http://unisci.com/stories/20013/0926014.htm
26-Sep-2001
Researchers at UT Southwestern Medical
Center at Dallas have discovered a biochemical pathway that helps describe
how neurons in the brain and spinal cord form their connections.
“By learning how nerve fibers grow
and form connections in the embryonic brain and spinal cord, we may ultimately
be able to determine how to coax nerves to regrow and regenerate,” said
Dr. Mark Henkemeyer, a professor in the Center for Developmental Biology
at UT Southwestern.
The researchers’ studies focus on
a specific group of receptors and ligands that are widely expressed in
the developing nervous system.
Normally, ligands produced by one
cell bind their corresponding receptor, which is expressed on target cells.
This causes a change in the receptor, allowing it to transduce signals
into the receiving cell.
Although the body contains a vast
array of different classes of receptors and ligands, Henkemeyer and his
team have been working to learn how a particular group of such molecules,
the Eph receptors and ephrin ligands, communicate biochemical signals between
two cells.
Earlier discoveries by Henkemeyer
and his colleagues came from genetic studies using mutant mice as animal
models to uncover functions for the Ephs and ephrins.
“We found that these molecules communicate
important signals that guide the growing tips of embryonic nerve fibers
(the axon growth cone) and, therefore, help form networks of neurons and
synapses in the brain in a process called axon pathfinding,” Henkemeyer
said. “We're trying to define the cellular and biochemical basis of how
neurons can establish all these connections.”
The entire circuitry of the brain
and the nervous system is controlled by this pathfinding, which leads to
the formation of intricate and highly precise connections.
“I like to view the brain as the
amazing organic supercomputer,” Henkemeyer said. “But what's most amazing
is that, unlike the supercomputers that humans assemble with their hands,
neural networks, which are much more complicated than any man-made computer,
self-wire during embryonic and postnatal development. That's the big mystery
-– trying to figure out how the nervous system self-wires.
“The key message of this present
study is something that we've been working on for many years,” Henkemeyer
said. “When I first came to UT Southwestern to set up my laboratory, we
realized that the Eph receptors and ephrins are important partners in axon
pathfinding. Before then, everyone thought the ephrins were the ligands
that bound to the Eph receptor on the axon, which then turned on the axon
pathfinding signal.
"What I discovered, and what we continue
to work on today, is that the ligands -— the ephrins themselves -– are
also receptors.”
This finding was unprecedented, Henkemeyer
said.
“For the most part, everyone thought
ligands bind receptors, receptors send signals and, all of a sudden, we're
saying, ‘No, the receptor is actually the ligand, and the ligand is the
receptor.’”
Researchers then labeled the traditional
concept of the receptor-mediated signal as a “forward” signal to distinguish
it from the “reverse” signal that the ephrin ligands transduce into their
own cell.
“We laid out the hypothesis five
years ago that the ephrins were also receptors and that they transduce
what we call the ‘reverse' signal, and we also proposed that the ‘reverse’
signal was important in axon pathfinding.”
The present work now published in
Nature is an important extension of the researchers’ earlier description
of “reverse” signaling, as it describes in detail the biochemical signal
transduction cascades that ephrins can transduce into their cell.
“Although a tremendous amount of
research remains to be carried out,” Henkemeyer said, “we are one step
closer to figuring out how the brain and spinal cord wire themselves up.”
The study represents five years’
worth of work by Henkemeyer and UT Southwestern Ph.D. candidate Chad Cowan,
who received the 2001 UT Southwestern Nominata Award, the Southwestern
Graduate School of Biomedical Sciences’ top award, for his thesis research
and studies.
The research was made possible by
support from the Kent Waldrep Center for Basic Research on Nerve Growth
and Regeneration and a grant from the Welch Foundation.
[Contact: Angela Genusa]
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Further study into the new data,
published in the Sept. 13 issue of the journal Nature, could potentially
lead to discoveries about the role of this pathway in nerve regrowth and
regeneration.