Ancient DNA from the abyss

TRACI WATSON
Last updated 12:50 09/05/2013
Plankton
F LEJZEROWICZ et al
ANCIENT: A deep sea drifter that yielded 32,500-year-old DNA.

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In the middle of the South Atlantic, there's a patch of sea almost devoid of life. There are no birds, few fish, not even much plankton. But researchers report they've found buried treasure under the empty waters: Ancient DNA hidden in the muck of the sea floor, which lies 5km below the waves.

The DNA, from tiny, one-celled sea creatures that lived up to 32,500 years ago, is the first to be recovered from the abyssal plains, the deep-sea bottoms that cover huge stretches of Earth.

In a separate finding published this week, another research team has reported teasing out plankton DNA that's up to 11,400 years old from the floor of the much shallower Black Sea.

The researchers said that the ability to retrieve such old DNA from such large stretches of the planet's surface could help reveal everything from ancient climate to the evolutionary ecology of the seas.

"We have been able to show that the deep sea is the largest long-time archive of DNA, and a major window to study past biodiversity," said Pedro Martinez Arbizu, a deep-sea biologist of the German Centre for Marine Biodiversity Research in Wilhelmshaven and an author of the paper on South Atlantic DNA.

The new studies were "very exciting," said micropaleontologist Bridget Wade of the University of Leeds in the United Kingdom, who was not connected to the research.

Until now, it wasn't clear "how far back in time you could take these DNA studies. These records are telling you new information that wasn't found in the fossil record."

The South Atlantic team went looking for DNA in plugs of silt and clay coaxed out of the ocean floor hundreds of kilometres off the Brazilian coast.

The researchers were after genetic material from two related groups of marine organisms, the foraminifera and the radiolarians.

Both were single-celled, and both included many species with beautiful pearly shells that fossilise nicely, making them a favourite target of researchers studying the prehistoric oceans.

The researchers used special pieces of DNA specific to radiolarians and foraminifera to fish out DNA from those groups.

Then they sequenced the DNA and compared the results to known foraminifera and radiolarian DNA sequences.

Their analysis showed they'd found 169 foraminifera species and 21 radiolarian species, many of which were unknown.

What's more, many of the foraminifera species belonged to groups that didn't form fossils, the researchers reported online in Biology Letters .

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The work showed that it was possible to trace all species, not just those that fossilize, said Jan Pawlowski, a foraminifera specialist and one of the paper's authors, of the University of Geneva in Switzerland.

The results gave "us a completely different view… [that] may open new insights into what's happened in the past," he said.

For example, he said, different species of these wee creatures prefer different water temperatures.

So DNA from buried sediments could be used to track the abundance of different species over time, revealing changes in ocean temperature.

The second team looked at DNA buried in the floor of the Black Sea, which was once a giant lake, but became connected to the Mediterranean Sea roughly 9000 years ago, though the date is debated.

The researchers examined sediments from waters only 980 metres deep, which was much shallower than the abyssal plain.

But the oldest Black Sea layers that were analysed were similar to those at the South Atlantic site: The mud at the sea bottom had scant amounts of organic matter and had been exposed to oxygen, which, in theory, should have made it tough to scrape up any preserved DNA.

It didn't. New material had buried the older layers, cutting off their oxygen, and more recent Black Sea sediments weren't exposed to oxygen at all.

The result was a rich trove of ancient DNA from as many as 2700 species, including green algae, fungi, and dinoflagellates, a type of one-celled aquatic creature.

The diverse collection allowed the scientists to track the fate of different species over time, as their DNA blinked in and out of the sediments.

One type of marine fungus, for example, first appeared in the sediments roughly 9600 years ago — exactly when some forms of freshwater plankton and a freshwater mussel vanish, the team reports this week in the Proceedings of the National Academy of Sciences. That suggests that marine waters started to invade the lake roughly 600 years earlier than thought.

The team also found DNA from a form of marine alga in 9300-year-old sediments, though the alga doesn't show up in the fossil record until 2500 years ago, said molecular paleoecologist Marco Coolen of the Woods Hole Oceanographic Institution in Massachusetts and an author of the Black Sea paper.

Other ancient DNA studies have been discredited after supposedly ancient genetic material turned out to be modern contaminants, but those fears don't apply to this new research, said micropaleontologist Michal Kucera of the University of Bremen in Germany.

He said that both teams took the necessary steps to avoid contamination, and their results didn't look like contaminants.

In the Biology Letters results, for instance, DNA from older sediments was more degraded than material from more recent sediment — not what you'd expect if the DNA were a laboratory stowaway.

Kucera and Wade praised both studies as paving the way for the use of ancient marine DNA to illuminate the history of the ocean.

Coolen's finding of marine species invading the Black Sea earlier than had been thought "is not something you could see from looking at fossils or sediment properties," Kucera said.

Wade said that it may be possible, once researchers can identify the DNA of species that prefer certain environmental conditions, to use deep-water DNA to reveal changes in climate.

"Most of the environment on Earth is marine deep ocean," including the area where Pawlowski's team found DNA, she said.

"So it makes it very exciting that they're looking in this environment and finding DNA."

- SCIENCE NOW

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