. More communications would definitely help to cultivate a translational mindset.   DNA testing is the most powerful tool in parentage and kinship determinations and for mixed stain in criminal investigations. Novel statistical methods and user-friendly software developed by Professor Wing Kam FUNG and his team from the Research Division for Mathematical and Statistical Science, provided a simple means of assessing the weight of DNA evidence. This easy-to-use software built upon sophisticated statistical theory and methodology has been used by forensic and paternity laboratories worldwide in evaluating thousands of cases, with very positive feedback on its analysis of complex kinship and DNA mixtures. The developed methodology and software are of fundamental importance in legal contexts. A particularly striking example of the impact of the tool was its success in identifying three badly burnt bodies in the Hot-Air Balloon Burst Tragedy in Egypt in 2013, the investigation of which was concluded in the Hong Kong Coroner’s Court in 2016. Fung also solved the DNA mixture problem in the O J Simpson case, a murder case that involved the famous football player which caused a media sensation in the mid-’90s. Translational research would involve considering the societal needs and how efficient and effective the applications can be translated from the complex theory. Whilst a lot of statistical research focuses on methodology, Professor Fung also looks into the applications and tries to apply complex theories to practical problems for societal needs. “The goal of my project is to develop sophisticated statistical methodology and to provide user-friendly software for practitioners such as forensic scientists. More communications would definitely help to cultivate a translational mindset,” Professor Fung said.

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Translational Research Series: Reduction of illegal global wildlife trade through novel conservation forensics research

Dr Caroline DINGLE Director of Conservation Forensics Lab   The goal of forensic research is to provide evidence that can be used to aid enforcement and legal efforts to prosecute wildlife-related crimes.   Hong Kong has long been a central hub in international wildlife trade networks, be it legal or illegal trade. This is due in part to the high volume of trade transactions through its major port, along with its prime location as a transit hub between origin and destination countries. Every year, substantial worth of documented trade passes through Hong Kong’s borders. While much wildlife trade is legal, the quantity of trade provides the opportunity to launder illegally sourced and traded species and products. The Research Division for Ecology and Biodiversity’s research on wildlife trade has involved decades of multidisciplinary work. Building upon HKU’s history of monitoring illegal trade and the impacts on wild populations, the Conservation Forensics Lab was established in 2016 to investigate the wildlife trade. Having developed a range of molecular and isotopic forensics and data-analysis tools for countering wildlife crime, research undertaken at the Lab has provided data used as evidence to increase enforcement of national and international laws that protect endangered species and support illegal wildlife trade reduction. Data-based methods for tracing illegal evidence Multiple laboratory and data-based methods are used to describe patterns, quantify the scale and identify species involved in the trade. By using genetic and biogeochemical approaches, species and their geographic origins can be identified, revealing whether a species is being traded legally or not. Biogeochemical studies could help determine whether an animal was captive-bred or wild-caught, a piece of evidence key to trace whether a species is being sold legally or not. Results from these studies have led to successful prosecutions as well as higher levels of protection for species impacted by trade. Conservation actions stemming from these research projects have resulted in increased protection of turtles, pangolins, and fish under the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES) and via the International Union for Conservation of Nature (IUCN). Newly developed forensics techniques  Looking forward, Director of the Lab Dr Caroline DINGLE expected the newly developed forensics techniques would continue to provide evidence to support successful prosecution. “We are currently developing methods to apply stable isotope analysis (SIA) to determine whether an animal is captive or wild-caught. SIA has been used widely in ecology, but it is relatively new that this tool is being applied to wildlife forensics. While more work needs to be done to verify that this is a robust forensic tool, it is so far very promising.“ In collaboration with HKU Faculty of Law, the Lab also contributes to the Species Victim Impact Statements (SVIS) Initiative. The aim of this Initiative is to develop statements that provide information on the impacts of wildlife trade on wild populations of species threatened by trade. These statements are made available to the prosecution and judicial teams involved in wildlife crime case.  “We are working to develop a database of reference samples for genetic and isotopic work. This database would be a crucial reference tool for local authorities seeking to comprehensively monitor wildlife trade in Hong Kong and assist in the international goal to more effectively prevent fraudulent trade in protected species,” Dingle added.   Highlights of successful cases Dr David BAKER Action: gathered the first evidence of the illegal trading of European eelsinto Asia and Hong Kong. Impact: genetically identified glass eels (juveniles of the endangered European eel) intercepted by Hong Kong Customs, leading to a successful prosecution. Dr Timothy BONEBRAKE Action: conducted a social network analysis of data collected from a range of online sources on Chinese seizures of pangolins. Impacts: 1) supported the increased protection of pangolins under the CITES and IUCN. 2) These studies were influential in contributing to the successful proposals for the up-listing and increased protection of the Chinese pangolins from Appendix II to I. Professor David DUDGEON Action: quantified the illegal turtle trade in markets. Impact: his work was influential in the successful proposal and subsequent increased protection of the big-headed turtle (family Platysternidae) from Appendix II to I. USD billions of wildlife and wildlife products are traded internationally without species-level traceability. Photo courtesy of Astrid ANDERSSON. Photo of painted wood turtle (Rhinoclemmys pulcherrima). Photo courtesy of Astrid ANDERSSON. Researchers of Conservation Forensics Lab: (from the right) Director: Dr Caroline DINGLE Founding members: Dr Timothy BONEBRAKE, Dr David BAKER and Professor David DUDGEON Other member: Dr Hannah MUMBY Yellow-crested Cockatoos (Cacatua sulphurea) for sale in Hong Kong's bird market. Photo courtesy of Astrid ANDERSSON.

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Translational Research Series: OLED - Organic light-emitting diode

Professor Vivian Wing Wah YAM Philip Wong Wilson Wong Professor in Chemistry and Energy Chair Professor of Department of Chemistry   We need to better equip ourselves through life-long learning, and at the same time be aware of the most up-to-date science and technology development in the world, and to understand the need of the industry, said Professor Vivian Wing Wah YAM. Research Division for Chemistry Researchers:  Professor Chi Ming CHE（On the left） Zhou Guangzhao Professor in Natural Sciences and Chair Professor Professor Vivian Wing Wah YAM Philip Wong Wilson Wong Professor in Chemistry and Energy and Chair Professor       The Research Division for Chemistry has a strong tradition of transition metal complex chemistry and has pioneered various classes of highly efficient metal complex emitters. The Division’s strengths also include inorganic excited states and their photophysics and photochemistry. These areas bring seminal and sustained contributions to the development of robust and highly emissive organic light-emitting diode (OLED) materials. OLEDs are amongst one of the most promising energy-efficient display technologies that can be found everywhere, including smartphones, 8K televisions, head-worn displays like augmented reality (AR) and virtual reality (VR) equipment. OLEDs work by passing electricity through incredibly thin layers of organic semiconductors. Excited states formed in these organic materials will radiatively decay to their initial, stable “non-excited” state, i.e. the ground state, and release energy in the form of light.   Contribution to highly emissive OLED display  Professor Chi Ming CHE is a world-recognised expert in phosphorescent metal complexes and the use of long-lived excited states for photocatalysis. His pioneering “one-chelating-ligand+one metal” design strategy has successfully generated various classes of high-performance platinum(II) emitters for OLEDs.  Professor Vivian YAM is a world-recognised expert in molecular design and spectroscopic studies of luminescent metal-based molecular functional materials, particularly in the manipulation and harnessing of excited states for light-enabled technologies and functions. She has pioneered new classes of luminescent metal complexes, especially gold(III) complexes that are photo-stable and capable of displaying unprecedented room-temperature phosphorescence properties. Her seminal work on organogold(III) phosphors in 1993 has paved the way for the first gold-based OLED in 2005. Subsequent works feature various classes of gold(III) emitters with bidentate, tridentate, and tetradentate ligands with unprecedented high performance and high operational stabilities, together with the generation of Hong Kong-owned intellectual property rights.  Forming partnerships with industries   These innovative works have attracted considerable industrial interests to collaborate with Professor Yam’s team at HKU and to sponsor her work to realise their commercial use in display technology. She has long-term collaboration and strategic partnerships with industries, especially the collaboration with TCL Corporation Ltd., one of China’s largest enterprise groups in consumer electronics on the global scale, and its subsidiaries to develop new printable OLED materials and technology. There is an increasing number of display producers joining the OLED market, with market revenue projected to reach more than USD69 billion by 2027.  “The development of our own proprietary luminescent materials that are nationally and Hong Kong-owned is really timely,” said Professor Yam. Currently, most of the commercially available phosphors are based on iridium(III) complexes, where foreign companies hold most of the key patents. Our luminescent gold(III) complexes with high originality hold great promises to overcome these business monopolies. Taking advantages of the rich gold reserve in China, being the second largest in the world, the development of luminescent gold(III) complexes can exploit China’s natural resources and competitive edge to develop cheaper and high-performance metal phosphors with Hong Kong-owned intellectual property rights.  Working closely with the industry can definitely facilitate more collaborations and motivate more downstream translational activities. This will provide new avenues for the display and solid-state lighting companies in Hong Kong and the Mainland to obtain a fair share of the OLED market. “Our research works in the past are mostly curiosity-driven, but now we are going to do more application-inspired basic research as well as translational research, and hopefully, to enhance Hong Kong’s translational competency and to produce a great impact on the society,” said Professor Yam. Click here to learn more about the research projects of Professor Chi Ming CHE.  Click here to learn more about the research projects of Professor Vivian YAM.  

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International joint research reveals how fish adapt to ocean acidification by modifying gene expression

Human-driven global change is challenging the scientific community to understand how marine species might adapt to predicted environmental conditions in the near-future (e.g. hypoxia, ocean warming, and ocean acidification). The effects of the uptake of anthropogenic atmospheric CO2 by oceans affects (i.e. ocean acidification) propagate across the biological hierarchy, from changes in the building blocks of life at nano-scales to organism, physiology and behaviour through ecosystem processes and their properties. To survive in a reduced pH environment, marine organisms have to adjust their physiology which, at the molecular level, is achieved by modifying the expression of genes. The study of such changes in gene expression can aid in revealing the adaptive mechanisms of life under predicted future ocean acidification conditions. Making use of natural laboratories There are a few places on this planet where volcanic activity has CO2 bubbling from the seafloor creating conditions that are similar to those predicted to occur across the oceans in the near-future. Such natural laboratories can then help us to understand what will happen to marine organisms in the future under an ocean acidification scenario. Therefore, researchers from Research Division for Ecology & Biodiversity of The University of Hong Kong (HKU) and Swire Institute of Marine Science, jointly with researchers from The University of Adelaide, travelled to a remote volcanic island of New Zealand called White Island. They collected samples from CO2 seeps and nearby locations, and analysed molecular data from a fish species (the Common triplefin) with ecological evidence of being successfully adapted to acidified environments at CO2 volcanic vents. The findings were recently published in a peer-reviewed open access journal Evolutionary Applications.  Studying evolutionary mechanism through species mutations The study found a higher gene expression in gonads in fish living in the CO2 vents with reduced pH than those from control environments with ambient CO2 and pH conditions. Most of those genes were functionally involved in the maintenance of pH homeostasis, increased metabolism, and regulatory functions of downstream biological processes revealing important processes a fish needs to adjust to live in a lower pH environment. Interestingly, it was mainly the male fish with this expression signature hinting at reproductive consequences as males provide parental care of the nests.  When looking at the actual sequence of these genes and their genetic variation, the authors found evidence of a long-term process of natural selection. The genetic changes, which we call mutations, providing the fish with adaptive advantages for living in an acidified, are located in DNA sequences regulating the expression of the genes. These mutations in regulatory sequences would not impact the fitness of the individuals carrying them when living in an ambient pH environment, but these might allow fine-tuned physiological regulation in a reduced pH environment. Such standing genetic variation in DNA regulatory sequences could provide for the adaptive potential to near-future ocean acidification in fishes. Moreover, the authors propose an evolutionary mechanism by means this adaptive potential to ocean acidification could be maintained in natural populations of fishes. Fish species tend to occur across wide geographical ranges with different pH. Thus, it is likely that similar to what happens in Common triplefins, the genetic variation allowing for life in slightly reduced or variable pH environments already exist within many fish populations. Highly dispersive larvae of fishes contribute to the flow of this genetic variation among the populations of a species. Hence, it might be expected that the genetic variation in regulatory sequences of gene expression efficiently adjusting the physiological responses to reduced pH will provide the raw material for adaptive natural selection in the near-future under increasing ocean acidification. “The findings of this study imply that one of the more relevant things in terms of the capacity of the marine species to respond to future changes in their environmental conditions is their current genetic variation. Thus, the assessment of the levels of genetic diversity of different marine species is the most important, and we are currently working on it,” said Dr Natalia PETIT-MARTY, first author of the paper and Postdoctoral Fellow in the group led by Dr Celia SCHUNTER at Research Division for Ecology and Biodiversity & Swire Institute of Marine Science, HKU.  “We are very fortunate to get to visit these remote places providing us with a glimpse of how the oceans may look like in the future. To make sure our findings are applicable across different marine ecosystems, we also travelled to CO2 vents at tropical coral reefs in Papua New Guinea and rocky reefs in the Mediterranean Sea, and will continue our research on the adaptive potential of marine fishes to ocean acidification,” added Dr Celia SCHUNTER, Assistant Professor at Research Division for Ecology and Biodiversity & Swire Institute of Marine Science, HKU.  The complete study was first published in Evolutionary Applications on April 8th, 2021. N. Petit-Marty, I. Nagelkerken, S. D. Connell, and C. Schunter. (2021). Natural CO2 seeps reveal adaptive potential to ocean acidification in fish. The research paper can be accessed from here.   

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Remembrance website of Professor Brian Morton

It is with deep sadness that we mourn for the passing away of Emeritus Professor Brian MORTON on March 28, 2021 in his sleep, at the age of 78. We honour the memory of Professor Morton in many aspects, be it his relentless commitment in founding the Swire Marine Laboratory (later renamed as the Swire Institute of Marine Science) 3 decades ago, or his significant contributions in teaching and research in marine biology as well as in pioneering the marine environmental conservation in Hong Kong. He had served HKU for almost 34 years and was appointed Professor Emeritus of Marine Ecology on retirement. For his many achievements, he was made a Life Fellow of the Pacific Science Association (1993) and elected to the Global 500 by UNEP in recognition of his contributions to Pacific marine science and conservation, respectively. In 1997, he was invested as Knight (Ridder) in the Order of the Golden Ark, The Netherlands, in 1999 invested OBE, the UK, for contributions to conservation and marine science, respectively, and was the recipient of the Duke of Edinburgh Conservation Gold Medal in 2004 and Doctor of Science of The University of Hong Kong in 2014. We honour the memory of Professor Morton for his lifetime dedication to the research in local marine fauna and flora. He will be dearly missed by all whose lives he touched, and we offer our deepest condolences to his family.   Please visit here to remember Professor Brian Morton.

