Thermotolerance induced by heat, sodium arsenite, or puromycin: its inhibition and differences between 43 degrees C and 45 degrees C

HSF1 is required for cellular adaptation to daily temperature fluctuations

The heat shock response (HSR) is a universal mechanism of cellular adaptation to elevated temperatures and is regulated by heat shock transcription factor 1 (HSF1) or HSF3 in vertebrate endotherms, such as humans, mice, and chickens. We here showed that HSF1 and HSF3 from egg-laying mammals (monotremes), with a low homeothermic capacity, equally possess a potential to maximally induce the HSR, whereas either HSF1 or HSF3 from birds have this potential. Therefore, we focused on cellular adaptation to daily temperature fluctuations and found that HSF1 was required for the proliferation and survival of human cells under daily temperature fluctuations. The ectopic expression of vertebrate HSF1 proteins, but not HSF3 proteins, restored the resistance in HSF1-null cells, regardless of the induction of heat shock proteins. This function was associated with the up-regulation of specific HSF1-target genes. These results indicate the distinct role of HSF1 in adaptation to thermally fluctuating environments and suggest association of homeothermic capacity with functional diversification of vertebrate HSF genes.

Heat Shock Protein 27, a Novel Downstream Target of Collagen Type XI alpha 1, Synergizes with Fatty Acid Oxidation to Confer Cisplatin Resistance in Ovarian Cancer Cells

Simple Summary

Collagen type XI alpha 1 (COL11A1) is a novel biomarker associated with poor survival in ovarian cancer and a promoter of ovarian cancer cell resistance to cisplatin. However, it is poorly understood how COL11A1 promotes ovarian cancer cisplatin resistance. We performed assays to discover the biological molecules that are activated by COL11A1 in ovarian cancer cells. We found that heat shock protein 27 (HSP27), a cellular stress response protein, is activated by COL11A1. Furthermore, we observed that depletion and drug inhibition of HSP27 makes ovarian cancer cells grown on COL11A1 to be more susceptible to cisplatin treatment. We also discovered that ovarian cancer cells upregulate fatty acid oxidation (FAO), a metabolic process that breaks down fats to generate energy and biomolecules, to compensate for the loss of HSP27. Our findings have therapeutic implications for clinicians who wish to treat ovarian tumors that maintain high levels of COL11A1 and HSP27.

Abstract

Collagen type XI alpha 1 (COL11A1) is a novel biomarker associated with cisplatin resistance in ovarian cancer. We have previously reported that COL11A1 activates Src-Akt signaling through the collagen receptors discoidin domain receptor 2 (DDR2) and integrin α1β1 to confer cisplatin resistance to ovarian cancer cells. To identify the potential signaling molecules downstream of COL11A1 signaling, we performed protein kinase arrays and identified heat shock protein 27 (HSP27) as a potential mediator of COL11A1-induced cisplatin resistance. Through receptor knockdown and inhibitor experiments, we demonstrated that COL11A1 significantly upregulates HSP27 phosphorylation and expression via DDR2/integrin α1β1 and Src/Akt signaling in ovarian cancer cells. Furthermore, genetic knockdown and pharmacological inhibition of HSP27, via ivermectin treatment, significantly sensitizes ovarian cancer cells cultured on COL11A1 to cisplatin treatment. HSP27 knockdown or inhibition also decreases NFκB activity as well as the expression of inhibitors of apoptosis proteins (IAPs), which are known downstream effector molecules of COL11A1 that promote cisplatin resistance. Interestingly, HSP27 knockdown or inhibition stimulates ovarian cancer cells to upregulate fatty acid oxidation (FAO) for survival and cisplatin resistance, and dual inhibition of HSP27 and FAO synergistically kills ovarian cancer cells that are cultured on COL11A1. Collectively, this study identifies HSP27 as a novel and druggable COL11A1 downstream effector molecule that may be targeted to overcome cisplatin resistance in recurrent ovarian cancer, which often overexpress COL11A1.

Utilizing Edible Agar as a Carrier for Dual Functional Doxorubicin-Fe3O4 Nanotherapy Drugs

The purpose of this study was to use agar as a multifunctional encapsulating material to allow drug and ferromagnetism to be jointly delivered in one nanoparticle. We successfully encapsulated both Fe3O4 and doxorubicin (DOX) with agar as the drug carrier to obtain DOX-Fe3O4@agar. The iron oxide nanoparticles encapsulated in the carrier maintained good saturation of magnetization (41.9 emu/g) and had superparamagnetism. The heating capacity test showed that the specific absorption rate (SAR) value was 18.9 ± 0.5 W/g, indicating that the ferromagnetic nanoparticles encapsulated in the gel still maintained good heating capacity. Moreover, the magnetocaloric temperature could reach 43 °C in a short period of five minutes. In addition, DOX-Fe3O4@agar reached a maximum release rate of 85% ± 3% in 56 min under a neutral pH 7.0 to simulate the intestinal environment. We found using fluorescent microscopy that DOX entered HT-29 human colon cancer cells and reduced cell viability by 66%. When hyperthermia was induced with an auxiliary external magnetic field, cancer cells could be further killed, with a viability of only 15.4%. These results show that agar is an efficient multiple-drug carrier, and allows controlled drug release. Thus, this synergic treatment has potential application value for biopharmaceutical carrier materials.

