Reduced thermotolerance in aged cells results from a loss of an hsp72- mediated control of JNK signaling pathway

Aged organisms exhibit a greatly decreased ability to induce the major heat shock protein, Hsp72, in response to stresses, a phenomenon that can also be observed in cell cultures (Heydari AR, Takahashi R, Gutsmann A, You S and Richardson A (1994) Hsp70 and aging. Experientia 50: 1092–1098). Hsp72 was shown to protect cells from a variety of stresses. The protective function of Hsp72 has been commonly ascribed to its chaperoning ability. However, recently we showed that Hsp72 protects cells from heat shock by suppression of a stress-kinase JNK, an essential component of the heat-induced apoptotic pathway (Gabai VL, Meriin AB, Mosser DD, Caron AW, Rits S, Shifrin VI and Sherman MY (1997) Hsp70 prevents activation of stress kinases. A novel pathway of cellular thermotolerance. J Biol Chem 272: 18033–18037). Here we demonstrate that because of the diminished inducibility of Hsp72 in aged cells, Hsp72-mediated control of JNK signaling pathway is compromised. This results in increased rate of apoptotic cell death following heat shock. We show that forced expression of Hsp72 in aged cells from an adenovirus-based vector completely suppresses activation of JNK by heat shock and consequently protects from heat-induced apoptosis. We also demonstrate for the first time that it is possible to restore endogenous expression of Hsp72 in aged cells. This can be achieved by treatment with the proteasome inhibitor MG132. Induction of Hsp72 in aged cells under these conditions leads to suppression of JNK activation by a heat shock and restoration of thermotolerance manifested in a lower rate of apoptosis.     

Suppression of stress kinase JNK is involved in HSP72-mediated protection of myogenic cells from transient energy deprivation. HSP72 alleviates the stewss-induced inhibition of JNK dephosphorylation

Since protection of cells from stress-induced apoptosis by the heat shock protein Hsp72 involves suppression of stress kinase JNK, we suggested that Hsp72-mediated JNK inhibition might also be critical for myocardial protection from ischemia/reperfusion. Transient energy deprivation of H9c2 myogenic cells, used as an in vitro model of myocardial ischemia, led to cell death that had morphological features of apoptosis and necrosis and was independent of caspases. Surprisingly, this unusual type of cell death was regulated by JNK and ERK kinases. In fact, specific inhibition of JNK increased cell survival; specific inhibition of ERKs enhanced deleterious consequences of energy deprivation, whereas inhibition of p38 kinase had no effect. Hsp72 suppressed activation of JNK and did not increase ERK activity, suggesting that inhibition of JNK is the important component of Hsp72-mediated protection. Upon transient energy deprivation, activation of JNK proceeds via two distinct pathways, stimulation of JNK phosphorylation by a protein kinase SEK1 and inhibition of JNK dephosphorylation. Remarkably, in cells exposed to transient energy deprivation, Hsp72 enhanced the rate of JNK dephosphorylation but did not affect SEK1 activity. Therefore, it appears that Hsp72 specifically down-regulates JNK by accelerating its dephosphorylation, which reduces the susceptibility of cardiac cells to simulated ischemia/reperfusion.     

Inactivation of dual-specificity phosphatases is involved in the regulation of extracellular signal-regulated kinases by heat shock and hsp72

