09 Jul 2021
Songbirds like it sweet! A research co-developed by HKU Evolutionary Biologist found that Songbird ancestors evolved a new way to taste sugar
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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