Molecular characterization and expression of a heat shock protein gene (HSP90) from the carmine spider mite, Tetranychus cinnabarinus (Boisduval)

In this study, the cDNA of Tetranychus cinnabarinus (Boisduval) (Acarina: Tetranychidae) HSP90 (designated TcHSP90) was cloned using a combination of the homology cloning and rapid amplification of cDNA ends (RACE) approaches. The full-length cDNA of TcHSP90 is 2595 bp, including a 5′-untranslated region (UTR) of 177 bp, 3′-UTR of 249 bp, and an open reading frame (ORF) of 2169 bp. The ORF encodes a polypeptide of 722 amino acids with a predicted molecular weight of 83.45 kDa and a theoretical isoelectric point of 4.81. There is an mRNA polyadenylation signal of ATTAAA at the positions 2558-2564. In addition, the expression pattern of TcHSP90 mRNA relative to that of beta-actin gene in the three stains of T. cinnabarinus (AbR, abamectin-resistant strain; HR, heat-resistant strain; SS, the susceptible strain) were examined by using fluorescent real time quantitative PCR after the impact of abamectin, high and low temperature, respectively. The results showed that under the normal condition, the mRNA level of TcHSP90 was 1.64 and 1.29-fold higher in the AbR and HR than in SS, respectively. After 8 h treatment with abamectin, the TcHSP90 mRNA levels of SS, AbR, and HR were 1.25, 1.87, and 2.05-fold higher than those of their untreated controls, respectively. The TcHSP90 mRNA levels of SS, AbR, and HR were also significantly increased after being induced at 40 degrees C for 1 h, and they were 3.76, 3.42, and 3.79-fold higher than those of their untreated controls, respectively. The mRNA level of TcHSP90 was also significantly increased after being induced at 4 degrees C for 1 h. These results suggest that TcHSP90 might be involved in the abamectin and extreme temperature resistance or tolerance.

Induction of Thermotolerance by Chemical Agents in Enucleate Erythrocytes

Erythrocytes treated with various chemical agents for 1 h at 37 degrees C showed resistance to a subsequent 1 h heat treatment at 53 degrees C. Maximal thermotolerance was observed 6 h after 3 mM DNP and 0.03 mM disulfiram treatment and 4 h after diamide exposure at 0.3 mM. Our results suggest that chemically induced thermotolerance to heat treatment in erythrocytes was similar to heat-induced thermotolerance.

Development of cross-resistance between heat and cisplatin or hydroxyurea treatments in FaDu squamous carcinoma cells

BACKGROUND

Induction of hyperthermia by radiofrequency ablation is gaining popularity in treating a variety of solid tumors. This study examined an impact of sublethal heat treatment interacted with chemotherapeutic drugs on the survival of head and neck squamous carcinoma cells using in vitro model.

MATERIALS AND METHODS

FaDu cells were subjected to heat treatment at 42 degrees C or 45 degrees C for 15 min either before or after exposure to cisplatin or hydroxyurea. The survival of cells was determined by 3-(4,5-dimethylthiazolyl-2)-2,5-diphenyltetrazolium bromide assay. The RNA and protein levels of various heat shock proteins were examined by reverse transcription polymerase chain reaction and Western blot analysis, respectively. Cell cycle progression was analyzed by flow cytometry with propidium iodide staining.

RESULTS

FaDu cells preheated to 45 degrees C exhibited an increased resistance to hydroxyurea but not to cisplatin. The heat treatment resulted in induction of HSP70 expression at transcript and protein levels, but there was no change in expression of HSP90beta and HSP27. After heat treatment, cells accumulated in S-phase at 3 h and proceeded to G(2)/M phase at 24 h. When cells pre-exposed to drugs for 24 h, the cisplatin-treated cells exhibited a higher thermotolerance than the hydroxyurea-treated cells at heat treatment of 45 degrees C. Cisplatin and hydroxyurea caused cells to accumulate in S-phase and increased the protein expression of HSP27 but not HSP90beta and HSP70.

CONCLUSION

FaDu cells surviving the heat treatment expressed HSP70 and disrupted cell cycle progression, which resulted in developing a resistance to subsequent hydroxyurea treatment. However, the heat treatment did not have an effect on the sensitivity to cisplatin. In the reversed procedure, pre-exposure to hydroxyurea and cisplatin resulted in developing a thermotolerance.

Dislocation and degradation from the ER are regulated by cytosolic stress

Akey step in ER-associated degradation (ERAD) is dislocation of the substrate protein from the ER into the cytosol to gain access to the proteasome. Very little is known about how this process is regulated, especially in the case of polytopic proteins. Using pulse-chase analysis combined with subcellular fractionation, we show that connexins, the four transmembrane structural components of gap junctions, can be chased in an intact form from the ER membrane into the cytosol of proteasome inhibitor-treated cells. Dislocation of endogenously expressed connexin from the ER was reduced 50-80% when the cytosolic heat shock response was induced by mild oxidative or thermal stress, but not by treatments that instead upregulate the ER unfolded protein response. Cytosolic but not ER stresses slowed the normally rapid degradation of connexins, and led to a striking increase in gap junction formation and function in otherwise assembly-inefficient cell types. These treatments also inhibited the dislocation and turnover of a connexin-unrelated ERAD substrate, unassembled major histocompatibility complex class I heavy chain. Our findings demonstrate that dislocation is negatively regulated by physiologically relevant, nonlethal stress. They also reveal a previously unrecognized relationship between cytosolic stress and intercellular communication.

