Ancient Molocule Preserves Earliest & Most Profound Events of Evolutionary Past
An ancient molecule, known as Transfer RNA, central to every task a cell performs and thus essential to all life preserves some of the earliest and most profound events of the evolutionary past in its structure.
“Perhaps in evolution there are things that are so fundamental that they are kept, held onto, for millions or even billions of years,” Caetano-Anollés of the University of Illinois said. “Those are the fossils, the molecular fossils, that tell us about the past. Therefore, studying these molecules can address fundamental questions in biology and evolution.”
Transfer RNA (tRNA) is the most direct intermediary between genes
and proteins. Like many other RNAs (ribonucleic acids), tRNA aids in
translating genes into the chains of amino acids that make up proteins.
With the help of a highly targeted enzyme, each tRNA molecule
recognizes and latches onto a specific amino acid, which it carries
into the protein-building machinery. In order to successfully add its
amino acid to the end of a growing protein, tRNA must also accurately
read a coded segment of messenger RNA, which gives instructions for the
exact sequence of amino acids in the protein.
The fact that tRNA is so central to the task of building proteins
probably means that it has been around for a long time, Caetano-Anollés
said. His inquiry began with a hunch that understanding the structural
properties of tRNA would shed light on how organisms and viruses
evolved.
All tRNAs assemble themselves into a shape that, if flattened,
resembles a cloverleaf. The team began by looking for patterns in this
cloverleaf structure, using detailed data from hundreds of molecules
representing viruses and each of the three superkingdoms of life:
archaea, bacteria and eukarya.
The researchers converted all distinguishing features of the individual
tRNA cloverleaf structures into coded characters, a process that
allowed a computerized search for the most “parsimonious” (that is, the
simplest, most probable) tRNA family tree. They conducted the same
analysis on the tRNAs of each of the superkingdoms, to see how far
these groupings diverged from the overall tree. This comparison allowed
them to determine the order in which viruses and each of the
superkingdoms diverged.
The new analysis supports an earlier study that suggested that the
archaea were the first to arise as an evolutionarily distinguishable
group. Archaea are microbes that can survive in boiling acid, near
sulfurous ocean vents or in other extreme environments. The earlier
study, also led by Caetano-Anollés, analyzed the vast catalog of
protein folds – those precisely configured regions in proteins that
give them their functionality – as a guidebook to evolutionary history.
“The transfer RNA data matches our earlier data,” Caetano-Anollés said.
“This is important because two lines of independent evidence are
supporting each other.”
The new analysis also indicates that viruses emerged not long after the
archaea, with the superkingdoms eukarya and bacteria following much
later – and in that order. This finding may influence the ongoing
debate over whether viruses existed prior to, or after, the emergence
of living cells, Caetano-Anollés said.
“This supports the idea that viruses arose from the cellular domain,” he said.
The study, co-written by Gustavo Caetano-Anollés, and postdoctoral researcher University of Illinois Institute for Genomic Biology and Feng-Jie Sun, appears March 7 in PLoS Computational Biology.
Posted by Casey Kazan.
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