Mosaic evolution painted lorikeets a rainbow of color
New study shows how color pattern evolution lets birds use bright colors for signaling while remaining hidden from predators
- Date:
- February 26, 2020
- Source:
- American Museum of Natural History
- Summary:
- A new study examines how color evolved in one of the flashiest groups of parrots -- Australasian lorikeets -- finding that different plumage patches on the birds evolved independently. The study helps explain why it's possible for the birds' faces and front sides to display a dazzling variety of colors -- from vibrant ultraviolet blue only visible to other birds to deep crimson and black -- while their wings and backs tend to be the same color: green.
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A new study examines how color evolved in one of the flashiest groups of parrots -- Australasian lorikeets -- finding that different plumage patches on the birds evolved independently through time. The study, published this week in the journal BMC Evolutionary Biology, helps explain why it's possible for the birds' faces and front sides to display a dazzling variety of colors -- from vibrant ultraviolet blue only visible to other birds to deep crimson and black -- while their wings and backs tend to be the same color: green.
"All birds need to balance being attractive to potential mates while having some kind of camouflage against potential predators," said Brian Smith, an associate curator in the American Museum of Natural History's Department of Ornithology and one of the co-authors of the new study. "So how do lorikeets, which have a very extreme appearance, get so colorful without being predated by lizards or hawks?"
To help answer this question, Smith and Jon Merwin, a Museum research assistant who began the project as a student at Columbia University, took visible-light and UV-light photos of 98 historic Museum specimens of Australasian lorikeets -- those that live in New Guinea, Australia, and surrounding archipelagos -- representing nearly all of the diversity in the group. Many birds can see in the ultraviolet spectrum, to which most humans are blind, so the researchers used a special program that translates color into "bird vision." They collected data from 35 plumage patches on the birds across the face, head, back, wings, breast, and lower abdomen. Those color data were modeled within the tree of life for lorikeets to test whether different patches of the birds are more likely to evolve under certain scenarios.
They found that the plumage patches that are most likely to be involved in predation avoidance are greatly conserved across long evolutionary timescales while the patches that are likely involved in mate recognition or courtship evolved rapidly. The probable explanation is that when looking for a mate, it may help each species to have different colors on the front, so they can find their own kind. But while being hunted from above, it's beneficial for the birds to blend in with the trees, so their backs may be adapted for camouflage and their colorful fronts for easy recognition.
In general, the researchers identified three plumage groupings that have evolved together through time: the face and head, the back and wings, and the breast region and lower abdomen. This so-called mosaic evolution -- where subsets of traits evolve independently of others -- underlies the extraordinary diversification of plumage colors seen in lorikeets today.
"The range of colors exhibited by lorikeets adds up to a third of the colors birds can theoretically observe," Merwin said. "We were able to capture variation in this study that isn't even visible to the human eye. The idea that you can take color data from Museum specimens, infer patterns, and gain a larger understanding of how these birds evolved is really amazing."
Color evolution is a burgeoning topic in avian biology, with previous research conducted on birds of paradise and hummingbirds, and with a number of other studies in progress. Smith and Merwin plan to tackle the greater parrot group (Psittaciformes) next. Their lorikeet study will be featured in the Museum's new exhibition The Nature of Color, opening to the public on March 9, 2020.
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Materials provided by American Museum of Natural History. Note: Content may be edited for style and length.
Journal Reference:
- Jon T. Merwin, Glenn F. Seeholzer, Brian Tilston Smith. Macroevolutionary bursts and constraints generate a rainbow in a clade of tropical birds. BMC Evolutionary Biology, 2020; 20 (1) DOI: 10.1186/s12862-020-1577-y
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