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heatshock

Heat shock refers to exposure to elevated temperatures that disrupt cellular proteostasis. In many organisms, such stress triggers a conserved transcriptional program called the heat shock response (HSR), which upregulates a group of proteins known as heat shock proteins (HSPs). HSPs function as molecular chaperones and are involved in protein folding, prevention of aggregation, and, when needed, targeted degradation of damaged proteins.

The regulatory circuitry of the heat shock response varies by domain of life. In bacteria, the response

The primary outcome of the heat shock response is enhanced proteostasis: increased capacity to refold denatured

Heat shock responses are broadly conserved across bacteria, archaea, plants, and animals and can be triggered

is
governed
mainly
by
the
sigma
factor
σ32
(RpoH),
which
increases
transcription
of
chaperones
such
as
DnaK,
DnaJ,
and
GrpE.
In
eukaryotes,
heat
shock
transcription
factors
(e.g.,
HSF1
in
animals,
HsfA1
in
plants)
sense
proteotoxic
stress;
they
trimerize,
translocate
to
the
nucleus,
bind
heat
shock
elements
in
DNA,
and
induce
expression
of
HSPs
such
as
HSP70,
HSP90,
HSP60,
and
small
HSPs.
Feedback
mechanisms,
including
binding
of
HSPs
to
the
transcription
factors,
help
shut
off
the
response
when
homeostasis
is
restored.
proteins,
prevent
aggregation,
and
mediate
degradation
of
severely
damaged
proteins.
This
can
confer
acquired
thermotolerance,
where
a
prior
mild
heat
exposure
improves
survival
under
subsequent
heat
stress.
by
other
forms
of
proteotoxic
stress,
such
as
oxidative
stress
or
toxins.
The
concept
is
widely
used
in
research
on
stress
physiology,
aging,
neurodegenerative
disease,
and
cancer
biology.