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HKU researchers identify promising new biologics for obesity-related diseases

The research teams at The University of Hong Kong led by Professor Xuechen LI from the Research Division for Chemistry and Department of Chemistry as well as Professor Yu WANG from the Department of Pharmacology and Pharmacy, reported a synthetic biotherapeutics with promising anti-tumour, insulin sensitising and hepatoprotective activities in the Journal of the American Chemical Society. Obesity is a global pandemic associated with a significantly reduced life expectancy, it also increases the risk of type 2 diabetes, hypertension, coronary heart disease, stroke, chronic kidney disease and cancer. Adiponectin, as a protein hormone and adipokine, regulates glucose levels and improve lipid metabolism, and is a major player in the pathogenesis of obesity, insulin resistance and metabolic syndrome. Obese patients have low adiponectin levels, a condition known as hypoadiponectinemia, which contributes to increase risks of cardiovascular, metabolic diseases as well as aggressive development of malignancies with poor prognoses. Adiponectin supplementation is a long-sought-after strategy for the prevention and treatment of cancer and metabolic diseases, especially in obese patients. However, the adiponectin application in therapy has been hampered by the difficult production of human adiponectin. The teams have been working on the development of synthetic compounds which can mimic the bioactivity of adiponectin over the past seven years. Finally, they developed an efficient synthetic approach to produce the adiponectin-derived glycopeptides that exhibit potent anti-tumour, insulin-sensitising and metabolic activities in various mouse models. The products hold greater potentials for clinical application in obesity and related medical complications, such as type 2 diabetes, hypertension, coronary heart disease, stroke, chronic kidney disease and cancer. Professor Li and Professor Wang believe that this finding opens the door to explore the opportunity of using the synthetic glycopeptide as a potential adiponectin downsized mimic supplementary in clinical treatment. The apparent advantage of these synthetic glycopeptides is that they can be readily produced by chemical process. The two teams are continuing to apply for research grants which can support them to further evaluate the potential of these agents in preclinical studies for drug development. About the research paper: https://pubs.acs.org/doi/10.1021/jacs.1c02382 Image caption:(From left to right) Mr Yuanxin LI (Department of Pharmacology and Pharmacy), Professor Yu WANG (Department of Pharmacology and Pharmacy), Dr Yiwei ZHANG (Department of Pharmacology and Pharmacy), Mr Hongxiang WU (Research Division for Chemistry and Department of Chemistry) and Professor Xuechen LI (Research Division for Chemistry and Department of Chemistry).

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Research co-led by HKU and Lingnan ecologists reveals that wealth inequality is key driver of global wildlife trade

It was commonly assumed that wildlife products are exported from low-income countries to meet the demand of consumers in wealthy economies, and therefore, a widening wealth gap may drive up the volume of global trade and endanger wildlife. Recently, a research team co-led by Research Division for Ecology and Biodiversity (E&B), Faculty of Science, the University of Hong Kong (HKU) and the Science Unit (SU) of Lingnan University (LU) corroborated this premise by analysing global wildlife trade databases. The research team includes Dr Jia Huan LIEW, Research Assistant Professor of SU, and Emeritus Professor David DUDGEON from E&B, HKU. Their findings are published in Science Advances. Wealthier countries take the vast part of the responsibility A major take-home message of the study was that wealthy countries are responsible for most of the world’s wildlife trade. The top three importers of wild animals were the United States, France, and Italy, while in Asia, wealthier nations including China, Singapore, and Japan were all net importers of wildlife products. On the supply-end of the trade, countries with better logistics capabilities (e.g., Indonesia) also exported more wildlife products. Hong Kong has long been a global hub of the legal wildlife trade, importing approximately 13 million individual animals between 1998 and 2018. In particular, the city was a major destination for fishes, sharks, and rays. The researchers looked at 20 years of legal wildlife trade data, ranging from live corals for hobbyist, to wild-caught sturgeons for aquaculture, and seahorses for traditional remedies. During this period, an estimated 421 million individual animals were traded globally, and the market was more extensive when there was greater wealth inequality between countries. The study’s findings may have important implications in a post-pandemic world, where issues surrounding the wildlife trade is once again in the spotlight. The COVID-19 virus is believed to have spread to humans via the wildlife trade, leading notably, to a ban on the consumption of wild terrestrial animals in China. While increased regulation may suppress trade in the short term, the pandemic’s impact on the global economy will likely exacerbate wealth inequality between nations by disproportionately impacting some parts of the world. This, according to research findings that show a positive correlation between wealth inequality and the extent of the global wildlife market, could encourage more international trade in wildlife products. There were marked inequalities between exporters and importers of wildlife products, and importers were generally better off in all measures of socioeconomic well-being. For example, the largest trade partnership the study recorded was between the USA (importer) and Indonesia (exporter), where the per capita GDP of the US was 20 times that of Indonesia. Other prominent trade flows include exports from Jamaica to France (importer per capita GDP 8 times higher) and exports from Indonesia to Singapore (importer per capita GDP 17 times higher). Urge for reduction of demands for animal products Inequalities in the wildlife market and the dominant role of wealthy countries highlights the importance of efforts to reduce the demand for wildlife products via awareness campaigns or product substitution, among others. “One message is that it is evidently demand from richer countries that is fueling the capture and trade of wildlife from poor/low-income countries.  That means that it is the responsibility of affluent consumers in rich countries to do something to limit their demands and greed for animal products,” says Emeritus Professor Dudgeon. This may also be a more socially equitable approach than blanket bans on wildlife harvesting that could impact vulnerable communities reliant on the trade. “Globally, we need to manage the trade in wildlife in a way which does not endanger their populations and the communities that rely on it for a source of protein or important source of livelihood,” says Dr Janice LEE, Assistant Professor at the Asian School of the Environment. For the paper in Science Advances, please click here.     Image 1. Top participants of the legal wildlife trade in the last 20 years.     Image 2. Elephant tusks seized by the National Parks Board of Singapore, Singapore Customs, and the Immigration & Checkpoints Authority of Singapore. Photo Credit: Marcus CHUA

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HKU physicists developed a new algorithm solving a long standing problem in constrained quantum material models

The intrinsic scale limit of current quantum material hinders possible development of technology, thus the discovery of a new generation of quantum materials holds the key to technological revolutions, such as stable topological quantum computers, high-temperature superconductors, high capacity information and energy storage. Nevertheless, due to their nature of strongly correlated electrons, it is not uncommon for the next generation of quantum materials to have extremely complex interactions with the environment, making it difficult to study their properties and to make use of them.  Scientists are working proactively to learn how this next generation of quantum materials could reach and remain stable at topological phase and how to make use of their excited particles. Recently, Postdoctoral Fellow Dr Zheng YAN and Associate Professor Dr Zi Yang MENG, from the Research Division for Physics and Astronomy of the Faculty of Science at the University of Hong Kong (HKU), have invented a new algorithm that could solve a large class of important constrained quantum material models, via powerful supercomputer combined with theoretical analysis. They also teamed up with Dr Yancheng WANG from China University of Mining and Technology, Dr Nvsen MA from Beihang University, and Professor Yang QI from Fudan University to employ the algorithm and untangle a long-standing puzzle of a typical constrained quantum materials model, ‘quantum dimer model’.  Their study reveals the unique non-trivial interaction among ‘visons’, a mysterious particle which is excited in a topological order which carries finite emergent flux, and uncover the real property of this useful particle which may push ahead the development of technological innovation. The research findings are recently published in the renowned academic journal npj Quantum Materials.    Background Many modern technologies are based on the quantum nature of materials, such as silicon-based computers, solar cells or lithium-ion batteries. These current generation quantum materials all belong to the category of weakly-correlated systems, where the interactions between electronic degrees of freedom are not dominant and are not sensitive to their environment, hence, they are reasonably easier for scientists to study their properties. On the other hand, the next generation quantum materials based on strong correlations between electrons (they are also denoted as quantum many-body systems) are becoming more crucial for the development of modern technologies as well as for addressing the major challenges in our society. For instance, the 2D quantum moiré materials, a type of next generation quantum material, can be used as magic angle twisted bilayer graphene, the next-generation AI computing chips that go beyond Moore’s law, the high-temperature superconductor for lossless energy transmission and high-speed Maglev train, and the quantum frustrated magnets and topological unit for quantum computers and quantum information, etc. However, due to the intrinsic exponential complexity of the underlying quantum many-body problem, that scientists have to solve millions of thousands of the electrons in the material in a quantum mechanical way, these complicated systems require modern computational techniques and advanced numerical analysis to reveal their microscopic mechanisms. Indeed, the need for inventing better algorithm and simulation of quantum materials for validating microscopic models as well as to guide experiments, has stimulated the development of novel theoretical and numerical concepts and techniques beyond the frontiers of the existing knowledge, and to discover better materials to benefit our society.   Quantum dimer model and sweeping cluster Monte Carlo method   To study the properties of these quantum many-body materials, scientists first need to build proper models for the next generation quantum materials and solve their properties at different conditions (differ phases, response in temperature, pressure, electric and magnetic fields, etc.) via large-scale simulations on supercomputers and analyse the results by advanced physics and mathematics tools, then adjust the model parameters to fit in the experimental observations and make predictions for future experiments. Figure 1. Building models for the next generation quantum materials:  (a) the triangular lattice quantum dimer model (QDM). (b) The solid hexagon and dashed rectangle are the Brillouin zone (BZ) for the dimer and vison. (c) Phase diagram of triangular QDM.   Among these quantum many-body models, there exist a large class of dubbed constrained models, in which not only the electrons experience the mutual quantum interactions with millions of other electrons, their unique existence in model and material are further constrained by certain strict rules that further limit their movements. Such constraints at the first appearance look unphysical, but they are the key ingredients of establishing the novel material properties, as the constraints could filter unwanted (usually high-energy) excitations that mask the fragile quantum nature and help us to directly access the low-energy physics with pure quantum entanglement. For example, it has been long anticipated that one such constrained model, triangular lattice quantum dimer model, could give rise to the topological phase of matter, in which the excitations therein are the building blocks to realise topological quantum computer and computation. Unfortunately, such constrained quantum model still cannot be simulated without approximation with modern numerical approaches. This is because due to the constraints, all the simulations should work in a restricted space. It is like a speeding car on a narrow and winding road without hitting the banks. The HKU team finally manages to change the situation by inventing and employing a new algorithm – the sweeping cluster quantum Monte Carlo algorithm – to fully solve the triangular lattice quantum dimer model. Figure 2.  Spectra of dimer, vison-convolution and vison of the triangular quantum dimer model. These are only possible from the new simulation algorithm invented by the HKU team   New discovery of topological excitations which carries long range quantum entanglement Using the new algorithm and from their simulations on the Tianhe-II supercomputer, the research team found clear quantum entangled excitations (scientifically called vison and dimer excitations) without the interference of high-energy excitation. Vison is a mysterious particle that oftens appear in pairs, and is difficult to detect a single vison in ordinary models. It is a kind of emergent article (anyons) excited in a topological order which carries finite emergent flux. Via the new developed algorithm, the HKU team could compute the spectrums of single vison, dimer (coupled visons in real model), vison-convolution (also known as VC; visons with weak interaction) as shown in Fig.2. It is interesting to notice that the VC spectral gap at M point is higher than the dimer gap at the same point, suggesting that visons actually have a binding energy in forming the dimer correlation and consequently their interaction effect is attractive and gives rise to a bound state with lower energy than the naive convolution. Through this study, they reveal the unique non-trivial interaction among the mysterious visons.  Figure 3.  (a), (b), (c) and (d) are the projection of the four-dimensional order parameter at the QSL-VBS critical point with on the two-dimensional planes. (Inset) The density distribution per unit sphere area of the O(4) order parameter modulus at critical point, such radial dependence reveals that the order parameter indeed form a four-dimensional sphere. From (a) (b) to (c) (d), order parameter changes from being uniformly distributed to being more concentrated on some points, which means vison condensation.   Furthermore, the research group also found emergent continuous symmetry at the phase transition from the topological phase to a solid phase in the model as shown in Fig.3. From (a), (b) and inset figures, it is clear a 4D sphere histogram and radius is conserved. Through the simulation, researchers further saw that vison condenses on certain points on a four-dimensional sphere in the order parameter space as (c) and (d) shown to prove the results of the previous predictions made by theorists. This reveals the mechanism of vison condensation and critical point.  New algorithm brings new opportunity This finding helps scientists to understand the behaviour and interaction of anyons in the topological order, which might have potential applications in future quantum information technologies. With the powerful new algorithms and the unique properties of topological excitations discovered, many interesting research and potential applications with topological quantum materials can be pursued from here.   Dr Meng remarked, “The new algorithm for constrained quantum models and their solutions of topological excitations will eventually bring benefits to society, such that these visons are the information carrier for quantum computation and quantum computers. Our algorithm enables us to directly access numerical results with key theoretical predictions quantitatively, which is not possible before. Such efforts will certainly lead to more profound and impactful discoveries in quantum materials.”    About Dr Zheng Yan and Dr Zi Yang Meng Dr Zheng Yan is currently a postdoctoral fellow at Dr Meng’s quantum simulation group. He invented the original version of the sweeping cluster quantum Monte Carlo method during his PhD study in Fudan University.   Dr Zi Yang Meng is an expert in Monte Carlo simulation of quantum many-body systems, and has recently made the breakthrough in quantum material research. He was awarded the “2020 Tianhe Star Award” by the National Supercomputer Center of China for his outstanding accomplishments and promotion of computational oriented research on the Tianhe supercomputer.  Professor Yang QI of Fudan University performed the quantum field theory analysis of the numerical results and made sense of it all.  The work was supported by the Research Grants Council of HKSAR, the Ministry of Science and Technology of China and the National Science Foundation of China.  The journal paper at npj Quantum Materials can be accessed here.   

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Retired Trailblazing Ecologist - Professor David DUDGEON: A Lifelong Inspiration

Professor David DUDGEON Emeritus Professor from School of Biological Sciences Professor Dudgeon has spent almost 40 years at HKU. While at HKU, Professor Dudgeon has served, inter alia, as Department Head (repeatedly), Science Faculty Board Chairman, and Associate Dean. He was Director of the School of Biological Sciences from 2015 to 2018.   A lecturer has to be entertaining to an extent, and to have a story to present. A boring lecture for 40 students is 40 hours wasted. The point of the lecturer is to try and inspire the students to feel they want to learn more about the subject themselves.   For a newly retired professor, little seems to have changed for Professor David DUDGEON. In his office, folders and documents populated the shelves that line the well-lit room. We began the interview in his home away from home for the past 30 years, and from across his desk, Professor Dudgeon let out a reminiscent sigh as he took a trip down memory lane while recounting his beginnings with Ecology and Conservation. Although it was not his original plan, he found himself reading Zoology at university which led him into an exciting career in Ecology. His passion for this area lay in championing for nature: “Nature is silent, it’s mute”. Looking back at the time when the development of the Chek Lap Kok Airport was still underway, Professor Dudgeon remembered the resultant decline in Chinese White Dolphin populations. “We repeatedly hear this talk about balance, and eventually, our poor dolphins will be ‘balanced’ into extinction because they cannot speak up for themselves!” Professor Dudgeon always sustains his unfazed determination as it is an important quality that ecologists and conservationists should bring. “We have a role to make people aware of and be a spokesperson for the environment, because nature cannot speak for itself.” A role model of students If you have ever had the opportunity to take one of Professor Dudgeon’s courses, you would be blown away by the intricacies of each and every lecture. “A lecturer has to be entertaining to an extent, and to have a story to present. A boring lecture for 40 students is 40 hours wasted. The point of the lecturer is to try and inspire the students to feel they want to learn more about the subject themselves.” Professor Dudgeon, with over three decades of research and teaching experience at HKU under his belt, dished out some simple yet valuable advice to our students. “I always say to my students, what’s the ‘so what’ question here? You might be studying koalas, and you might say not very much is known about koalas, but I'd say so what? Not very much is known about a lot of things.” The humorous professor knows how to keep students’ attention. “Or the worst-case scenario, you’re in the Knowles Building trapped in the lift with the President and he asks why you’re studying that you’re studying, you had better have a good reason!” Article by Kengie TANG, BSc student majoring in Biological Sciences “I was beyond grateful to be given the opportunity to sit down with Professor Dudgeon for this interview.His contributions towards conservation is undoubtedly remarkable, and his advice truly resonated with me as I hope it would for other students. Leaving the interview, I have newfound motivation to dig deep into my passions as I continue my journey at HKU. It was truly an honour to speak with someone with as much wisdom and passion as Professor Dudgeon, and I sincerely wish him a well-deserved retirement!“    

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Seeing the unseen: HKU scientists develop a new chemical tool that sheds light on how proteins recognise and interact with each other

A research group led by Professor Xiang David LI from the Research Division for Chemistry and the Department of Chemistry, The University of Hong Kong, has developed a novel chemical tool for elucidating protein interaction networks in cells. This tool not only facilitates the identification of a protein’s interacting partners in the complex cellular context, but also simultaneously allows the ‘visualisation’ of these protein-protein interactions. The findings were recently published in the prestigious scientific journal Molecular Cell. In the human body, proteins interact with each other to cooperatively regulate essentially every biological process ranging from gene expression and signal transduction, to immune response.  As a result, dysregulated protein interactions often lead to human diseases, such as cancer and Alzheimer's disease. In modern biology, it is important to comprehensively understand protein interaction networks, which has implications in disease diagnosis and can facilitate the development of treatments. To dissect complex protein networks, two questions need to be answered: the ‘who’ and ‘how’ of protein binding. The ‘who’ refers to the identification of a protein’s interacting partners, whereas the ‘how’ refers to the specific ‘binding regions’ that mediate these interactions. Answering these questions is challenging, as protein interactions are often too unstable and too transient to detect. To tackle this issue, Professor Li’s group has previously developed a series of tools to ‘trap’ the protein-to-protein interactions with a chemical bond. This is possible because these tools are equipped with a special light-activated ‘camera’ – diazirine group that capture every binding partner of a protein when exposed to UV light. The interactions can then be examined and interpreted. Unfortunately, the ‘resolution’ of this ‘camera’ was relatively low, meaning key information about how proteins interact with each other was lost. To this end, Professor Li’s group has now devised a new tool (called ADdis-Cys) that has an upgraded ‘camera’ to improve the ‘resolution’. An alkyne handle installed next to the diazirine makes it possible to ‘zoom in’ to clearly see the binding regions of the proteins. Coupled with state-of-the-art mass spectrometr , ADdis-Cys is the first tool that can simultaneously identify a protein’s interacting partners and pinpoint their binding regions. In the published paper, Professor Li’s lab was able to comprehensively identify many protein interactions — some known and some newly discovered — that are important for the regulation of essential cellular processes such as DNA replication, gene transcription and DNA damage repair. Most importantly, Professor Li’s lab was able to use ADdis-Cys to reveal the binding regions mediating these protein interactions. This tool could lead to the development of chemical modulators that regulate protein interactions for treating human diseases. As a research tool, ADdis-Cys will find far-reaching applications in many areas of study, particularly in disease diagnosis and therapy. For more information about the paper “A tri-functional amino acid enables mapping of binding sites for posttranslational modification-mediated protein-protein interactions” published in Molecular Cell, please visit here. For more information about Professor Xiang David Li and his research group, please visit their group’s webpage.       

