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exocitosis

Exocitosis, also called exocytosis, is the cellular process by which vesicles derived from the Golgi apparatus or endosomal compartments fuse with the plasma membrane to release their contents into the extracellular space. This process also transfers membrane lipids and proteins to the cell surface, contributing to membrane turnover.

In regulated exocytosis, vesicle fusion is triggered by an intracellular signal, typically a rise in cytosolic

Mechanistically, vesicles are transported to the plasma membrane and dock at specific sites through interactions between

Roles include neurotransmission, hormone secretion, enzyme release, and certain immune responses, as well as membrane remodeling

Clinical relevance includes links to secretory disorders such as diabetes mellitus (impaired insulin release) and some

calcium
ions.
In
neurons,
calcium
influx
through
voltage-gated
channels
triggers
neurotransmitter
release.
In
many
secretory
cells,
hormones
and
enzymes
are
released
in
response
to
stimuli
such
as
other
signaling
molecules
or
nutrients.
In
constitutive
exocytosis,
vesicles
fuse
with
the
plasma
membrane
in
a
continuous,
unregulated
manner,
supplying
membrane
components
and
secreted
proteins.
v-SNAREs
on
the
vesicle
and
t-SNAREs
on
the
target
membrane.
Priming
reactions
prepare
the
fusion
machinery;
upon
Ca2+
binding
to
sensor
proteins,
the
SNARE
complex
drives
membrane
fusion.
Fusion
can
be
complete,
with
vesicle
contents
released
and
the
vesicle
membrane
incorporated,
or
transient
in
kiss-and-run
fusion,
allowing
rapid
reuse
of
vesicle
components.
and
surface
receptor
turnover.
Exocytosis
is
essential
for
cellular
communication
and
maintenance,
and
its
dysfunction
can
affect
multiple
tissues.
neurodegenerative
diseases.
Toxins
that
disrupt
exocytosis,
such
as
botulinum
and
tetanus
toxins,
cleave
SNARE
proteins
and
inhibit
vesicle
fusion,
illustrating
the
pathway’s
importance
for
normal
physiology.