Scientists may have cracked the 'aging process' in species

New research from the University of Kansas might resolve a mystery in the "aging process" in species—or, how a species' risk of going extinct changes after that species appears on the scene.

For years, evolutionary biologists believed older species lacked any real advantage over younger ones in avoiding extinction—an idea known as "Red Queen theory" among researchers.

"The Red Queen theory is that species have to keep running just to stay still, like the character in Lewis Carroll's book 'Through the Looking-Glass,'" said lead author James Saulsbury, postdoctoral researcher in the Department of Ecology & Evolutionary Biology at KU. "This idea was turned into a kind of ecological theory in the 1970s in an attempt to explain an observation that extinction risk didn't seem to change over the lifespan of species."

Yet the years have not been kind to this theory.

"In the earliest investigations of this phenomenon, species of all ages seemed to go extinct at about the same rate, perhaps just because of the relative crudeness of the evidence available at the time," Saulsbury said. "This made sense under this Red Queen model, where species are constantly competing with other species that are also adapting alongside them."

But as more data was collected and analyzed in more sophisticated ways, scientists increasingly found refutations of Red Queen theory.

"Scientists kept finding instances where young species are especially at risk of extinction," Saulsbury said. "So we had a theory vacuum—a bunch of anomalous observations and no unified way of understanding them."

But now, Saulsbury has led research appearing in the Proceedings of the National Academy of Sciences that may resolve this mystery. Saulsbury and his co-authors have shown that the relationship between a species' age and its risk of going extinct could be accurately predicted by an ecological model called the "neutral theory of biodiversity."

Neutral theory is a simple model of ecologically similar species competing for limited resources, where the outcome for each species is more or less random.

In the theory, "Species either go extinct or expand from small initial population size to become less vulnerable to extinction, but they are always susceptible to being replaced by their competitors," according to a lay summary of the PNAS paper. By extending this theory to make predictions for the fossil record, Saulsbury and colleagues found that neutral theory "predicts survivorship among fossil zooplankton with surprising accuracy and accounts for empirical deviations from the predictions of Red Queen more generally."

Saulsbury's co-authors were C. Tomomi Parins-Fukuchi of the University of Toronto, Connor Wilson of the University of Oxford and the University of Arizona, and Trond Reitan and Lee Hsiang Liow of the University of Oslo.

While neutral theory might seem to spell curtains for Red Queen theory, the KU researcher said Red Queen still has value. Mainly, it proposes the still valid idea that species compete in a zero-sum game against one another for finite resources, always battling for a bigger slice of nature's pie.

"Red Queen theory has been a compelling and important idea in the evolutionary biological community, but the data from the fossil record no longer seems to support that theory," Saulsbury said. "But I don't think our paper really refutes this idea because, in fact, the Red Queen theory and the neutral theory are, in a deep way, pretty similar. They both present a picture of extinction happening as a result of competition between species for resources and of constant turnover in communities resulting from biological interactions."

Ultimately, the findings not only help make sense of the forces that shape the natural world but may be relevant for conservation efforts as species face increasing threats from climate change and habitat loss around the globe.

"What makes a species vulnerable to extinction?" Saulsbury asked. "People are interested in learning from the fossil record whether it can tell us anything to help conserve species. The pessimistic side of our study is that there are ecological situations where there isn't a whole lot of predictability in the fates of species; there's some limit to how much we can predict extinction. To some extent, extinction will be decided by seemingly random forces—accidents of history. There's some support for this in paleobiological studies."

He said there have been efforts to understand predictors of extinction in the fossil record, but not many generalities have emerged so far.

"There's no trait that makes you immortal or not susceptible to extinction," Saulsbury said. "But the optimistic side of our study is that entire communities can have patterns of extinction that are quite predictable and understandable. We can get a pretty good grasp on features of the biota, like how the extinction risk of species changes as they age. Even if the fate of a single species can be hard to predict, the fate of a whole community can be quite understandable."

Saulsbury added a caveat: It remains to be seen how broadly the neutral explanation for extinction succeeds across different parts of the tree of life.

"Our study is also working on the geological timescale in millions of years," he said. "Things may look very different on the timescale of our own lifetimes."