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HKU scientist contributed in newly launched Second World Ocean Assessment

Since the introduction of the First World Ocean Assessment (WOA I) that provided a comprehensive report on the state of the planet’s oceans for the first time, the second report has just been consolidated and launched as the Second World Ocean Assessment (WOA II), the major output of the second cycle of the Regular Process for Global Reporting and Assessment of the States of the Marine Environment, including Socioeconomic Aspects, in connection with Earth Day 2021 which will be observed on 22 April. It is the newest outcome of the only integrated assessment of the world’s ocean at the global level covering all three pillars of sustainable development. The WOA I that was released in 2016 established a baseline for measuring the state of marine environment and provided a scientific basis for action by governments, intergovernmental processes, policy-makers and others involved in ocean affairs. WOA II focuses on its major update by observing the trends since the publication of WOA I and identifying current gaps in knowledge and capacity. Dr Moriaki YASUHARA (School of Biological Sciences, Research Division for Ecology & Biodiversity, and Swire Institute of Marine Science, The University of Hong Kong) contributed to the deep-sea chapter in the first assessment five years ago, and now expands his contribution to wider aspects. Yasuhara's expertise in marine sciences ranges from biology via paleontology and geology to oceanography, and he is one of the several specialists who have deep expertise in all these fields. He has also worked in world oceans such as Pacific, Atlantic, Indian, Arctic, and Antarctic Oceans as well as marginal seas from shallow to deep sea floors. His broad expertise and experience led him to contribute four chapters of Estuaries and deltas; Continental slopes and submarine canyons; High-latitude ice; and Abyssal plains in the new WOA II just launched. "I am very glad to participate in the assessment by providing my knowledge and experience. I have been joining intensive meetings in Doha, Qatar and New York, USA for brainstorming, planning and writing up. It's busy but very fun and productive to collaborate with the world's leading experts," said Yasuhara. "Ever since the last assessment about 5 years ago, we have new discoveries that are both exiting and depressing, since they increase our scientific knowledge but also clearly show further degradation of and risk to marine ecosystems," added Yasuhara. Yasuhara concluded "Estuaries and deltas have urgent issues such as eutrophication, deoxygenation, source river damming, because of direct contact to urban areas. Polar regions have stronger negative effects and implications from global warming such as melting sea ice than lower latitudes. However, risks in deep sea should not be discounted. Despite its remote environment, it is not immune from human-induced impacts. I am working as a co-lead in the climatic change group of an international deep-sea conservation network, Deep Ocean Stewardship Initiative, and addressing emergent issues such as combined impacts of deep-sea mining and climatic change, combined effects of warming and deoxygenation, and green geoengineering impacts." The launch event was broadcasted online here.  Link of the Second World Ocean Assessment: https://www.un.org/regularprocess  For more information about Dr Moriaki Yasuhara’s research, please visit here.    The Second World Ocean Assessment (WOA II) is the major output of the second cycle of the Regular Process for Global Reporting and Assessment of the States of the Marine Environment, including Socioeconomic Aspects. Photo courtesy of United Nations   A pair of California sheep head and a giant sea star  in the kelp forest around one of California’s Channel Islands. Photo courtesy of Hannes Klostermann, Winner of 2020 World Oceans Day  Photo Competition (Underwater Seascapes)   Rich biodiversity under the water.  Photo courtesy of Galice Hoarau, Winner of 2019 World Oceans Day  Photo Competition (Underwater Life).  

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The website of Faculty of Science won the Gold Award in Web Accessibility Recognition Scheme 2020-2021

  The website of Faculty of Science won the Gold Award in Web Accessibility Recognition Scheme 2020-2021 for incorporating web accessibility design, which complies with the legal requirement on protection against disability discrimination. This is the fourth award received by the Faculty regarding website design.         Website of Faculty of Science: www.scifac.hku.hk About the Web Accessibility Recognition Scheme: www.web-accessibility.hk

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Undergraduate research experiences open door to research career for physics student

Simba ZOU Summer Research Fellowship@Laboratory for Space Research (LSR) (BSc Year 2) & Young Scientist Scheme (YSS) Major in Physics (Intensive)   SRF strengthened my interest and determination in pursuing academic research as my life career.       Mr Simba Xiang ZOU, a second-year BSc student majoring in Physics (Intensive) and being enrolled in Young Scientist Scheme(YSS), has been fascinated by the discipline since his childhood. From fundamental building blocks of the universe to the magnificent gigantic stars and immense galaxies, Simba was attracted by this age-old subject that dates back to the times of ancient Greece. This explains his strong interest and motivation to study physics at university.  After being accepted by the Faculty’s Summer Research Fellowship (SRF) Scheme, which supports science undergraduates to conduct research under the supervision of an academic, Simba was assigned to work at the Laboratory for Space Research (LSR) in Cyberport last summer. Here he spent over two months working on a topic related to planetary nebulae, the glowing ghostly relics of dying stars. During the period, he was given access to a globally significant and unique database called “HASH” (Hong Kong/ AAO/ Strasbourg H-alpha Planetary nebula research platform that contains sets of multi-wavelength imaging data and optical spectroscopy of all known Galactic PN, and his job was to perform manual checking on the reliability of some specific subset of those data for PN with identified central stars. It took Simba a while to get into the research mode, comprehend jargons, acquaint and master the necessary research skills, but soon he managed to find a way to catch up.  Learn from the experts Most helpful of all is that he found himself, unsurprisingly learning a lot from the astronomy experts. While working on the data analysis of planetary nebulae, Simba was supervised by the Director of LSR and expert in the field Professor Quentin PARKER, which greatly improved his efficiency in working out the project, and many other experienced researchers were there to offer their helping hands. "It was like entering a marvellous academic community!" Simba said. During his summer fellowship, he assisted Professor Parker in correcting the central star coordinates of a list of planetary nebulae published in other journal papers, of which he conducted a large portion of data analysis. He also analysed two newly established planetary nebulae catalogues, where some interesting conclusions about the aforementioned errors spotted are drawn. His research findings will form the basis of a future refereed journal paper where he will be a co-author. Facing up real obstacles Simba believes that the SRF scheme does not only provide a valuable opportunity for enthusiastic students to have an early taste in conducting research, but it also equips them with the ability to self-study, that he believes plays a key role in pursuing a research career.  "For a year-two student, it is hard for me to start a research topic of my own due to limited disciplinary knowledge. However, the SRF scheme inspires me to learn more about astronomy, astrophysics and quantum physics, which I believe I will be able to find my research path very soon. It is also great to explore my research interest and possible topics, which may in turn affect my choices of courses later on during my undergraduate study. I would say it strengthened my interest and determination in pursuing academic research as my life career." During the Summer Research Fellowship, Simba was surrounded by experts who gave him the best learning experience.    Simba has got a chance to be the second author of a journal paper.   The fantastic scenery outside LSR.  Other student stories  

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What do the Galapagos Islands have in common with ponds in Finland? They are both laboratories, where scientists like HKU’s Professor Juha Merila, can observe evolution in action

  The Galapagos Islands is where Charles Darwin formulated the theory of evolution. Darwin realised that groups of animals of the same species had become stranded on different islands of the Galapagos archipelago and lost contact with each other. In isolation, they evolved into organisms often very different from the original stranded ancestor.   The same process still goes on around us – Professor Juha Merila of the Research Division for Ecology & Biodiversity and the School of Biological Sciences, observed evolution as it takes place, in real time, in ponds in his native Finland.   Finland is a land of lakes and ponds – on the map they look like islands of water in the sea of forest. Just like on the Galapagos, some animals, such as fish and amphibians, are often cut off from their fellow species in other ponds. But unlike the Galapagos, these Finnish “freshwater islands” have no giant tortoises or marine iguanas. Professor Merila observed evolution in small fish, a species known as nine-spined stickleback.   Sticklebacks are very common in the northern hemisphere. Able to live equally well in salt and freshwater, these small fish can move freely between the sea, lakes and rivers. Over the millennia, populations of sticklebacks become cut off from their “mother populations” in the sea. Trapped in a small lake or a pond, sticklebacks found themselves in a very different environment.   One of the changes probably came as a relief to sticklebacks – unlike the sea, the small Finnish ponds have no large predatory fish that can gobble up them up in one go. In the sea, the sticklebacks’ natural defence against fish predators are two large, sharp pelvic spines – if you grab a stickleback, it will immediately stick them out perpendicularly to its bodyline, making itself very hard to swallow.   In the ponds where Merila did his research, there are no such large predators, and the pelvic spines offer no advantage. They are also heavy, and pond sticklebacks have been shedding this load. They do so by losing their pelvis that the spines are part of.   Losing your pelvis, a major skeletal structure, also means losing your legs. About fourteen million years ago, lizards did just that, giving rise to legless snakes.  But some snakes, such as pythons, still have remnants of legs, now reduced to a pair of claws. These claws are the equivalent of stickleback’s pelvic spines.   The gene responsible for the pelvis loss and reduction in sticklebacks has been known for years, and is called Pitx1. The same gene is also present in humans, and is thought to be tied to a condition known as club foot.   Merila’s research, however, showed that in nine-spined stickleback populations in isolated ponds in Finland, not only Pitx1, but several other genes are also involved in loss or reduction of pelvis. Merila adds that we still do not know what those genes are.   Merila explains that populations of sticklebacks that he studied in Finland have no contact with each other – fish are unable to travel from pond to pond over land. This means that there is no gene flow between populations in different ponds. Gene flow enriches genetic material of a population by giving the evolution more gene variants to work with. Stuck with the original set of gene variants that they inherited from the mother population, different populations of Finnish sticklebacks have to find their own genetic solution to their new common problem – living in ponds.   “Different populations of sticklebacks solve this common problem with similar phenotypic - meaning they look the same, changes. But they arrive at this same result in different ponds by using different genes. This hidden genetic diversity tells us that nature is often much more complicated and diverse than how it looks at the surface.” Says Merila.   Large, voracious fish may no longer be a threat to sticklebacks in ponds, but freshwaters come with a different predator, a “horrible” one, according to Merila. This predator is an insect - dragonfly larva.   Dragonfly larvae are ambush predators. Sitting motionless on underwater vegetation they wait for prey to swim by. When a small fish, an insect, or a crustacean gets within range, the larva fires at it a specialised organ knows as mask, a specially adapted mouth part, grabbing the prey and then devouring it bit by bit. Pelvic spines, an effective defence again a predator that tries to swallow stickleback whole, are not only useless against dragonfly larvae, but actually make it easier for them to grab a stickleback.   What options are open to pond sticklebacks to deal with this new predator? One is to get rid of the spines by losing the pelvis that the spines are part of.   Another evolutionary response, says Merila, is to outgrow the predator. Nine-spined Finnish sticklebacks that Merila worked with, are doing it in parallel with losing their pelvises, and have become “giants” compared to their marine relatives. They reach the length of 12 centimetres, which is twice the length of marine nine-spined sticklebacks, and several times the size of the larvae of most species of dragonflies.   Merila delights in the ability of evolution for find solutions for problems set by the changes in the environment: “Richard Dawkins in his book, I think it was The Blind Watchmaker, said – evolution is a tinkerer!”     Article by Dr Pavel Toropov from Research Division of Ecology and Biodiversity and School of Biological Sciences Finland is a country of lakes and ponds. Each one can act as an island where populations of some species exist in isolation, creating ideal conditions to study evolution, just like on the Galapagos Islands. (Credit: Handout) A “giant” nine-spined stickleback from a Finnish pond. Living in ponds without fish predators, the species is responding to their new predators – dragonfly larvae, by outgrowing them. (Credit: Petri Kuokka) Marine iguanas on one of the Galapagos Islands. The species is an example of how an isolated population evolved to become very different from its ancestors. (Credit: Pavel Toropov) Nine-spined sticklebacks are very common in the Northern Hemisphere, and can live in both the sea and the freshwaters. (Credit: Petri Kuokka) One of the Finnish ponds where Prof Merilä and his team did their research on sticklebacks. (Credit: Juha Merilä) Professor Juha Merilä in his office. (Credit: Pavel Toropov)

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Professor Guosheng Yin elected as a Fellow of the Institute of Mathematical Statistics 2021

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Science Teachers Received the HKU Excellence Awards 2020

  Congratulations to our teachers for their being honored at the HKU Excellence Awards Presentation Ceremony 2020. The Faculty is very proud of their achievements and would like to join the university to pay tribute to the outstanding work of our exceptional teachers and researchers.   Outstanding Teaching Award 2020 Dr Janet CHAN Kit Yan, School of Biological Sciences more Dr Thiyagarajan VENGATESEN, School of Biological Sciences more   Outstanding Young Researcher Award 2020 Dr AU YEUNG Ho Yu, Department of Chemistry more Dr Timothy Carlton BONEBRAKE, School of Biological Sciences more Dr Neil Ryan MC KENZIE, Department of Earth Sciences more   Outstanding Research Student Supervisor Award 2020 Professor David DUDGEON, School of Biological Sciences more   Knowledge Exchange Excellence Award 2020 Dr Caroline Elise DINGLE, Dr David Michael BAKER, Dr Timothy Carlton BONEBRAKE and  Professor David DUDGEON from School of Biological Sciences ‘Reduction of Illegal Global Wildlife Trade through Novel Conservation Forensics Research’ more  

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In Loving Memory of Doctor of Science and Emeritus Professor Brian Morton

It is with deep sadness that we mourn for the passing away of Emeritus Professor Brian MORTON on March 28, 2021 in his sleep, at the age of 78. We honour the memory of Professor Morton in many aspects, be it his relentless commitment in founding the Swire Laboratory (later renamed as Swire Institute of Marine Science) 3 decades ago, or his significant contributions in teaching and research in marine biology as well as in pioneering the marine environmental conservation in Hong Kong. Professor Morton obtained his degrees from King's College, the University of London, and almost immediately joined The University of Hong Kong as an Assistant Lecturer. He remained in Hong Kong for almost 34 years and, on retirement, was appointed Professor Emeritus of Marine Ecology. He published extensively on the marine biology and ecology of Hong Kong, China, the Azores and the Gulf of Mexico. On retirement in 2003, he returned to his childhood home on the south coast of England and wrote his book (2008) entitled “The historical ecology of the River Arun and its beaches at Littlehampton, West Sussex: 1,000 years of change”, and later in 2018 he published another book “The Story of a Mute Swan on the River Arun at Littlehampton in West Sussex, England”. For his many achievements, he was made a Life Fellow of the Pacific Science Association (1993) and elected to the Global 500 by UNEP in recognition of his contributions to Pacific marine science and conservation, respectively. In 1997, he was invested as Knight (Ridder) in the Order of the Golden Ark, The Netherlands, in 1999 invested OBE, the UK, for contributions to conservation and marine science, respectively, and was the recipient of the Duke of Edinburgh Conservation Gold Medal in 2004 and Doctor of Science of The University of Hong Kong in 2014. We honour the memory of Professor Morton for his lifetime dedication to the research in local marine fauna and flora. He will be dearly missed by all whose lives he touched, and we offer our deepest condolences to his family.    Revisit an interview with Professor Morton by clicking here. 