Heat shock response by cells treated with azetidine-2-carboxylic acid

The purpose of this study is to reinvestigate the heat shock response in cells treated with the antimetabolite azetidine-2-carboxylic acid (azetidine), an analogue of proline. Previous studies could not clearly discriminate between the progressive thermosensitization caused by amino acid analogues and a parallel induction of thermotolerance by heat shock. Incubation of H35 cells with 2.5 mm azetidine causes an increasing thermosensitization which achieves a maximum after approximately 18-22 h. At this point, azetidine does not prevent the development of acute thermotolerance following a heat shock at 42.5 degrees C, or the simultaneous induction of chronic thermotolerance during mild hyperthermia at 38-41 degrees C. However, for both the acute and chronic heating conditions thermotolerance levels are reduced in proportion with azetidine-thermosensitization. Incorporation of azetidine causes an apparent downward temperature shift of approximately 1 degree C relative to the time-temperature relationships for normal, or following heat shocks, for thermotolerant cells. After 18 h of incubation with azetidine, protein synthesis is reduced by a factor of 4 and cells show a preferential synthesis of heat shock proteins (hsp). A heat shock then, although inducing thermotolerance, is not followed by any noticeable effect on the synthesis of hsps. It is shown that the combination of prolonged azetidine treatment and heat shock causes a persistent inhibition of protein synthesis. This is hypothesized to result in the development of hsp synthesis independent thermotolerance. Additional treatment following heat shock in azetidine-treated cells with the protein synthesis inhibitor cycloheximide does not affect the induction of thermotolerance. In contrast to the heat shock response, no thermotolerance induction is observed in azetidine-treated cells after an exposure to sodium arsenite.

Effects of azetidine-2-carboxylic acid on treatments of hepatoma cells with single or fractionated X-ray irradiations and on thermal radiosensitization in normal and thermotolerant cells

The amino acid analog azetidine-2-carboxylic acid (azetidine) is a potent sensitizer to both hyperthermia and ionizing radiation. Incubation of H35 hepatoma cells with 2.5 mM azetidine before or after treatments with X-rays causes a time- and sequence-dependent enhancement of cell killing. Exposure of cells to 1-1.5 mM azetidine for 96 h in combination with repeated doses of 3 Gy X-rays at 24 h intervals causes an enhanced reduction of the surviving cell population due to both radiosensitization and an additional growth inhibition. Azetidine does not prevent the induction of thermotolerance after a heat shock. This thermotolerance proportionally reduces thermal radiosensitization but does not seem to affect azetidine radiosensitization. It is suggested that thermal radiosensitization and azetidine radiosensitization operate by different mechanisms.

Heat shock-induced acquisition of thermotolerance at the levels of cell survival and translation in Xenopus A6 kidney epithelial cells

In this study we have investigated the acquisition of thermotolerance in a Xenopus laevis kidney A6 epithelial cell line at both the level of cell survival and translation. In cell survival studies, A6 cells were incubated at temperatures ranging from 22 to 35°C for 2 h followed by a thermal challenge at 39°C for 2 h and a recovery period at 22°C for 24 h. Optimal acquisition of thermotolerance occurred at 33°C. For example, exposure of A6 cells to 39°C for 2 h resulted in only 3.4% survival of the cells whereas prior exposure to 33°C for 2 h enhanced the survival rate to 69%. This state of thermotolerance in A6 cells was detectable after 1 h at 33°C and was maintained even after 18 h of incubation. Cycloheximide inhibited the acquisition of thermotolerance at 33°C suggesting the requirement for ongoing protein synthesis. The optimal temperature for the acquisition of translational thermotolerance also occurred at 33°C. Treatment of A6 cells at 39°C for 2 h resulted in an inhibition of labeled amino acid incorporation into protein which recovered to approximately 14% of control after 19 h at 22°C whereas cells treated at 33°C for 2 h prior to the thermal challenge recovered to 58% of control levels. These translationally thermotolerant cells displayed relatively high levels of the heat shock proteins hsp30, hsp70, and hsp90 compared to pretreatment at 22, 28, 30, or 35°C. These studies demonstrate that Xenopus A6 cells can acquire a state of thermotolerance and that it is correlated with the synthesis of heat shock proteins.Key words: Xenopus laevis, heat shock protein, hsps, A6 cells, chaperone, thermotolerance.

Heat shock protein expression and drug resistance in breast cancer patients treated with induction chemotherapy

Heat shock proteins (Hsps) are induced in vitro by several cytotoxic drugs; in human breast cancer cells these proteins appear to be involved in anti-cancer drug resistance. The present report was designed to analyze whether chemotherapy affects in vivo the expression of Hsp27, Hsp70, Hsc70 and Hsp90 in breast cancer patients treated with induction chemotherapy and whether these proteins may be determinants of tumor resistance to drug administration. We have analyzed 35 biopsies from breast cancer patients treated with induction chemotherapy. Expression of the Hsps in the tumors was compared with (i) histological and clinical responses to chemotherapy, (ii) tumor cell proliferation measured by proliferating cell nuclear antigen (PCNA) immunostaining and nucleolar organizer regions (AgNORs) staining and (iii) the expression of estrogen and progesterone receptors. We also compared disease-free survival (DFS) and overall survival (OS) with the expression of the Hsps studied. After chemotherapy, nuclear Hsp27 and Hsp70 expression was increased and Hsp70 and Hsc70 cytoplasmic expression was decreased. A high nuclear proportion of Hsp70 in tumor cells (>10%) correlated significantly with drug resistance. We also observed that patients whose tumors expressed nuclear or a high cytoplasmic proportion (>66%) of Hsp27 had shorter DFS. The combination of Hsp27 and Hsp70 levels showed a strong correlation with DFS. Neither the cellular proliferation nor the levels of steroid receptors showed any significant difference before or after drug administration or during follow-up of patients. Our results suggest that Hsp27 and Hsp70 are involved in drug resistance in breast cancer patients treated with combination chemotherapies.

