Special Fellow Defne Yarar investigates
actin in action
CAMBRIDGE, Mass. (August 8, 2007) — Among your
body’s proteins, actin is a workhorse, and it
seems to be everywhere. The protein is strung into
microfilaments that help to give your cells structure,
allow them to move, divide them, and let your muscles
contract.
Actin is also a key player in endocytosis, the primary
mechanism by which cells ingest nutrients and other
macromolecules. Defne Yarar, PhD, who first demonstrated
this role in mammalian cells, has been appointed a
Special Fellow of the Whitehead Institute and MIT Center
for Cancer Research, arriving in September. Her lab
space will be at the MIT Center for Cancer Research.
“Defne has identified a key player
in the endocytosis pathway,” says
Whitehead Member Hidde Ploegh. “That pathway
is so fundamental—so important for virus
entry, nutrient intake and other processes—that
Whitehead can ill afford to lack expertise in
endocytosis.” |
Yarar began by studying actin as a graduate student
in the laboratory of Mathew Welch, PhD, at the University
of California/Berkeley, investigating how the actin
filaments that crisscross the cell—collectively
known as the cytoskeleton—are regulated during
cell movement.
Scientists already knew that a cell travels by extending
actin filaments ahead of its leading edge. But they
didn’t know the details of the polymerization
process by which these filaments begin to extend themselves.
Working with purified proteins, Yarar and her colleagues
showed that the Wiskott-Aldrich Syndrome protein (WASP)
could stimulate the Arp2/3 protein complex, which is
known to kick off filament polymerization. She further
demonstrated this by coating plastic beads with WASP,
placing them in a culture derived from frog eggs and
examining the formation of actin filaments at the surface
of the beads.
Yarar went on to study the role of the actin cytoskeleton
in endocytosis, as a postdoctoral fellow and then a
senior fellow in the laboratory of Sandra Schmid, PhD,
at The Scripps Research Institute in La Jolla, California.
The primary route for the cellular uptake of macromolecules
is a process called clathrin-mediated endocytosis,
during which a structural protein called clathrin assists
the cell's outer membrane in folding inward to form
vesicles—small balloon-like structures, entirely
enclosed by a membrane. This operation is essential
for nutrient uptake, certain forms of cell regulation
(such as turning off extracellular growth signals),
immune system function and other crucial tasks.
Wondering whether the actin cytoskeleton also plays
a role in endocytosis, Yarar completed biochemical
assays indicating that the process continues even when
actin polymerization has ended. Studies of live cells
with a high-resolution fluorescence microscope showed,
however, that loss of actin polymerization almost shuts
down endocytosis. Yarar followed up with studies of
how this process is regulated, pinpointing an essential
role for a protein called SNX9, which aids both in
remodeling the cell membrane and in driving actin filament
formation.
At Whitehead, Yarar will continue to probe the mystery
of actin’s precise role in endocytosis—with
live cell imaging, electron microscopy and tests with
drugs and genetic inhibitors. In addition, she will
utilize a variety of research techniques to examine
how SNX9 and other proteins regulate actin during endocytosis. “The
identification of novel factors that regulate this
protein during endocytosis will
enable the development of assays to screen for human
disease and the identification of potential targets
for new drug therapies,” Yarar explains.
“Defne has identified a key player in the endocytosis
pathway,” comments Whitehead Member Hidde Ploegh. “That
pathway is so fundamental—so important for virus
entry, nutrient intake and other processes—that
Whitehead can ill afford to lack expertise in endocytosis.
We’re excited that Defne will be joining us to
fill that need.” |
