A graphical representation of glycine on
a surface in the interstellar medium bombarded by cosmic rays to produce
peptides, the building block of proteins. Credit: Alfred Thomas Hopkinson. The
stars are adapted from NIRCam image of the Cosmic Cliffs. Credit: NASA / ESA /
CSA / STScI
Challenging
long-held assumptions, Aarhus University researchers have demonstrated that the
protein building blocks essential for life as we know it can form readily in
space. This discovery,
appearing in Nature Astronomy,
significantly raises the statistical probability of finding extraterrestrial
life.
In a modern laboratory at Aarhus
University and at an international European facility in Hungary (HUN-REN
Atomki), researchers Sergio Ioppolo and Alfred Thomas Hopkinson conduct
pioneering experiments. Within a small chamber, the two scientists have mimicked
the environment found in giant dust clouds thousands of light-years away. This
is no easy feat.
The temperature in these regions is a
freezing -260° C. There is almost no pressure, meaning the researchers must
constantly pump out gas particles to maintain an ultra-high
vacuum. They are simulating
these conditions to observe how the remaining particles react to radiation,
exactly as they would in a real interstellar environment.
In the background, Associate Professor
Sergio Ioppolo (left) and Postdoc Alfred Thomas Hopkinson (right) discussing
experimental plans. In the foreground, two ultra-high vacuum chambers used to
investigate reactions under interstellar medium conditions. Credit: Dr. Signe
Kyrkjebø, Aarhus University
"We already know from earlier
experiments that simple amino acids, like glycine, form in interstellar space. But we
were interested in discovering if more complex molecules, like peptides, form
naturally on the surface of dust grains before those take part in the formation
of stars and planets," says Ioppolo.
Peptides are amino acids bonded
together in short chains. When peptides bond with one another, they form
proteins, which are essential for life as we know it. Looking for the
precursors to proteins is therefore vital in the search for the origin of life,
Ioppolo explains.
The two researchers placed glycine
in the chamber, irradiated it with cosmic ray analogs produced by an ion
accelerator at HUN-REN Atomki, and analyzed the results.
"We saw that the glycine
molecules started reacting with each other to form peptides and water. This
indicates that the same process occurs in interstellar space," Hopkinson
says. "This is a step toward proteins being created on dust particles, the
same materials that later form rocky planets."
Where stars are born
Ioppolo, Hopkinson, and their
colleagues at Aarhus University study and mimic the giant dust clouds between
the stars because these are the birthplaces of new solar systems.
"We used to think that only
very simple molecules could be created in these clouds. The understanding was
that more complex molecules formed much later, once the gases had begun
coalescing into a disk that eventually becomes a star," Ioppolo explains.
"But we have shown that this is clearly not the case."
The discovery is significant
because it suggests that these essential molecules are far more abundant in the
universe than previously believed.
"Eventually, these gas clouds
collapse into stars and planets. Bit by bit, these tiny building blocks land on
rocky planets within a newly formed solar system. If those planets happen to be
in the habitable zone, then there is a real probability that life might
emerge," Ioppolo explains.
"That said, we still don't
know exactly how life began. But research like ours shows that many of the
complex molecules necessary for life are created naturally in space."
The Ice Chamber for
Astrophysics–Astrochemistry (ICA) ultra-high vacuum chamber at Atomki, Hungary.
This was a chamber used to process glycine with high-energy protons. Credit:
Béla Sulik / HUN-REN Institute for Nuclear Research (Atomki)
A universal reaction
It might seem like a minor
discovery that peptides form naturally from the simplest amino acids in space.
However, the chemical process through which amino acids bond is universal. This
suggests that the same reaction likely occurs with other, more complex amino
acids as well, explains Hopkinson.
"All
types of amino acids bond into peptides through the same reaction. It is
therefore very likely that other peptides naturally form in interstellar space
as well," says Hopkinson. "We haven't looked into this yet, but we
are likely to do so in the future."
Amino acids and peptides are not the
only building blocks essential to life; membranes, nucleobases, and nucleotides
are necessary as well. Whether these also form naturally in space remains
unknown, but Ioppolo, Hopkinson, and their colleagues at the Center for
Interstellar Catalysis are working hard to find out.
"These molecules are some of the
key building blocks of life," explained co-author Professor Liv Hornekær,
the InterCat center leader. "They might actively participate in early
prebiotic chemistry, catalyzing further reactions that lead toward life."
"There's still a lot to be discovered, but our research team is working on answering as many of these basic questions as possible," Ioppolo says. "We've already discovered that many of the building blocks of life are formed out there, and we'll likely find more in the future."
Provided by Aarhus
University
Source: Complex building blocks of life form spontaneously in space, research reveals
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