Extracellular signal-regulated kinase 1 (ERK1) and ERK2 (ERK1/2) dramatically enhance survival of cells exposed to heat shock. Using Cos-7 cells and primary human fibroblasts (IMR90 cells), we demonstrated that heat shock activates ERKs via two distinct mechanisms: stimulation of the ERK-activating kinases, MEK1/2, and inhibition of ERK dephosphorylation. Under milder heat shock conditions, activation of ERKs proceeded mainly through stimulation of MEK1/2, whereas under more severe heat shock MEK1/2 could no longer be activated and the inhibition of ERK phosphatases became critical. In Cos-7 cells, nontoxic heat shock caused rapid inactivation of the major ERK phosphatase, MKP-3, by promoting its aggregation, so that in cells exposed to 45 degrees C for 20 min, 90% of MKP-3 became insoluble. MKP-3 aggregation was reversible and, 1 h after heat shock, MKP-3 partially resolubilized. The redistribution of MKP-3 correlated with an increased rate of ERK dephosphorylation. Similar heat-induced aggregation, followed by partial resolubilization, was found with a distinct dual-specificity phosphatase MKP-1 but not with MKP-2. Therefore, MKP-3 and MKP-1 appeared to be critical heat-labile phosphatases involved in the activation of ERKs by heat shock. Expression of the major heat shock protein Hsp72 inhibited activation of MEK1/2 and prevented inactivation of MKP-3 and MKP-1. Hsp72DeltaEEVD mutant lacking a chaperone activity was unable to protect MKP-3 from heat inactivation but interfered with MEK1/2 activation similar to normal Hsp72. Hence, Hsp72 suppressed ERK activation by both protecting dual-specificity phosphatases, which was dependent on the chaperone activity, and suppressing MEK1/2, which was independent of the chaperone activity.     

Hsp27 protects mitochondria of thermotolerant cells against apoptotic stimuli

Enhanced cell survival and resistance to apoptosis during thermotolerance correlates with an increased expression of heat shock proteins (Hsps). Here we present additional evidence in support of the hypothesis that the induction of Hsp27 and Hsp72 during acquired thermotolerance in Jurkat T-lymphocytes prevents apoptosis. In thermotolerant cells, Hsp27 was shown to associate with the mitochondrial fraction, and inhibition of Hsp27 induction during thermotolerance in cells transfected with hsp27 antisense potentiated mitochondrial cytochrome c release after exposure to various apoptotic stimuli, despite the presence of elevated levels of Hsp72. Caspase activation and apoptosis were inhibited under these conditions. In vitro studies revealed that recombinant Hsp72 more efficiently blocked cytochrome c-mediated caspase activation than did recombinant Hsp27. A model is presented for the inhibition of apoptosis during thermotolerance in which Hsp27 preferentially blocks mitochondrial cytochrome c release, whereas Hsp72 interferes with apoptosomal caspase activation.     

Heat shock triggers MAPK activation and MKP-1 induction in Leydig testicular cells

Testicular function is highly dependent on temperature control. In Leydig testicular cells, the signaling pathway activated by heat stress is poorly defined. Here we describe the molecular events triggered by heat shock (HS, 10 min, 45 degrees C) in MA-10 cells. HS produced a rapid and transient activation of ERK1/2 and JNK kinases, and also increased MAP kinase phosphatase-1 (MKP-1) protein and mRNA levels. The effect of HS on MKP-1 messenger reached significance at 15 min, peaked (3.5-fold) at 60 min, and was partially dependent on ERK1/2 activity. The temporal profiles of MKP-1 protein levels and MAPKs phospho-dephosphorylation suggest that MKP-1 induction could contribute to ERK1/2 and JNK inactivation after HS. In summary, this study indicates that the response to heat stress in Leydig cells includes the activation of MAPKs related to cell survival (ERK1/2) and death (JNK), and the induction of a MAPK activity inhibitory loop.     

Induction of heat shock proteins (HSPs) by sodium arsenite in cultured astrocytes and reduction of hydrogen peroxide-induced cell death

Induction of heat shock proteins (HSPs) protects cells from oxidative injury. Here Hsp72, Hsp27 and heme oxygenase-1 (HO-1) were induced in cultured rat astrocytes, and protection against oxidative stress was investigated. Astrocytes were treated with sodium arsenite (20-50 micro m) for 1 h, which was non-toxic to cells, 24 h later they were exposed to 400 micro m H2O2 for 1 h, and cell death was evaluated at different time points. Arsenite triggered strong induction of HSPs, which was prevented by 1 micro g/mL cycloheximide (CXH). H2O2 caused cell loss and increased cell death with features of apoptosis, i.e. TdT-mediated dUTP nick-end labelling (TUNEL) reaction and caspase-3 activation. These features were abrogated by pre-treatment with arsenite, which prevented cell loss and significantly reduced the number of dead cells. The protective effect of arsenite was not detected in the presence of CHX. Pre-treatment with arsenite increased protein kinase B (Akt) and extracellular signal regulated kinase 1/2 (ERK1/2) phosphorylation after H2O2. However, while Akt phosphorylation was prevented by CHX, Erk1/2 phosphorylation was further enhanced by CHX. The results show that transient arsenite pre-treatment induces Hsp72, HO-1 and, to a lesser extent, Hsp27; it reduces H2O2-induced astrocyte death; and it causes selective activation of Akt following H2O2. It is suggested that HSP expression at the time of H2O2 exposure protects astrocytes from oxidative injury and apoptotic cell death by means of pro-survival Akt.     