Differential activity of bcl-2 and ICE enzyme family protease inhibitors on Fas and puromycin-induced apoptosis of glioma cells

Fas ligand is a potent inducer of apoptosis in human glioma cells by the Fas/Fas ligand pathway. With comparable efficiency, metalloprotease inhibitors including puromycin and bestatin induce apoptosis in glioma cells. To evaluate the involvement of potential components involved in Fas ligand- and metalloprotease inhibitor-induced apoptosis, we investigated the effect of anti human Fas antibody, soluble Fas ligand and puromycin on cultures of human malignant glioma cell lines (LN-18, LN-229, T98G). Stimulation with Fas ligand lead to apoptotic cell death within 16 h. Costimulation with the translational inhibitor cycloheximide and the transcription blocker actinomycin D did not reduce Fas ligand toxicity. In contrast, apoptosis induced by puromycin was blocked by cycloheximide and decreased by subtoxic doses of actinomycin D in all three gliomas. Whereas inhibition of caspase activity with the general inhibitor zVAD-fmk resulted in a complete block of Fas ligand-induced cell death, puromycin-mediated apoptosis was found to be unaffected by zVAD-fmk as well as by more specific inhibitors for caspase-1 (Interleukin-1 beta converting enzyme) and caspase-3 (CPP32/Yama). Other prominent components involved in many apoptotic pathways as bcl-2 and reactive oxygen intermediates were also examined. Bcl-2 which protects glioma cells from Fas ligand-induced cell death, was shown to have only a small protective effect on puromycin-induced apoptosis. The tested radical scavengers did not reduce Fas- or puromycin-mediated killing of human glioma cells.

Thermotolerance expression in mitotic CHO cells without increased translation of heat shock proteins

The objective of this study was to unequivocally demonstrate thermotolerance expression in mammalian cells in the absence of stress-induced synthesis of heat shock proteins (HSPs). Mitotic cells were selected as an experimental system since their genome was in the form of condensed chromosomes and ostensibly incapable of being transcribed; thus, obviating stress-induced HSP gene expression. Asynchronous Chinese hamster ovary (CHO) cells were treated with 0.2 microgram/ml nocodazole to accumulate cells in mitosis for harvest by mitotic shakeoff. Cells were maintained in mitosis with nocodazole during thermotolerance induction, thermotolerance development, and all challenge hyperthermia exposures. Although the heat shock transcription factor was activated by the thermotolerance inducing heat shock, as indicated by gel mobility shift assay, no increase in steady-state HSP mRNA levels was detected, as expected. Preferential synthesis of HSPs from extant mRNA was not detected during thermotolerance development and cellular levels of the 27 kDa, 70 kDa, and 90 kDa heat shock proteins remained constant, as determined by Western Blot analyses. The magnitude and induction threshold of expressed thermotolerance was not diminished when cells were incubated with 10.0 micrograms/ml cycloheximide during thermotolerance development confirming that new protein synthesis was not requisite. Parallel experiments were performed using nonmitotic cells in which protein synthesis was inhibited during thermotolerance development with 10.0 micrograms/ml cycloheximide. As with mitotic cells, high levels of thermotolerance were attained without detectable increases in the cellular content of the 27 kDa, 70 kDa, and 90 kDa heat shock proteins. The results of this study demonstrated that high levels of thermotolerance could be expressed in mitotic cells without stress-induced, preferential synthesis of HSPs, and support the contention that a substantial fraction of thermotolerance expressed in nonmitotic cells also occurs independently of induced HSP synthesis.

Thermal response in murine L929 cells lacking alpha B-crystallin expression and alpha B-crystallin expressing L929 transfectants

We investigated the role of alpha B-crystallin expression in the development of thermotolerance in murine L929 cells. An initial heat-shock of 10 min at 45 degrees C induced thermotolerance in these cells to a heat challenge at 45 degrees C administered 24 h later. The thermotolerance ratio at 10(-1) isosurvival was 1.7. Expression of alpha B-crystallin gene was not detected during the 24 h incubation at 37 degrees C following heat shock by either northern or western blots. In contrast, inducible HSP70 synthesis was observed during this time period. Thus, this cell line provided an unique system in which to examine the effects of transfected alpha B-crystallin on thermoresistance and thermotolerance. Cells stably transfected with alpha B-crystallin under the control of an inducible promoter did not show a significant increase in the ability to develop thermotolerance. However, a stably transfected L929 clone expressing high levels of constitutive alpha B-crystallin exhibited an approximately 50% increase in thermal resistance over parental and control cells. Though expression of alpha B-crystallin is not requisite for the development of thermotolerance in L929 cells, overexpression of transfected alpha B-crystallin can contribute to increased thermoresistance.

Induction of thermotolerance by chemical agents in Lactococcus lactis subsp. lactis IL1403

Like in other organisms tested to date, adapted cells of Lactococcus lactis subsp. lactis IL1403 pretreated at 42 degrees C for 30 min develop a thermotolerant state, i.e. an increased ability to survive subsequent exposure to a lethal challenge temperature (52 degrees C for 15 or 30 min). In different cellular systems, chemicals as diverse as divalent metal salts, natural or synthetic compounds trigger the development of thermotolerance. Yet, in L. lactis subsp. lactis IL1403, among the 17 chemicals tested, only four induced this transient increased tolerance to heat: cadmium chloride, mercury chloride, sodium azide and beta-mercaptoethanol. Intriguingly, none of these four compounds induced the synthesis of three major heat shock proteins (DnaK, GroEL and hsp104-analogue), which are believed to be responsible for thermotolerance in most organisms. It is suggested that: (i) the lesions produced by these various 'proteotoxic' agents are fundamentally different from those produced by heat; (ii) heat shock protein synthesis and transient induced tolerance to heat are not tightly correlated phenomena in L. lactis subsp. lactis as they are in Escherichia coli and some other organisms.