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Interview: Professor David Dudgeon speaks about his latest book - Freshwater Biodiversity – Status, Threats and Conservation

Last year, Professor David DUDGEON, Emeritus Professor of School of Biological Sciences, released a book “Freshwater Biodiversity – Status, Threats and Conservation”. The book is an urgent call to protect our freshwaters - lakes and rivers that we rely on for drinking water and to irrigate crops, and whose fisheries are actually larger than the sea fisheries.   In the book, his 9th, Dudgeon explains why lakes and rivers, that amount to less than 1% of our planet’s surface area but are home to almost 9% of the world’s species, are far more fragile than marine and terrestrial ecosystems. He tells of the extent of damage and exploitation the freshwaters have suffered – much greater than what the humanity has inflicted on land and in the sea. With quotes from Leonardo da Vinci to Shakespeare and Greta Thunberg, and headings such as “Have all the Bigger Freshwater Fishes Really Had Their Chips?”, the book is a wealth of hard-hitting facts: that, according to population trend data, freshwater animals have declined by 81% since the 1970 - far more than those on land or in the oceans, and that about a third of all freshwater species are now endangered. Dudgeon concludes the book with a warning that, despite climate change threatening to wreck our freshwater ecosystems beyond repair, there are still no adequate international strategies or targets to protect the planet’s lakes and rivers.   When people think of life in the water, it means life in the sea. Freshwater does not get a look in!   P: Dr Pavel TOROPOV from Research Division of Ecology and Biodiversity and School of Biological Sciences D: Professor David DUDGEON from Research Division of Ecology and Biodiversity and School of Biological Sciences   P: What made you write this book? D: In 2006 I was a coordinator of a review article published by Cambridge University Press, which said - look, tigers and whales and corals are threatened by humans, and almost everyone knows that, but nobody cares about freshwater biodiversity! That article became very widely cited and Cambridge University Press asked me – can you expand it into book? It was around 2008-2009 when I committed to writing it, but I found there was a lot to say. I didn’t finish until 2019.    P: Why are freshwater ecosystems so vulnerable, more so than terrestrial or marine ecosystems? D: Fresh waters are embedded within human-dominated landscapes and are the receivers of any insults affecting (the surrounding) terrestrial systems. Also, humans take out or divert the medium that freshwater animals need to live - this does not happen to sea water. Most fresh water animals have tiny ranges (a single lake or river basin), and so are more easily driven to extinction by a single event, say an episode of pollution, than their land- or sea-based counterparts.    Climate change will increase human demands for water, as we will need more water to grow food in a hotter world. So freshwater critters are more at risk from climate change that most other animals, given the dual problem of changing water availability and warming. Plus, if you are in an isolated lake or an east-west flowing river, you do not have the option of moving north into cooler climes.  Freshwater is also a multiuser resource for which humans compete. A factory owner using a river for waste disposal 'competes' with a farmer who wants that water for irrigation, as well as with those who need good quality water to sustain fisheries or as a source of potable water.  Someone building a dam upstream of any of these users also will compromise the  availability of water for others. After all this competition among human users there is not much left over for nature.   P: Yet freshwaters tend to be overlooked by the public and the conservationists, why is that? D: People are distracted about leopards, tigers - all those wonderful animals that live on land! When you look at David Attenborough documentaries, there is just one episode in the original Life on Earth series that deals with freshwater. When people think of life in the water, (for them) it means life in the sea; freshwater does not get a look in! What proportion of world fisheries occur in the oceans and in freshwater? (The answer is) Half and half, actually slightly more in freshwater. The Mekong (river) alone provides 10% of the world’s (total) fishery yields! But most people think that all the fish live in the sea! That’s not the case, but most of the fish living in freshwater are small - because the big ones have long since been fished out - dull-coloured  species, but people disregard them in favour of gaudy marine coral fish and tasty groupers.   P: Hong Kong’s freshwater biodiversity does not get mentioned often. D: There is a lot of freshwater biodiversity in Hong Kong: over 100 species of dragonflies, 25 amphibians, more than 70 freshwater fishes, including some endemic species that are found nowhere else in the world. And there are freshwater crabs and shrimps, and a host of aquatic insects.   P: You discovered several new species in Hong Kong, including a new species of fish – Hong Kong paradise fish, correct? D: I 'discovered' the Hong Kong paradise fish in a local marshland some years ago, although I did not initially conclude that it was an entirely unknown species. That judgement was made by two German ichthyologists and they named it Macropodus hongkongensis.  (In Hong Kong) I've also described a new dragonfly and some mayflies and caddisflies, but I guess that is of much less interest! And I had some new species of bugs and beetles (found in Hong Kong) named after me.   P: Why does not the plight of tropical freshwater fisheries that you describe in your book, get far less attention, compared to the problems of European sea fishermen? D: To be honest, this is because those affected are poor people of colour. Also, they often catch small fish - these freshwater fisheries are largely beneath the radar, in Europe anything in a lake or river that is not salmon, is not a fish worth eating.  But (in tropical freshwater fisheries) many fish eaten are small fish, that are consumed whole or fermented and used as fish paste or garnish.   P: In the book, you go through all the threats to freshwaters – overexploitation, river regulation, but the largest chapter is about invasive species – 90 pages. D: Yes, I got a little carried away there, but some people take a view that invasive species are the most pernicious threat to biodiversity. Freshwaters are more vulnerable to invasives than marine ecosystems, because freshwaters are like islands surrounded by land, and each island is not saturated with respect to species. That could mean that there is space for invasive species to get in there, and there is not necessarily a species in the ecosystem that can parasitize and kill that invader. I don’t think you can go out and eliminate the invasives, with very few exceptions.  Invasion, lie extinction, is forever.  Invasives tend to do well in systems that we have degraded or shifted from natural state. Unless we can restore them, the native species have little chance to recover.   P: Do Aichi Biodiversity targets (set by the UN’s Convention on Biodiversity in 2010) or the 17 United Nations Sustainable Development Goals cater for freshwater? D: There is no Aichi target referring specifically to protecting life in fresh waters.  But there certainly should be one! The ‘Life below water’ Sustainable Development Goal refers solely to oceans, and could be extended to cover freshwater animals.   P: What would you set as new targets to protect freshwater biodiversity? D: Maintaining the flow of rivers, maintaining longitudinal connection and mimicking the natural seasonal ups and downs in flow in some way. We also need to have something about sustainable exploitation of living resources – fishes, frogs, and so on. One thing I did not touch on in this book - we are unsustainably removing sand from rivers for use in making concrete for building. It is happening in the Mekong Delta, it is happening in the Yangtze, and all over India. We must stop over exploiting the non-biological part of the environment too. Then it is the question of controlling water pollution, and of somehow managing invasive species. You need a black list of the species people are not allowed to bring in to countries where they may become a nuisance. We know what we need to do. But the willpower to do it is not there!   P: In the book you call the loss of species due to human action “morally repugnant”, and say that if we ever want biodiversity to be considered in decision making, loss of species must be considered as such. D: This is from a talk I gave in Liverpool about freshwater biodiversity -  I said: “we need to stand up and say to those who make the decisions - this loss of species is morally repugnant!” And I thought: “Am I going out on a limb here?” But I got applause and some people then posted it on Twitter. Or so I heard, I am too old to do social media.   P: A quote from your book: “it is a challenge to remain optimistic about the future of freshwater biodiversity”.  Are you hopeful? D: Before I wrote this book, I would give talks on this, and someone would always come up to me and say: “You depressed me so much!” I thought I managed to avoid being overly pessimistic in this book, although I tried to be realistic.  Anyway, my answer is - I am not hopeful, but I am optimistic!   Article by Dr Pavel Toropov from Research Division of Ecology and Biodiversity and School of Biological Sciences A typical family catch on the River Marañón in Peruvian Amazonia. Small fish account for large part of freshwater fisheries' landings. Image: Pavel Toropov European sturgeon used to be found in rivers across Europe, reaching lengths of up to 6 metres. Now the species is critically endangered. Large freshwater fish are becoming increasingly rare worldwide. Image: Hans Braxmeier / Pixabay Hong Kong paradise fish – a new species discovered in Hong Kong by Professor Dudgeon. Image: David Dudgeon Red-eared sliders, originally from North America, are one of the world's worst invasive animal species, and are frequently the subject of misguided mercy releases in Hong Kong. Image: Alan Leung The Mekong River is not only the worlds’ largest inland fishery, but also accounts for 10% of combined global fisheries. It is the source of protein for millions of people. Image: Richard Mcall / Pixabay Water hyacinth is one of the most destructive invasive plant species. It that can quickly overgrow freshwater habitats, smothering the water surface and impeding oxygen exchange. Image: nguyenhuungli / Pixabay   Freshwaters, such as the Yangtze River that flows through the Chinese megapolis of Chongqing, are embedded within terrestrial ecosystems and receive a massive impact from the surrounding human activity. Image: Sicheng Yang / Pixabay The Hoover Dam in the USA. Dams are highly damaging to the functioning of river ecosystems. Image: RJA1988 / Pixabay Professor Dudgeon’s latest book – “Freshwater Biodiversity – Status, Threats and Conservation” took ten years to complete. Image: Alex Reshikov Professor David Dudgeon in his office. Image: Alex Reshikov

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Research on microfluidic platform for metastasis detection and drug discovery won a Silver Medal at 2021 Inventions Geneva Evaluation Days

A research team led by Professor Alice Sze Tsai WONG from the Research Division for Molecular and Cell Biology, including her collaborators Dr Shanshan LI, Dr Ka Man IP, Dr Kei Shuen TANG and Professor Ho Cheung SHUM, won a Silver Medal at the Special Edition 2021 Inventions Geneva Evaluation Days hosted by The International Exhibition of Inventions of Geneva (IEIG).  The team developed a microfluidic tool that captures metastatic cancer cells, which can differentiate metastatic and non-metastatic cells by biochemical and biophysical characteristics of individual cells, aiming for diagnostic and drug screening purposes. It works best with ovarian cancer, colorectal, gastric and prostate cancers.  IEIG is one of the most significant global annual events devoted exclusively to inventions, and also a platform for enthusiastic scientists and inventors to present their latest invention for the first time. This year’s competition is a first-ever special virtual-only edition of IEIG, offering the possibility for around 600 inventors from about 20 countries worldwide to participate in the competition by presenting their invention via a 3-minute video. These inventions were evaluated on virtual platforms by the international jury of specialists from 10 to 14 March 2021. For details about the International Exhibition of Inventions of Geneva, please visit: https://inventions-geneva.ch/en/home/ Affiliations of the research team:  Dr Ka Man IP, Postdoctoral Fellow of Research Division for Molecular and Cell Biology Dr Shanshan LI, Honorary Research Associate of HKU - Shenzhen Hospital Professor Ho Cheung SHUM, Professor of Department of Mechanical Engineering Dr Kei Shuen TANG, Honorary Research Assistant Professor of Research Division for Molecular and Cell Biology Professor Alice Sze Tsai WONG, Associate Dean(Teaching and Learning) and Professor of Research Division for Molecular and Cell Biology

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Newsletter spolights - "Do Physics", make a big impact!

Professor Hoi Kwong LO Director of Research Division for Physics & Astronomy and Chair Professor of Department of Physics   I encourage our faculty members to think big and be ambitious in their research plans, this is the only key of making a difference to the society.     Professor Hoi Kwong LO has just entered a new chapter in his life – being appointed as the Director of Research Division of Physics and Astronomy. This is not only the first time he has taken up an administrative role in a university, but also the first permanent position that he has ever had in Hong Kong after three decades living abroad. Professor Lo was born and raised in Hong Kong. His winning of the Prince Philip Scholarship in 1986 was a life-changing point for him, which allowed him to set sail and pursue his dreams in Cambridge. Since then, he started his prolonged journey in the UK and North America. “It's very exciting to be back to my home town. There‘s quite a change, but I’m happy to embrace the new chapter in my life. It’s like ‘give and take’ – I won a scholarship to Cambridge for undergraduate studies, and now I’ve got a chance to contribute back in some way,” said Professor Lo. What you wear speaks for you. The subtle yet eye-catching quote “something different” imprinted on Professor Lo’s tee on the interview day made a statement for him. “Yes, I want a change.” As a top-notch scientist in the research domain of quantum information processing, he was among the first to demonstrate the impossibility of a whole class of quantum cryptographic protocols including quantum bit commitment, thus correcting an error that had been believed for a long time in the field. “I have achieved quite a bit throughout my research life, and now I hope I could make a bigger impact by influencing others.” Formulating new strategies for scientific research The Division has been traditionally strong in two strategic research areas: condensed matter physics and astrophysics. Under the new strategic direction, the Division will continue to retain its traditional strengths while expanding substantially in two new areas: quantum information science (QIS) and optics and photonics. “Physics is very diverse. Our four strategic areas do represent some of the most active areas of physics research today.” QIS has become a strategic research initiative in many large firms, including IBM, Intel, Google, Microsoft and Alibaba, which are all investing heavily in quantum technologies including quantum computing. “Quantum computing not only can break standard encryption schemes such as Rivest–Shamir–Adleman (RSA), but also can lead to an exponential speed-up for some computational problems such as the simulations of quantum systems in quantum physics and quantum chemistry. Quantum cryptography, which is my own specialty, offers information-theoretic security (also known as the Holy Grail of communication security).” Besides the four strategic areas, the Division will also continue to investigate in nuclear physics and elementary particle physics through international collaborations. Leveraging the Division’s long-standing existing strength on the theoretical side, it plans to grow substantially on the experimental side in the next few years. The primary mission of the Division as a research unit is to ‘do physics’. Since many of our academic staff, postdocs, and graduate students are highly capable and talented, I hold the vision that our Research Division could be a premier research centre in physics and astronomy.” Interdisciplinary approach facilitates problem solving  The growing call for interdisciplinary research boosts synergy where cross-disciplinary knowledge can be integrated and broadened. Take Professor Lo as an example, he has been leading a career path highly related to interdisciplinary research. The power of interdisciplinarity is self-explanatory in Professor Lo’s story. “I studied mathematics for my bachelor‘s degree, and physics for my PhD. During my postdoc years, I did research in theoretical computer science. For the 17 years at the University of Toronto, I held a joint appointment across two faculties. Owing to my own experience, I am a firm believer in interdisciplinary research.” One of the main growth areas will be quantum information science. The plan there is to establish an Institute of Quantum Science over the next few years, which combines the strengths in quantum matter (a part of condensed matter physics) and QIS. Moreover, it will include researchers in physics, chemistry, mathematics, computer science and engineering. In building up the Institute, the Division will need to reach out to other Divisions and Departments to explore joint appointments and collaborative projects. “I also like to work with industries as I have had six years of industrial experiences with three years (1996-1999) at Hewlett-Packard Labs, Bristol, in the UK and three years (1999-2003) in a quantum start-up MagiQ Technologies, Inc. New York, NY. So, to make a big impact, we may need to collaborate with others. If people from different disciplines work together, they are likely to solve bigger scientific problems.” Another important growth area is optics and photonics including optical metamaterials. It is also closely related to QIS. It involves both physicists and electrical engineers and it is a subject that involves both fundamental physics and real-life applications. The Division has been very much in an uptrend in last few years. According to the last round of Research Assessment Exercise (RAE), its annual citations (ISI) have more than doubled from 6,856 in 2013 to 16,398 in 2018, which shows that the research activities have improved rather substantially in terms of both quality and quantity. “We are doing outstanding research in condensed matter physics. For instance, Professor Wang YAO has got some very highly cited papers and is also a highly cited researcher. Besides that, we have been winning more awards including two Croucher Senior Research Fellowships and getting more research grants. We secured some funding from Collaborative Research Fund (CRF) –  two by Professor Maohai XIE, one by Professor Jeremy LIM and the other one by Professor Zidan WANG.” As a leader of the Research Division, his mission is to create a good research atmosphere and maximise the potential of the Division. “I encourage our faculty members to think big and be ambitious in their research plans. This is the only key of making a difference to the society,” Professor Lo added.   Achievements of Division members in recent years  2020 Professor Wang YAO was elected as a fellow of American Physical Society and the Croucher Foundation Senior Research Fellowship Professor Shijie XU, Professor Mao Hai XIE and collaborators won the Ministry of Education Natural Science Award (2nd class) 2017 Professor Xiaodong CUI was awarded the Croucher Foundation Senior Research Fellowship    Profile  2019 Fellow of Optical Society(OSA) 2018 Fellow of American Physical Society (APS) 2003 Outstanding Young Researcher Award (OYRA) by the OCPA (Overseas Chinese Physicists Association) Premier’s Research Excellence Award 1986 - 1989 Prince Philip Scholarship

