Scientists confirm 3.5 billion-year-old fossil life in rock

Scientists confirm 3.5 billion-year-old fossil life in rock

MIAMI - AFP
Scientists confirm 3.5 billion-year-old fossil life in rock

It took more than 10 years of painstaking work, grinding an Australian rock containing fossils smaller than the eye could see, to confirm the earliest direct evidence of life on Earth, scientists said Dec. 18.

The 3.5-billion-year-old fossils, many narrower than a human hair, are described in the Proceedings of the National Academy of Sciences, a peer-reviewed US journal.

Other teams of scientists have reported even earlier signs of fossil life, going back 3.95 billion years. But those studies are based on either an apparent shape of a microfossil, or a chemical trace, not both. 

"None of these studies are regarded as proof of life," lead author John Valley, professor of geoscience at the University of Wisconsin-Madison, said. "This is the first, oldest place where we have both morphology and the chemical fingerprint of life."

Eleven kinds of microbes, preserved in both their cylindrical or snake-like structures, are preserved in the rock. 

Some of the bacteria are now extinct, while others are similar to contemporary microbes.

The tiny fossils were found in 1982 from the Apex chert deposit of Western Australia. Two scientific papers were published on the rock's apparent microbial contents; one in 1993 and another in 2002. But critics raised questions, suggesting instead they were not life but odd minerals that merely looked like biological specimens. So Valley and his fellow researchers spent a decade developing a technique to tease apart the contents of the fossils.

Researchers at the University of Wisconsin-Madison modified a tool, called a secondary ion mass spectrometer (SIMS), to grind down the original sample one micrometer at a time, without destroying the fossils which were "suspended at different levels within the rock and encased in a hard layer of quartz," said the report.

"Each microfossil is about 10 micrometers wide; eight of them could fit along the width of a human hair."

The technique allowed scientists to detect ratios of carbon-12 from the carbon-13 within each fossil, and compare them to a section of the rock which had no fossils.

"The differences in carbon isotope ratios correlate with their shapes," Valley explained. "If they're not biological there is no reason for such a correlation." 

Some of the microbial life inside is believed to have relied on the Sun to produce energy, while others consumed methane, which was a big part of Earth's early atmosphere before oxygen.

"This was a well-developed microbial community," Valley said.

The hunt for the first evidence of life is all-consuming for some scientists, eager to pinpoint the earliest signs after the Earth formed some 4.6 billion years ago.

Microbial life likely began as far back as 4.3 billion years ago, said co-author William Schopf, professor of paleobiology at the University of California, Los Angeles (UCLA).

The existence of several different kinds of microbes 3.5 billion years ago shows that "life had to have begun substantially earlier -- nobody knows how much earlier -- and confirms it is not difficult for primitive life to form and to evolve into more advanced microorganisms," he said.

A separate study published in September in the journal Nature said researchers had found 3.95 billion-year-old chemical traces of life in Canadian rocks.

However, that study, which proclaimed the oldest evidence of life on Earth, also raised skepticism.

One of those critics, Martin Whitehouse, a geologist at the Swedish Museum of Natural History in Stockholm, said the PNAS report appears to be "a sound study."

"Regarding the Canadian study, the main differences are (a) these new findings are actual fossils preserving morphology, not just blobs of graphite," he said.

"And (b) the geochronological interpretation of the Canadian example is, in my opinion, fundamentally flawed, whereas here the dating is unambiguous."

Researchers hope their technique can one day be applied to other microfossils, perhaps even those that come from cosmic bodies beyond Earth.

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