Sifting through mud for signs of life and death
ON a scorching summer day, Mark Stoeckle threw a bucket into the murky waters of New York’s East River to fill three small plastic bottles.
The biologist hopes the water he collected contains the genetic trail of the river’s diverse life including all of its fish, and of course, the occasional rat.
“We’ve cleaned up the East River significantly, but we’re still dumping a lot of stuff,” said Stoeckle of Rockefeller University. “This will give us a better idea of whether fish are recovering or not.”
He doesn’t have to catch the fish himself, a dangerous task given the river’s rocky bottom and strong currents. He just needs to look for the tiny bits of DNA they leave behind to track them.
Animals lose hair, scales and feathers as they move. They also discard skin cells and waste. All of these leave traces of genetic material that can be detected hours, weeks or even millennia later.
Scientists say analyzing the DNA floating in waterways or hiding in soil, which they call environmental DNA or eDNA, promises to help in managing and protecting biodiversity. The tactic has become increasingly popular in the past few years and has already provided clues of ancient mammoths in Siberia, early warnings of frog die-offs in California and evidence of elusive sawfish in Mexico.
Sam Chew Chin, a fish ecologist at York College in New York, said he used to be a “muddy-boots and bloodydesk biologist.” Studying fish meant capturing them and eventually killing them. Now, he searches for whales off of Long Island by testing water, making his job faster and cheaper.
It wasn’t always like that. Nobody really cared about eDNA a decade ago, said Danish geneticist Eske Willerslev, who pioneered the technique.
He had been traveling to Siberia to sample permafrost. The frozen soil was so cold that he thought ancient genetic material could have remained intact throughout the years.
In 2002, with a handful of permafrost samples the size of a sugar cube, he was able to identify the genetic material of bison, horses and many different plants that lived hundreds of thousands of years ago. He also found the preserved DNA of mammoths.
Environmental DNA “helps us reach the inaccessible,” said Willerslev from the Natural History Museum of Denmark, adding that this approach will play a key role in scientists’ quest to understand nature.
Examples of this are appearing in other fields, where eDNA has changed how researchers think about conservation.
When Colleen Kamoroff spent the summer collecting water in 2015 from the lakes in California’s Sierra Nevada, she saw a healthy group of native mountain yellow-legged frogs hopping around. One month later, they were all dying.
The culprit: a microorganism that has caused the decline of about 200 amphibian species around the world, called chytrid fungus.
Curious whether the frogs could have been saved if she had seen early signs, Kamoroff, a wildlife biologist who works for Yosemite National Park in California, started looking for chytrid fungus DNA in the water she had sampled. She was surprised to find it.