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Research reveals that the sediment of Hong Kong’s Tolo Harbour contains Antibiotic Resistant Genes

A study by HKU scientists Dr Chen Jiarui of State Key Laboratory of Pharmaceutical Biotechnology at the Department of Medicine and Dr Shelby McIlroy of the Swire Institute of Marine Science (SWIMS) and Research Division for Ecology & Biodiversity, showed that bacteria in the sediment of Hong Kong’s Tolo Harbour contain Antibiotic Resistant Genes (ARGs).    The presence of ARGs indicates that bacteria in Hong Kong’s marine sediments have evolved to become resistant to a wide range of antibiotics. Infections by such bacteria may be untreatable and potentially fatal.    Chen and McIlroy’s research is part of the Marine Global Earth Observatory (MarineGeo) Initiative, directed by the Smithsonian’s Tennenbaum Marine Observatories Network (TMON). Partners in MarineGEO, HKUs Swire Institute of Marine Science (SWIMS) one of them, are cataloguing the biodiversity of coastal marine life around the world. The aim is to understand how and why this biodiversity is changing, and the consequences this change may have for people.    McIlroy decided to focus on the very small organisms that are usually overlooked in marine biodiversity surveys – bacteria in the sand and mud on the sea bottom.   “We wanted to link biodiversity in the marine environment to human health, so we decided to look at microbiome (ecosystem of microscopic organisms such as bacteria) in the sediments.” Says McIlroy.   The scientists took samples of the sediment from 4 locations – Centre Island, deep inside Tolo Harbour, Che Lei Pai in Tolo Channel, Port Island just outside the entrance to Tolo Channel, and Tung Ping Chau in Mirs Bay. High levels of pollution in Tolo Channel are well documented.    The bacteria were identified using a DNA-based method known as “shotgun sequencing” –all of the DNA was extracted together from a sample of sediment, and then ran through the database of known bacterial DNA to produce a list of bacteria present.    In order to make a connection between these bacteria and their possible impact on human health, the researchers looked at the presence of certain genes in the bacterial DNA “soup” that was extracted from the mud. The choice fell on the genes for antibiotic resistance known as ARGs.   ARGs are genetic blueprints from which bacteria build the internal machinery that allows them to survive an “attack” by antibiotics.    In the paper, McIlroy separated the bacteria they found into 4 groups based on what “machinery” their ARGs coded for.    “Some bacteria have e-flux pumps that pump out antibiotics out of the cell as fast as they can. Other bacteria have enzymes that inactivate antibiotics by cutting them up or chemically degrading them. Other bacteria can protect parts of their DNA that antibiotics attack – by making small alterations to parts of their DNA that antibiotics recognise, or by putting a chemical compound onto that part of DNA to protect it from the antibiotic.” Explained McIlroy.   The “most worrying finding”, says McIlroy, was a clear relationship between the ARGs and pollution.    Chen explained that the sites followed a pollution gradient – the pollution increases the deeper you go from Mirs Bay into the Tolo Channel. Center Island, the innermost site, had the highest abundance of ARGs, much higher than Ting Ping Chau that is located outside Tolo, in Mirs Bay.     Another alarming finding was that the genes for the most effective antibiotic resistance mechanism – the efflux pump, were the most common. Bacteria equipped with the e-pump can use this method to get rid of any antibiotic that is attacking their cell.    ARGs found in the bacteria in Hong Kong’s marine sediments provide resistance to a wide range of antibiotics. These included penicillin, tetracyclines, and also fluoroquinolones - a group that includes ciprofloxacin, one of the most widely used antibiotics worldwide, often used for urinary tract infections.    The bacteria in the sediment develop antibiotic resistance by being subjected to prolonged exposure to antibiotics, but how do the antibiotics end up in the sea?  A person taking antibiotics passes them into their faeces and then the inadequately treated sewage containing these antibiotics reaches the sea where it comes into contact with bacteria in the sediment.    The exposure then kicks off evolutionary response – bacteria adapt, finding ways to counteract the effect of antibiotics and, with generations, developing genes that give them resistance to antibiotics. For this reason, the use of antibiotics must be tightly controlled.   According to the World Health Organisation, “antibiotic resistance is one of the biggest threats to global health today.”   The Chief Medical Officer for England, Dame Professor Sally Davies, said that antibiotic resistance could “lead to the end of modern medicine as we know it” with routine operations and childbirth becoming increasingly dangerous.    The overuse of antibiotics by Hong Kongers has been well documented. A 2015 paper in Hong Kong Medical Journal concluded that: “The general public’s knowledge about antibiotics is inadequate. 30% of the public would expect or request antibiotics for a common cold.” Completely ineffective against cold and flu that are caused by viruses, not bacteria, antibiotics are sold without prescriptions in many of the cities pharmacies.   McIlroy says that even though ARGs have been found in bacteria in Hong Kong’s seas, there is no cause for over-reaction: “Pathogens and bacteria are everywhere - they occur naturally in the environment. Just because you find something (like antibiotic-resistant bacteria), it does not mean you are in an outbreak situation.”   However, she says that the results of the research mean that the problem must be addressed: “Clearly, there are issues with water quality that have implications for human health. We are now expanding this work across the wider breadth of Hong Kong.”   Article by Dr Pavel Toropov from Research Division of Ecology and Biodiversity and School of Biological Sciences   Dr Mcllroy collecting sediment samples at Tung Ping Chau Dr Shelby McIlroy collecting samples amonst the corals at Tung Ping Chau where the pollution was least and the levels of ARGs the lowest   

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Name an Ant initiative - HKU taxonomist brings attention to biodiversity loss by sharing with the public the excitement of discovering new life

At work in his office. (Photo by Alex Reshikov) Dr Benoit Guénard is a taxonomist and ecologist at HKU’s  Research Division for Ecology & Biodiversity Research at the Faculty of Science. Guénard finds and describes new forms of life, and his team have been making discoveries of new species of ants and other invertebrates in Hong Kong and Macau. In order to make the public aware of the importance of protecting small invertebrates such as ants that are crucial for maintaining healthy ecosystems, Guénard started Name an Ant initiative, where a financial donor has the right to name a new species of ant. Whoever takes part in this initiative will join Harrison Ford and Barack Obama, who both had ant species named after them in recognition to their contribution to protecting the environment.   “You probably read in the news – a craft that cost 2,7 billion dollars has just been sent to Mars to seek life. This is great, but as someone who works on biodiversity, I can tell you that 80% of life on this planet is estimated to be unknown. Even in Hong Kong there are a lot of species to discover!” says Guénard.   Since his arrival in Hong Kong in 2014, Guénard and his students have been discovering and describing new life -  9 new species of ants, 3 species of flies and 3 species of wasps – all new to science, all of them found here in Hong Kong. In the much smaller, far less wild Macau, Guenard’s team described 2 new species of ants. In 2019, the discovery of three new ant species by Guénard’s team made headlines.   “We don’t need to go to Mars to find new life. If I scoop up some leaf litter just here”, Guénard points at a green space on campus, “It is likely to harbour new species - ants, pseudoscorpions, springtails, mites.” One of the new ant species Guénard described, was found  “right here, 200 metres from HKU’s plaza”.   Why are there so many undiscovered species right under our noses, in the middle of Hong Kong’s urban sprawl?   “The problem is that nobody looks for them”, says Guénard, explaining that the attention of the public, the scientists and the conservationists often focuses on larger species. Small land arthropods, a group that includes insects, spiders, mites, millipedes and centipedes, remain “below the radar.”   But, he says, land arthropods account for 80% of the world’s biodiversity. These small animals are extremely important – they are essential for ecosystem functioning and must be protected.   Ants are especially important. Thousands of species of plants rely on ants for seed dispersal and ants are also indispensable soil engineers. They enrich the soil by burying vast quantities of organic matter inside it, and by digging their nests, ants maintain the turnover of organic matter in the soil, ensuring that it stays fertile and can support other life. On his website, Guénard quotes Harvard professor Edward O. Wilson who called ants “the little things that run the world”.   In Hong Kong these ecosystem engineers are directly threatened by land development and must be protected. But before protecting a species, we must first name it.   “We need to know how to distinguish them and give them names. Once we give them names, we can start studying them - what do they do? Why are they important, and to what extent? How are they connected together in the ecosystem?”   Scientists say that we are now in the middle of the sixth mass extinction crisis. Guénard quotes a 2015 study that estimates that we may have already lost 7% of the planet’s species – approximately 130,000 in total, far more than previously thought. The same study warns that land invertebrates are under-represented in such estimates, despite them representing the bulk of the world’s biodiversity.   The result is that, not only do we not know how many species of ants and spiders we have already lost, invertebrate species are going extinct without having been described first -ecosystems are losing their vital working parts without people ever knowing what they are.   One of the reasons why discovery and naming of invertebrate species cannot keep up with the rate of extinctions, explains Guénard, is that taxonomy – the discipline of describing and classifying living organisms, is often seen as unexciting and tedious by the biologists and the public.   Guénard tries to break this stereotype by involving both undergraduate students and the public in taxonomy, and he does so by sharing with them the excitement of discovery of new life.   “I try to engage the undergraduate students – the young biologists. They can leave their first mark in science by describing a new species!”   Another incentive is that the students can take part in the official naming of the new species, leaving a permanent record in science.   “I give them the choice how to name the species - sometimes we call the species after other ant biologists. Unfortunately, one of my colleagues passed away last fall, we named one new species after him.” Guénard’s team also named an ant species after Lantau Island, where it was discovered - Strumigenys lantaui.   In 2018 Guénard came up with Name an Ant initiative. Donors can decide on a name of a new species of ant that Guénard’s research discovers and describes.   “You can support biodiversity research by funding us, and we will name an ant with a name you want.”   The money donated is used for a variety of essential uses that species description requires - hiring research staff, paying publication fees, buying equipment, and paying for research permits.   Name an Ant is already working. In 2019, Guenard’s team described three new species of ants in Hong Kong. One was named Strumigenys nathistorisoc, to honour the contribution of funds from the Hong Kong Naturalist Society.   Guénard says that a new private donor has recently stepped forward: “She is enthusiastic about it! We discovered 7 new species, not from Hong Kong, from other parts of China and also Vietnam, and the donor said - I will support you. We have hired a former undergraduate student who recently graduated to work on it, and the donor can pick a name. Perhaps, she will name it after one of her children.”   “It is a great way to engage the community. People should feel proud to be describing biodiversity for conservation.”   The tradition of naming species after people who made contributions to environmental protection and science is well-established.   Pheidole harrisonfordi, an ant that lives in the forest litter in Central America, was named after the actor Harrison Ford in 2003, in recognition of the Hollywood star’s efforts in conservation and environmental education.   Barack Obama also has an ant species named after him - Zasphinctus obamai, described in 2017 by several of Guénard’s colleagues, as well as two species of fish, two spiders, a bird, a bee, a worm, a lichen, a beetle, a blood fluke, and an extinct species of lizard.   Donald Trump has only one species named after him – a moth Neopalpa donaldtrumpi, whose head scales resemble the ex-president’s distinctive hairstyle.   Article by Dr Pavel Toropov from Research Division of Ecology and Biodiversity and School of Biological Sciences Ant species collection - some of the funds from Name an Ant initiative will go towards making and maintaning such collections (Photo by Alex Reshikov) Work station in Benoit Guénard's lab - a microphotograph of the head of a new species currently being described is on the computer screen (Photo by Alex Reshikov) Guénard at a microscope workstation where the new morphology of new species is studied and described (Photo by Alex Reshikov) Research assistant Wilfred Kit Lam Tang going through ant collection - he has worked with Guénard on discovery an description of numerous species of ants (Photo by Alex Reshikov)  

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Legal wildlife trade – ten times bigger than the illegal trade, and doing massive damage to biodiversity

Legal Market in Whale Meat and Live Primates Worth Hundreds of Millions of US Dollars The illegal wildlife trade, estimated at about 23 billion US dollars per year, has been covered extensively in the media. Legal wildlife trade has received much less attention, but in her 2020 research, Astrid Andersson from Research Division for Ecology and Biodiversity of the School of Biological Sciences showed that the legal wildlife trade was worth almost ten times more than the illegal trade – over 200 billion US dollars per year.    Andersson analysed customs’ data from 1997 to 2016, from 201 countries. Her results showed that the legal wildlife trade has been over-exploiting nature on a colossal scale, removing millions upon millions of animals, from whales to sea horses, from the world’s ecosystems. In addition, the outdated bureaucracy leaves the legal trade wide open for criminals to launder and hide vast quantities of illegal trade.    The numbers are staggering. For example, 247 million dollars’ worth of whale, manatee, seal and dolphin meat was sold, absolutely legally, between 1997 and 2016. Yet, unlike the illegal wildlife trade, the legal trade is continuing almost unnoticed and largely unmonitored.    The customs information that Andersson analysed, is catalogued according to the internationally established categories of wildlife products, and each category is represented by its own customs code. The codes, what they represent, and the amounts of money involved, all make for a very unnerving reading.    “Meat and Offal of Primates”(code 20830) was worth almost 11 million US dollars, but “Live Primates” (code 10611) dwarfed that - 3 billion dollars’ worth of live monkeys, apes and lemurs were bought and sold in 20 years.    Trade in “Live Birds of Prey” was worth 333 million, “Live Parrots” - 777 million. “Live Reptiles” - for pet trade, was worth 1,9 billion dollars. “Reptile Meat” – mainly turtles and snakes - 73 million.    Just like with the illegal wildlife trade, where Hong Kong is a global hub, the city punches well above its weight in the legal trade too – here Hong Kong SAR is ranked 8th globally, behind the USA, China, Japan, Spain, France, Thailand and Germany, countries with far larger economies and populations.   Andersson categorised legal wildlife trade into categories – wild meat, furniture, pet trade, seafood, traditional Chinese medicine (TCM), and fashion.   Hong Kong turned out to the world leader in the fashion category  -  import and export of animal furs and skins of crocodiles and snakes. For TCM, the city is ranked second, behind only Mainland China.    Andersson says: “I don’t think the distinction between legal and illegal trade is that relevant. The two are intertwined, and the legal trade provides an avenue for illegal wildlife to be laundered. And, just because it is called legal, it does not mean it is harmless – the legal trade needs to be monitored, and very closely.”    Article by Dr Pavel Toropov from Research Division of Ecology and Biodiversity and School of Biological Sciences Squirrel monkeys on sale - the legal trade in live primates is very lucrative (Photo Credit: Michelle Garforth Venter) Wildcaught song birds on sale in Hong Kong (Photo Credit: Astrid Andresson) Venomous species of reptiles can also be traded legally. Here a highly venomous rattlesnake is on sale in Germany (Photo Credit: Handout) Whale meat - the legal trade in the meat of whales and seals is worth millions of dollars (Photo Credit: Robert Bahn)   Astrid Andersson at her desk - she has just defended her PhD thesis on the trade in  cockatoos  (Photo Credit: Alex Reshikov)  