Integrity of intermediate filaments is associated with the development of acquired thermotolerance in 9L rat brain tumor cells

Withangulatin A (WA), a newly discovered withanolide isolated from an antitumor Chinese herb, has been shown to be a vimentin intermediate filament-targeting drug by using immunofluorescence microscopy. Together with cytochalasin D and colchicine, these drugs were employed to investigate the importance of vimentin intermediate filaments, actin filaments, and microtubules in the development of acquired thermotolerance in 9L rat brain tumor cells treated at 45 degrees C for 15 min (priming heat-shock). Acquired thermotolerance was abrogated in cells incubated with WA before the priming heat-shock but it could be detected in cells treated with WA after the priming heat-shock. In contrast, cytochalasin D and colchicine do not interfere with the development of thermotolerance at all. The intracellular localizations of vimentin and the constitutive heat-shock protein70 (HSC70) in treated cells were examined by using immunofluorescence microscopy and detergent-extractability studies. In cells treated with WA before the priming heat-shock, vimentin IFs were tightly aggregated around the nucleus and unable to return to their normal organization after a recovery under normal growing conditions. In contrast, the IF network in cells treated with WA after the priming heat-shock was able to reorganize into filamentous form after a recovery period, a behavior similar to that of the cells treated with heat-shock only. HSC70 was found to be co-localized with vimentin during these changes. It is suggested that the integrity of intermediate filaments is important for the development of thermotolerance and that HSC70 may be involved in this process by stabilizing the intermediate filaments through direct or indirect binding.

Effect of thermotolerance on heat-induced excess nuclear-associated proteins

Earlier studies reported that thermotolerance had two effects on the heat-induced increase in nuclear-associated proteins (NAPs); reduction in NAP levels immediately following hyperthermia and facilitation of NAP recovery to control levels. It has also been demonstrated that there are two phases of thermotolerance; one that requires newly synthesized proteins (protein synthesis dependent thermotolerance; PSDT), and another that does not (protein synthesis independent thermotolerance; PSIT). This study was designed to determine if these two phases of thermotolerance affected NAP binding in a similar or different manner. The results demonstrated that protein synthesis during thermotolerance development was not required to reduce NAP levels measured immediately following hyperthermia, but was required to facilitate NAP recovery to control levels following hyperthermia. Reducing NAP levels was the predominant mechanism by which thermotolerance protected cells from this lesion at 43.0 degrees C while facilitated NAP recovery predominated in protecting against exposure to 45.5 degrees C. The facilitated recovery of NAPs required only proteins synthesized following thermotolerance induction and prior to the second heat challenge. Proteins synthesized following the second heat challenge were not requisite. Finally, the processes that facilitate NAP recovery were inhibited at 3 degrees C, suggesting that they are enzymatically mediated.

Induction of tolerance to hypothermia and hyperthermia by a common mechanism in mammalian cells

Pretreatment by hypothermic (25 degrees C) cycling (PHC) of attached exponential-phase V79 Chinese hamster cells by Method 4 (24 hr at 25 degrees C + 1.5 hr at 37 degrees C + 24 hr at 25 degrees C + trypsin + 3 hr at 37 degrees C) or by Method 3 (48 hr at 25 degrees C + trypsin + 3 hr at 37 degrees C) make mammalian V79 cells significantly more resistant to 43 degrees C hyperthermia. There is no significant difference in the 43 degrees C curves whether Method 3 or 4 is used for pre-exposure. If pre-exposure at 15 or 10 degrees C, the resistance to hyperthermia is significantly reduced. PHC by Method 4 significantly increases survival of cells exposed to 5 degrees C and, to a lesser extent, to 10 degrees C. The increase in hyper- and hypothermic survival after PHC cannot be accounted for by changes in cell cycle distribution. Heat-shock protein synthesis is not induced by PHC; hence, protection does not result from newly synthesized proteins. When cells are made tolerant to hyperthermia by a pretreatment in 2% DMSO for 24 hr at 37 degrees C (Method 8), the cells are not more resistant to subsequent exposures to hypothermia, either at 5 or 10 degrees C. The results imply that there may be two mechanisms of inducing resistance to hyperthermia, only one of which also confers resistance to hypothermia.

Effect of amino acid analogs on the development of thermotolerance and on thermotolerant cells

Exposure of HA-1 Chinese hamster fibroblasts to amino acid analogs has been shown to have a heat-sensitizing effect as well as inducing the heat shock response (Li and Laszlo, 1985a). In this study, we have examined the effect of amino acid analogs on the development of thermotolerance after a brief heat shock or exposure to sodium arsenite and the effect of amino acid analogs on cells that are already thermotolerant. Exposure of HA-1 cells to amino acid analogs inhibited the development of thermotolerance following a mild heat shock or treatment with sodium arsenite. However, cells that were already thermotolerant were resistant to the sensitizing action of amino acid analogs. The refractoriness of thermotolerant cells to amino acid analog treatment developed in parallel with thermotolerance. The uptake of the arginine analog, canavanine, and its incorporation into proteins was not altered in the thermotolerant cells. Furthermore, another biological consequence of exposure to amino acid analogs, sensitization to ionizing radiation, also was not altered in the thermotolerant cells. The inhibition of the development of thermotolerance by amino acid analogs and the refractoriness of thermotolerant cells to the heat-sensitizing action of amino acid analogs lend further support the role of heat-shock proteins in the phenomenon of thermotolerance.

Thermotolerance in mammalian cells. Protein denaturation and aggregation, and stress proteins

Cells that have been pre-exposed to thermal stress can acquire a transient resistance against the killing effect of a subsequent thermal stress. The cause for this phenomenon, called thermotolerance, seems to be an enhanced resistance of proteins against thermal denaturation and aggregation. This resistance can be expressed as an attenuation of damage formation (less initial damage) or as a better repair of the protein damage (facilitated recovery). Heat Shock (or better, Stress) Proteins (HSPs) may play a role in and even be required for thermal resistance. However, rather than stress-induced enhanced synthesis and elevated total levels of HSPs per se, the concentration of, both constitutive and inducible, HSPs at and/or (re)distributed to specific subcellular sites may be the most important factor for the acquisition of thermotolerance. Specific HSPs may be involved either in damage protection or in damage repair.

