In 1988, an associate professor started growing cultures of Escherichia coli. Twenty-one years and 40,000 generations of bacteria later, Richard Lenski, who is now a professor of microbial ecology at Michigan State University, reveals new details about the differences between adaptive and random genetic changes during evolution.
By generation 20,000, for example, the group found that some 45 genetic mutations had occurred, but 6,000 generations later a genetic mutation in the metabolism arose and sparked a rapid increase in the number of mutations so that by generation 40,000, some 653 mutations had occurred. Unlike the earlier changes, many of these later mutations appeared to be more random and neutral.
The long-awaited findings show that calculating rates and types of evolutionary change may be even more difficult to do without a rich data set. “The fluid and complex coupling observed between the rates of genomic evolution and adaptation even in this simplistic system cautions against categorical interpretations about rates of genomic evolution in nature without specific knowledge of molecular and population-genetic processes,” the paper authors wrote.
Such detailed pictures of mutation rates have been made possible since the advent of rapid genome sequencing. “It’s extra nice now to be able to show precisely how selection has changed the genomes of these bacteria, step by step over tens of thousands of generations,” Lenski said.
The new data “beautifully emphasize the succession of mutational events that allowed these organisms to climb toward higher and higher efficiency in their environment,” Dominique Schneider of the Université Joseph Fourier in Grenoble, France, and a coauthor on the paper, said in a prepared statement. The paper, published online today in Nature, also happens to come 150 years after Charles Darwin published his Origin of Species (Scientific American is a part of the Nature Publishing Group)
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