According to Marvin et al. sHSPs independently express not only in heat shock response but also have developmental roles in embryonic or juvenile stages of mammals,
teleost fish and some lower vertebral genomes. hspb1 (HSP27) is expressed during stress and during the development of embryo, somites, mid-hindbrain, heart and lens in
zebrafish. Expression of the hspb4 gene, which codes for
alpha crystallin, increases considerably in the lens in response to heat shock.
Upregulation in stress Production of high levels of heat shock proteins can also be triggered by exposure to different kinds of environmental
stress conditions, such as
infection,
inflammation, exercise, exposure of the cell to harmful materials (
ethanol,
arsenic, and
trace metals, among many others),
ultraviolet light,
starvation,
hypoxia (
oxygen deprivation), nitrogen deficiency (in plants) or water deprivation. As a consequence, the heat shock proteins are also referred to as
stress proteins and their
upregulation is sometimes described more generally as part of the
cell stress response. The mechanism by which heat shock (or other environmental stressors) activates the heat shock factor has been determined in bacteria. During heat stress, outer membrane proteins (OMPs) do not fold and cannot insert correctly into the outer membrane. They accumulate in the
periplasmic space. These OMPs are detected by DegS, an inner membrane
protease, that passes the signal through the membrane to the sigmaE transcription factor. However, some studies suggest that an increase in damaged or abnormal proteins brings HSPs into action. Some bacterial heat shock proteins are upregulated via a mechanism involving
RNA thermometers such as the
FourU thermometer,
ROSE element and the
Hsp90 cis-regulatory element. Petersen and Mitchell found that in
D. melanogaster a mild heat shock pretreatment which induces heat shock
gene expression (and greatly enhances survival after a subsequent higher temperature heat shock) primarily affects
translation of
messenger RNA rather than
transcription of RNA. Heat shock proteins are also synthesized in
D. melanogaster during recovery from prolonged exposure to cold in the absence of heat shock. A mild heat shock pretreatment of the same kind that protects against death from subsequent heat shock also prevents death from exposure to cold. Some members of the HSP family are expressed at low to moderate levels in
all organisms because of their essential role in protein maintenance.
Management Heat-shock proteins also occur under non-stressful conditions, simply "monitoring" the cell's proteins. Some examples of their role as "monitors" are that they carry old proteins to the cell's "recycling bin" (
proteasome) and they help newly synthesised proteins fold properly. These activities are part of a cell's own repair system, called the "cellular stress response" or the "heat-shock response". Recently, there are several studies that suggest a correlation between HSPs and dual frequency ultrasound as demonstrated by the use of LDM-MED machine. Heat shock proteins appear to be more susceptible to self-degradation than other proteins due to slow
proteolytic action on themselves.
Cardiovascular Heat shock proteins appear to serve a significant cardiovascular role. Hsp90,
hsp84, hsp70,
hsp27,
hsp20, and
alpha B crystallin all have been reported as having roles in the cardiovasculature.
Hsp90 binds both
endothelial nitric oxide synthase and soluble
guanylate cyclase, which in turn are involved in vascular relaxation. The subset of hsp70, extracellular hsp70 (ehsp70) and intracellular hsp70 (ihsp70), has been shown to have a pivotal role in managing
oxidative stress and other physiological factors. Krief et al. referred hspb7 (cvHSP - cardiovascular Heat shock protein) as cardiac heat shock protein. Gata4 is an essential gene responsible for cardiac morphogenesis. It also regulates the gene expression of hspb7 and hspb12. Gata4 depletion can result in reduced transcript levels of hspb7 and hspb12 and this could result in cardiac myopathies in zebrafish embryos as observed by Gabriel et al. hspb7 also acts in the downregulation of Kupffer vesicles which is responsible for regulation of left-right asymmetry of heart in zebrafish. Along with hspb7, hspb12 is involved in cardiac laterality determination. Hsp20 appears significant in development of the smooth muscle phenotype during development. Hsp20 also serves a significant role in preventing platelet aggregation, cardiac myocyte function and prevention of apoptosis after ischemic injury, and skeletal muscle function and muscle insulin response. Hsp27 is a major phosphoprotein during women's contractions. Hsp27 functions in small muscle migrations and appears to serve an integral role.
Immunity Function of heat-shock proteins in immunity is based on their ability to bind not only whole proteins, but also peptides. The affinity and specificity of this interaction is typically low. It was shown, that at least some of the HSPs possess this ability, mainly
hsp70,
hsp90,
gp96 and
calreticulin, and their peptide-binding sites were identified. But gp96 immune function could be peptide-independent, because it is involved in proper folding of many immune receptors, like
TLR or
integrins.
Antigen presentation HSPs are indispensable components of
antigen presentation pathways - the classical ones and also
cross-presentation Heat-shock proteins can signal also through
scavenger receptors, which can either associate with TLRs, or activate pro-inflammatory intracellular pathways like
MAPK or
NF-kB. With the exception of SRA, which down-regulates immune response.
Lens Alpha
crystallin (
α4- crystallin) or hspb4 is involved in the development of lens in Zebrafish as it is expressed in response to heat shock in the Zebrafish embryo in its developmental stages. ==Clinical significance==