Role of hsp105 in protection against stress-induced apoptosis in neuronal PC12 cells.

hsp105alpha is a stress protein characteristically highly expressed in the brain compared with other tissues in mammals. Here, to examine whether hsp105alpha plays a pivotal role in the nervous system, we tested the capability of hsp105alpha to protect against apoptosis in rat neuronal PC12 cells. Various stress treatments such as serum deprivation, heat shock, hydrogen peroxide, etoposide, and actinomycin D induced apoptosis in PC12 cells with characteristic shrinking of nuclei and chromatin. However, PC12 cells that constitutively overexpressed mouse hsp105alpha exhibited a strong protective effect against apoptosis induced by these stress treatments. Cleavage of poly(ADP-ribose) polymerase induced in PC12 cells by these treatments was inhibited in the constitutively overexpressed hsp105alpha cells. Furthermore, c-Jun N-terminal kinase (JNK) was activated in the cells treated with heat shock but not other treatments, and the heat-induced JNK activation was inhibited by the constitutive expression of hsp105alpha.Thus, hsp105alpha prevents not only heat-induced apoptosis by inhibiting JNK activation, but also prevents the apoptosis induced by other stressors through different pathways, and may play important roles in neuronal protection.     

Dissociation of 68,000 Mr heat shock protein synthesis from thermotolerance expression in rat fibroblasts

Rat embryonic fibroblasts growing exponentially at either 35, 37, or 39 degrees C were exposed to 42 degrees C for times up to 6 hr. Cell survival was unaffected by this heat shock in cultures growing at 39 degrees C but survival was decreased in a temperature dependent manner in cells growing at 37 or 35 degrees C. Exposure to 42 degrees C of cells previously adapted to 35 or 37 degrees C resulted in the induction of heat shock proteins (hsps) with apparent molecular weights of 68,000 (hsp 68), 70,000 (hsp 70), and 89,000 (hsp 89); cells previously adapted to 39 degrees C expressed all hsps except hsp 68. Inasmuch as the synthesis of certain hsps may function to protect cells from thermal damage, these data indicate that hsp 68 may not be required for this adaptation-related thermotolerant survival response. Hsp 68 may only be expressed in cells destined to die.     

The chaperone function of hsp70 is required for protection against stress-induced apoptosis

Cellular stress can trigger a process of self-destruction known as apoptosis. Cells can also respond to stress by adaptive changes that increase their ability to tolerate normally lethal conditions. Expression of the major heat-inducible protein hsp70 protects cells from heat-induced apoptosis. hsp70 has been reported to act in some situations upstream or downstream of caspase activation, and its protective effects have been said to be either dependent on or independent of its ability to inhibit JNK activation. Purified hsp70 has been shown to block procaspase processing in vitro but is unable to inhibit the activity of active caspase 3. Since some aspects of hsp70 function can occur in the absence of its chaperone activity, we examined whether hsp70 lacking its ATPase domain or the C-terminal EEVD sequence that is essential for peptide binding was required for the prevention of apoptosis. We generated stable cell lines with tetracycline-regulated expression of hsp70, hsc70, and chaperone-defective hsp70 mutants lacking the ATPase domain or the C-terminal EEVD sequence or containing AAAA in place of EEVD. Overexpression of hsp70 or hsc70 protected cells from heat shock-induced cell death by preventing the processing of procaspases 9 and 3. This required the chaperone function of hsp70 since hsp70 mutant proteins did not prevent procaspase processing or provide protection from apoptosis. JNK activation was inhibited by both hsp70 and hsc70 and by each of the hsp70 domain mutant proteins. The chaperoning activity of hsp70 is therefore not required for inhibition of JNK activation, and JNK inhibition was not sufficient for the prevention of apoptosis. Release of cytochrome c from mitochondria was inhibited in cells expressing full-length hsp70 but not in cells expressing the protein with ATPase deleted. Together with the recently identified ability of hsp70 to inhibit cytochrome c-mediated procaspase 9 processing in vitro, these data demonstrate that hsp70 can affect the apoptotic pathway at the levels of both cytochrome c release and initiator caspase activation and that the chaperone function of hsp70 is required for these effects.     