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HKU Science excels in QS World University Rankings by Subject 2021

According to the QS World University Rankings by Subject 2021, HKU Science continues to excel in a wide array of science disciplines. The rankings symbolise the relentless effort of all Faculty members, and we will not be complacent but devote to achieve teaching and research excellence, creating knowledge and impacts.  Ranking summary: Life Sciences & Medicine: #55 Natural Sciences: #52 Biological Sciences: #75 Chemistry: #52 Earth & Marine Sciences: #49 Environmental Sciences: #44 Geology: #50 Materials Science: #61 Mathematics: #53 Physics & Astronomy: #66 Statistics & Operational Research #48    

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HKU-led research promotes territory-wide extension of plastic bottle deposit scheme

Plastic waste problem has become increasingly serious in Hong Kong. Roughly 20% of plastic solid waste is disposed to landfills every year, despite its high recycling potential. In view of this, a HKU research team from Research Division for Ecology and Biodiversity collaborated with the Environmental Association Limited, aiming to explore the feasibility of implementing plastic bottle deposit in Hong Kong. The results found that a proper recycling point could build citizens’ trust on plastic recycling. The suggested bottle deposit scheme could help to recycle over 56 million plastic bottles in a year, and more than 60% of the interviewees indicated their support towards the scheme.     The study has also developed a framework for the plastic bottle deposit system, suggesting  consumers to pay HK$1 refundable deposit and HK$0.5 handling fee for each plastic bottle beverage. Echoing the Waste Blueprint for Hong Kong 2035 released by the HKSAR Government in early February, this study provides useful data for implementing the Producer Responsibility Scheme on Plastic Beverage Containers, a new measure proposed by the Government. The results reveal how bottle deposit scheme reduce plastic bottle waste, help to achieve circular economy and reduce waste to be landfilled.   Reversing plastic pollution The Environmental Association Limited has introduced Reverse Vending Machines to Hong Kong since 2009, with the aims to promote recycling and to understand the difficulties faced by the recycling industry.   A Master’s research led by Dr Janet CHAN from HKU Research Division for Ecology and Biodiversity and assisted by her student Ms Jade LAM from the Master of Science in Environmental Management Programme, studied the public recycling habits, the incentives for citizens to recycle, the relationship between recycling location and recycling rate, as well as the examples of bottle deposit schemes in foreign countries. During the research, a total of 130,000 beverage containers had been collected in the study period, and 327 Hong Kong citizens were interviewed on their attitude to recycling of plastic bottles.   There are about 300 Reverse Vending Machines recently in Hong Kong, with around 2,000 beverage machines in the territory. This study estimates that at least 2,000 Reverse Vending Machines are needed for Hong Kong to recycle plastic bottles effectively.   Confirming the feasibility of extending the plastic bottle deposit scheme Through this research, the team has confirmed the feasibility of plastic bottle deposit scheme in Hong Kong. Jade Lam from the Master of Science in Environmental Management Programme said, “More than 70% of the interviewees do recycling because of their environmental considerations. The result shows that a proper recycling method could improve citizen’s confidence towards bottle recycle.” She added, “More than 60% of the interviewees support the bottle deposit scheme, reflecting that the general public have a positive attitude towards the scheme.”   To develop a framework for the plastic bottle deposit system, this research case studied the schemes implemented in Norway, Germany, Hawaii, South Korea, which play leading roles in plastic bottle waste management. The suggested framework includes: 1) a short-term goal: a plastic bottle labelling registration system which is similar to that of South Korea for glass bottles. In this registration system, all imported beverages in plastic bottles must be registered so that the beverage importers could receive the deposit refund; 2) a long-term goal: a comprehensive recycling system which is referenced to that implemented in Norway. In this recycling system, for example, a consumer needs to pay HKD$1 refundable deposit and HKD$0.5 handling fee for each plastic bottle beverage.   This study estimates that 2,000 Reverse Vending Machines are required to achieve the long-term recycling goal. Dr Janet Chan opined,“ Plastic waste is an imminent environmental crisis no matter in Hong Kong or around the world. I am delighted to see this study provides concrete figures and a down-to-earth framework for effective recycling of local plastic bottles. It demonstrates how Reverse Vending Machines support the Producer Responsibility Scheme on Plastic Beverage Containers, a new measure proposed by the Government very recently.”   Dr Wing Kwong YAU, CEO of Environmental Association Limited said, “We introduced Reverse Vending Machines to HK since 2009, with roadshows and demonstrations at shopping malls, residential estates and sports facilities. Reverse Vending Machines are common in foreign countries and provide strong incentives to increase the recycling rate. The findings of this study are valuable and reflect local citizens are still not very familiar with Reverse Vending Machines yet. Bottle deposit will also be a useful tool to encourage recycling and support the recycling industry by steadying the recycling rate and ensuring the quality of recyclables. Based on the suggestions of HKU, 2,000 machines can avoid more than 56 million plastic bottles ending up in the landfills. Based on our 10 years’ experience in managing the machines and the findings of this study, we provide a solid ground for the Government to consider implementing the bottle deposit scheme.     About Environmental Association Limited The Association aims to promote environmental education and conservation through workshops, trainings, programmes and public participation. Established in 1997 and a registered charity, the Association’s mission is made possible through the passion of volunteers, support of local community, and devotion of the staff members. It now operates four environmental centres including, Taipo Market Recycling Store, Taipo Geoheritage Centre, Fung Yuen Butterfly Reserve, EWise Discovery Centre.   Click here for the link to the research paper.   There are about 300 Reverse Vending Machines in Hong Kong. This study estimates that 2,000 Reverse Vending Machines are required to achieve the long-term recycling goal. Recyclables in Reverse Vending Machine will be compressed for easier  transportation.  

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School of Biological Sciences’ KE project on conservation forensics research awarded the Knowledge Exchange Excellence Award 2020

A team of ecologists from Conservation Forensics Laboratory and the School of Biological Sciences including Dr Caroline DINGLE, Dr David BAKER, Dr Timothy BONEBRAKE and Professor David DUDGEON, has  recently been awarded the university-level Knowledge Exchange(KE) Excellence Award 2020, in recognition of their outstanding accomplishments in their KE project entitled “Reduction of Illegal Global Wildlife Trade through Novel Conservation Forensics Research”.  Wildlife trade poses a growing threat to the survival of many species. Although some wildlife products are traded legally, many are not. Illegal wildlife trade is the fourth most lucrative organised activity, worth billions of US dollars annually. As global demand increases for illegally harvested and traded wildlife products, endangered species are pushed closer towards extinction. Situated in the heart of Asia, Hong Kong acts as an important trading hub in the wildlife trafficking network. The School’s research on wildlife trade has involved decades of multidisciplinary work. The team’s conservation research supports efforts by governments and NGOs to increase enforcement of national and international laws protecting endangered species and supporting illegal wildlife trade reduction. Conservation actions stemming from their research resulted in increased protection of turtles, pangolins and fish under the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES) and via the International Union for Conservation of Nature (IUCN). The team is also developing new forensics techniques to further help fight wildlife crime and support successful prosecutions. The KE Excellence Award of HKU was set up to encourage more colleagues and students in the University to join the ranks in the quest of deepening KE. This year, the award will be presented at the HKU Excellence Awards Presentation Ceremony on March 31, 2021.    

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HKU’s Conservation Forensics Lab revealed thousands of species traded legally through Hong Kong with inadequate traceability Leading to unnoticed over-exploitation of common species

Biodiversity is declining at an unprecedented rate, due primarily to human activity. Illegal and unsustainable wildlife trade is one of the major drivers of these declines, while much wildlife trade is legal, and the quantity of trade provides the opportunity to launder illegally sourced and traded species and products. Researchers from the Conservation Forensics Lab at HKU and Research Division for Ecology and Biodiversity, analyzed trends in global legal wildlife trade from 1997 to 2016, and revealed that legal wildlife trade averaged $220 billion per year over this period, approximately double the international trade in tea, coffee and spices, and eclipsing – by order of magnitude – annual trade in trafficked wildlife, estimated between $7-23 billion each year. This tremendous legal trade is declared using the Harmonized System (HS) Code system, a global product classification system which is used for encompassing all traded commodities globally; in which, seafood, furniture and fashion were the largest categories of traded wildlife commodities. The research shows that legal wildlife trade remains largely unexamined, despite its scale, and that 34% of trade is declared using overly broad codes that only specify taxonomic class and above. The research team therefore suggests that the HS Codes be distilled to increase traceability and help monitor trade. The paper has been published in the science journal Global Ecology and Conservation. Hong Kong as a major transit hub The vast majority of legal wildlife trade involved seafood (~82%), with the top trading countries being the USA, China and Japan. When removing seafood from the analysis, Hong Kong was the overall top wildlife trader globally, especially in trade for fashion (furs and skins) and Traditional Chinese Medicine (TCM). This indicates the pivotal role of this small territory as a major transit hub for global wildlife trade, especially as a re-exporter: more than 90% of the wildlife/wildlife products imported into the territory are re-exported. Additionally, Thailand and Vietnam are also important re-exporters, as they are among the top five exporters of “processed wildlife”. Targeting these locations for resource allocation (financial, personnel, training, equipment) in customs inspections of wildlife could have a maximum impact relative to investment. This research, led by PhD student Astrid ANDERSSON from the Conservation Forensics Lab at HKU and Research Division for Ecology and Biodiversity, relied on data from the UN Comtrade database, which includes official statistics of international trade. The database uses the HS Code system, in which approximately 5,300 codes encompassing all traded commodities globally. Since the primary function of these code are to provide data for statistics and tax purposes, rather than the ecological considerations, it is not designed to track individual products, and can be very broad, with a single code encompassing up to thousands of species. Breaking the broad codes for sustainability Though the Convention on International Trade in Endangered Species of Wild Fauna and Flora(see note 1) (CITES) appendices track and regulate legal trade in more than 35,000 threatened species, there are still many thousands more species traded for which there is little-to-no traceability, for examples, various reptiles, birds and fish are traded at high volumes and diverse across major markets, and species-level information is lost in these general codes. Andersson and her colleagues found that much legal wildlife trade is conducted under vague, all-encompassing codes with broad descriptions, some of which are used particularly frequently. For example, CITES does not cover many songbirds, fish, trees or plants traded. These species are often traded as pets, furniture or traditional medicine - the very categories identified as having frequent use of broad codes. The “Live reptile” code includes nearly 10,000 snake, lizard, turtle and crocodilian species, only approximately 10% of which are documented by CITES. In the pet category, 95% of trade in the pets category was declared under broad codes such as “Live ornamental fish”, “Other live birds” and “Live reptiles” – not allowing for tracking of trade of individual species. CITES only includes 162 species of fish – which leaves thousands of fish also traded untraceably under the “Live ornamental fish” code. Critically endangered species such as Straw-headed bulbuls, a songbird popular in the pet trade due to their singing ability, have been driven nearly to extinction due to wildlife trade. Species that are currently common, such as the Oriental Magpie-robin, are increasingly seen in wildlife markets and without sufficient monitoring these could also face severe population declines across their range. The current HS Code system may not be perfectly designed for tracking wildlife trade, but it is the only available method to date for tracking international legal trade for non-endangered species, and these trades are tracked via the CITES. The authors of the study suggest that the system could be refined to allow for better tracking of wildlife trade. “Our research constitutes a first step in uncovering the issues that are inherent in the current system, and detailing how it can be improved to protect biodiversity,” says Astrid Andersson, PhD student and author of the research. “We identify countries/territories where targeted enforcement could be particularly impactful, and priority wildlife trade areas for additional, species-specific code allocation,” she adds. The current prevalence of broad HS Code descriptions provides a low-resolution trade landscape characterized by vague parameters preventing effective monitoring of trade. This impedes enforcement and results in undetected mislabeling of protected species by a number of means, including covert farming and trading in protected species, fraudulent declaration of wild-caught individuals within a farm-sourced shipment, and underreporting trade volumes. These issues would become more detectable if HS Codes relating to wildlife were broken down to genus or species level.  “Unsustainable trade in wildlife poses a major threat to biodiversity globally. While much international wildlife trade is legal, the scale of this trade can lead to unnoticed over-exploitation of species because we cannot properly monitor the level of trade,” says Dr Caroline DINGLE, Director of the Conservation Forensics Lab at HKU, Senior Lecturer from the Research Division for Ecology and Biodiversity and co-author of the study. “It is important to have systems in place which allow us to monitor legally traded wildlife to prevent further biodiversity declines, and to continuously adjust these systems in response to new patterns of trade.” Dingle added. Note 1: CITES (the Convention on International Trade in Endangered Species of Wild Fauna and Flora) is an international agreement between governments. Its aim is to ensure that international trade in specimens of wild animals and plants does not threaten their survival.  The research paper “CITES and beyond: illuminating 20 years of global, legal wildlife trade” can be accessed here.  Author: Andersson AA, Tilley HB, Lau W, Dudgeon D, Bonebrake TC, Dingle C.   Many marine species are traded at high volumes and values and without species-level data – a scenario in which over-exploitation can go unnoticed. Photo courtesy: Astrid Andersson Hong Kong is the biggest importer and the second-biggest exporter of traditional medicine globally. Photo courtesy: Astrid Andersson Co-author of the study Hannah Tilley records songbirds for sale in the Hong Kong bird market in Mong Kok. Photo courtesy: Astrid Andersson USD billions of wildlife and wildlife products are traded internationally without species-level traceability. Photo courtesy: Astrid Andersson This research is led by PhD student Astrid ANDERSSON from the Conservation Forensics Lab at HKU and Research Division for Ecology and Biodiversity. Dr Caroline DINGLE, Director of the Conservation Forensics Lab at HKU, Senior Lecturer from the Research Division for Ecology and Biodiversity is the co-author of the study.  