The relationship between hsp 70 localization and heat resistance

Using indirect immunofluorescence we have investigated the kinetics of nuclear accumulation and removal of hsp 70 in HA-1 Chinese hamster fibroblasts exposed to elevated temperatures. The kinetics of accumulation of hsp 70 in the nuclei were found to be time/temperature dependent at all temperatures tested (42-45 degrees C). At a given temperature, the fraction of cells manifesting nuclear localization of hsp 70 increased with exposure time. For a given duration of heating, the fraction of cells manifesting nuclear localization of hsp 70 increased with the temperature. The kinetics of the nuclear accumulation of hsp 70 were similar for normal HA-1 cells, their heat-resistant variants, and transiently thermotolerant cells (triggered by prior exposure to a brief heat shock or to sodium arsenite). Upon return to 37 degrees C after heat shock, the kinetics of removal of the hsp 70 associated with the nucleus was dependent on the severity of the initial heat challenge. However, for a given heat dose, the decay of nuclear localization of hsp 70 was more rapid in thermotolerant and heat-resistant cells than in their normal counterparts. These results suggest that the increased levels of hsp 70 associated with the transient or permanently heat-resistant state may play a direct role in restoring and/or repairing heat-induced nuclear and nucleolar alterations associated with heat-induced cell killing. Furthermore, they also suggest that the heat-resistant state may involve ameliorated repair of heat-induced cellular alterations.

The thermoresistant state: protection from initial damage or better repair?

The induction of and recovery from heat-induced perturbations in several cellular parameters were examined in normal, transiently thermotolerant, and permanently heat-resistant HA-1 Chinese hamster fibroblasts. The initial heat-induced perturbations in total cellular protein synthesis, RNA synthesis, vimentin-containing intermediate filaments, and nuclear protein mass were similar in the three different cell types which display various levels of thermal resistance as determined by clonogenic survival. The posthyperthermia recovery from the heat-induced perturbations in all of the cellular parameters was more rapid in both the permanently heat-resistant cells and in the transiently thermotolerant cells. This response was observed in cells in which transient thermotolerance was induced by either a mild heat shock or exposure to sodium arsenite. The development and decay of the capacity for more rapid recovery from the initial heat-induced perturbations in total cellular protein and RNA synthesis paralleled the development and decay of clonogenic thermotolerance. Overall, these results support the notion that more rapid recovery from similar levels of heat-induced perturbations in various cellular parameters are a salient feature of both the transiently and permanently heat-resistant state.

Effect of pH on quercetin-induced suppression of heat shock gene expression and thermotolerance development in HT-29 cells

When cells were heated for 15 min at 45 degrees C, they became thermotolerant to a second heat exposure at 45 degrees C. Thermotolerance developed rapidly, reached its maximum 6 hr after heat shock, and then gradually decayed. The development of thermotolerance was partially suppressed by treatment with various concentrations of quercetin (0.05-0.2 mM) at pH 7.4 after the initial heat treatment. In contrast, the drug markedly inhibited thermotolerance development at pH 6.5. Furthermore, a combination of low pH and quercetin treatment distinctively altered the expression of HSP70 gene compared with that of HSP28 or HSP90 gene. These results demonstrate a good correlation between the amount of HSP70 gene expression and development of thermotolerance.

MK-801, but not anisomycin, inhibits the induction of tolerance to ischemia in the gerbil hippocampus

We examined whether MK-801, an N-methyl-D-aspartate (NMDA)-receptor antagonist, or anisomycin, a reversible protein synthesis inhibitor, inhibits the induction of ischemic tolerance following preconditioning with sublethal ischemia in gerbil hippocampus. Preconditioning with 2 min of ischemia, which induced heat shock protein-72 immunoreactivity, prevented hippocampal CA1 neuronal damage following 3 min of ischemia produced 3 days later. MK-801, but not anisomycin, inhibited the induction of tolerance although the heat shock protein synthesis was reduced in both groups. The present result suggests that NMDA receptor activation, causing stress response, induces the ischemic tolerance.

Relationship between thermal tolerance and protein degradation in temperature-sensitive mouse cells

The induction of thermotolerance was studied in a temperature sensitive mouse cell line, ts85, and results were compared with those for the wild-type FM3A cells. At the nonpermissive temperature of 39 degrees C, ts85 cells are defective in the degradation of short-lived abnormal proteins, apparently because of loss of activity of a ubiquitin-activating enzyme. The failure of the ts85 cells to develop thermotolerance to 41-43 degrees C after incubation at the nonpermissive temperature of 39 degrees C correlated with the failure of the cells to degrade short-lived abnormal proteins at 39 degrees C. However, the failure of the ts85 cells to develop thermotolerance to 43 degrees C during incubation at 33 degrees C after either arsenite treatment or heating at 45.5 degrees C for 6 or 10 min did not correlate with protein degradation rates. Although the rate of degrading abnormal protein was reduced after heating at 45.5 degrees C for 10 min, the rates were normal after arsenite treatment or heating at 45.5 degrees C for 6 min. In addition, when protein synthesis was inhibited with cycloheximide both during incubation at 33 degrees C or 39 degrees C and during heating at 41-43 degrees C, resistance to heating was observed, but protein degradation rates at 39 degrees C or 43 degrees C were not altered by the cycloheximide treatment. Therefore, there is apparently no consistent relationship between rates of degrading abnormal proteins and the ability of cells to develop thermotolerance and resistance to heating in the presence of cycloheximide.