Hsp72 functions as a natural inhibitory protein of c-Jun N-terminal kinase

Hsp72, a major inducible member of the heat shock protein family, can protect cells against many cellular stresses including heat shock. In our present study, we observed that pretreatment of NIH 3T3 cells with mild heat shock (43 degrees C for 20 min) suppressed UV-stimulated c-Jun N-terminal kinase 1 (JNK1) activity. Constitutively overexpressed Hsp72 also inhibited JNK1 activation in NIH 3T3 cells, whereas it did not affect either SEK1 or MEKK1 activity. Both in vitro binding and kinase studies indicated that Hsp72 bound to JNK1 and that the peptide binding domain of Hsp72 was important to the binding and inhibition of JNK1. In vivo binding between endogenous Hsp72 and JNK1 in NIH 3T3 cells was confirmed by co-immunoprecipitation. Hsp72 also inhibited JNK-dependent apoptosis. Hsp72 antisense oligonucleotides blocked Hsp72 production in NIH 3T3 cells in response to mild heat shock and concomitantly abolished the suppressive effect of mild heat shock on UV-induced JNK activation and apoptosis. Collectively, our data suggest strongly that Hsp72 can modulate stress-activated signaling by directly inhibiting JNK.     

Stress-mediated signaling in PC12 cells - the role of the small heat shock protein,Hsp27, and Akt in protecting cells from heat stress and nerve growth factor withdrawal

We have investigated the role of stress-activated signaling pathways and the small heat shock protein, Hsp27, in protecting PC12 cells from heat shock and nerve growth factor (NGF) withdrawal-induced apoptosis. PC12 cells and a stable cell line overexpressing Hsp27 (HSPC cells) were subjected to heat shock. This resulted in the rapid activation of Akt followed by p38 mitogen-activated protein kinase (MAPK) signaling, with phosphorylation and intracellular translocation of Hsp27 also detectable. Hsp27 was found to form an immunoprecipitable complex with Akt and p38 MAPK in both non-stimulated and heat shocked cells, although after heat shock there was a gradual dissociation of Akt and p38 from the Hsp27. Cells were differentiated with NGF and then subjected to NGF withdrawal, a treatment which results in substantial cell death over 24-72 h. Hsp27 was shown to be protective against this treatment, since HSPC cells which overexpress Hsp27 showed significantly less cell death than the parental PC12 cells. In addition, we observed that phosphorylation of Akt was maintained in HSPC cells subjected to heat shock and NGF withdrawal compared with the parental cells. Taken together, our results suggest that Hsp27 may protect Akt from dephosphorylation and may also act in stabilizing Akt.     

HSP72 can protect cells from heat-induced apoptosis by accelerating the inactivation of stress kinase JNK

The major heat shock protein Hsp72 prevents heat-induced apoptosis. We have previously demonstrated that transiently expressed Hsp72 exerts its anti-apoptotic effect by suppressing the activity of stress-kinase JNK, an early component of the apoptotic pathway initiated by heat shock. On the other hand, constitutive expression of Hsp72 does not lead to suppression of heat-induced JNK activation, yet still efficiently prevents apoptosis. To address this apparent contradiction, we studied the effects of constitutively expressed Hsp72 on activation of JNK and apoptosis in Rat-1 fibroblasts. We found that the level of heat-induced apoptosis directly correlated with the duration rather than the magnitude of JNK activity following heat shock. Constitutively expressed Hsp72 strongly reduced the duration of JNK while it did not suppress initial JNK activation. These effects were due to Hsp72-mediated acceleration of JNK dephosphorylation. Addition of vanadate to inhibit JNK phosphatase activity completely prevented the anti-apoptotic action of Hsp72. Therefore, suppression of heat-induced apoptosis by Hsp72 could be fully accounted for by its effects on JNK activity.     

