Intracellular localization of the heat shock protein, HSP110, in Xenopus laevis A6 kidney epithelial cells

Heat shock protein 110 (HSP110) is a large molecular mass chaperone that is part of the HSP70/DnaK superfamily. In the present study, we examined the accumulation of HSP110 in Xenopus laevis A6 kidney epithelial cells. Immunoblot analysis, using a homologous antibody, detected the presence of HSP110 in A6 cells maintained at 22 degrees C. The relative levels of HSP110 accumulation increased after heat shock or sodium arsenite treatment. Immunocytochemical analysis revealed that constitutively expressed HSP110 was localized in the cytoplasm in a diffuse granular pattern with enrichment in the nucleus. In A6 cells heat shocked at 33 degrees C or 35 degrees C for 2 to 4 h, HSP110 accumulation was enhanced and detected primarily in the cytoplasm as thread- or spindle-like structures. In contrast, HSP30 was not detected constitutively and heat shock treatment of A6 cells induced a relatively uniform punctate pattern primarily in the cytoplasm. Also, treatment of A6 cells at 35 degrees C for 6 h resulted in the presence of HSP110 and HSP30 enriched in the nucleus of most cells. Finally, A6 cells treated with 25 microM sodium arsenite produced very dense HSP110 structures primarily in the cytoplasm while HSP30 was enriched in the cytoplasm in a granular pattern.     

Heat-induced increases in endothelial NO synthase expression and activity and endothelial NO release

Endothelial nitric oxide (NO) synthase (eNOS) is regulated by heat shock protein 90 (HSP90), a heat-inducible protein; however, the effect of heat shock on eNOS expression and eNO release is unknown. Bovine aortic endothelial cells were incubated for 1 h at 37 degrees C, 42 degrees C, or 45 degrees C and cell lysates were evaluated with the use of Western blotting. We observed a 2.1 +/- 0.1-fold increase in eNOS protein content, but no change in HSP90 content, HSP70 content, or HSP90/eNOS association, 24 h after heat shock at 42 degrees C. We also observed a 7.7 +/- 1.5-fold increase in HSP70 protein content, but did not observe a change in eNOS or HSP90 24 h after heat shock at 45 degrees C. eNOS activity and maximal bradykinin-stimulated NO release was significantly increased 24 h after heat shock at 42 degrees C. Heat shock in rats (core temperature: 42 degrees C, 15 min) resulted in a significant increase in aortic eNOS, HSP90, and HSP70 protein content. The aorta from heat-shocked rats exhibited a decreased maximal contractile response to phenylephrine, which was abolished by preincubation with NG-nitro-l-arginine. We conclude that prior heat shock is a physical stimulus of increased eNOS expression and is associated with an increase in eNOS activity, agonist-stimulated NO release, and a decreased vasoconstrictor response.     

Heat shock causes the collapse of the intermediate filament cytoskeleton in Drosophila embryos

Heat shock has a dramatic effect on the organization of the cytoplasm, causing the intermediate filament cytoskeleton to aggregate at the nucleus. This has previously been shown in cultured Drosophila and mammalian cells. In this paper we analyze the heat lability of the intermediate filament cytoskeleton in early Drosophila embryos by indirect immunofluorescence. At all stages of embryogenesis tested, the intermediate filament cytoskeleton, which is maternally provided, is severely disturbed by 30 min heat shock at 37 degrees C. After the nuclei have migrated to the subcortical cytoplasm, it collapses around them. Nuclei in all heat-shocked embryos are considerably enlarged and become displaced. Embryos before cellular blastoderm stage, in which heat shock protein synthesis is not inducible, are irreversibly arrested in development by heat shock. Embryos at or after cellular blastoderm, which do synthesize heat shock proteins in response to stress, are also immediately arrested in development but continue development when returned to 25 degrees C. We discuss the possibility that cytoplasmic events such as the intermediate filament cytoskeleton rearrangement may be involved in heat shock-mediated phenocopy induction.     

