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cotransmitters

Cotransmitters are chemical messengers released from a presynaptic neuron alongside the primary transmitter, contributing to synaptic signaling in a coordinated way. The term encompasses a broad range of molecules, including small-molecule transmitters that accompany another transmitter, as well as neuropeptides that are released from distinct vesicle populations. Cotransmission describes the phenomenon in which a neuron emits more than one transmitter and these signaling molecules interact to shape the postsynaptic response.

Release and mechanisms

Many neurons contain two vesicle systems: small clear vesicles carrying classical fast transmitters, and large dense-core

Examples and significance

Cotransmission is well documented in both peripheral and central nervous systems. In the sympathetic system, norepinephrine

Notes

Cotransmitters are an active area of research, with ongoing debates about the exact roles of specific molecules

vesicles
containing
neuropeptides
or
other
modulators.
Release
of
these
vesicles
can
be
frequency-
and
Ca2+-dependent,
with
high-frequency
or
sustained
activity
favoring
the
release
of
neuropeptides.
A
presynaptic
neuron
may
therefore
release
a
fast
transmitter
to
produce
an
immediate
effect
and
one
or
more
cotransmitters
to
modulate
the
response
over
longer
timescales.
Cotransmitters
can
act
on
distinct
receptors,
produce
depolarization
or
hyperpolarization,
influence
ion
channels,
and
engage
second
messenger
cascades.
They
can
also
modulate
the
release
probability
of
the
primary
transmitter
via
presynaptic
receptors,
adding
another
layer
of
control
to
synaptic
communication.
is
often
co-released
with
ATP
and
neuropeptide
Y,
contributing
to
rapid
signaling
and
longer-term
modulation.
In
other
circuits,
acetylcholine
or
dopamine
may
be
released
together
with
neuropeptides
or
purines,
expanding
the
range
of
physiological
effects.
Understanding
cotransmitters
illuminates
how
neurons
diversify
signaling,
influence
plasticity,
and
participate
in
complex
processes
such
as
pain,
mood,
arousal,
and
autonomic
regulation.
in
different
circuits
and
how
release
dynamics
shape
function.