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Washington.– Researchers have discovered the
first brain regulatory gene that shows clear evidence of evolution from
lower primates to humans.
They said the evolution of humans might well have
depended in part on hyperactivation of the gene, called prodynorphin
(PDYN), that plays critical roles in regulating perception, behavior
and memory.
They reported that, compared to lower primates,
humans possess a distinctive variant in a regulatory segment of the
prodynorphin gene, which is a precursor molecule for a range of
regulatory proteins called "neuropeptides." This variant increases the
amount of prodynorphin produced in the brain.
While the researchers do not understand the
physiological implications of the activated PDYN gene in humans, they
said their finding offers an important and intriguing piece of a puzzle
of the mechanism by which humans evolved from lower
primates.
They also said that the discovery of this first
evolutionarily selected gene is likely only the beginning of a new
pathway of exploring how the pressure of natural selection influenced
evolution of other genes.
They also said their finding demonstrates how
evolution can act more efficiently to alter the regulatory segments, or
"promoters," that determine genes' activity, rather than on the gene
segment that determines the structure of the protein it
produces.
Such regulatory alteration, they said, can more
readily generate variability than the hit-or-miss mutations that alter
protein structure and function.
Proteins constitute the molecular machinery of
the cell, for example, catalyzing the multitude of chemical reactions
in the cell. DNA genes constitute the blueprints for such proteins,
with the regulatory segments of these genes determining how actively
the genes churn out proteins.
The researchers published their findings in the
December 2005 issue of the Public Library of Science. They were Gregory
Wray and David Goldstein of Duke University; Matthew Rockman of
Princeton University; Matthew Hahn of Indiana University; Nicole
Soranzo of University College London; and Fritz Zimprich of the Medical
University of Vienna in Austria. The research was sponsored by the
National Science Foundation and NASA.
"We focused on the prodynorphin gene because it
has been shown to play a central role in so many interesting processes
in the brain," said Wray. These include a person's sense of how well
they feel about themselves, their memory and their perception of
pain.
And it's known that people who don't make enough
of prodynorphin are vulnerable to drug addiction, schizophrenia,
bipolar disorders and a form of epilepsy. So, we reasoned that humans
might uniquely need to make more of this substance, perhaps because our
brains are bigger, or because they function differently.
"Also importantly, the part of the gene that
produces the prodynorphin protein shows no variation within humans, or
even between humans and any of the great apes," said Wray, who is a
professor of biology.
"So, if we found any variation in this gene due
to evolution, it was likely to be in its regulation. And our premise is
that the easiest way to generate evolutionary change is to alter
regulation."
In their studies, the researchers analyzed the
sequence structure of the PDYN promoter segment in humans and in seven
species of non-human primates – chimpanzees, bonobos, gorillas,
orangutans, baboons, pig-tailed macaques and rhesus monkeys.
They found significant mutational changes in the
regulatory sequence leading to humans that indicated preservation due
to positive evolutionary selection.
They also found an "evolution-by-association," in
which sequences near the regulatory segment showed greater mutational
change – as if they were "dragged along" with the evolving regulatory
sequence.
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