After an eight-year effort to recover DNA from Greenland’s frozen interior, researchers say they’ve managed to sequence gene fragments from ancient fish, plants, and even a mastodon that lived 2 million years ago.
It’s the oldest DNA ever recovered, beating the mark set only last year when a different team recovered genetic material from a million-year-old mammoth tooth.
The new effort looked at genetic material that was left behind by dozens of species and washed into sediment layers long ago when Greenland was much warmer than today.
“Here you are getting the whole ecosystem,” says Eske Willerslev of the University of Copenhagen, who led the effort. “You know exactly that at this time, and this place, these organisms were together.”
The genetic findings, which paint a picture of an era when Greenland was covered with flowering plants and cottonwood trees, could provide clues to how ecosystems adapted to warmer climates in the past.
“Here you have a map of where and how to edit the genetics of plants to make them resilient to climate change,” says Willerslev. He adds that the ancient DNA could provide a “road map” to help plant species adapt to a climate that's warming very quickly.
Speaking at an online press conference organized by the journal Nature, which also published the report, Willerslev said the forested ecosystem revealed by the gene fragments included flowering plants and trees, species currently absent from the area, where nothing much lives except lichen and some musk ox.
“This is an ecosystem with no modern analogue. It’s a mixture between arctic species and temperate species,” says Willerslev. “It's a climate similar to what we expect to face on Earth due to global warming, and it gives us some idea how nature can respond to increasing temperatures.”
Some researchers have proposed using findings about ancient DNA to re-create extinct mammals like woolly mammoths, but Willerslev says plants “will be much more important” even though they are “not as sexy” as a pachyderm.
Research on old DNA began in 1984, when scientists recovered readable genes from a dried-out quagga, a type of extinct zebra. Since then, new methods and specialized gene-sequencing machines have allowed them to probe deeper and deeper into the past.
DNA breaks apart with time, so the older it is, the smaller the pieces become—until there’s nothing left to detect. And the shorter the fragments are, the trickier it is to assign them to a specific groups of plants or animals.
“The huge damage pattern made it very clear it was ancient DNA,” says Willerslev, who says he and his colleagues began working with the Greenland samples in 2006. “When it's 2 million years, there has been so much evolutionary time, that whatever [species] you are finding are not necessarily very similar to what you see today.”
The Danish team says the DNA they found was preserved by freezing temperatures and bound to clay and quartz, which also slows down the process of degradation.
Exactly how far back in time researchers will be able to see remains an open question. “Probably we are close to the limit, but who knows,” says Tyler Murchie, a postdoctoral fellow at McMaster University who develops methods for studying ancient DNA. He notes that the Dutch researchers were successful in combining several techniques to “create a robust reconstruction of this ecosystem.”
Willerslev once predicted it would be impossible to recover DNA from anything that lived more than a million years ago. Now that he’s broken the record, he is reluctant to say where the limit lies. “I wouldn’t be surprised if...we could go back twice as far,” he says. “But I wouldn't guarantee it.”
Biotechnology and health
What to know about this autumn’s covid vaccines
New variants will pose a challenge, but early signs suggest the shots will still boost antibody responses.
A biotech company says it put dopamine-making cells into people’s brains
The experiment to treat Parkinson’s is a critical early test of stem cells’ potential to tackle serious disease.
Tiny faux organs could crack the mystery of menstruation
Researchers are using organoids to unlock one of the human body’s most mysterious—and miraculous—processes.
How AI can help us understand how cells work—and help cure diseases
A virtual cell modeling system, powered by AI, will lead to breakthroughs in our understanding of diseases, argue the cofounders of the Chan Zuckerberg Initiative.
Get the latest updates from
MIT Technology Review
Discover special offers, top stories, upcoming events, and more.