Phosphorylation of HSP27 during development and decay of thermotolerance in Chinese hamster cells

The small molecular weight heat shock protein HSP27 was recently shown to confer a stable thermoresistant phenotype when expressed constitutively in mammalian cells after structural gene transfection. These results suggested that HSP27 may also play an important role in the development of thermotolerance, the transient ability to survive otherwise lethal heat exposure after a mild heat shock. In Chinese hamster O23 cells increased thermoresistance is first detected at 2 h after a triggering treatment of 20 min at 44 degrees C, attains a maximum at 5 hours, and decays thereafter with a half-life of 10 h. We found that the development and decay of transient thermotolerance cannot be solely explained on the basis of changes in the cellular concentration of HSP27. The cellular HSP27 concentration is not increased appreciably at 2 h after heat shock and attains a maximum at 14 h. Similar results were obtained in the case of another heat shock protein, HSP70. HSP70 follows slightly faster kinetics of accumulation (peaks at 10 h) and decays much more rapidly (ti/2 = 4h) than HSP27 (t1/2 = 13h). HSP27 has 3 isoelectric variants A, B, and C of which B and C are phosphorylated. In cells maintained at normal temperature, HSP27A represents more than 90% of all HSP27. Shifting the cell culture temperature from 37 to 44 degrees C induces the incorporation of 32P into the more acidic B and C forms, a process that occurs very rapidly since the reduction in the concentration of the A form and a corresponding increase in the level of B and C is detectable by immunoblot analysis within 2.5 min at 44 degrees C. Analyses performed at various times during development and decay of transient thermotolerance revealed a close relationship between the effect of heat shock on HSP27 phosphorylation and cell ability to survive. For example, fully thermotolerant cells (5 h post-induction) are refractory to induction of HSP27 phosphorylation by a 20-min heat shock. The induction of HSP27 phosphorylation was also studied in a family of clonal cell lines of O23 cells that are thermoresistant as a result of the constitutive expression of a transfected human HSP27 gene. In these thermoresistant cells, phosphorylation of the endogenous hamster HSP27 is induced to a level comparable to that found in the thermosensitive parental cells. However, phosphorylation of the exogenous human protein, which represents more than 80% of total HSP27 in these cells, was much less induced.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphorylation-dependent cellular localization and thermoprotective role of heat shock protein 25 in hippocampal progenitor cells

The present study examined phosphorylation-dependent cellular localization and the thermoprotective role of heat shock protein (HSP) 25 in hippocampal HiB5 cells. HSP25 was induced and phosphorylated by heat shock (at 43 degrees C for 3 h). HSP25, which was located in the cytoplasm in the normal condition, translocated into the nucleus after the heat shock. Transfection experiments with hsp27 mutants in which specific serine phosphorylation residues (Ser(78) and Ser(82)) were substituted with alanines or aspartic acids showed that phosphorylation of HSP27 is accompanied by its nuclear translocation. Phosphorylation of mitogen-activated protein kinases (MAPKs) such as p38 MAPK and ERK was markedly increased by the heat shock, and SB203580 (a p38 MAPK kinase inhibitor) and/or PD098059 (a MEK inhibitor) inhibited the phosphorylation of HSP25, indicating that p38 MAPK and ERK are upstream regulators of HSP25 phosphorylation in the heat shock condition. In the absence of heat shock, actin filament stability was not affected by SB203580 and/or PD098059. Heat shock caused disruption of the actin filament and cell death when phosphorylation of HSP25 was inhibited by SB203580 and/or PD098059. In addition, actin filament was more stable in Asp(78,82)-hsp27 (mimics the phosphorylated form) transfected HiB5 cells than in the normal and Ala(78,82)-hsp27 (nonphosphorylative form) transfected cells. In accordance with actin filament stability, the survival rate against the heat shock increased markedly in Asp(15,78,82)-hsp27 expressing HiB5 cells but decreased in Ala(15,78,82)-hsp27 expressing cells. These results support the idea that phosphorylation of HSP25 is critical for the maintenance of actin filament and enhancement of thermoresistance. Interestingly, HSP25 was dephosphorylated and returned to cytoplasm in a recovery time-dependent manner. This phenomenon was accompanied by an increment of apoptotic cell death as determined by nuclear and DNA fragmentation and fluorescence-activated cell sorter analysis. These results suggest that nuclear-translocated HSP25 might function to protect nuclear structure, thereby preventing apoptotic cell death.     