hsp70: Nuclear concentration during environmental stress and cytoplasmic storage during recovery

The intracellular distribution of the major Drosophila heat-shock protein hsp70 was determined by indirect immunofluorescence with monoclonal antibodies. During heat shock the protein concentrates strongly in nuclei while a small quantity remains cytoplasmic. During recovery hsp70 leaves the nuclei and becomes distributed throughout the cytoplasm. With a second heat shock it is rapidly transported back into the nucleus. Nuclear translocation depends not on the temperature per se, but on the physiological state of the cell since it also occurs after exposure to an anoxic atmosphere at normal temperatures. We also provide evidence that hsps protect cells from the toxic effects of anoxia, as well as heat, and conclude that nuclear translocation of hsp70 is related to its function in protecting the organism from both forms of environmental stress.     

DNA sequence variation and latitudinal associations in hsp23, hsp26 and hsp27 from natural populations of Drosophila melanogaster

Heat shock genes are considered to be likely candidate genes for environmental stress resistance. Nucleotide variation in the coding sequence of the small heat shock genes (hsps) hsp26 and hsp27 from Drosophila melanogaster was studied in flies originating from the Netherlands and eastern Australia. The hsp26 gene was polymorphic for an insertion/deletion of three extra amino acids and two nonsynonymous changes in all populations. The hsp27 gene exhibited two nonsynonymous changes and three synonymous mutations. The hsp26 polymorphism showed a latitudinal cline along the east coast of Australia. This pattern was not confounded by the fact that the shsps are located in the inversion In(3 L)P which also shows a latitudinal cline in eastern Australia. A similar latitudinal cline was found for the previously described variation in hsp23, while frequencies of hsp27 alleles did not change with latitude. These findings suggest that variation at two of the shsps or closely linked loci are under selection in natural populations of D. melanogaster.     

hsp70-DnaJ chaperone pairs prevent nitric oxide-mediated apoptosis in RAW 264.7 macrophages

Excess nitric oxide (NO) induces apoptosis in some cell types, including macrophages. Heat shock protein of 70 kDa (hsp70) has been reported to protect cells from various stresses, including apoptosis-inducing stimuli. Several mammalian cytosolic DnaJ homologs, partner chaperones of hsp70 family members, have been identified. We asked if a DnaJ homolog is required to prevent NO-mediated apoptosis. When mouse macrophage-like RAW 264.7 cells were treated with an NO donor, SNAP, apoptosis occurred. This apoptosis could be prevented by pretreatment of the cells with heat or a low dose of SNAP. Under these conditions, levels of hsc70 (an hsp70 member) remained unchanged, whereas hsp70 was markedly induced. Of the DnaJ homologs dj1 (hsp40/hdj-1) was strongly induced and dj2 (HSDJ/hdj-2) was moderately induced. In transfection experiments, hsp70, hsc70, dj1 or dj2 alone was ineffective in preventing NO-mediated apoptosis. In contrast, both dj1 and dj2, in combination with hsc70 or hsp70, prevented the cells from apoptosis. The hsp70-DnaJ chaperone pairs exerted their anti-apoptotic effects upstream of caspase 3 activation, and apparently upstream of cytochrome c release from mitochondria.     

Antioxidant-mediated inhibition of the heat shock response leads to apoptosis

We examined the hypothesis that reactive oxygen species (ROS) contribute to the induction of heat shock proteins (hsps) during stress response. Exposure of HL-60 human myelocytic cells to 42 degrees C induced both hsp72 and hsp27. In the presence of the antioxidant molecules pyrrolidine dithiocarbamate or 1,10-phenanthroline induction of hsp72 and 27 was significantly decreased, while N-acetyl-L-cysteine caused a slight reduction. Prevention of hsp induction was associated with heat sensitization and increased caspase activity, indicating that the cells were undergoing apoptosis. These data suggest that ROS contribute to the induction of hsps and furthermore, that hsp induction and apoptosis are mutually exclusive events within the same cell.     

