Darwin's finches, inhabiting the Galápagos archipelago and Cocos island, constitute an iconic model for studies of speciation and adaptive evolution. A team of scientists from Uppsala University and Princeton University has now shed light on the evolutionary history of these birds and identified a gene that explains variation in beak shape within and among species. The study is published today in Nature, on the day before the 206th anniversary of the birth of Charles Darwin. Show Darwin's finches are a classical example of an adaptive radiation. Their common ancestor arrived on the Galapagos about two million years ago. During the time that has passed the Darwin's finches have evolved into 15 recognized species differing in body size, beak shape, song and feeding behaviour. Changes in the size and form of the beak have enabled different species to utilize different food resources such as insects, seeds, nectar from cactus flowers as well as blood from iguanas, all driven by Darwinian selection. "We have now sequenced 120 birds including all known species of Darwin's finches, as well as two closely related species in order to study their evolutionary history," explains Sangeet Lamichhaney PhD student and shared first author on the paper. Multiple individuals of each species were analyzed and for some species birds from up to six different islands were sampled to study variation within and between islands. One important insight was that gene flow between species has played a prominent role throughout the evolutionary history of the Darwin's finches. The scientists could even trace clear signs of hybridization between a warbler finch and the common ancestor of tree and ground finches that must have occurred about a million year ago. "During our field work on the Galapagos we have observed many examples of hybridization between species of Darwin's finches but the long-term evolutionary effects of these hybridizations have been unknown," say Peter and Rosemary Grant, Princeton University, who know more about the biology of the Darwin's finches than anyone else in the world after carrying out field work on the Galapagos during a 40 year period. "Now we can safely conclude that interspecies hybridization has played a critical role in the evolution of the finches, and has contributed to maintaining their genetic diversity," says Peter Grant. The most striking phenotypic diversity among the Darwin's finches is the variation in the size and shape of the beaks. Charles Darwin was struck by this biological diversity, and compared it with the variety he was accustomed to among European birds such as the hawfinch, the chaffinch and warblers, as documented in his book "The Voyage of The Beagle." The team investigated the genetic basis for variation in beak shape by comparing two species with blunt beaks and two species with pointed beaks. Fifteen regions of the genome stood out as being very different in this contrast, and as many as six of these contained genes that previously have been associated with craniofacial and/or beak development. "The most exciting and significant finding was that genetic variation in the ALX1 gene is associated with variation in beak shape not only between species of Darwin's finches but also among individuals of one of them, the medium ground finch," explains Leif Andersson, Uppsala University, Swedish University of Agricultural Sciences and Texas A&M University, who led the study. "This is a very exciting discovery for us since we have previously shown that beak shape in the medium ground finch has undergone a rapid evolution in response to environmental changes. Now we know that hybridization mixes the different variants of an important gene, ALX1," says Rosemary Grant. The ALX1 gene codes for a transcription factor with a crucial role for normal craniofacial development in vertebrates, and mutations that inactivate this gene cause severe birth defects including frontonasal dysplasia in humans. -"This is an interesting example where mild mutations in a gene that is critical for normal development leads to phenotypic evolution," comments Leif Andersson. "I would not be surprised if it turns out that mutations with minor or minute effects on ALX1 function or expression contribute to the bewildering facial diversity among humans," says Leif Andersson. Story Source: Materials provided by Uppsala University. Note: Content may be edited for style and length.