HSP70 kinetics study by continuous observation of HSP-GFP fusion protein expression on a perfusion heating stage

The direct correlation between levels of heat shock protein expression and efficiency of its tissue protection function motivates this study of how thermal doses can be used for an optimal stress protocol design. Heat shock protein 70 (HSP70) expression kinetics were visualized continuously in cultured bovine aortic endothelial cells (BAECs) on a microscope heating stage using green fluorescent protein (GFP) as a reporter. BAECs were transfected with a DNA vector, HSP(p)-HSP70-GFP which expresses an HSP70-GFP fusion protein under control of the HSP70 promoter. Expression levels were validated by western blot analysis. Transfected cells were heated on a controlled temperature microscope stage at 42 degrees C for a defined period, then shifted to 37 degrees C for varied post-heating times. The expression of HSP70-GFP and its sub-cellular localization were visualized via fluorescence microscopy. The progressive expression kinetics were measured by quantitative analysis of serial fluorescence images captured during heating protocols from 1 to 2 h and post-heating times from 0 to 20 h. The results show two sequential peaks in HSP70 expression at approximately 3 and 12 h post-heat shock. A progressive translocation of HSP70 from the cytoplasm to the nucleus was observed from 6 to 16 h. We conclude that we have successfully combined molecular cloning and optical imaging to study HSP70 expression kinetics. The kinetic profile for HSP70-GFP fusion protein is consistent with the endogenous HSP70. Furthermore, information on dynamic intracellular translocation of HSP70 was extracted from the same experimental data.     

Characterization of the 105-kDa molecular chaperone. Identification, biochemical properties, and localization.

We have characterized the biochemical properties of the testis and brain-specific 105-kDa protein which is cross-reacted with an anti-bovine HSP90 antibody. The protein was induced in germ cells by heat stress, resulting in a protein which is one of the heat shock proteins [Kumagai, J., Fukuda, J., Kodama, H., Murata, M., Kawamura, K., Itoh, H. & Tanaka, T. (2000) Eur. J. Biochem.267, 3073-3078]. In the present study, we characterized the biochemical properties of the protein. The 105-kDa protein inhibited the aggregation of citrate synthase as a molecular chaperone in vitro. ATP/MgCl2 has a slight influence of the suppression of the citrate synthase aggregation by the 105-kDa protein. The protein possessed chaperone activity. The protein was able to bind to ATP-Sepharose like the other molecular chaperone HSP70. A partial amino-acid sequence (24 amino-acid residues) of the protein was determined and coincided with those of the mouse testis- and brain-specific APG-1 and osmotic stress protein 94 (OSP94). The 105-kDa protein was detected only in the medulla of the rat kidney sections similar to OSP94 upon immunoblotting. The purified 105-kDa protein was cross-reacted with an antibody against APG-1. These results suggested that APG-1 and OSP94 are both identical to the 105-kDa protein. There were highly homologous regions between the 105-kDa protein/APG-1/OSP94 and HSP90. The region of HSP90 was also an immunoreactive site. An anti-bovine HSP90 antibody may cross-react with the 105-kDa protein similar to HSP90 in the rat testis and brain. We have investigated the localization and developmental induction of the protein in the rat brain. In the immunohistochemical analysis, the protein was mainly detected in the cytoplasm of the nerve and glial cells of the rat brain. Although the 105-kDa protein was localized in all rat brain segments, the expression pattern was fast in the cerebral cortex and hippocampus and slow in the cerebellum.     

Heat-induced preferential synthesis and redistribution of HSP 70 and 28 families in Chinese hamster ovary cells

We observed that members of two HSP families (70 and 28 kDa) preferentially redistributed into the nucleus after heating at 45.5 degrees C for 10 min. The rates of synthesis and redistribution of these proteins were different for each member of HSP families during incubation period at 37 degrees C after heat shock. The maximum rates of synthesis of HSP 70 and HSP 28 families, except HSP 28c, were 6-9 hr after heat shock, whereas the maximum rates of redistribution were 3-6 hr after heat shock. These results suggest that the rates of redistribution of these proteins may be dependent on the amount of intracellular proteins as well as the alteration of binding affinity of nucleoproteins following heat shock.     