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Thirty-nine HKU Science members ranked as the World’s Top 2% most-cited scientists by Stanford University

With concerted efforts with the publishing house Elsevier and scientific research organisation SciTech Strategies, Stanford University has created a ranking of 2% of the best scientists whose publications are most frequently cited by other authors across the globe, making the 159,648 researchers the most influential researchers in the science world. Among the top 2% scientists, 39 professoriate staff and affiliated members from HKU Science are included in the list under versatile disciplines, in which 5 of them under the subject field of Geochemistry & Geophysics, which performs the best among all categories. The list is based on data from Scopus, that ranks journals and indicates a citation index. The research paper can be accessed from here.   Subject Field Number of researchers Subject Field Number of researchers Analytical Chemistry 1 General Chemistry 1 Applied Physics  4 General Physics 1 Artificial Intelligence & Image Processing 2 Geochemistry & Geophysics 5 Astronomy & Astrophysics 3 Geological & Geomatics Engineering 1 Behavioral Science & Comparative Psychology 1 Inorganic & Nuclear Chemistry 1 Biochemistry & Molecular Biology 1 Marine Biology & Hydrobiology 2 Biotechnology 1 Materials 1 Chemical Physics 2 Nanoscience & Nanotechnology 1 Environmental Engineering 1 Organic Chemistry 3 Evolutionary Biology 1 Paleontology 1 Fisheries 1 Plant Biology & Botany 1 Food Science  3        

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HKU planetary scientists discover evidence for a reduced atmosphere on ancient Mars

Both Earth and Mars currently have oxidising atmospheres, which is why iron-rich materials in daily life develop rust (a common name for iron oxide) during the oxidation reaction of iron and oxygen. The Earth has had an oxidising atmosphere for approximately two and a half billion years, but before that, the atmosphere of this planet was reducing – there was no rust. The transition from a reduced planet to an oxidised planet is referred to as the Great Oxidation Event or GOE. This transition was a central part of our planet’s evolution, and fundamentally linked to the evolution of life here – specifically to the prevalence of photosynthesis that produced oxygen. Planetary geologists at HKU have discovered that Mars underwent a great oxygenation event of its own – billions of years ago, the red planet was not so red. The discovery was published recently in Nature Astronomy in a paper led by research postgraduate student Jiacheng LIU and his advisor Associate Professor Dr Joe MICHALSKI, both affiliated with the Research Division for Earth and Planetary Science and Laboratory for Space Research. The researchers used infrared remote sensing and spectroscopy to measure the molecular vibration of the material on the Martian surface from orbit, in order to reveal the mineralogy and geochemistry of ancient rocks on Mars. Through detailed comparisons of infrared remote sensing data and data collected in the laboratory here on Earth, the team showed that ancient rocks on Mars exposed at the surface had been weathered under reducing conditions, indicating a reduced atmosphere did exist. Many people are aware that Mars is cold and dry now, but ~ 3.5 billion years ago, it was warmer and wetter. It was warm enough to allow the formation of river channels, lakes and minerals that formed by interaction with water. Scientists who have used mathematical models to constrain the conditions of an early Martian atmosphere, have concluded that greenhouse warming occurred, but they also concluded from their models that the greenhouse must have included reduced gases rather than carbon dioxide, implied that a reducing atmosphere might have existed. Yet until now, there has not been any evidence that the reduced atmosphere of early Mars actually occurred. This work indicates that it did exist. This project involved detailed infrared remote sensing of Mars, using infrared spectroscopy to map minerals in exposed, weathered rock units. The work was built on detailed analysis of weathered volcanic rocks in Hainan Island in southwestern China, where thick sequences of basalt, similar to volcanic rocks on Mars occur. Jiacheng Liu analysed the altered rocks systematically using infrared spectroscopy in the laboratory and produced a paper on that research published recently in Applied Clay Science. “Jiacheng has carried out a truly excellent PhD project, built on careful analysis in the laboratory and application of those laboratory results to remote sensing of Mars,” Dr Michalski commented, “Jiacheng has built on his detailed work on samples from Hainan Island to show that similar mineralogical trends occurred in rocks on Mars.” Assistant Professor Dr Ryan MCKENZIE from Research Division for Earth and Planetary Science is also impressed by these findings. “This is a rather remarkable study with findings that will significantly impact how we understand the early evolution of terrestrial planets and their surface environments. The transition from a reducing to oxidising atmosphere on Earth ~2.5 billion years ago was only possible because the existence of life, as oxygen is a waste product of metabolic processes like photosynthesis. Without microbes producing oxygen, it would not accumulate in our atmosphere, and we could not be here. While there are certainly differences in the local conditions Mars and Earth have been subjected to during their evolutionary histories, my mind can’t help but start thinking about what Jiancheng’s results may mean for a potential early Martian biosphere,” Dr Mckenzie remarked. As China’s first mission to Mars Tianwen-1 is underway – has successfully arrived in Mars orbit on February 10 and set to land on Mars in May 2021, scientists are preparing for an exciting year of Mars exploration and discovery. This work demonstrates how spectroscopy and remote sensing lead to fundamental discoveries of significant importance for understanding Mars' history. As we begin to understand the most ancient history of Mars, researchers are ready to directly search of any signatures that life might have once existed on ancient Mars, and HKU plans to be at the centre of this great scientific adventure. About the Research Division for Earth and Planetary Science and the Laboratory for Space Research at HKU The Research Division for Earth and Planetary Science and the Laboratory for Space Research specialise in applications of traditional Earth and environmental science techniques and skills for modern space science challenges. Dr Joe Michalski operates the Planetary Spectroscopy and Mineralogy Laboratory at HKU and is the Deputy Director of the Laboratory for Space Research. Learn more about Dr Joseph Michalski: http://www.clays.space ; Twitter: @michalski_hk ; Instagram: michalski_hk About the research paper published in Nature Astronomy, click here. About the research paper published in Applied Clay Science, click here. The blue-toned rocks in the upper-left of the image are depleted in iron because it was removed during weathering on ancient Mars. This is geological evidence that iron was lost from the rocks in reduced conditions

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Newsletter Spotlights - Ready to step out of boundaries

Professor Michael Kwok Po Ng Director of Research Division of Mathematical & Statistical Science and Chair Professor of Department of Mathematics     As traditionally, we mathematicians and  statisticians are focused on individual  research problems, but now we are ready  to involve more in cross-disciplinary  collaborations.   “It’s always good to be back home,” said Professor Michael Kwok Po NG while leaning back in his office chair comfortably. Spending most of his time studying and working at HKU, Professor Ng left his alma mater for career developments in 2005, and it has been a year since his returning. Obtaining both his bachelor’s and master’s degrees from HKU, he started his research career in the Run Run Shaw Building. “It’s a place which shaped me to who I am today and where we continue to nurture generations of researchers in mathematics and statistics, a place just like my second home.” Besides his strong tie to HKU, the establishment of the Faculty’s Research Division of Mathematical & Statistical Science is one of the reasons prompting his rejoining of the Science family as the Division Director. If opportunity does not knock, build a door. Beyond challenges, he sees the huge opportunities that lie ahead. As a management who steers the direction, his visions are to foster research collaborations among faculties, and to integrate the research activities of two intertwined subjects, Mathematics and Statistics, into one platform with research excellence. “This is one of my primary missions upon returning to HKU,” he stated. A mission to empower researchers Professor Ng formulated some goal-orientated strategies which require substantial collaboration with researchers of diverse interests. “Win-win cooperation facilitates mutual benefits for collaborating parties — we have skills and expertise that help Divisions analyse a huge amount of data properly for disparate disciplines; on the other hand, we can also benefit from the findings and the process of developing new research applications. So it is all about collaboration.” Aiming at creating a thriving research environment, his first strategy is to mobilise and cross-fertilise expertise and facilitate knowledge sharing for core research areas. “Currently we have eight research groups with different interests and focus. Through fostering intellectual exchange, we strive to come up with more innovative research ideas, create more research frontiers, and be more competitive in attracting research funding.” While sharing of expertise can enhance both quality and versatility of research, networking can help apply research results into practical use and for the betterment of society. It is utmost essential that we can keep strengthening our network through research partnership and collaboration. “It is a global approach, not limited to local or regional, and beyond geographical areas, we would also like to connect the academic circle to the world of business and the community, incubate areas that demonstrate strong commercial potential and address societal needs like data science and artificial intelligence.” Interdisciplinary approach in action Aligning with the Faculty and the University strategy, interdisciplinary approach is one of the indispensable strategies that Professor Ng is going to adopt and expand. In the past year, he has already put this into practice. A PhD student has been participating in a machine learning project for the development and validation of prognosis model of mortality risk in patients with COVID-19 with medical doctors from Union Hospital, Wuhan and Beijing Chaoyang Hospital, Beijing; some experts from the Division are collaborating with the MTR Corporation in an interdisciplinary cooperation for condition-based monitoring systems and artificial intelligence for the operation of its railway network; internal collaborations involving cross-discipline experts have been carried out through the HKU-TCL Joint Research Centre for Artificial Intelligence and Big Data Research Cluster, and more joint positions within divisions will be created to enhance these kinds of activities. ”We will strive to enhance our engagement in more innovative research projects with other disciplines, in the hope of sparking more creative ideas with new attempts,” said Professor Ng. Achievements of Division members in recent years  2020 Second Prize of Hunan Natural Science Award: Professor Michael NG, Professor Wai Ki CHING and their PhD students 2019 Professor Ngai Ming MOK was elected as Fellow of the American Mathematical Society 2018 Professor Xiao Ming YUAN won the Higher Education Outstanding Scientific Research Output Awards Professor Jeff Jianfeng YAO was named Fellow by the Institute of Mathematical Statistics 2017 Professor Ngai Ming MOK was elected as Member of Hong Kong Academy of Sciences 1994 － 2019 HKU was ranked No.2 worldwide and No.1 in Asia based on research contributions from the top 4 actuarial journals (Insurance: Mathematics and Economics, North American Actuarial Journal, ASTIN Bulletin, and Scandinavian Actuarial Journal) amongst non-business schools over a 25-year period from 1994 to 2019      Profile  2020 - Present Chairman, HKU-TCL Joint Research Centre for AI 2019 - Present Director, Big Data Research Cluster, Faculty of Science, HKU 2017  Received Feng Kang Prize of Scientific Computing and was selected as a SIAM Fellow 2014  Received HKBU President's Award for Outstanding Performance in Scholarly Work 2001 HKU Outstanding Young Researcher Award

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HKU chemists resolve a long-standing challenging problem on Metal-Metal interaction, the first team to prove that strong M-M’ Pauli repulsion leads to repulsive metallophilicity

A research team led by Professor Chi-Ming CHE and Dr Jun YANG, from the Research Division for Chemistry and Department of Chemistry at the Faculty of Science of the University of Hong Kong, has resolved a long-standing fundamental problem in the field of metal-metal closed-shell interaction. This work has been published in the journal Proceedings of the National Academy of Sciences (PNAS). Metal-Metal closed-shell interaction, also known as metallophilicity, has a huge impact in diverse fields of chemistry, such as supramolecular chemistry and organometallic chemistry. Early reports on metallophilicity could be traced back to the 1970s. Many leading theoretical chemists around the world made contributions in the field, such as Roald Hoffmann (1981 Nobel Laureate in Chemistry), Pekka Pyykkӧ, etc.. Metallophilicity is important in the fabrication of self-assemblies by transition metal complexes, which has demonstrated profound applications in organic semiconductors, bio-sensing and functional optoelectronic materials. Going beyond conventional wisdom The term "metallophilicity" originated from Europe and has been extensively used by chemists as a guiding principle in molecular design studies and to rationalize the spectroscopic properties of transition metal complexes. Up to now, the general consensus of metallophilicity in the academic community is “attractive”, which has been conceived to come from orbital hybridization and/or relativistic effect of heavy metal atom, such as gold or platinum (3rd row metal in the elemental table). Together with Professor Che and Dr Yang, Postdoctoral Fellow Dr Qingyun WAN and co-workers questioned the conventional wisdom of coordination chemists, concluding that the metallophilicity is not an attractive interaction in organometallic complex, but is actually repulsive in nature due to strong M-M’ Pauli repulsion. They performed a combined theoretical and experimental research on metallophilicity and observed strong M-M’ Pauli repulsion in organometallic complex having closed-shell electronic configurations, which will provide a new theoretical perspective on the possibility of making new supramolecular materials with inexpensive earth-abundant transition metal complexes, such as that of palladium or silver or nickel (1st or 2nd row metals in the elemental table). It is also a crucial achievement in the fundamental understanding of weak intermolecular interactions. Background and achievement In the microworld of small molecules, there are many types of interactions. Metallophilicity describes the interaction between metal atoms as having closed-shell electronic configurations. In the early 1970s, chemists observed an interesting phenomenon that two closed-shell metal atoms could form a short metal-metal distance. A special “attraction” was proposed to exist between two metal atoms, pushing two metal atoms coming close. Many theoretical models were raised to account for such an attachment, such as the model of orbital hybridization or relativistic effect of the heavy metal. However, these theoretical models have conflictions with some experiment observations, like the relatively shorter Ag-Ag distance in Ag complexes compared to the Au-Au distance in the Au analogues. Thus, this problem has remained controversial for a long time and always plagued inorganic and theoretical chemists. The researchers at HKU used high-level calculation methods and experimental techniques to investigate such a tough problem, and proved that the metallophilicity is repulsive in nature due to strong M-M’ Pauli repulsion. They concluded that orbital hybridization and relativistic effect would strengthen the metal-metal Pauli repulsion when forming a close metal-metal contact. Intermolecular dispersion and electrostatic interaction will counter-balance the metal-metal repulsion, leading to a short metal-metal distance. This theoretical model could well explain why Ag-Ag distance is shorter than the Au-Au distance, due to weaker Ag-Ag Pauli repulsion which is induced by less orbital hybridization in the Ag complex. By a conservative estimation, there were more than 5,000 papers published in the literature related to “attractive metallophilicity”. The statement of “repulsive metallophilicity” is first proposed by the research team in their recent PNAS publication. This work was also recognized by Professor Harry GRAY in Caltech, who was awarded the Wolf Prize in Chemistry in 2004, one of the most honorable awards in the field. About the research team The research was conducted by a joint team under Professor Chi-Ming Che and Dr Jun Yang from the Research Division for Chemistry and Department of Chemistry. Postdoctoral fellow Dr Qingyun Wan from Professor Che’s group is the first author, while Dr Wan, Dr Yang and Professor Che are co-corresponding authors. Dr Wai-Pong To, Research Assistant Professor from Professor Che’s group, is another chemist contributing to the research. The research has secured continuous support from the Research Grants Council of Hong Kong, State Key Laboratory of Synthetic Chemistry at HKU and also the Information Technology Services of the University. The research team would also like to show their gratitude to the Basic Research Program-Shenzhen Fund, and the Major Program of Guangdong Basic and Applied Research. About Professor Chi-Ming Che Professor Chi-Ming Che received his BSc (1978) and PhD (1982) degrees from HKU. Following his research studies at the California Institute of Technology from 1980 to 1983, he joined HKU Chemistry in 1983 and was promoted to Chair Professor in 1992. From 1999-2016, he was appointed as Dr Hui Wai-Haan Chair of Chemistry. He is currently the Zhou Guangzhao Professor in Natural Sciences and the Director of State Key Laboratory of Synthetic Chemistry at HKU. Professor Che has received numerous awards/honors. At the age of 38, he was elected as a member of the Chinese Academy of Sciences (CAS), becoming the first Hong Kong scientist to receive this honour and the youngest member of CAS at that time. He is also the first in the local community to receive the First Class Prize of the State Natural Science Award of China (2006). In 2013, he was elected to Foreign Associate (later renamed as International Member) of National Academy of Sciences USA. In 2015, he was elected as a Founding member, a Director and the Vice-President of The Academy of Sciences of Hong Kong. Since 2016, he has been serving as the Head of Department of Chemistry at HKU. His current H-index is 120. For more information about Professor Che and his research group, please visit here. About Dr Jun Yang Dr Jun Yang is currently an Assistant Professor of Theoretical Chemistry at HKU. His research group is interested in developing and utilizing ab-initio quantum computational methodologies for many-body chemistry problems. Recent research activities include the development of low-scaling correlated electronic structure methods, many-body excited states of strong correlation, mean-field theory for nonadiabatic electronic-vibrational couplings as well as machine learning extension of these methods for realistic materials. For more information about Dr Jun Yang and his research group, please visit here. About Dr Qingyun Wan Dr Qingyun Wan received her BSc degree in Material Physics from University of Science and Technology of China in 2014. Under the supervision of Professor Li-Zhu WU and Professor Chen-Ho TUNG in the Technical Institute of Physics and Chemistry, Chinese Academy of Sciences (CAS), She conducted her final-year project in the area. In 2014, she moved to HKU and joined Professor Chi-Ming Che’s research team as a graduate student. She then had an exchange in Massachusetts Institute of Technology (MIT) in 2018 for half a year, working in the lab of Professor Christopher C CUMMINS. Her research interests include the synthesis and application of supramolecular materials based on organometallic complexes, and computational chemistry. Dr Wan has published 16 peer-reviewed research articles, including 5 first-authored and/or correspondingauthored papers in Chem (1), JACS (1), ACIE (2) and PNAS (1). Click here to read the research paper.  Periodic table showing element which could exhibit metallophilicity. Chemical structure of the Au and Ag complex, and the calculation results showing stronger Au-Au Pauli repulsion than the Ag-Ag Pauli repulsion.  

