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March 23, 2000
Media Contact: Kim McDonald
UCSD STUDY OF UNCOORDINATED FRUIT FLIES PROVIDES
MOLECULAR CLUES TO HEARING PROBLEMS IN
HUMANS
In an ingenious study of severely uncoordinated fruit
flies,
scientists at the University of
California, San Diego have obtained the first molecular
hints
of how humans and other complex organisms hear, maintain
their
balance and sense touch.
In the March 24 issue of Science, the researchers at the
university’s
Department of
Biology and Howard Hughes Medical Institute report their
discovery
of a gene in Drosophila that, when altered, disrupts the
molecular
functioning of the fruit fly’s mechanoreceptor
cells. This
results in flies that are unable to hear and sense the world
around them, and are so uncoordinated that without help from
the researchers they quickly die.
"You literally have to hand-feed them, put food in
their
mouths, because they’re so
uncoordinated that they just can’t function in any
other
way," said Richard G. Walker, a
postdoctoral researcher at UCSD and the first author of the
study. “It’s a lethal mutation, because once they
come out of their pupal cases they are so uncoordinated that
they just fall into their food, which is kind of sticky,
where
they get stuck and die.”
Scientists have known for the past 15 years that mechanical
energy in the form of sound and touch can be transformed by
tiny mechanoreceptor cells into chemical and electrical
signals
that are processed by the brain to hear, sense touch,
maintain
balance and determine the position of one’s limbs in
space.
Many of these cells, which are found in vertebrate and
invertebrate
animals, consist of tiny hair-like structures that, when
deflected,
open ion channels in the cells, triggering the release of
neurotransmitters,
which then produce electrical responses in the brain.
“The mechanical senses are conserved through
evolution,
from the tiniest organisms to
humans, because they all perform this critical function,
which
is to respond to mechanical
stimulation,” said Charles S. Zuker, a professor of
biology
who headed the study. “Our
enjoyment of wonderful symphonies is nothing but the
conversion
of mechanical energy into electrical signals by the cells in
our inner ear.”
What scientists have not known is how genes affect the
detailed
molecular processes in these mechanoreceptor cells. Such
cells
are typically small and relatively scarce, making it
difficult
for researchers to accumulate enough material for
biochemical
studies. But in Drosophila, the bristles of the
mechanoreceptor
cells on the insect’s thorax are especially large
and prominent,
making them amenable for biochemical and
electrophysiological
studies. Because so many of its genes have been
identified and
mapped, the fruit fly is also an ideal organism on which to
conduct genetic studies.
To conduct the study, Walker first screened 27 strains
of Drosophila
with genetic
mutations that made them severely uncoordinated. These
mutants,
which were isolated six years ago by Maurice Kernan, a
postdoctoral
researcher in Zuker’s lab who is now at the State
University
of New York at Stony Brook, are thought to have a variety of
mutations that prevent their brains from receiving
signals from
their mechanoreceptor cells. However, Walker wanted only
those
mutants with defects in the mechanoelectrical
transduction pathway itself. He found them by measuring the
electrical currents of their
mechanoreceptor neurons when the hair bristles of the cells
were deflected slightly, an action that in normal insects
produces
a small electrical current. The cells are so sensitive that
a movement that deflects the bristles only a small fraction
of a micrometer can be sensed by the brain.
After Walker found three strains that produced little or no
electrical current, dubbed
nompC for “no mechanoreceptor potential C,” he
identified
a gene, encoding a novel ion
channel, that when put into nompC flies restored the mutants
to normal. Aarron T. Willingham, a graduate student working
in Zuker’s lab, tied the defects to mutations in
this gene,
confirming nompC’s identity.
“Once they cloned
nompC, everything was
clear,” said
Peter G. Gillespie of the Oregon
Hearing Research Center and Vollum Institute at the
Oregon Health
Sciences University.
“nompC is definitely part of the fly transduction
channel,
either the pore itself or a principal component. This
work has
enormous significance as it suggests that one could find
other
mechanotransduction channels by looking for relatives of nompC.
Identifying any protein that serves within any mechanical
transduction
apparatus has been exceptionally difficult. But here we have
a clear answer.”
The UCSD researchers found a homologous, or functionally
similar,
protein produced by
a similar gene in the roundworm C. elegans. They suspect
that
similar genes and proteins are found in humans and other
vertebrate
organisms that have retained the same genetic and
biochemical
machinery as Drosophila and C. elegans through evolution.
“If
there’s one thing we’ve learned over the past
80 years,
it’s that model organisms like
Drosophila are wonderful engines of discovery,” said
Zuker.
“They not only allow us to
efficiently focus on problems that are hard to track in
higher
organisms, they also recapitulate much of the same
biology as
more complex forms. In essence, we are nothing but a big
fly.”
He and his colleagues believe their discovery
could have application in understanding
and treating hearing loss, which is estimated to affect some
30 million Americans.
“As hard as it may be to visualize, there are very
strong
developmental and physiological
parallels between mechanosensation as done by fly
bristles and
by the human inner ear,” said James W. Posakony, a
biology
professor at UCSD. “So it is quite possible that a
human
version of this channel protein exists and has a major role
in how we hear. This would be of extreme importance in
understanding
both hearing and deafness in humans.”
“Hearing loss is a major medical problem in
industrialized
countries, because hearing
loss comes in many different shapes and forms,” said
Zuker.
“Many are inherited and many are due to abuse.
It’s
very likely that both types of human disorders are
intimately
tied to defects in the ability of these cells to perform. So
understanding the mechanism of mechanosensory signalling can
produce some very important insights into how to treat,
prevent
and diagnose hearing disorders.”
# # #
To obtain photos or video, contact Kim McDonald
Photo/Video credit: Richard Walker, UCSD
Photo caption: UCSD scientists have discovered a gene in
this
uncoordinated strain of Drosophila that, when altered,
disrupts
the molecular functioning of the fruit fly's mechanoreceptor
cells. Because the physiology of these cells is
remarkably similar
to that of cells in the inner ear of humans, their
achievement
should provide important insights into how to treat, prevent
anddiagnose human hearing disorders.
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