Expression of the small heat shock protein gene, hsp30, in Rana catesbeiana fibroblasts

In the present study, we examined the expression of the Rana catesbeiana small heat shock protein gene, hsp30, in an FT fibroblast cell line. Northern and western blot analyses revealed that hsp30 mRNA or HSP30 protein was not present constitutively but was strongly induced at a heat shock temperature of 35 degrees C. However, treatment of FT cells with sodium arsenite at concentrations that induced hsp gene expression in other amphibian systems caused cell death. Non-lethal concentrations of sodium arsenite (10 microM) induced only minimal accumulation of hsp30 mRNA or protein after 12 h. Immunocytochemical analyses employing laser scanning confocal microscopy detected the presence of heat-inducible HSP30, in a granular or punctate pattern. HSP30 was enriched in the nucleus with more diffuse localization in the cytoplasm. The nuclear localization of HSP30 was more prominent with continuous heat shock. These heat treatments did not alter FT cell shape or disrupt actin cytoskeletal organization. Also, HSP30 did not co-localize with the actin cytoskeleton.     

Dynamic changes in the structure and intracellular locale of the mammalian low-molecular-weight heat shock protein.

Mammalian cells grown at 37 degrees C contain a single low-molecular-weight heat shock (or stress) protein with an apparent mass of 28 kilodaltons (kDa) whose synthesis increases in cells after exposure to elevated temperatures or other forms of physiologic stress. Herein we present data demonstrating that heat shock protein 28 exists in a number of dynamic states depending upon the physiologic state of the cell. Biochemical fractionation of 37 degrees C cells in the absence of nonionic detergent revealed that the 28-kDa protein partitioned approximately equally between the soluble and insoluble fractions. The addition of detergent in the fractionation procedure resulted in all of the protein distributed within the soluble phase. In contrast, in cells first heat shocked and then fractionated in the presence of detergent, most of the 28-kDa protein was found within the insoluble fraction. These biochemical results appeared entirely consistent with indirect immunofluorescence experiments, demonstrating that the 28-kDa protein resided within the perinuclear region of 37 degrees C cells in close proximity to the Golgi complex. After heat shock treatment, the 28-kDa protein relocalized within the nucleus and resisted detergent extraction. The extent of 28-kDa protein redistribution into the nucleus and its detergent insolubility increased as a function of the severity of the heat shock treatment. With time of recovery from the heat treatment there occurred a gradual return of the 28-kDa protein into the detergent-soluble phase. Concomitant with these changes in 28-kDa protein solubility was a corresponding change in the apparent size of the protein as determined by gel filtration. While at 37 degrees C cells the protein exhibited a mass of 200 to 800 kDa; after heat shock the protein assumed sizes of 2 MDa or greater. Using immunoelectron microscopy, we show an accumulation of these aggregates of 28-kDa protein within the nucleus. Finally, we show that the heat-dependent redistribution of the 28-kDa protein from the cytoplasm into the nucleus was greatly diminished when the cells were first rendered thermotolerant, and we suggest that this simple assay (i.e., 28-kDa protein detergent solubility) may prove useful in evaluating the thermotolerant status of a cell or tissue.     

Inhibition of heat shock protein synthesis and thermotolerance by cycloheximide

Chinese hamster ovary (CHO) cells were exposed to a 43 degrees C, 15-min heat shock to study the relationship between protein synthesis and the development of thermotolerance. The 43 degrees C heat shock triggered the synthesis of three protein families having molecular weights of 110,000, 90,000, and 65,000 (HSP). These proteins were synthesized at 37 and 46 degrees C. This heat shock also induced the development of thermotolerance, which was measured by incubating the cells at 46 degrees C 4 h after the 43 degrees C heat treatment. CHO cells were also exposed to 20 micrograms/ml of cycloheximide for 30 min at 37 degrees C, 15 min at 43 degrees C, and 4 h at 37 degrees C. This treatment inhibited the enhanced synthesis of the Mr 110,000, 90,000, and 65,000 proteins. The cycloheximide was then washed out and the cells were incubated at 46 degrees C. HSP synthesis did not recover during the 46 degrees C incubation. This cycloheximide treatment also partially inhibited the development of thermotolerance. These results suggest that for CHO cells to express thermotolerance when exposed to the supralethal temperature of 46 degrees C protein synthesis is necessary.     