Accumulation of major stress protein 70kDa protects myeloid and lymphoid cells from death by apoptosis

The major heat shock protein, hsp70, is known to contribute to the mechanisms of cell protection against a variety of stress and cytotoxic factors, providing an increase of cell survival. Whether hsp70 could be implicated in the rescue of cells from stress-induced death proceeding on apoptotic pathway is not well established. Here we report that susceptibility of myeloid and lymphoid cell lines to apoptosis induced by heat shock or ethanol coincides with hsp70 content and can be modulated by changes in expression of this protein. Cells of lymphoid and myeloid lines differing in basal and inducible level of the protein were tested. The cells containing higher amounts of hsp70 (U937, Jurkat, Molt4) were more resistant to the apoptosis-inducing stimuli then cells which accumu-late lower amounts of the protein (HL60) and especially those lacking the protein (NSO). Inhibition of hsp70 accumulation by quercetin made cells more susceptible to the same apoptotic inducer. Enhancement of hsp70 expression by previous heating or by liposomal delivery of the exogenic protein to the cells lacking hsp70 made them more resistant to apoptosis. The possible mechanisms of the hsp70 protective effect in apoptosis are discussed.     

Phosphorylation-dependent structural alterations in the small hsp30 chaperone are associated with cellular recovery

Small heat shock proteins (hsps) act as molecular chaperones by preventing the thermal aggregation and unfolding of cellular protein; however, the manner by which cells regulate chaperone activity remains unclear. In the present study, we examined the role of phosphorylation on the chaperone function of the Xenopus small hsp30. Both heat stress and sodium arsenite treatment in A6 cells resulted in a rapid activation of p38alpha and MAPKAPK-2. Surprisingly, the association of MAPKAPK-2 with hsp30 and its subsequent phosphorylation were more prevalent during recovery after heat stress. Treatment of A6 cells with SB203580, an inhibitor of the p38 MAP kinase pathway, resulted in a loss of hsp30 phosphorylation. Phosphorylation resulted in the formation of smaller multimeric hsp30 complexes and resulted in a significant loss of secondary structure. Consequently the phosphorylation-induced structural changes severely compromised the ability of hsp30 to prevent the heat-induced aggregation of citrate synthase and luciferase in vitro. We confirmed that the loss of chaperone activity was coincident with an attenuated binding of phosphorylated hsp30 with target proteins. Our data suggest that phosphorylation may be necessary to regulate the post-heat stress molecular chaperone activity of hsp30.     

Immunolocalization of stress proteins and extracellular matrix proteins in the rat tibia

Stress proteins (heat shock proteins [hsps]) serve a number of protective functions, including protection from apoptosis and acting as chaperones during protein biosynthesis. For example, hsp 27 has been defined as a chaperone for the G3 domain of aggrecan, while hsp 47 is the chaperone for type I collagen. Separate cytoprotective roles for hsp 27 and hsp 70 have been demonstrated. The aim of this study was to define the expression of hsps in osteoblastic and chondrocytic cells of the growing rat long bone in relationship to the immunohistochemical localization of aggrecan, type I collagen and the presence of fragmented DNA that defines apoptotic events. Tibiae were harvested from Fisher 344 rats (n=6) and fixed in 10% buffered formalin. Samples were decalcified in 10% EDTA, bisected, and processed for histologic examination. Sections (5 mm) were immunohistochemically stained using a streptavidin-biotin detection method. Co-localization of hsps with apoptosis was achieved using the TUNEL procedure. In the rat tibia growth plate, aggrecan was generally distributed throughout cartilage and chondrocytes. However, hsp 27 expression was observed only in the lower hypertrophic chondrocytes. hsp27 was present in osteoblasts lining newly formed bone. hsp 47 staining was also prominent within these osteoblasts where collagen type I immunolocalization occurred. The inducible form of hsp 70 was localized to the osteoblastic cells lining new bone in the primary spongiosa. In cartilage, DNA fragmentation was restricted to the hypertrophic, hsp27-positive, chondrocytes. In contrast, DNA fragmentation was not co-localized with hsp27-positive osteoblastic cells of the primary spongiosa, although occasional apoptotic cells were identified. These results indicate that apoptosis is a mechanism by which hypertrophic chondrocytes are eliminated from cartilage prior to calcification, but that other mechanisms are also likely to be involved. They also suggest that hsps have cytoprotective and biosynthetic functions within osteoblasts and chondrocytes, but apoptotic signals may override these effects in some instances, resulting in apoptosis.     