Hsp72 and stress kinase c-jun N-terminal kinase regulate the bid-dependent pathway in tumor necrosis factor-induced apoptosis

The major inducible heat shock protein Hsp72 has been shown to protect cells from certain apoptotic stimuli. Here we investigated the mechanism of Hsp72-mediated protection from tumor necrosis factor (TNF)-induced apoptosis of primary culture of IMR90 human fibroblasts. Hsp72 temporarily blocked apoptosis in response to TNF and permanently protected cells from heat shock. An Hsp72 mutant (Hsp72 Delta EEVD) with a deletion of the four C-terminal amino acids, which are essential for the chaperone function, blocked TNF-induced apoptosis in a manner similar to that of normal Hsp72 but did not inhibit heat shock-induced death. Therefore, the chaperone activity of Hsp72 is dispensable for suppression of TNF-induced apoptosis but is required for protection from heat shock. In fibroblasts derived from Bid knockout mice, similar temporal inhibition of TNF-induced apoptosis was seen. In these cells neither normal Hsp72 nor Hsp72 Delta EEVD conferred additional protection from apoptosis, suggesting that Hsp72 specifically affects Bid-dependent but not Bid-independent apoptotic pathways. Furthermore, both normal Hsp72 and Delta Hsp72EEVD inhibited Bid activation and downstream events, including release of cytochrome c, activation of caspase 3, and cleavage of poly-ADP-ribose polymerase. Both Hsp72 and Delta Hsp72EEVD blocked activation of the stress kinase c-jun N-terminal kinase (JNK) by TNF, and specific inhibition of JNK similarly temporarily blocked Bid activation and the downstream apoptotic events. These data strongly suggest that in TNF-induced apoptosis, Hsp72 specifically interferes with the Bid-dependent apoptotic pathway via inhibition of JNK.     

Regulation of necrosis of H9c2 myogenic cells upon transient energy deprivation. Rapid deenergization of mitochondria precedes necrosis and is controlled by reactive oxygen species, stress kinase JNK, HSP72 and ARC

Subjecting myogenic H9c2 cells to transient energy deprivation leads to a caspase-independent death with typical features of necrosis. Here we show that the rupture of cytoplasmic membrane, the terminal event in necrosis, is shortly preceded by rapid depolarization of mitochondrial membranes. The rapid deenergization of mitochondria critically depended upon prior generation of reactive oxygen species (ROS) during ATP depletion stage. Accordingly, expression of catalase prevented mitochondrial depolarization and averted subsequent necrosis. Interestingly, trifluoperazine, a compound that protects cells from ischemic insults, prevented necrosis of H9c2 cells through inhibition of ROS production. Other factors that regulated the mitochondrial membrane depolarization and subsequent loss of plasma membrane integrity include a stress kinase JNK activated at early steps of recovery from ATP depletion, as well as an apoptotic inhibitory protein ARC. Accordingly, inhibition of JNK or overexpression of ARC prevented mitochondrial depolarization and rescued H9c2 cells from necrosis. ROS and JNK affected mitochondrial deenergization and necrosis independently of each other since inhibition of ROS production did not prevent activation of JNK, whereas inhibition of JNK did not suppress ROS accumulation. Therefore, JNK activation and ROS production represent two independent pathways that control mitochondrial depolarization and subsequent necrosis of cells subjected to transient energy deprivation. Overexpression of ARC, although preventing mitochondrial depolarization, did not affect either JNK activation or production of ROS. The major heat shock protein Hsp72 inhibited JNK-related steps of necrotic pathway but did not affect ROS accumulation. Interestingly, mitochondrial depolarization and subsequent necrosis can be suppressed by an Hsp72 mutant Hsp72DeltaEEVD, which lacks chaperone function but can efficiently suppress JNK activation. Thus, Hsp72 is directly implicated in a signaling pathway, which leads to necrotic death.     