Acquisition of thermotolerance induced by heat and arsenite in HeLa S3 cells: Multiple pathways to induce tolerance?

Recent data indicate that cells may acquire thermotolerance via more than one route. In this study, we observed differences in thermotolerance development in HeLa S3 cells induced by prior heating (15 minutes at 44 degrees C) or pretreatment with sodium-arsenite (1 hour at 37 degrees C, 100 microM). Inhibition of overall protein and heat shock protein (HSP) synthesis (greater than 95%) by cycloheximide (25 micrograms/ml) during tolerance development nearly completely abolished thermotolerance induced by arsenite, while significant levels of heat-induced thermotolerance were still apparent. The same dependence of protein synthesis was found for resistance against sodium-arsenite toxicity. Toxic heat, but not toxic arsenite treatments caused heat damage in the cell nucleus, measured as an increase in the protein mass of nuclei isolated from treated cells (intranuclear protein aggregation). Recovery from this intranuclear protein aggregation was observed during post-heat incubations of the cells at 37 degrees C. The rate of recovery was faster in heat-induced tolerant cells than in nontolerant cells. Arsenite-induced tolerant cells did not show an enhanced rate of recovery from the heat-induced intranuclear protein aggregation. In parallel, hyperthermic inhibition of RNA synthesis was the same in tolerant and nontolerant cells, whereas post-heat recovery was enhanced in heat-induced, but not arsenite-induced thermotolerant cells. The more rapid recovery from heat damage in the nucleus (protein aggregation and RNA synthesis) in cells made tolerant by a prior heat treatment seemed related to the ability of heat (but not arsenite) to induce HSP translocations to the nucleus.

Inhibition of protein synthesis and heat protection: histidinol-resistant mutant cell lines

The mechanism of histidinol (HST)-induced heat protection was investigated to test the hypothesis that the cessation of protein synthesis itself is one of the events involved in heat protection. For this study, we isolated three HST-resistant mutant strains. HST (5 mM), which inhibited protein synthesis by 88% in the wild type, caused only 0, 9, and 25% inhibition in three mutants, respectively. The drug, which afforded heat protection, (i.e., a 125-fold increase in survival from 4 x 10(-3) to 5 x 10(-1) after 2 hr at 43 degrees C in wild type), did not protect mutant cells from heat killing. In contrast, cycloheximide (10 micrograms/ml) which inhibited protein synthesis by 95% in both wild type and mutant cell types, protected both cell types from heat killing. Therefore, these results suggest that the cessation of protein synthesis, per se, preventing synthesis of nascent polypeptides, is a major event leading to heat protection.

Effect of tunicamycin on glycosylation of a 50 kDa protein and thermotolerance development

We investigated whether or not a 50 kDa glycoprotein might play an important role in protein synthesis-independent thermotolerance development in CHO cells. When cells were heated for 10 min at 45.5 degrees C, they became thermotolerant to a heat treatment at 45.5 degrees C administered 12 hr later. The thermotolerance ratio at 10(-3) isosurvival was 4.4. The cellular heat shock response leads to enhanced glycosylation of a 50 kDa protein. The glycosylation of proteins including a 50 kDa glycoprotein was inhibited by treatment with various concentrations of tunicamycin (0.2-2 micrograms/ml). The development of thermotolerance was not affected by treatment with tunicamycin after the initial heat treatment, although 2 micrograms/ml tunicamycin inhibited glycosylation by 95%. However, inhibiting protein synthesis with cycloheximide (10 micrograms/ml) after the initial heat treatment partially inhibited the development of thermotolerance. Nevertheless, there was no further reduction of thermotolerance development by treatment with a combination of 2 micrograms/ml tunicamycin and 10 micrograms/ml cycloheximide. These data suggest that development of thermotolerance, especially protein synthesis-independent thermotolerance, is not correlated with increased glycosylation of the 50 kDa protein.

Heat-induced morphological alterations in non-tolerant and thermotolerant cells

CHO cells were heated at 43 degrees C or 45 degrees C for various durations up to 300 min. Survival values varied from 5 x 10(-1) to 10(-7). Unheated, non-tolerant control cells were compared with cells made thermotolerant (TT) by incubating at 37 degrees C for 6 or 12 h after treatment with either sodium arsenite (100 microM-As) or 45.5 degrees C for 10 min, respectively. Groups also were included in which heat-induced TT cells were heated at 43 degrees C for 5 h immediately before they were challenged at 45 degrees C; in these groups, cycloheximide was sometimes added to inhibit protein synthesis before and/or during heating at 43 degrees C. Morphological alterations were quantified immediately and at various times after heating by using phase-contrast microscopy to determine the percentage of cells that were severely blebbed and rounded. About 800 cells were analysed per datum point. When effects of heat on thermotolerant cells were compared with effects of heat on non-tolerant cells, heat-induced thermotolerance (HTT) was observed by an increase in survival, and by a reduction in the percentage of cells with morphological alteration observed immediately after the challenging heat. After the As treatment, very little thermotolerance was observed for morphological alterations immediately after the challenging heat, although thermotolerance was observed for survival. However, as the cells were incubated for 12 or 24 h at 37 degrees C after the challenging heat treatment, recovery from morphological alterations was observed in the As-TT cells. Possible mechanisms for the difference between HTT and As-TT are discussed.

