Researchers at Penn State University have developed a chemical model
that mimics a possible step in the formation of cellular life on Earth
four-billion years ago. Using large "macromolecules" called polymers,
the scientists created primitive cell-like structures that they infused
with RNA -- the genetic coding material that is thought to precede the
appearance of DNA on Earth -- and demonstrated how the molecules would
react chemically under conditions that might have been present on the
early Earth.
The journal Nature Chemistry is posting the research as an Advance Online Publication on 14 October 2012.
In modern biology, all life, with the exception of some viruses, uses
DNA as its genetic storage mechanism. According to the "RNA-world"
hypothesis, RNA appeared on Earth first, serving as both the
genetic-storage material and the functional molecules for catalyzing
chemical reactions, then DNA and proteins evolved much later. Unlike
DNA, RNA can adopt many different molecular conformations and so it is
functionally interactive on the molecular level. In the
soon-to-be-published research paper, two professors of chemistry,
Christine Keating and Philip Bevilacqua, and two graduate students,
Christopher Strulson and Rosalynn Molden, probe one of the nagging
mysteries of the RNA-world hypothesis.
"A missing piece of the RNA-world puzzle is compartmentalization,"
Bevilacqua said. "It's not enough to have the necessary molecules that
make up RNA floating around; they need to be compartmentalized and they
need to stay together without diffusing away. This packaging needs to
happen in a small-enough space -- something analogous to a modern cell
-- because a simple fact of chemistry is that molecules need to find
each other for a chemical reaction to occur."
To test how early cell-like structures could have formed and acted to
compartmentalize RNA molecules even in the absence of lipid-like
molecules that make up modern cellular membranes, Strulson and Molden
generated simple, non-living model "cells" in the laboratory. "Our team
prepared compartments using solutions of two polymers called
polyethylene glycol (PEG) and dextran," Keating explained. "These
solutions form distinct polymer-rich aqueous compartments, into which
molecules like RNA can become locally concentrated."
The team members found that, once the RNA was packed into the
dextran-rich compartments, the molecules were able to associate
physically, resulting in chemical reactions. "Interestingly, the more
densely the RNA was packed, the more quickly the reactions occurred,"
Bevilacqua explained. "We noted an increase in the rate of chemical
reactions of up to about 70-fold. Most importantly, we showed that for
RNA to 'do something' -- to react chemically -- it has to be
compartmentalized tightly into something like a cell. Our experiments
with aqueous two-phase systems (ATPS) have shown that some
compartmentalization mechanism may have provided catalysis in an
early-Earth environment."
Keating added that, although the team members do not suggest that PEG
and dextran were the specific polymers present on the early Earth, they
provide a clue to a plausible route to compartmentalization -- phase
separation. "Phase separation occurs when different types of polymers
are present in solution at relatively high concentrations. Instead of
mixing, the sample separates to form two distinct liquids, similar to
how oil and water separate." Keating explained. "The aqueous-phase
compartments we manufactured using dextran and PEG can drive biochemical
reactions by increasing local reactant concentrations. So, it's
possible that some other sorts of polymers might have been the molecules
that drove compartmentalization on the early Earth." Strulson added
that, "In addition to the RNA-world hypothesis, these results may be
relevant to RNA localization and function in non-membrane compartments
in modern biology."
The team members also found that the longer the string of RNA, the
more densely it would be packed into the dextran compartment of the
ATPS, while the shorter strings tended to be left out. "We hypothesize
that this research result might indicate some kind of primitive sorting
method," Bevilacqua said. "As RNA gets shorter, it tends to have less
enzyme activity. So, in an early-Earth system similar to our dextran-PEG
model system, the full-length, functional RNA would have been sorted
and concentrated into one phase, while the shorter RNA that is not only
less functional, but also threatens to inhibit important chemical
reactions, would not have been included."
The scientists hope to continue their investigations by testing their
model-cell method with other polymers. Keating added, "We are
interested in looking at compartmentalization in polymer systems that
are more closely related to those that may have been present on the
early Earth, and also those that may be present in contemporary
biological cells, where RNA compartmentalization remains important for a
wide range of cellular processes."
This research was funded by the National Science Foundation (grant CHE-0750196).
Journal Reference:
- Christopher A. Strulson, Rosalynn C. Molden, Christine D. Keating, Philip C. Bevilacqua. RNA catalysis through compartmentalization. Nature Chemistry, 2012; DOI: 10.1038/nchem.1466C
Courtesy: ScienceDaily
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