Meteorites May Reveal Why Certain Amino Acids Are
"Left-Handed"
This may either be among the most profoundly
significant stories ANN will report this year... or one of the
all-time weirdest, period. Or both. NASA scientists analyzing the
dust of meteorites have discovered new clues to a long-standing
mystery about how life works on its most basic, molecular
level.
"We found more support for the idea that biological molecules,
like amino acids, created in space and brought to Earth by
meteorite impacts help explain why life is left-handed," said Dr.
Daniel Glavin of NASA's Goddard Space Flight Center in Greenbelt,
MD. "By that I mean why all known life uses only left-handed
versions of amino acids to build proteins." Glavin is lead author
of a paper on this research appearing in the Proceedings of the
National Academy of Sciences March 16.
Proteins are the workhorse molecules of life, used in everything
from structures like hair to enzymes, the catalysts that speed up
or regulate chemical reactions. Just as the 26 letters of the
alphabet are arranged in limitless combinations to make words, life
uses 20 different amino acids in a huge variety of arrangements to
build millions of different proteins.
Amino acid molecules can be built in two ways that are mirror
images of each other, like your hands. Although life based on
right-handed amino acids would presumably work fine, "you can't mix
them," says Dr. Jason Dworkin of NASA Goddard, co-author of the
study. "If you do, life turns to something resembling scrambled
eggs -- it's a mess. Since life doesn't work with a mixture of
left-handed and right-handed amino acids, the mystery is: how did
life decide -- what made life choose left-handed amino acids over
right-handed ones?"
Over the last four years, the team carefully analyzed samples of
meteorites with an abundance of carbon, called carbonaceous
chondrites. The researchers looked for the amino acid isovaline and
discovered that three types of carbonaceous meteorites had more of
the left-handed version than the right-handed variety -- as much as
a record 18 percent more in the often-studied Murchison meteorite.
"Finding more left-handed isovaline in a variety of meteorites
supports the theory that amino acids brought to the early Earth by
asteroids and comets contributed to the origin of only left-handed
based protein life on Earth," said Glavin.
All amino acids can switch from left-handed to right, or the
reverse, by chemical reactions energized with radiation or
temperature, according to the team. The scientists looked for
isovaline because it has the ability to preserve its handedness for
billions of years, and it is extremely rarely used by life, so its
presence in meteorites is unlikely to be from contamination by
terrestrial life. "The meteorites we studied are from before Earth
formed, over 4.5 billion years ago," said Glavin. "We believe the
same process that created extra left-handed isovaline would have
created more left-handed versions of the other amino acids found in
these meteorites, but the bias toward left-handed versions has been
mostly erased after all this time."
The team's discovery validates and extends the research first
reported a decade ago by Drs. John Cronin and Sandra Pizzarello of
Arizona State University, who were first to discover excess
isovaline in the Murchison meteorite, believed to be a piece of an
asteroid. "We used a different technique to find the excess, and
discovered it for the first time in the Orgueil meteorite, which
belongs to another meteorite group believed to be from an extinct
comet," said Glavin.
The team also found a pattern to the excess. Different types of
meteorites had different amounts of water, as determined by the
clays and water-bearing minerals found in the meteorites. The team
discovered meteorites with more water also had greater amounts of
left-handed isovaline. "This gives us a hint that the creation of
extra left-handed amino acids had something to do with alteration
by water," said Dworkin. "Since there are many ways to make extra
left-handed amino acids, this discovery considerably narrows down
the search."
If the bias toward left-handedness originated in space, it makes
the search for extraterrestrial life in our solar system more
difficult... while also making its origin a bit more likely,
according to the team.
(Images by NASA/Mary Pat Hrybyk-Keith)