THE FUNCTION OF HEAT-SHOCK PROTEINS IN STRESS TOLERANCE

We earlier demonstrated that hsp68 is deficiently induced upon stress in the glucocorticoid-resistant, dedifferentiated Reuber rat hepatoma clone 2 cells, but is strongly activated in the differentiated, glucocorticoid-sensitive Faza 967 cells from which clone 2 was derived. We used the two cell types to address the questions whether hsp68 is specifically involved in the development of thermotolerance and/or thermoresistance or drug resistance. Our experiments show that clone 2 cells were not protected from the killing effect of heat by pretreatment with sodium arsenite, whereas Faza 967 cells were. These results strongly suggest a role of hsp68 in the development of thermotolerance in hepatoma cells. Stable heat-resistant variants of clone 2 cells were also isolated, where an increased basal expression of several hsps was observed together with the (at least partial) restoration of the heat-inducibility of hsp68. These results suggest that several hsps are needed to protect the critical biological processes at high temperature. The heat-resistant hepatoma cells also became resistant to several anticancer drugs. The multidrug resistance of the hepatoma variants correlates with the overexpression of the plasma membrane P-glycoprotein. Our results showing that severely stressed hepatoma cells overexpressed the mdr gene(s) raise the possibility that the P-gp may participate in protection against environmental stress such as heat.     

Primary tumor tissue lysates are enriched in heat shock proteins and induce the maturation of human dendritic cells.

Upon exposure to lysates or supernatants of necrotic transformed cell lines, human dendritic cells (DCs) undergo maturation. In contrast, DCs exposed to apoptotic transformed cell lines or necrotic lysates of primary cells remain immature. Analysis of supernatants of necrotic transformed cell lines showed them to be enriched in the heat shock proteins (hsp)70 and gp96, in contrast to supernatants of primary cells. Likewise, cells from a variety of primary human tumors contained considerably higher levels of hsp than their normal autologous tissue counterparts. Of the majority of human tumors enriched in hsps (hsp70 and/or gp96), their corresponding lysates matured DCs. The maturation effect of tumor cell lysates was abrogated by treatment with boiling, proteinase K, and geldanamycin, an inhibitor of hsps, suggesting that hsps rather than endotoxin or DNA were the responsible factors. Supporting this idea, highly purified, endotoxin-depleted hsp70, induced DC maturation similar to that seen with standard maturation stimuli LPS and monocyte conditioned medium. These results suggest that the maturation activity inherent within tumor cells and lines is mediated at least in part by hsps. The release of hsps in vivo as a result of cell injury should promote immunity through the maturation of resident DCs.     

Bacterial GroEL-like heat shock protein 60 protects epithelial cells from stress-induced death through activation of ERK and inhibition of caspase 3

