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Birds of a feather do flock together

·3 min read

COLD SPRING HARBOR, N.Y., Nov. 17, 2020 /PRNewswire/ -- Nearly 200 years ago, Charles Darwin observed striking diversity among Galapagos Islands' finches, leading him to propose that natural selection shapes species. Today, some biologists focus their attention on a related group of birds, the finch-like capuchino seedeaters of South America. These researchers are revealing the forces that drive evolution.

Capuchino seedeaters are finch-like birds that live in South America. Over the last 50,000 generations, they’ve split into different species with distinct colorations, though there were no physical or genetic barriers to their interbreeding. This is an illustration of one species of southern capuchino seedeater, Sporophila hypoxantha. Illustration: Ben Wigler/CSHL
Capuchino seedeaters are finch-like birds that live in South America. Over the last 50,000 generations, they’ve split into different species with distinct colorations, though there were no physical or genetic barriers to their interbreeding. This is an illustration of one species of southern capuchino seedeater, Sporophila hypoxantha. Illustration: Ben Wigler/CSHL

In the Proceedings of the Natural Academy of Sciences, Cold Spring Harbor Laboratory Professor Adam Siepel and collaborators at Cornell University and the Herzliya Interdisciplinary Center in Israel use genetic evidence to explain how different species of capuchino seedeaters acquired distinct patterns of coloration. Their findings shed light on the role of selective sweeps—a genetic process in which a naturally occurring variation becomes advantageous—in the emergence of new species.

Capuchino seedeaters are of interest to evolutionary biologists because they have diversified from their common ancestor relatively recently. Each species has characteristic plumage and its own song. Differences are caused by lots of variations in only a few dozen spots in otherwise remarkably similar genomes. These small genetic "islands of differentiation" distinguish each species early in their evolutionary split from one another. Over time, as the species diverge more, researchers expect more of their genomes to change.

A few years ago, Leo Campagna and Irby Lovette at Cornell determined that many of these islands affected pigment production genes. In the current study, Siepel's group collaborated with Campagna and Lovette to identify additional differentiation sites and investigate their causes.

Two different genetic processes can create islands of differentiation: selective sweeps or a genetic incompatibility limiting the passage of specific DNA segments within a population. Computational tools developed in Siepel's lab allowed his team, led by postdoctoral researcher Hussein Hejase, to discriminate between these possibilities. Comparing the genomes of 60 birds from five species confirmed that most of the islands of differentiation that separate today's seedeater species arose due to selective sweeps.

Notably, Siepel explained, most of these appear to be due to soft selective sweeps:

"The soft sweep acts on a variant that already exists in the population. But that variant newly comes under selective pressure, maybe because of a change of environment, a new predator, a new food, whatever. Or in this case, we think because of sexual selection, because the birds of the opposite sex found some aspect of that variant attractive, whether its coloration or song, and that helped push it to high frequency."

Siepel said the finding shows that even quite striking islands of genetic differentiation can be explained by soft sweeps that acted separately on newly emerging species.

About Cold Spring Harbor Laboratory
Founded in 1890, Cold Spring Harbor Laboratory has shaped contemporary biomedical research and education with programs in cancer, neuroscience, plant biology and quantitative biology. Home to eight Nobel Prize winners, the private, not-for-profit Laboratory employs 1,100 people including 600 scientists, students and technicians. For more information, visit www.cshl.edu

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SOURCE Cold Spring Harbor Laboratory