Induction of acquired thermotolerance in Tetrahymena thermophila: effects of protein synthesis inhibitors.

When Tetrahymena thermophila cells growing at 30 degrees C are shifted to either 40 or 43 degrees C, the kinetics and extent of induction of heat shock mRNAs in both cases are virtually indistinguishable. However, the cells shifted to 40 degrees C show a typical induction of heat shock protein (HSP) synthesis and survive indefinitely (100% after 24 h), whereas those at 43 degrees C show an abortive synthesis of HSPs and die (less than 0.01% survivors) within 1 h. Cells treated at 30 degrees C with the drugs cycloheximide or emetine, at concentrations which are initially inhibitory to protein synthesis and cell growth but from which cells can eventually recover and resume growth, are after this recovery able to survive a direct shift from 30 to 43 degrees C (ca. 70% survival after 1 h). This induction of thermotolerance by these drugs is as efficient in providing thermoprotection to cells as is a prior sublethal heat treatment which elicits the synthesis of HSPs. However, during the period when drug-treated cells recover their protein synthesis ability and simultaneously acquire the ability to subsequently survive a shift to 43 degrees C, none of the major HSPs are synthesized. The ability to survive a 1-h, 43 degrees C heat treatment, therefore, does not absolutely require the prior synthesis of HSPs. But, as extended survival at 43 degrees Celsius depends absolutely on the ability of cells to continually synthesize HSPs, it appears that a prior heat shock as well as the recovery from protein synthesis inhibition elicits a change in the protein synthetic machinery which allows the translation of HSP mRNAs at what would otherwise be a nonpermissive temperature for protein synthesis.     

Effects of low culture temperature on the induction of hsp70 mRNA and the accumulation of hsp70 and hsp105 in mouse FM3A cells.

We have shown that heat shock does not induce the synthesis of hsp70 in FM3A cells maintained at a low culture temperature of 33 degrees C although it does so in cells maintained at 37 degrees C [T. Hatayama et al. (1991) Biochem. Int. 24, 467-474]. In this paper, we show that FM3A cells maintained at 37 degrees C produced hsp70 mRNA during continuous heating at 42 degrees C or during postincubation at either 37 or 33 degrees C after being heated at 45 degrees C for 15 min, whereas cells maintained at 33 degrees C did not produce hsp70 mRNA during continuous heating at 37, 39, 42, or 45 degrees C, or during postincubation after being heated at any temperature. Thus the lack of hsp70 synthesis in cells maintained at 33 degrees C seemed to be due to the absence of hsp70 mRNA induction. Also, hsp70 was accumulated in cells maintained at 37 degrees C during continuous heating at 42 degrees C and during postincubation at 37 degrees C after heat shock at 45 degrees C, but not during postincubation at 33 degrees C. The cellular level of the constitutive hsp73 as well as the mRNA level were both similar in cells maintained at 33 and 37 degrees C. On the other hand, the cellular level of the constitutive hsp105 in cells maintained at 33 degrees C was only half of that in cells maintained at 37 degrees C. These hsp105 levels increased significantly in both types of cells after continuous heating at 39 degrees C. These findings indicate that the culture temperature affects not only the induction of hsp70 mRNA but also the accumulation of hsp70 and hsp105 in the cells.     

Hsp105 reduces the protein aggregation and cytotoxicity by expanded-polyglutamine proteins through the induction of Hsp70

