Temporal and spatial distribution of heat shock mRNA and protein (hsp70) in the rabbit cerebellum in response to hyperthermia

We have previously investigated the expression of hsp70 genes in the hyperthermic rabbit brain at the mRNA level by Northern blot and in situ hybridization procedures. Our studies have now been extended to the protein level utilizing Western blot and immunocytochemistry. Using an antibody which is specific to inducible hsp70, a prominent induction of hsp70 protein in glial cells of hyperthermic animals was noted. In particular, Bergmann glial cells in the cerebellum are strongly immunoreactive while adjacent Purkinje neurons are immunonegative. Extension of our in situ hybridization studies to a time course analysis revealed that the initial glial induction events were followed by a delayed accumulation of inducible hsp70 mRNA in Purkinje neurons at 10 hr post-heat shock. In control animals, high levels of constitutively expressed hsc70 mRNA and protein were observed in Purkinje neurons. Similar hsc70 and hsp70 mRNA observations were also made in neurons of the deep cerebellar nuclei and in motor neurons of the spinal cord. Our results suggest that these neuronal cell types accmulate hsp70 mRNA in response to hyperthermic treatment; however, the response is delayed when compared to the rapid response seen in glial cells. The high constitutive levels of hsc70 in certain neuronal cell types may play a role in the initial dampening of the hsp70 induction response in these cells. © 1993 Wiley-Liss, Inc.     

Transcriptional malfunctioning of heat shock protein gene expression in spinocerebellar ataxias

Among the various dominantly-inherited spinocerebellar ataxias (SCAs), at least seven of them belong to the polyglutamine disease group and are caused by glutamine-coding CAG triplet repeat expansion. The expanded coding CAG repeat translates into a polyglutamine stretch in the disease protein, which leads to late-onset and progressive neurodegeneration. Expanded polyglutamine adopts a misfolded protein conformation, and is itself a cellular stressor which induces robust heat shock response (HSR). Under polyglutamine stress, heat shock proteins (Hsps) are produced in neurons to assist refolding and/or promote the degradation of misfolded proteins. Along with the progressive nature of polyglutamine degeneration, a gradual decline of HSR in degenerating neurons was observed. Such kind of reduction can be observed in a large family of hsp gene expression, including hsp22, 26, 27, and 70. This underscores an intimate relationship between the inducibility of hsp gene expression and the disease progression. In this review, we describe the current understandings of hsp gene dysregulation in polyglutamine disease.     

gp120 neurotoxicity fails to induce heat shock defenses,while the over expression of hsp70 protects against gp120

gp120, the coat glycoprotein of HIV, can damage CNS neurons. This appears to mostly involve an indirect pathway in which gp120 infects microglia, triggering the release of cytokines and glutamatergic excitotoxins which then damage neurons. A well-characterized response of cells to insults is to mobilize the heat stress response, a defense that has a number of protective consequences. We tested the capacity of gp120, at a dose well-documented to be neurotoxic, to activate the heat shock response in cultures from cortex and hippocampus, two brain regions sensitive to the neurotoxic effects of gp120. We found that gp120 failed to induce expression of hsp70, hsp25 or hsp90 in cortical or hippocampal cultures, under conditions where induction can be demonstrated in response to other insults. The failure of gp120 to induce a heat shock response is significant because we subsequently demonstrated that such an induction would have been beneficial. Specifically, over expression of hsp70 with a herpes viral amplicon vector protected cultured hippocampal neurons from gp120 neurotoxicity.     

Aberrant stress‐induced Hsp70 expression in immune cells in multiple sclerosis

Heat shock protein 70 (Hsp70), a prominent member of the heat shock protein family, is a stress‐induced chaperone, contributing to the “protein triage” mechanism. However, we and others have previously shown that chaperonin activity of Hsp70 also promotes immune recognition of protein/peptide antigens, including myelin autoantigens. Hsp70 has been strikingly elevated in multiple sclerosis (MS) lesions. In a search for the mechanism of Hsp70 up‐regulation in MS, we analyzed Hsp70 expression in peripheral blood mononuclear cells (PBMCs) from MS patients (n = 49), healthy controls (n = 40), and patients with rheumatoid arthritis, (RA; n = 13). Hsp70 was detected by Western blot, and Hsp70 levels were quantified by ELISA. We found that Hsp70 was expressed at low levels in ex vivo PBMCs. However, after heat shock, Hsp70 was up‐regulated significantly more (up to sixfold) in MS patients compared with healthy controls. This significant overproduction of Hsp70 was also seen following another stress condition, LPS stimulation. Hsp70 is a product of several independent genes, and we found the HSPA1B gene product to be the major form responsible for Hsp70 protein overexpression in PBMCs. Hsp70 overexpression was preceded by increased nuclear presence of heat shock factor 1 (HSF1). HSF1 activation depends on phosphorylation, and we found that inhibition of the A group of protein kinase C isoenzymes significantly reduced inducible Hsp70 production. These results indicate that immune cells from MS patients are more prone to Hsp70 induction under stress conditions, suggesting a possible link between Hsp70 overexpression and development of autoimmunity. © 2010 Wiley‐Liss, Inc.     

