Skip to main content

‘Living Fossil’ Lizards Are Constantly Evolving—You Just Can’t See It

New research into the “stasis paradox” challenges the rules of evolution

A close-up photo of a brown Anolis with red throat shown against a black background.

Cuban brown anole.

Paul Starosta/Getty Images

Evolution can perform spectacular makeovers: today's airborne songbirds descended from the wingless, earthbound dinosaurs that roamed millions of years ago, for example. But some organisms seem to change very little, even over eons—the coelacanth, a modern-day fish, is nearly identical to its 410-million-year-old fossilized counterparts.

Scientists have long wondered how these species withstand the pressures of natural selection. The prevailing hypothesis for this “stasis paradox” has been that natural selection keeps some species unchanged by selecting for moderate or average traits (so-called stabilizing selection) rather than selecting for more extreme traits that would cause a species to change (directional selection). But a study published in the Proceedings of the National Academy of Sciences USA contradicts this idea, showing that evolution constantly favors different traits in seemingly unchanging animals that improve short-term survival. In the long term, though, “all that evolution cancels out and leads to no change,” says the study's lead author, James Stroud, a biologist at the Georgia Institute of Technology.

Stroud and his colleagues studied four anole lizard species, all relatively unchanged for 20 million years, living on a small island in Florida's Fairchild Tropical Botanic Garden. The researchers captured members of these populations every six months for three years. They measured each lizard's head size, leg length, mass and height, as well as the size of its sticky toe pads, noting which individuals survived. Stroud expected to observe stabilizing selection at work preserving moderate traits. Instead he saw clearer evidence of directional selection: some lizards with unique traits, such as stickier toes, survived better in the short term.


On supporting science journalism

If you're enjoying this article, consider supporting our award-winning journalism by subscribing. By purchasing a subscription you are helping to ensure the future of impactful stories about the discoveries and ideas shaping our world today.


In each generation, though, the “best” traits changed—for instance, long legs aided survival in some years and short legs in others. The direction and strength of selection fluctuated so much that sometimes there was no clear pattern. Such changes are probably happening “back and forth on a micro scale with no net directional change,” says Rosemary Grant, a Princeton University evolutionary biologist, who has studied stabilizing selection in Darwin's finches.

Because the new study shows that natural selection favored extreme traits from year to year rather than moderate ones, its results don't support the theory of stabilizing selection. Instead they offer “a good explanation for why we see what we think is stabilizing selection,” says Tadashi Fukami, an ecologist studying evolution at Stanford University. Many new traits are evolving in the short term, but they don't provide a crucial advantage over the long term. In other words, species in stasis may simply have found the best possible combination of traits for lasting success in their environment.

So what happens when a static species' environment changes more dramatically? To help answer this bigger question, Stroud is still making trips to Florida to follow ever more generations of the lizards.

Donavyn Coffey is a Kentucky-based journalist who covers health, technology and rural communities.

More by Donavyn Coffey
Scientific American Magazine Vol 330 Issue 2This article was originally published with the title “Peak Evolution” in Scientific American Magazine Vol. 330 No. 2 (), p. 11
doi:10.1038/scientificamerican0224-11