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filopodia

Filopodia are slender, actin-rich cellular protrusions that extend from the surface of many cell types. They function as sensory and exploratory structures, probing the extracellular environment to guide migration, adhesion, and cell–cell interactions.

Structure and composition: Filopodia are typically 0.1 to 0.3 micrometers in diameter and can reach several

Biogenesis and dynamics: Filopodium formation is driven by activation of Cdc42 and downstream effectors, including formins

Functions: They enable environmental sensing, chemotaxis, and directional migration. In neurons, filopodia from growth cones guide

Regulation: Rho family GTPases, especially Cdc42 and Rac, regulate formation; actin regulators such as IRSp53, N-WASP,

Clinical and research relevance: Filopodia are involved in development, wound healing, and cancer cell invasion, where

micrometers
in
length.
Their
core
consists
of
tightly
packed,
parallel
bundles
of
filamentous
actin
(F-actin),
stabilized
by
actin-bundling
proteins
such
as
fascin
and
fimbrin.
The
tip
contains
actin
filaments
in
a
growth
zone
with
regulatory
proteins
that
promote
elongation,
while
the
membrane
envelops
the
protrusion.
such
as
mDia2
and
the
Ena/VASP
family,
which
promote
polymerization
at
the
growing
tip.
The
Arp2/3
complex,
which
generates
branched
networks
in
lamellipodia,
is
less
central
within
the
central
filopodial
bundle,
though
it
may
contribute
at
the
base.
Filopodia
often
arise
from
preexisting
lamellipodial
networks
but
can
also
form
de
novo,
and
they
continually
extend
and
retract
in
response
to
cues.
axon
pathfinding.
In
other
cell
types,
they
facilitate
adhesion,
ligand
capture,
and
exploration
of
substrates
and
neighboring
cells.
and
VASP
coordinate
actin
assembly.
Phosphoinositides
and
mechanical
cues
also
modulate
filopodial
dynamics.
dynamic
protrusions
contribute
to
cell
movement
and
interaction
with
the
environment.