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Newly discovered sea urchin fossil is the oldest of its kind

Posted November 6, 2015

Researchers have uncovered a sea urchin fossil that pushes back a fork in its family tree by 10 million years, according to a new study.

Sea urchin. Image credit: Ingvar-fed, Wikimedia Commons

Sea urchin. Image credit: Ingvar-fed, Wikimedia Commons

A team from USC found the fossil — Eotiaris guadalupensis — in collections of the Smithsonian Institution from the Glass Mountains of west Texas, where it had been buried in a rock formation that dates back to 268.8 million years at its youngest.

“This fossil pushes the evolution of this type of sea urchin from the Wuchiapingian age all the way back to the Roadian age,” said David Bottjer, professor at the USC Dornsife College of Letters, Arts and Sciences, and senior author of a paper announcing the study that appeared in Nature Scientific Reports.

The paper was a collaboration between labs overseen by Bottjer at USC and Eric Davidson at the California Institute of Technology. Jeffrey Thompson, a Ph.D. student at USC, found the fossils of Eotiaris guadalupensis in the Smithsonian collections and was the lead author on this study.

Two types of urchins

Eotiaris guadalupensis is a cidaroid, one of the two main types of sea urchins found in today’s oceans. The other group, the euechinoids, evolved wildly varying body types and accounts for almost all sea urchins alive today. Cidaroids, by contrast, look pretty much the same as they did millions of years ago. Both evolved from an ancestral group of echinoids known as the Archaeocidaridae, which are now extinct.

The divergence of the two groups marks a major — and relatively abrupt — shift in the genetic organization of sea urchins.

“It’s not just the color of a moth’s wing changing,” said Bottjer, referring to the classic example of the peppered moth in England that, in the post-Industrial Revolution’s sooty skies, began to appear in a darker color. “We’re looking at tightly intertwined networks of genes that change together to cause major morphological differences.”

Pinning down the time at which the two groups diverged allows evolutionary biologists to better understand the processes that occur during major evolutionary changes.

Bottjer and Thompson will also expand on these findings at Geological Society of America meeting in Baltimore, where they will discuss the burgeoning field of paleogenomics — the tracking of morphological innovations from the fossil record which are produced by known genes in modern organisms, in order to date when these genes first evolved — in separate presentations.

Source: USC

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