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Faculty of Science receives funding of over HK$38 Million from Collaborative Research Fund (CRF) 2020/21 of University Grants Committee

The Collaborative Research Fund (CRF) of the University Grants Committee comprises Collaborative Research Equipment Grant and Collaborative Research Project Grant, supporting multi-investigators in diverse disciplines to engage in more creative and high quality cross-disciplinary projects. Eight projects of the Faculty receive a funding of HKD 38,841,067 from the CRF 2020/21 in January 2021. Among the awarded projects, 4 are from the Research Division for Chemistry, 3 from the Research Division for Molecular & Cell Biology , and 1 from the Research Division of Physics & Astronomy. The awarded projects are as follows:  Principal Coordinator Research Division Project Title Professor Xuechen LI Chemistry Integrative Chemical Biology Approaches to Investigate the Biological Process of  Bacterial Pseudaminic Acid Dr Xiaoyu LI Chemistry Development of DNA-encoded glycan constructs as multivalent influenza hemagglutinin inhibitors towards novel anti-influenza therapy Dr Yuanliang ZHAI Molecular & Cell Biology Structure and molecular mechanisms of the eukaryotic replisome Professor Aleksandra DJURISIC Physics & Astronomy Controlling the moisture – towards stable and efficient flexible perovskite solar cells Dr Chaogu ZHENG Molecular & Cell Biology Investigating protein homeostasis during neuronal development and aging through cell-specific proteomics and interactomics Dr Aixin YAN Molecular & Cell Biology Deciphering the Physiological Functions and Regulation of the Endogenous CRISPR-Cas System for Biotechnological and Therapeutic Exploitations: Type I-F as a Paradigm Professor Hongzhe SUN Chemistry Mass cytometry, a multiplexed single-cell technology for chemical biology and precision medicine Professor Xuechen LI Chemistry Development of glycopeptide-based anti SARS-CoV-2 vaccines   For more details about the funding results, please click here. 

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HKU-led Physics research team receives funding of over HK$80 Million from Areas of Excellence Scheme, set to uncover emerging technologies of 2D materials to revolutionize electronics, optoelectronics and photonics

A team of physicists, engineers and chemists from across local institutions, led by Chair Professor Wang YAO of Research Division for Physics & Astronomy under Faculty of Science, The University of Hong Kong (HKU), working on the research of fundamentals and emerging technologies of two-dimensional (2D) materials, has recently been awarded a funding of over HK$80 million from the Areas of Excellence (AoE) Scheme 2020/21 (Ninth Round) under the University Grants Committee (UGC). This will facilitate the exploration of fundamental physics in the new realm of two-dimensional atomic crystals and their van der Waals heterostructures with the abundant quantum degrees of freedom (e.g. spin, valley); and to explore quantum engineering of materials and devices in the unprecedented atomically thin 2D geometries, with the aim to revolutionize electronics, optoelectronics and photonics. The team of leading experts of 2D materials in Hong Kong were assembled to capitalize on this great opportunity. This AoE project is an inter-institutional and interdisciplinary one covering physics, applied physics, chemistry, electrical engineering, comprising 17 scientists from HKU, City University of Hong Kong, The Chinese University of Hong Kong, The Hong Kong Polytechnic University, and The Hong Kong University of Science and Technology.  “We are grateful to UGC for the recognition of our past achievement through the award of this funding, and most importantly for this opportunity to work together as a team to achieve something bigger in this exciting area.” said Professor Yao. Dean of Science Professor Matthew EVANS extended his heartfelt congratulations to the Project Coordinator and Co-Principal Investigators of this inter-institutional research project. “This is indeed a good start for 2021! We are all exhilarated by the news! I am most delighted to see the concerted efforts of our top-notch physicists and their collaborators in diverse disciplines on developing fundamental research on 2D materials, outracing other cutting-edge research and being recognized through the award of funding in this vigorous exercise,” said Professor Evans. The development of 2D materials and beyond The rapid development of information technology has been based on the continuous scaling down of microelectronic devices that improves cost, performance and power. This trend, empirically summarized as Moore's law, is coming to an end because of the intrinsic scale limit of silicon microelectronics. The new era of innovation will be profoundly different, calling for: new material systems to host even smaller devices under new geometry, new heterogeneity, new quantum degrees of freedom to carry information, and new physical principles to process and store information. Two-dimensional materials have a great potential to revolutionize microelectronics and information technology. The variety of 2D materials feature a wide range of material properties from metal, semiconductors, insulators to magnets and superconductors, as well as exotic physics associated with electrons’ quantum degrees of freedom (spin & valley) that could be exploited to encode and process information more efficiently. Their tiny thickness - just a few atoms at most - promises the ultimate miniaturization of devices, and unparalleled control of materials and device functions. Moreover, 2D materials feature an unprecedented flexibility in their assembly into heterostructures, through which new materials and device functionalities may emerge. This project aims to explore these exciting opportunities for revolutionizing electronics, optoelectronics and photonics, through a concerted effort addressing the fundamental issues from physics, materials synthesis to device engineering based on 2D materials.   Led by pioneers in the field of 2D materials, the team will seek to sustain Hong Kong’s edge in the field through basic and applied research, with a long-term goal of developing new prototype devices that will have application and commercialization potentials for Hong Kong. Background of the AoE Scheme The AoE Scheme was launched in 1998. The objective of the Scheme is to support the University Grants Committee-funded universities to build upon their existing strengths and develop them into areas of excellence. A total of 24 AoE projects from various disciplines have been funded in the past eight rounds of exercise. For the funding results of the Ninth Round Exercise, please visit here.    For details of another AoE project that the Faculty of Science takes part in, please visit here.    

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HKU Physicist participated in cross-institutional Areas of Excellence project on meta-materials and meta-devices

Professor Shuang ZHANG of Research Division for Physics & Astronomy was one of the Co-Principal Investigators of a successful grant application entitled “Meta-optics, Meta-acoustics and Meta-devices” in the Areas of Excellence (AoE) Scheme 2020/21 (Ninth Round). The application, led by Professor Din-Ping TSAI of The Polytechnic University of Hong Kong (PolyU), focuses on development of metamaterials and metasurfaces for bridging the gap between fundamental research and industrial applications of metamaterials. Specifically, the project aims at developing novel meta-materials and meta-devices that can control and manipulate electromagnetic and acoustic waves for improving the quality of human daily life. Metamaterials and meta-devices take advantages of the localized and non-localized resonances of artificial structures in which the response of the electrons, phonons, plasmons, and excitons are strongly modified to give novel properties and functionalities which are not found in nature. This AoE project will cover the design, numerical simulation, advanced manufacturing, characterizations and measurements of these materials for various applications including environment, biomedical, imaging and sensing, and information security. It is expected that this AoE project will generate a new platform for knowledge-based intelligent artificial materials and devices which are low energy consumption (“green”) and compatible with advanced manufacture in micro- and nano-electronics industrial techniques for wearable or portable innovation. The team consists of seven research groups from PolyU, The Hong Kong University of Science and Technology and The University of Hong Kong. The project has been awarded funding of HK$65 million from the AoE Scheme  (Ninth Round) under the University Grants Committee (UGC). In this project, Professor Zhang will be responsible for the development of topological photonics based on metamaterials, and tunable metasurfaces for dynamically shaping the wave-front of light. Background of the AoE Scheme The AoE Scheme was launched in 1998. The objective of the Scheme is to support the University Grants Committee-funded universities to build upon their existing strengths and develop them into areas of excellence. A total of 24 AoE projects from various disciplines have been funded in the past eight rounds of exercise. For the funding results of the Ninth Round Exercise, please visit: https://www.ugc.edu.hk/eng/rgc/funding_opport/aoe/funded_research/aoe9.html   

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Research co-led by Professor Hongzhe SUN from Research Division for Chemistry awarded the Local Top Ten innovation and technology news in 2020

A research co-led by Professor Hongzhe SUN, Norman & Cecilia Yip Professor in Bioinorganic Chemistry, Research Division for Chemistry, and Professor Kwok Yung YUEN, Henry Fok Professor in Infectious Diseases, Department of Microbiology, Li Ka Shing Faculty of Medicine, on discovery of a novel antiviral strategy for treatment of COVID-19 using existing metallodrugs, has been selected as one of the top 10 innovation news in 2020 by public vote. Organised by the Beijing-Hong Kong Academic Exchange Centre, the selection of the "Top ten innovation and technology news in 2020" aims to raise public awareness of scientific research achievements of Hong Kong institutions and pay tribute to researchers of various institutions, more than 2000 public audience engaged in the voting. Click here to learn more about the research.     

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Four decades of research on Japanese Izu Islands finds rising lizard temperatures may change predator-prey relationship with snakes

  A Japanese four-lined rat snake on Kozu Island.  Image credit: Félix Landry Yuan. HKU PhD student Félix Landry Yuan searching for lizards on Hachijo-Kojima. mage credit: Masami Hasegawa. The picturesque Kozu Island. Image credit: Félix Landry Yuan. (see note) Equipment in hand, researchers return from their field site on Hachijo-Kojima to be picked up by boat. Image credit: Masami Hasegawa   In a study spanning four decades, researchers from The University of Hong Kong’s Research Division for Ecology & Biodiversity (HKU) in the Faculty of Science, and Toho University’s Department of Biology (Toho), Japan, have discovered that predation by snakes is pushing lizards to be active at warmer body temperatures on islands where snakes are present, in comparison to islands free from snakes. Their work also detected significant climatic warming throughout the years and found lizard body temperatures to have also increased accordingly. The findings show that lizard thermal biology is highly dependent on predation pressures and that body temperatures are rising suggest that such ectothermic predator-prey relationships may be changing under climatic warming. Lizard VS Snakes on Izu Islands The research published in the journal Ecology Letters is the first to present long-term observations on the thermal biology behind the prey-predator relationship of snakes and lizards on the Izu Islands. Less than a million years old, these islands are located near the southeastern coast of the Japanese mainland and represent a valuable natural laboratory for studying ecological and evolutionary processes. Similar to the reasons initially drawing evolutionary biologists to the Galapagos, the simplified island system with low numbers of species overall provides an opportunity to directly study selective pressures on species. In this system, one dominant lizard species is found on all these islands; Okada's five-lined skink (Plestiodon latiscutatus). Its mainland predator, the Japanese four-lined rat snake (Elaphe quadrivirgata), is found on most but not all of the islands. This has resulted P. latiscutatus populations that have experienced different evolutionary pressures, either free from or subject to predation by E. quadrivirgata. The research was conducted by PhD student Félix LANDRY YUAN (HKU) and PhD Candidate Shun ITO (Tohoku University’s Graduate School of Life Science) and led by Dr Timothy BONEBRAKE (HKU) and Professor Masami HASEGAWA (Toho). Initial observation and data collection was first started by Professor HASEGAWA in the early 1980’s, when he first noticed lizard behaviour differed on islands with and without snakes. Professor Hasegawa has since continually visited the islands annually to catch lizards and snakes for body temperature and morphological measurements. The researchers have accordingly detected that annual temperatures across the Izu Islands had increased by just over 1°C since Professor Hasegawa first started his observations, and that lizard body temperature had also increased with the same magnitude. Higher body temperature helps the lizards In addition to body temperature measurements, in 2018 and 2019 Félix Landry Yuan carried a portable racetrack, tripod and camera to the islands to measure the speed at which lizards ran at different temperatures. By analyzing thermally dependent running speeds of over 150 lizards across the islands, the researchers were able to establish how predation by snakes affected lizard thermal biology and the probable consequences for their fitness. Dr Bonebrake notes that, “by racing lizards of different temperatures down a track, Félix was able to show that optimal temperatures were higher for lizards on the island with snakes, consistent with the high body temperatures observed on the island. Shun Ito was also able to identify differences in lizard hind leg length that had consequences for survival. Thus, the higher body temperatures and morphological differences help the lizards run faster and better escape the snakes. The exciting and unique aspect of this work is how the experimental work matches and supports the extensive natural history data and observation.” With climate change ongoing, the dynamics of this prey-predator relationship could be affected on islands with snakes, as lizard body temperatures are likely to continue to rise. In addition, as predation has considerable consequences for the thermal biology of its prey, the presence or absence of snake predators could differentially influence general vulnerability of lizards to climatic warming across islands. The Izu Islands demonstrate the value of island systems in teasing apart mechanisms through which predation directly influences behaviour, morphology and physiology of prey species. On the other hand, understanding the ways in which predation can affect prey responses to climate change requires long-term study. This international collaboration between HKU and Toho used these unique properties of this system (and Professor Hasegawa’s forethought and intensive data collections since the 80s) to show how predator-prey relationships may be vulnerable in a warming climate. “It is a great pleasure to reveal ecological and evolutionary responses among prey and predator interactions by this international research team. I’m very hopeful that the Izu islands become a key model island system to study ongoing evolution under global environmental change by attracting ambitious young Asian biologists to research this further.” Professor HASEGAWA said.     Toho University's Professor  Masami Hasegawa on Oshima. Image credit: Félix Landry Yuan. A basking Okada's five-lined skink on Hachijo-Kojima. Image credit: Masami Hasegawa    Félix Landry Yuan was supported by a Hong Kong PhD Fellowship from the Research Grants Council. Professor Masami Hasegawa received funding for this work from the Japan Society for the Promotion of Science (JSPS) - (19H03307, 15H04426). About the research paper “Predator presence and recent climatic warming raise body temperatures of island lizards”:https://onlinelibrary.wiley.com/doi/full/10.1111/ele.13671 Landry Yuan F*, Ito S*, Tsang TPN, Kuriyama T, Yamakazi T, Bonebrake TC, Hasegawa M (2021) Ecology Letters *These authors contributed equally to the manuscript. Note: With an approximate 3-10 hour boat ride away from Tokyo, depending on the island, the Izu Islands are easily accessible from the Japanese capital, although inter-island travel is not as flexible. For their field work, the researchers stayed at local family-run guest houses, and travelled to their study sites in the early morning where they searched for lizards until the late afternoon. 

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Food & Nutritional Science students serving the community under COVID-19

The protracted COVID-19 situation has put an unprecedented strain on food supply chains globally. While the community has been finding ways to step up to the challenges imposed by the fallout, 10 science students were also committed to foster food sustainability and help reduce food waste in the community by taking part in the Food & Nutritional Science Internship Scheme at NGOs.  Without any hesitation to contribute towards a more sustainable food environment, Year 3 student Ms Tsz Kiu WONG (third from the right) whose major is Food & Nutritional Science, got a 3-month internship in Feeding Hong Kong last summer, where she worked as an operation intern in the food sourcing team, assisting in identifying prospective food donors by placing cold-calls and sending cold-emails.  Turning difficulties into opportunities  The universal work-from-home practice made it exceptionally challenging to promote food donation, especially when potential donors are generally less incentivised to do so under the pressure of economic turmoil. Nonetheless, difficulties and adversity make one grow, Tsz Kiu paid extra efforts in liaising with donors and took the opportunity to familiarise herself with the software “Salesforce”, a cloud-based platform for customer relationship management which she has been learning to use in classes. She also compiled reports on potential food donors, amount of food donated, as well as the prediction of their future growth. Being a helper of the entire logistics process, from donation pitching to food collection and sorting, Tsz Kiu realised that the internship was a golden opportunity for her to get acquainted with how the food donation chain works. Other than hands-on working skills, she also learnt to be more patient and caring after making numerous phone calls and working with people in need. About Food & Nutritional Science Internship Scheme Among the 77 students participating in the Food & Nutritional Science Internship Scheme, 10 of them were with NGOs. The scheme aims to offer students the opportunities to gain authentic discipline-related working experience in the industry. Students have to take at least 160 hours of internship work, either within or outside the University, then compile a report and give a brief presentation upon completion.

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