Bacterial heat shock proteins (hsps) can have various effects on human cells. We investigated whether bacterial hsp60s can protect epithelial cells from cell death by affecting the mitogen-activated protein kinase (MAPK) signal pathways. Cell protection was studied by adding bacterial hsp60s to skin keratinocyte cultures (HaCaT cell line) before UV radiation. The results show that hsp60 significantly protected against UV radiation-induced cell death. Effects of UV radiation and exogenous hsp60 on phosphorylation of MAPKs and on activation of caspase 3 were examined by Western blot analysis. UV radiation strongly induced phosphorylation of p38 MAPK and formation of active caspase 3. A p38 inhibitor, SB 203580, totally blocked UV radiation-mediated activation of caspase 3. Preincubation with hsp60 strongly induced phosphorylation of ERK1/2 and inhibited UV radiation-mediated activation of caspase 3. PD 98059, a specific inhibitor of the ERK1/2 pathway, blocked this inhibitory effect of exogenous hsp60. Studies on the association between activity of MAPKs or caspase 3 and cell death showed that the ERK1/2 pathway inhibitor reversed protective effect of hsp60 while specific inhibition of p38 and caspase 3 reduced cell death. These results indicate that in HaCaT cells UV radiation mediates cell death through activation of p38 followed by caspase 3 activation. Exogenous hsp60 partially protects against UV radiation-mediated epithelial cell death through activation of ERK1/2, which inhibits caspase 3 activation.     

Distinct hsp70 domains mediate apoptosis-inducing factor release and nuclear accumulation

Although hsp70 antagonizes apoptosis-inducing factor (AIF)-mediated cell death, the relative importance of preventing its release from mitochondria versus sequestering leaked AIF in the cytosol remains controversial. To dissect these two protective mechanisms, hsp70 deletion mutants lacking either the chaperone function (hsp70-deltaEEVD) or ATPase function (hsp70-deltaATPase) were selectively overexpressed before exposing cells to a metabolic inhibitor, an insult sufficient to cause mitochondrial AIF release, nuclear AIF accumulation, and apoptosis. Compared with empty vector, overexpression of wild type human hsp70 inhibited bax activation and reduced mitochondrial AIF release after injury. In contrast, mutants lacking either the chaperone function (hsp70-deltaEEVD) or the ATP hydrolytic domain (hsp70-deltaATPase) failed to prevent mitochondrial AIF release. Although hsp70-deltaEEVD did not inhibit bax activation or mitochondrial membrane injury after cell stress, this hsp70 mutant co-immunoprecipitated with leaked AIF in injured cells and decreased nuclear AIF accumulation. In contrast, hsp70-deltaATPase did not interact with AIF either in intact cells or in a cell-free system and furthermore, failed to prevent nuclear AIF accumulation. These results demonstrate that mitochondrial protection against bax-mediated injury requires both intact chaperone and ATPase functions, whereas the ATPase domain is critical for sequestering AIF in the cytosol.     

Activation of Fas inhibits heat-induced activation of HSF1 and up-regulation of hsp70.

Activation of heat shock factor (HSF) 1-DNA binding and inducible heat shock protein (hsp) 70 (also called hsp72) expression enables cells to resist various forms of stress and survive. Fas, a membrane-bound protein, is a central proapoptotic factor; its activation leads to a cascade of events, resulting in programmed cell death. These two mechanisms with contradictory functions, promoting either cell survival or death, were examined for their potential to inhibit each other's activation. Induction of FAS-mediated signaling was followed by a rapid decrease in HSF1-DNA binding and inducible hsp70 expression. Inhibition of HSF1-DNA binding was demonstrated to be based on absent hyperphosphorylation of HSF1 during FAS signaling. These effects of FAS activation on the HSF1/hsp70 stress response were blocked by ICE (caspase 1) inhibitors, suggesting an ICE-mediated process. Furthermore, inhibition of HSF1/hsp70 was accompanied by an increase in apoptosis rates from 20% to 50% in response to heat stress. When analyzing the effects of HSF1/hsp70 activation on Fas-mediated apoptosis, protection from apoptosis was seen in cells with induced hsp70 protein levels, but not in cells that were just induced for HSF1-DNA binding. Thus, we conclude that inhibition of HSF1/hsp70 stress response during Fas-mediated apoptosis and vice versa may facilitate a cell to pass a previously chosen pathway, stress resistance or apoptosis, without the influence of inhibitory signals.