A study finds that a gene that helps form human faces also shapes the beaks of the famously varied Galápagos finches. Wide, slender, pointed, blunt: The many flavors of beak sported by the finches that flit about the remote Galápagos Islands were an important clue to Darwin that species might change their traits over time, adapting to new environments. Now scientists peering into the DNA of these birds have found a piece of genetic code that contributes to the striking variation in beak shape. (Watch a video to learn more about the unique animals of the Galápagos.) The discovery is described in a study published today in the journal Nature that also brings fresh insights into the forces that drive the formation of new species. The birds' past—and their current connections to one another—is more tangled than previously thought. The Galápagos finches are ideal subjects for observing the drama of evolution. The islands kept them isolated from competition with other birds on the South American mainland, and each island became its own little world. As a result, the 14 species show a startling range of beak shapes. Each is finely tuned to a specific way of getting food. To actually see evolution take place, starting in 1973 Rosemary and Peter Grant began spending months each year on the tiny volcanic outcrop called Daphne Major, meticulously measuring changes in the shapes and sizes of the finches there in tandem with variations in food supply and climate. The married scientific team are among the authors of the new paper. (Learn more about the Grants.) In the new article, scientists for the first time sequenced the genomes of the finches. They looked at 120 individuals, drawing from all of the known species. By comparing the genomes, they found a handful of subtle variations that appear connected to beak shape. The most obvious is in a gene known as ALX1, which is critical to the formation of facial and head bones. In humans, the malfunctioning of this gene results in deformities such as cleft palates. In the finches, a tiny difference in the ALX1 gene distinguished between birds that use a blunt, stout beak to crack open tough seed casings, and other birds whose more pointy beaks are better equipped to pick little seeds off the ground. Among the ground finches (Geospiza fortis) of Daphne Major, birds that inherited the blunt version of the gene from both parents had the bluntest beaks, those with one blunt and one pointy version of the gene had intermediate beaks, and those with two pointy variants had the sharpest. "I'm convinced that these are one of the changes that is explaining the difference between blunt and pointed [beaks]," said Leif Andersson, a geneticist at Sweden's Uppsala University, and one of the paper's authors. William Provine, a professor at New York's Cornell University and an expert in the history of evolutionary science, cautioned that the picture of which genes are controlling beak shape might not be as clear as this paper suggests. If more finch genomes are deciphered, the results could add new twists. "You don't know what else affects beak shape," Provine said. Andersson said they are now working to expand the collection of finch genomes, in hopes it will further clarify the genes driving differences between the birds. Galápagos mockingbirds (upper right) first gave Darwin the idea that island species might vary. Back in England, he examined the finches (three species on upper left; bottom left is a yellow warbler) more closely and realized their significance. Origins of New SpeciesAdditionally, the researchers discovered the species categories weren't as neat as they appeared. One species was made up of three distinct genetic groups, and the genomes of others are more similar than the team expected, suggesting that the birds interbred much more than we had realized, and over a longer time period, say the Grants. "The most important take-home message may be that species are not fixed, shut off from other species by inability to interbreed. On the contrary, for a long time, millions of years in some cases, they are capable of exchanging genes," the Grants wrote in an e-mail. The ground finches on Daphne Major illustrate why this can matter to the survival of a species. There, the G. fortis finches have interbred with two other species that tend to have pointy beaks, adding more of the pointy-beak variants into the gene pool. When a devastating drought hit the island in the mid-1980s, the Grants watched as the G. fortis population veered toward a pointier beak better suited to the remaining food supply. This new discovery—that interbreeding plays a bigger role in evolution than previously thought—echoes the first scientific encounter with these birds, said Frank Sulloway, a historian of science who has written extensively about Darwin. When Darwin first set foot on the Galápagos in 1835, the birds varied so much he failed to realize they were all finches. Another scientist pointed it out when he returned to England. "In a sense he was fooled by the extraordinary complexity and diversity," Sulloway said. "What this most recent study shows is this process of unfooling ourselves is still going on." What evidence did scientists use to determine that all the species of finches in the Galapagos have one common ancestor?Comparisons of DNA sequences revealed the evolutionary relationships among finch species. The data showed that all finch species living in the Galápagos Islands today are more closely related to one another than to any species of birds on the mainland, suggesting that they originated from a common ancestor.
What did the Grants measure on the ground finches?In 1978 the Grants returned to Daphne Major to document the effect of the drought on the next generation of medium ground finches. They measured the offspring and compared their beak size to that of the previous (pre-drought) generations. They found the offsprings' beaks to be 3 to 4% larger than their grandparents'.
What did the Grants observe about the finches?The Grants found that the offspring of the birds that survived the 1977 drought tended to be larger, with bigger beaks. So the adaptation to a changed environment led to a larger-beaked finch population in the following generation.
What evidence of evolution is Darwin's finches?So, the correct option is 'Biogeography'.
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What type of evidence did the grants the scientists use to determine that the finches are more related to each other than any one is to a species on the mainland?
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