Inhibition of heat shock protein synthesis and protein glycosylation by stepdown heating

Mammalian cells exhibit increased sensitivity to hyperthermic temperatures of 38-43 degrees C after an acute high-temperature heat shock; this phenomenon is known as the stepdown heating (SDH) effect. We characterized the SDH effect on (1) the synthesis of major heat shock proteins, HSP110, 90, 72/70, 60 (35S-amino acids label), (2) on heat-induced protein glycosylation (3H-D-mannose label), and (3) on thermotolerance expression, using cell survival as an endpoint. Partitioning of label between soluble and insoluble cell fractions was separately examined. Synthesis of high molecular weight HSPs (HSP110, 90, and 72/70) was increased both by acute (10 min, 45 degrees C) and chronic (1-6 h, 41.5 degrees C) hyperthermia, primarily in the soluble cytosol fraction. SDH (10 min, 45 degrees C + 1 to 6 h, 41.5 degrees C) completely inhibited labeling of HSP110, partially inhibited HSP90 labeling, and had virtually no effect on HSP72/70 synthesis, when compared with chronic hyperthermia alone. At the cell survival level, SDH increased sevenfold the rate of cell killing at 41.5 degrees C, but reduced the expression of thermotolerance by only a factor of two. This suggests that SDH sensitization did not result from changes in HSP72/70 synthesis, nor solely from inhibition of thermotolerance. 35S-labeled HSP60 and HSP50 were found primarily in the cellular pellet fraction after both acute and chronic hyperthermia. SDH completely inhibited 35S-labeling of both HSP60 and HSP50. Labeling of GP50 with 3H-D-mannose was also completely inhibited by SDH. Moreover, SDH progressively reduced N-acetylgalactosaminyl-transferase activity. The data demonstrate that heat sensitization by SDH is accompanied by complex and selectively inhibitory patterns of HSP synthesis and protein glycosylation. Profound inhibition of HSP110, HSP60, and HSP50/GP50 labeling suggests that these may be associated with mechanisms of SDH sensitization.

Differences in preferential synthesis and redistribution of HSP70 and HSP28 families by heat or sodium arsenite in Chinese hamster ovary cells

Since both heat and sodium arsenite induce thermotolerance, we investigated the differences in synthesis and redistribution of stress proteins induced by these agents in Chinese hamster ovary cells. Five major heat shock proteins (HSPs; Mr 110, 87, 70, 28, and 8.5 kDa) were preferentially synthesized after heat for 10 min at 45.5 degrees C, whereas four major HSPs (Mr 110, 87, 70, and 28 kDa) and one stress protein (33.3 kDa) were preferentially synthesized after treatment with 100 microM sodium arsenite (ARS) for 1 hr. Two HSP families (HSP70a,b,c, and HSP28a,b,c) preferentially relocalized in the nucleus after heat shock. In contrast, only HSP70b redistributed into the nucleus after ARS treatment. Furthermore, the kinetics of synthesis of each member of HSP70 and HSP28 families and their redistribution were different after these treatments. The maximum rates of synthesis of HSP70 and HSP28 families, except HSP28c, were 6-9 hr after heat shock, whereas those of HSP70b and HSP28b,c were 0-2 hr after ARS treatment. In addition, the maximum rates of redistribution of HSP70 and HSP28 families occurred 3-6 hr after heat shock, whereas that of HSP70b occurred immediately after ARS treatment. The degree of redistribution of HSP70b after ARS treatment was significantly less than that after heat treatment. These results suggest that heat treatment but not sodium arsenite treatment stimulates the entry of HSP70 and HSP28 families into the nucleus.

Cycloheximide increases the thermostability of proteins in Chinese hamster ovary cells

Protein denaturation resulting from temperatures between 42.0 degrees C and 50 degrees C has been observed and implicated as the lethal lesion for hyperthermic cell killing. A logical corollary is that protection against hyperthermic killing requires stabilization of cellular proteins against thermal denaturation. To test this, Chinese hamster ovary cells were treated with the heat protector cycloheximide and then subjected to differential scanning calorimetry to measure protein denaturation. Cycloheximide stabilized proteins that denatured between 42 degrees C and 52 degrees C in control cells by increasing their transition (denaturation) temperature by an average of 1.3 degrees C. In addition, cycloheximide reduced the cytotoxicity of actinomycin D and adriamycin, suggesting that protein stabilization protects cells against stresses other than hyperthermia.

Correlation between redistribution of a 26 kDa protein and development of chronic thermotolerance in various mammalian cell lines

Previous studies suggested that a 26 kDa protein might play an important role in protein synthesis-independent thermotolerance development in CHO cells. To determine if this phenomenon was universal, four mammalian cell lines, viz., CHO, HA-1, murine Swiss 3T3, and human HeLa, were studied. Cells were heated at 42 degrees C, and the level of 26 kDa protein in the nucleus was measured, together with clonogenic survival and protein synthesis. The results demonstrated that 1) the 26-kDa protein was present in the four different cell lines, and 2) the level of the 26 kDa protein in their nuclei was decreased by 30-70% after heating at 42 degrees C for 1 hr. However, restoration of this protein occurred along with development of chronic thermotolerance. The protein synthesis inhibitor cycloheximide (10 micrograms/ml) neither inhibited the development of chronic thermotolerance nor affected the restoration of the 26 kDa protein in the nucleus. In fact, this drug protected cells from hyperthermic killing and heat-induced reduction of 26 kDa protein in the nucleus. Heat sensitizers, quercetin (0.1 mM), 3,3'-dipentyloxacarbocyanine iodide (DiOC5[3]: 5 micrograms/ml), and stepdown heating (45 degrees C-10 min----42 degrees C), potentiated hyperthermic killing and inhibited or delayed the restoration of the 26 kDa protein to the nucleus. These results support a correlated, perhaps causal relationship between the restoration of the 26 kDa protein and chronic thermotolerance development in four different mammalian cell lines.

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.