Expression of heat shock genes (hsp70) in the rabbit spinal cord: localization of constitutive and hyperthermia-inducible mRNA species.

We have previously reported that hyperthermia induces the expression of a heat shock gene in the rabbit brain (Sprang and Brown, Mol Brain Res 3:89-93, 1987). Striking regional and cell type differences in the pattern of induction of the hsp70 mRNA were noted. Tissue injury also induces the rapid induction of hsp70 mRNA in the mammalian brain (Brown et al., Neuron 2:1559-1564, 1989). In the present study, in situ hybridization with 35S-labelled riboprobes specific for constitutive and inducible hsp70 mRNA species was employed to investigate the effect of fever-like temperatures on hsp70 gene expression in the rabbit spinal cord. Expression of constitutive hsp70 mRNA was detected in large motor neurons of both control and hyperthermic animals. Within 1 hr after hyperthermia, a massive induction of inducible hsp70 mRNA was noted in fibre tracts of the spinal cord, a pattern consistent with a strong glial response to heat shock. Induction was not observed in the large motor neurons.     

In vitro studies show that Hsp70 can be released by glia and that exogenous Hsp70 can enhance neuronal stress tolerance

Glial cells release a variety of molecules that support neuronal function. Because heat shock proteins (Hsps) are important in the survival of neurons subjected to metabolic stress, the possibility that glia can release the inducible form of the 70 kDa Hsp (Hsp70) was examined. Additionally, the ability of neuronal cells to show increased stress tolerance by taking up a mixture of constitutive and inducible forms of Hsp70 (Hsc/Hsp70) added to the extracellular fluid was tested. Human T98G glioma cells and differentiated LA-N-5 neuroblastoma cells were used as model glia and neurons to investigate these points. Hsp70 was analyzed using affinity chromatography, Western blotting, and immunofluorescence microscopy. The glioma cells were shown to export Hsp70 into the culture medium whether under normal conditions or subjected to heat shock. The amount of glial Hsp70 released ranged from 5 to 15 pg per 10⁶ cells per day, being greater following heat shock. Neuroblastoma cells took up biotinylated Hsc/Hsp70 within 1 h after it was added to the culture medium and it made them more resistant to heat shock (44°C) and to staurosporine-induced apoptosis. This increased stress tolerance was especially important in neuroblastoma cells induced to differentiate with phorbol ester because those ‘mature neurons’ showed a 10-fold decline in endogenous Hsp70, which was accompanied by increased susceptibility to heat shock and staurosporine-induced apoptosis. These results suggest that extracellular Hsp70 may provide a means by which glia can affect neuronal function, perhaps enhancing neuronal stress tolerance.     

Induction of heat shock (stress) genes in the mammalian brain by hyperthermia and other traumatic events: a current perspective

Is the heat shock response physiologically relevant? For example, following hyperthermia or ischemia, what neural cell types show induction of heat shock genes and what is the time course of the effect? Initial experiments in this area demonstrated the prominent Induction of a 70 kDa heat shock protein (hsp70) when labeled brain proteins isolated from hyperthermic animals were analyzed. Recently, in situ hybridization and immunocytochemistry have been utilized to map out the pattern of expression of both constitutively expressed and stress-inducible members of the hsp70 multigene family. Different types of neural trauma have been found to induce characteristic cellular responses in the mammalian brain with regard to the type of brain cell that responds by inducing hsp70 and the timing of the induction response. Fever-like temperature causes a dramatic induction of hsp70 mRNA within 1 hr in fiber tracts of the fore-brain and cerebellum, a pattern consistent with a strong glial response to heat shock. Tissue injury, namely, a small surgical cut in the cerebral cortex, induces a rapid and highly localized induction of hsp70 mRNA in cells proximal to the injury site. Using an immunocytochemical approach, a neuronal pattern of induction of hsp70 has been demonstrated following ischemia or kainic acid–induced seizures. It is apparent that the pattern of induction of hsp70 may be a useful early marker of cellular injury and may identify previously unrecognized areas of vulnerability in the nervous system.     

