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heteromers

A heteromer is a molecular complex formed by subunits that are different from one another. In contrast to homomers, which consist of identical subunits, heteromers combine distinct polypeptide chains to create a single functional unit. Heteromeric assemblies are common in protein networks, especially among receptors and ion channels, and they can assemble in various tissues and compartments inside the cell.

The formation of heteromers often changes the properties of the constituent subunits. Heteromerization can alter ligand

Detection and study of heteromers rely on biochemical and imaging approaches that reveal physical association and

binding,
signaling
pathway
preference,
channel
conductance,
trafficking,
and
regulatory
interactions.
In
cell
signaling,
heteromeric
G
protein–coupled
receptors
can
exhibit
pharmacology
and
signaling
biased
relative
to
their
parent
receptors.
Notable
examples
include
dopamine
D1–D2
receptor
heteromers
and
adenosine
A2A–D2
receptor
heteromers,
as
well
as
heteromeric
NMDA
receptors
composed
of
GluN1
with
GluN2
subunits.
Heteromeric
nicotinic
acetylcholine
receptors
(such
as
α4β2)
and
certain
GABA-A
receptor
assemblies
also
illustrate
this
principle,
with
subunit
composition
shaping
functional
responses.
functional
interaction.
Methods
include
co-immunoprecipitation,
cross-linking,
fluorescence
resonance
energy
transfer
(FRET),
bioluminescence
resonance
energy
transfer
(BRET),
and
proximity
ligation
assays.
Challenges
include
distinguishing
stable,
physiologically
relevant
heteromers
from
transient
or
co-localized
subunits
and
accounting
for
tissue-
or
condition-specific
assembly.
Understanding
heteromerization
enhances
insights
into
signaling
networks
and
can
inform
the
development
of
more
selective
therapeutic
agents.