SETI bioastro: Reports On "Weird Life" Almost Better Than Fiction

From: Larry Klaes (lklaes@bbn.com)
Date: Mon Apr 17 2000 - 12:24:24 PDT


03/30/00 BOZEMAN -- Michael Daly occasionally gets letters from
schoolchildren who find "the world's toughest bacterium" listed
in the Guinness Book of World Records.

Deinococcus radiodurans can withstand 10,000 times the amount of
radiation that would kill a human, earning it monikers like "Super
Bug" and "Conan the Bacterium."

"It's just phenomenal how much radiation life can take and remain
viable," said Daly, a scientist at the Uniformed Services University
of the Health Sciences, a military medical school in Bethesda, MD.

Daly was one of about 20 scientists who talked about their studies
of "weird life," or life in extreme environments, at a recent
conference near Big Sky, MT.

Sponsored by the National Aeronautics and Space Administration, the
conference will help the space agency finetune programs aimed at
understanding how life began in the violent early years of the planet.
Those answers may help determine whether life could exist elsewhere in
the Universe. The gathering was organized by the Thermal Biology
Institute at Montana State University-Bozeman.

Their Web page URL:

http://agadsrv.msu.montana.edu/lresclasses/TBI/

"We may be the generation to understand the origins of life," said
Anne Kinney, director of NASA's Astronomical Search for Origins
and Planetary Systems Program.

Recalling how Galileo's discovery of Jupiter's moons altered
people's world view in the 17th century, Kinney said astrobiology--
or the search for life in outer space--could have a similar impact
in our day.

"It comes down to, Are we the center of the universe or not?,"
Kinney said.

On this planet, life is not limited to the cushy places. Microbes--
mostly bacteria and organisms from a domain of life called archaea--
live in some of the coldest, hottest, deepest, driest, saltiest,
most acidic, nutrient-poor and oxygen-deprived environments scientists
have thought to look.

"It's a burgeoning field," said John Spear of the University of
Colorado. "People are literally beginning to look under the rocks."

D. radiodurans was living in swollen tins of irradiated meat when
discovered in Oregon in the 1950s. Studies revealed a unique, almost
bizarre, ability to repair numerous DNA double strand breaks--the
most lethal kind of genetic damage--within hours.

"Its DNA is highly damaged at 1.7 million rads," Daly said. (One
thousand rads is deadly to humans.) "Its DNA is all chopped up.
There are between 1,000 and 2,000 DNA fragments per cell, but
they're all fixed in about 24 hours."

Engineering D. radiodurans so it also has an appetite for toxic
compounds associated with nuclear waste would create an alternative
(and cheaper) cleanup method for the nation's 3,000 nuclear waste
sites, Daly said. So far such work, funded by the U.S. Department
of Energy, looks promising.

The potential usefulness of "extremophiles" cropped up repeatedly
during the two-day meeting. After all, an enzyme isolated from a
bacterium living in a Yellowstone National Park hot spring has
made possible DNA fingerprinting and a host of related genetic
studies and processes.

Many at the conference want to know how well the organisms they find
in the planet's meanest places are actually doing. Do they play active
parts in their ecosystems or are they just hanging out? Bacteria
frozen in Antarctic lake ice "barely can handle it," said MSU
ecologist John Priscu, whereas microbes in hotsprings in Yellowstone
National Park appear to be fairly well adapted.

"Living a poor man's existence" is how Florida State microbiologist
Imre Friedmann described microbes clinging to the underside of stones
in hot dry deserts like the Atacama in Chile. A doyen of the group,
Friedmann has studied extremophiles in both hot and cold environments,
including the Siberian permafrost, since the 1950s.

"But only lately have I begun to understand what makes them live
and die," he told the group.

Hot, dry environments are harsher than cold ones because the limiting
factor is water.

"In a super-cold environment, the limiting factor is not the cold
itself but the lack of warm hours," Friedmann said. "They need some
heat to keep alive."

But what makes the clock stop altogether is dehydration, said James
Clegg from the University of California at Davis. That is, unless
you're a microscopic invertebrate.

The embryos of brine shrimp called artemia can almost totally dry
out without dying, and then rehydrate themselves when there's water.
Nematodes and an organism called tardigrade can survive nearly 98
percent dehydration.

"They're neither dead nor alive," said Clegg, "What makes the clock
go is water."

Based on the "weird life" they've found on Earth, many of the
scientists expressed plausibility for simple organisms living
in outer space.

"I would not be surprised if there's life on Mars," said Daly.
"It's not unlikely."

The issue is how to look.

-###-

Sidebar: Life on the Edge

The limits of life on Earth are much broader than previously thought.
Examples of life at extreme conditions include:

Hottest: 235.4 F--bacteria from deep sea vents

Coldest: 5 F--microalgae in Antarctic rocks

Deepest: Bacteria, two miles underground in rocks

Most acidic: Unclassified organisms growing on gypsum in caves at pH 0

Highest radiation: 5 million rads--Deinococcus radiodurans (bacteria)

Saltiest: Bacteria, 30 percent salt environment

Deepest and Highest pressure: 1200 atm--at bottom of Marianas Trench (ocean)

Farthest: Moon, Streptococcus mitus (from human source) from Surveyor III
camera after three years unprotected on lunar surface

Source: NASA

Editor's Note: The original news release can be found at

http://www.montana.edu/wwwpb/univ/weird.html



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