Hsp105α and Hsp105β are major heat shock proteins in mammalian cells and belong to the HSP105/110 family. Hsp105α is expressed constitutively in the cytoplasm of cells, while Hsp105β, an alternatively spliced form of Hsp105α, is expressed specifically in the nucleus of cells during mild heat shock. Here, we show that not only Hsp105β but also Hsp105α accumulated in the nucleus of cells following the expression of enhanced green fluorescent protein with a pathological length polyQ tract (EGFP-polyQ97) and suppressed the intranuclear aggregation of polyQ proteins and apoptosis induced by EGFP-polyQ97. Mutants of Hsp105α and Hsp105β with changes in the nuclear localization signal sequences, which localized exclusively in the cytoplasm with or without the expression of EGFP-polyQ97, did not suppress the intranuclear aggregation of polyQ proteins and apoptosis induced by EGFP-polyQ97. Furthermore, Hsp70 was induced by the co-expression of Hsp105α and EGFP-polyQ97, and the knockdown of Hsp70 reduced the inhibitory effect of Hsp105α and Hsp105β on the intranuclear aggregation of polyQ proteins and apoptosis induced by EGFP-polyQ97. These observations suggested that Hsp105α and Hsp105β suppressed the expanded polyQ tract-induced protein aggregation and apoptosis through the induction of Hsp70.     

Effects of hyperthermia on p53 protein expression and activity

Although p53 responses after DNA damage have been investigated extensively, p53 responses after heat shock, which exerts cytotoxic action by mechanisms other than direct induction of DNA damage, are less well characterized. We investigated, therefore, the effect of hyperthermic exposures on the levels and DNA-binding activity of p53. Experiments were carried out with U2OS and ML-1 cells, known to express wild-type p53 protein. Although heating at 41 degrees C for up to 6 h had only a small effect on p53 levels or DNA binding activity, exposure to temperatures between 42.5 and 45.5 degrees C caused an immediate decrease in protein levels that was associated with a reduction in DNA binding activity. This observation is compatible with a high lability of p53 to heat shock, or heat sensitivity of the pathway regulating p53 levels in non-stressed cells. When cells were heated to 42.5 degrees C and returned to normal temperatures, a strong p53 response associated with an increase in protein levels and DNA binding activity was observed, suggesting the production of p53-inducing cellular damage. At higher temperatures, however, this response was compromised in an exposure-time-dependent manner. The increase in DNA binding activity was more heat sensitive than the increase in p53 levels and was inhibited at lower temperatures and shorter exposure times. Thus, the pathway of p53 activation is itself heat sensitive and compromised at high levels of exposure. Compared to p53 activation after exposure to ionizing radiation, heat-induced activation is rapid and short lived. When cells were exposed to combined heat and radiation, the response observed approximated that of cells exposed to heat alone. Wortmannin at 10 microM inhibited p53 activation for up to 2 h after heat shock suggesting the involvement of wortmannin-sensitive kinases, such as DNA-PK and ATM. Heat shock causes phosphorylation of p53 at Serine-15, but there is no correlation between phosphorylation at this site and activation of the protein. The results in aggregate indicate p53 activation in the absence of DNA damage by a heat-sensitive mechanism operating with faster kinetics than radiation-induced p53 activation. The former response may induce pathways preventing other stimuli from activating p53, as heat-induced activation of p53 is dominant over activation of p53 by DNA damage in combined-treatment experiments. These observations suggest means for abrogating p53 induction after DNA damage with the purpose of potentiating response and enhancing cell killing.     

Substrate utilization for lactate and energy production by heat-shocked L929 cells

The hypothesis that heat shock protein (HSP) induction depends on inhibition of respiration was tested by examining the effects of heat shock on tricarboxylic acid (TCA) cycle function. In control L929 cell cultures, glucose and exogenous pyruvate were converted primarily to lactate, and glutamine was extensively oxidized, accounting for more than one-half of the calculated ATP production. During heat shock at 42 degrees C, lactate production from all of the labeled substrates and total unlabeled lactate production increased significantly while oxygen consumption increased slightly. TCA cycle oxidation of pyruvate decreased during this period while that of glutamine increased. Uncoupling of oxidative phosphorylation caused large increases in oxygen consumption at both 37 degrees C and 42 degrees C, indicating that the capacity of the respiratory chain is not exceeded during heat shock. The net effect of these alterations in substrate utilization were decreased ATP generation and increased NADH utilization. Both 14CO2 and lactate production declined during the 24-h period after cultures were returned to 37 degrees C. On the basis of these data, we conclude that while inhibition of respiration plays no apparent role, other metabolic consequences of heat shock related to energy metabolism may be involved in HSP induction.