Mechanism of Saccharomyces cerevisiae yeast cell death induced by heat shock. Effect of cycloheximide on thermotolerance

The mechanism of yeast cell death induced by heat shock was found to be dependent on the intensity of heat exposure. Moderate (45°C) heat shock strongly increased the generation of reactive oxygen species (ROS) and cell death. Pretreatment with cycloheximide (at 30°C) suppressed cell death, but produced no effect on ROS production. The protective effect was absent if cycloheximide was added immediately before heat exposure and the cells were incubated with the drug during the heat treatment and recovery period. The rate of ROS production and protective effect of cycloheximide on viability were significantly decreased in the case of severe (50°C) heat shock. Treatment with cycloheximide at 39°C inhibited the induction of Hsp104 synthesis and suppressed the development of induced thermotolerance to severe shock (50°C), but it had no effect on induced thermotolerance to moderate (45°C) heat shock. At the same time, Hsp104 effectively protected cells from death independently of the intensity of heat exposure. These data indicate that moderate heat shock induced programmed cell death in the yeast cells, and cycloheximide suppressed this process by inhibiting general synthesis of proteins.     

Stress protein flux during recovery from simulated ischemia: induced heat shock protein 70 confers cytoprotection by suppressing JNK activation and inhibiting apoptotic cell death

Multiple stress proteins are recruited in response to stress in living cells. There are limited reports in the literature analyzing multiple stress protein shifts and their functional consequences on stress response. Using two-dimensional electrophoresis we have analyzed shifts in stress protein profiles in response to energy deprivation as a model of ischemic injury to kidneys. A group of chaperones and stress-induced mitogen activated protein (MAP) kinases were analyzed. In addition to examining stress protein induction and phosphorylation we have also examined the mechanism of cytoprotection by heat shock protein 70 (Hsp70). Our results show that, of the different stress proteins examined, only binding protein (BiP) and Hsp70 were significantly induced upon energy deprivation. Other stress proteins, including Hsp27, calnexin, Hsp90 and ERp57 showed alterations in their phosphorylation profiles. Three different MAP kinases, namely p38, extracellular signal regulated kisase and c-jun N-terminal kinase (JNK) were activated in response to energy deprivation. While JNK activation was linked to apoptosis, activated-p38 was involved in phosphorylation of Hsp27. Study of inhibitors of Hsp70 induction or pre-induction of Hsp70 indicated that induced Hsp70 was involved in the suppression of JNK activation thereby inhibiting apoptotic cell death. Our results provide important insights into the flux in stress protein profiles in response to simulated ischemia and highlight the antiapoptotic, cytoprotective mechanism of Hsp70 action.     

Protein-damaging stresses activate c-Jun N-terminal kinase via inhibition of its dephosphorylation: a novel pathway controlled by HSP72

Various stresses activate the c-Jun N-terminal kinase (JNK), which is involved in the regulation of many aspects of cellular physiology, including apoptosis. Here we demonstrate that in contrast to UV irradiation, heat shock causes little or no stimulation of the JNK-activating kinase SEK1, while knocking out the SEK1 gene completely blocks heat-induced JNK activation. Therefore, we tested whether heat shock activates JNK via inhibition of JNK dephosphorylation. The rate of JNK dephosphorylation in unstimulated cells was high, and exposure to UV irradiation, osmotic shock, interleukin-1, or anisomycin did not affect this process. Conversely, exposure of cells to heat shock and other protein-damaging conditions, including ethanol, arsenite, and oxidative stress, strongly reduced the rate of JNK dephosphorylation. Under these conditions, we did not observe any effects on dephosphorylation of the homologous p38 kinase, suggesting that suppression of dephosphorylation is specific to JNK. Together, these data indicate that activation of JNK by protein-damaging treatments is mediated primarily by inhibition of a JNK phosphatase(s). Elevation of cellular levels of the major heat shock protein Hsp72 inhibited a repression of JNK dephosphorylation by these stressful treatments, which explains recent reports of the suppression of JNK activation by Hsp72.