Marked alteration of c-fos and c-jun but not hsp70 messenger RNA expression in rat brain after cold-induced trauma: An in situ hybridization study

Immediate early gene (IEG) mRNA induction by cryogenic injury was examined using an in situ hybridization approach and the results compared with the heat shock protein mRNA expression. Hybridization signals for c-fos and c-jun mRNA were found after 30 min in the ipsilateral cortex, the hippocampal dentate granule cells and the piriform cortex, c-jun mRNA was also detected in the contralateral dentate gyrus and the piriform cortex, but was less extensive. Return to baseline values was observed at the 24 h time point. Peak induction, with silver grains observed mainly over the neurons on emulsion autoradiograms, was demonstrated in all cases 30 min to 1 h post-injury. In contrast, only slight hsp70 mRNA expression by the neurons surrounding the cold-injured site could be detected by microautoradiography, at 6 h following the trauma. The results indicate that cryogenic brain injury induces IEGs in a similar way to mechanical modes of injury such as lateral fluid percussion, but that hsp70 mRNA is hardly expressed, implying the possible existence of differences in stress response pathways.     

Localization of 70-kDa stress protein induction in gerbil brain after ischemia

Summary Induction of the 70-kDa heat shock protein, hsp70, has been demonstrated in brain following experimental stroke. In the present study, hsp70 was localized in gerbil brain at intervals after transient ischemia using a monoclonal antibody specific for stress-inducible forms of hsp70-related proteins. Induced immunoreactivity was found only in neurons, primarily in hippocampus, striatum, entorhinal cortex and some neocortical regions. Notably hsp70 accumulation was minimal in hippocampal CA1 neurons which die after brief ischemic episodes, but was most pronounced in dentate granule cells and CA3 neurons which are spared. The peak of CA3 immunoreactivity occurred at 48-h recirculation, at the onset of CA1 neuron loss at 2–4 days, demonstrating that hsp70 induction is also a component of this delayed hippocampal pathophysiology rather than a direct response to the metabolic disruption of the initial ischemic episode. These results suggest that hsp70 immunocytochemistry may serve as a marker for neuronal circuitry involved in proposed excitotoxic mechanisms after ischemia and other stresses. Control animals showed immunoreactivity in ependymal cells lining the ventricles, indicating a role for hsp70 in normal functioning of these specialized cells.     

Differential expression and induction of small heat shock proteins in rat brain and cultured hippocampal neurons

The so-called stress response involving up-regulation of heat shock proteins (Hsps) is a powerful mechanism of cells to deal with harmful conditions to which they are exposed throughout life, such as hyperthermia, hypoxia, or oxidative stress. Some members of the group of small Hsps (sHsps) seem to play a neuroprotective role in the brain. Here we analyzed the expression of all 11 sHsps in the rat brain by using RNA in situ hybridization and quantitative real-time RT-PCR. Additionally, we investigated sHsps in cultured neurons exposed to heat shock. We found seven sHsps to be expressed in the rat brain, with HspB5 (αB-crystallin), HspB6 (Hsp20), and HspB11 (Hsp16.2) showing the highest expression levels (4-24% of reference genes) followed by HspB1 (Hsp25) and HspB8 (Hsp22; 0.1-2% of reference genes), all being widely expressed in the brain areas investigated. HspB2 (MKBP) and HspB3, however, showed selective expression in only some regions (B2: cortex and hippocampus, B3: cortex and cerebellum). Whereas HspB5 was expressed mainly in the white matter, HspB6 showed the greatest expression in the cerebellar cortex, and HspB11 was widely distributed over the whole brain. In cultured hippocampal neurons, heat shock led to an increase of HspB1 and HspB8 mRNA and additionally HspB5 protein. Our data indicate that the sHsps induced by heat shock, HspB1, B5, and B8, might be especially involved in neuroprotection under stress conditions. The other sHsps showing constant neuronal expression may play a constitutive role or may be up-regulated and important in types of stresses other than heat shock.