David Moss
Researchers in the have shown that high-latitude bivalves live longer and grow slower than those in the tropics. Their findings are the subject of an article in the (The Royal Society, 2016).
David Moss, a Ph.D. student in the Earth sciences department, located in the College of Arts and Sciences, is the article’s lead author.
“We’ve created a global database of more than 1,100 populations of marine bivalves, documenting their maximum reported lifespan and growth rate, along with body size,” he says, referring to animals such as oysters, clams, scallops and mussels. “Cold-blooded marine animals, such as bivalves, are influenced by their environment, so latitudinal patterns that exist in bivalves likely exist in other invertebrates, too.”
After months of work by Moss and other members of the Earth sciences department, two patterns have emerged. The first reveals that, as a bivalve’s lifespan increases, its growth rate decreases. The second shows that long life and slow growth are common among animals near the North and South poles, whereas tropical bivalves, close to the equator, are fast-growing and short-lived.
“As the poles are thought to harbor ecosystems like those from millions of years ago, our data suggest that more ancient animals were slow-growing,” Moss says.
Among the bivalve mollusks the group has studied is the “Artica islandica,” found off the coast of Iceland. The world’s oldest animal, it is capable of living for more than 500 years.
Professor , in whose lab Moss is based, says bivalves are just as abundant in the fossil record as they are in today’s oceans. As a result, she and her students can easily recover bivalve lifespans and growth rates by studying the bands in their fossilized shells, a process analogous to tree-ring dating.
Ivany says this kind of work has implications for the study of the evolutionary history of life on Earth, and may help explain why the metabolism of cold-blooded animals has changed over time.
“Research shows that marine animals have gotten bigger over the last 500 million years,” Ivany says. “Because body size is determined by how fast you grow and how long you grow, this work sets the stage for us to move back in time and answer evolutionary questions about why and how animals have gotten bigger.”
Based on his group’s observations, Moss argues that the increase in body size of marine bivalves throughout the Phanerozoic, the current geologic eon stretching back more than 540 million years, should be accompanied by a shift to faster growth and a shorter lifespan.
Linda Ivany
Moss also hopes to pinpoint why biodiversity is high in the tropics and low near the poles.
“Short generation times and high mutation rates associated with short lifespan and fast growth enable new species to appear at a faster rate in the tropics,” he says. “The distribution of lifespan and growth with latitude might help explain one of the more fundamental patterns in the evolutionary and ecological history of animal life on the planet: the latitudinal diversity gradient.”
In addition to Moss and Ivany, the article is co-authored by Emily Judd, also a Ph.D. student in Earth sciences; Patrick Cummings ’17, Claire Bearden ’16, and Woo-Jun Kim ’15, all undergraduates at the time of the project; and Emily Artruc and Jeremy Driscoll, 2016 graduates of the .
All of the A&S participants have belonged to Ivany’s lab.
