Post #5293

Scientists Discover DNA “Flips” That Supercharge Evolution Researchers have identified segments of “flipped” DNA that may allow fish to adapt rapidly to new environments and eventually form new species. These unusual genetic changes appear to function as evolutionary “superchargers,” helping populations diversify at remarkable speed. Why does Earth contain such a vast variety of plants and animals? One of the central questions in biology is how new species originate and how the extraordinary diversity of life developed over time. Cichlid fish in Lake Malawi in East Africa provide an important example. Within this single lake, more than 800 species have emerged from a shared ancestor. This diversification happened in far less time than it took humans and chimpanzees to split from their own common ancestor. Even more striking is that this evolutionary explosion took place in the same body of water. Some cichlids evolved into large predators, while others specialized in grazing on algae, filtering sand for food, or feeding on plankton. Over time, each species adapted to its own ecological niche. Searching the Genome for Answers Scientists from the University of Cambridge and the University of Antwerp set out to understand how this rapid evolutionary change occurred. Their findings were published in the journal Science. The research team examined the DNA of more than 1,300 cichlid fish to see whether any unusual genetic features might explain the group’s extraordinary rate of diversification. “We discovered that, in some species, large chunks of DNA on five chromosomes are flipped – a type of mutation called a chromosomal inversion,” said senior author Hennes Svardal from the University of Antwerp. In most animals, reproduction involves a process called recombination. During this process, genetic material from each parent is shuffled and mixed together. However, recombination is largely prevented inside a chromosomal inversion. As a result, the group of genes contained in that flipped section remains linked and is passed down together from one generation to the next. This preserves useful combinations of genes that support survival in specific environments, which can accelerate evolutionary change. “It’s sort of like a toolbox where all the most useful tools are stuck together, preserving winning genetic combinations that help fish adapt to different environments,” said first author Moritz Blumer from Cambridge’s Department of Genetics. Source:SciTechDaily @EverythingScience