Skip to main content

Natural Selection at Single Gene Demonstrated

Developed at USC, test based on genomic data avoids pitfalls of older methods. The group's method can be applied to any organism.

Biologists seeking elusive proof of natural selection at the single-gene level have a powerful new tool at their disposal.

Chris Toomajian, postdoctoral researcher in molecular and computational biology in USC College, led a group that sought to replace the standard neutral model, a common but unrealistic test for natural selection, with a statistical method based on hard genomic data.

The group’s research was published online April 25 by Public Library of Science.

“Do we now have enough data to see the standard neutral model wasn’t appropriate?,” Toomajian asked. “We know something more now about how the population has been structured.”

Co-author Magnus Nordborg, associate professor of molecular and computational biology in USC College, predicted that earlier research would need to be revisited because the standard neutral model makes it too easy to infer selection at any given gene.

“Once you start looking at enough cases then you realize that, oops, it’s all under selection. I think a lot of that research is going to end up in the trash can,” Nordborg said.

The group’s method can be applied to any organism, including humans.

The PLoS paper focused on the weed Arabidopsis thaliana, and in particular on the FRIGIDA (FRI) gene, known to influence flowering time.

A. thaliana was once a plant that bloomed annually. But two versions of FRI that appeared thousands of years ago enabled the plant to flower year-round, helping it out-compete other plants.

Toomajian and his group showed that these two versions, also called gene variants, are too common to have spread solely by chance.

“We’ve shown that for one gene with an important role in that [flowering] process, there’s good evidence that there’s natural selection changing the behavior of the plants,” Toomajian said.

Why the variants were selected remains unclear, though some have suggested that the plant evolved under pressure from the spread of agriculture.

Toomajian’s group identified the gene variants through a comparison of 96 plants over 1,102 short fragments of the genome.

Each variant was assigned a score based on the similarity of two plants around the FRI gene relative to their similarity at other regions in the genome.

The higher the score, the less likely it is that a variant could have arisen and spread randomly.

The scoring formula accounts for the greater similarity expected in related plants.

Nordborg said that while natural selection is well documented at the whole-organism level, researchers consider biochemical proof of selection “the Holy Grail” of population genetics.

“What has proven very difficult is to connect specific molecular changes to selection,” Nordborg said.

The PLoS paper, along with other recent studies based on intrinsic genomic comparisons, brings biology closer to this goal.

Major funding for the team’s research came from the National Science Foundation. Researchers from the John Innes Centre at Norwich Research Park, U.K., contributed to the PLoS study.