Activation of heat shock gene transcription by heat shock factor 1 involves oligomerization, acquisition of DNA-binding activity, and nuclear localization and can occur in the absence of stress

Arabidopsis heat shock factor: isolation and characterization of the gene and the recombinant protein

We have isolated the Arabidopsis heat shock factor gene Athsf1 as genomic and corresponding cDNA sequences via cross-hybridization with tomato clones. Sequence analysis indicates only a partial homology with the HSFs from tomato and other organisms which is confined to the DNA-binding and the oligomerization domains. The gene is constitutively expressed but the level of mRNA for Athsf1 increases two-fold upon heat shock. However, the putative promoter region lacks the canonical heat shock elements. After expression in Escherichia coli the recombinant Athsf1 protein binds specifically to a synthetic oligonucleotide containing five heat shock elements. The native size of recombinant ATHSF1 in vitro is consistent with a trimer as demonstrated by chemical cross-linking and pore exclusion limit analysis.

Mechanism of quercetin-induced suppression and delay of heat shock gene expression and thermotolerance development in HT-29 cells

Previous studies have shown that a combination of low pH and quercetin (QCT) treatment following heat shock markedly suppresses and delays the expression of heat shock protein genes, particularly the HSP70 gene (Lee et al., Biochem. Biophys. Res. Commun., 186:1121-1128, 1992). The possible mechanism for alteration of gene expression by treatment with QCT at low pH was investigated in human colon carcinoma cells. Cells were heated at 45 degrees C for 15 min and then incubated at 37 degrees C for various times (0-12 h) with QCT (0.05-0.2 mM) at pH 7.4 or 6.5. Gel mobility-shift analysis of whole cell extracts from heated cells showed the formation of the heat shock transcription factor (HSF)-heat shock element (HSE) complex. Dissociation of HSF from the HSE of the human HSP70 promotor occurred within 4 h under both pH conditions. The kinetics of recovery were not affected by treatment with 0.1% dimethyl sulfoxide (DMSO). However, the dissociation of HSF-HSE complex was markedly delayed during treatment with a combination of low pH and QCT. In addition, in vitro transcription assays showed a suppression of initiation and elongation of HSP70 mRNA. These results may explain why the combination of low pH and QCT treatment suppresses and delays the HSP70 gene expression as well as thermotolerance development.

Regulation of chemical stress-induced hsp70 gene expression in murine L929 cells

We have investigated the regulation mechanism of chemical stress-induced hsp70 gene expression in murine L929 cells. Our data show that chemical treatments including sodium arsenite, cadmium chloride and sodium salicylate, induced significant synthesis of hsp70 and its mRNA. The induced hsp70 gene expression appears to be regulated at the transcriptional level. A factor (CHBF), which constitutively binds to the heat shock element (HSE) at 37 degrees C, functions like a negative regulator and the heat-induced heat shock factor (HSF) acts as an activator. The chemical treatments that induce significant hsp70 synthesis activate HSF binding to HSE but also dissociate the HSE-CHBF complex. Some chemical treatments, e.g. IPTG, which fail to activate hsp70 gene transcription, still activate HSF binding to HSE. However, in this case, the HSE-CHBF complex remained like that of untreated control cells.

HSP-72 synthesis is promoted by increase in [Ca2+]i or activation of G proteins but not pHi or cAMP

The family of 70-kDa heat-shock proteins (HSP-70) is evolutionarily highly conserved and has been shown to enhance cell survival from thermal injury. This study characterized HSP-72 induction in human epidermoid A-431 cells exposed to 45 degrees C for 10 min and determined the relationship between HSP-72, intracellular pH (pHi), adenosine 3',5'-cyclic monophosphate (cAMP), G proteins, and intracellular cytosolic free Ca2+ concentration ([Ca2+]i). Heat shock induced HSP-72 production, which was dependent on both temperature and the duration of heating. This HSP-72 induction was confirmed by Western blot analysis. HSP-72 levels in cells that had been heated then returned to 37 degrees C were elevated at 2 h (1.5 +/- 0.1 x control), reached a maximum at 8 h (2.7 +/- 0.1 x control), and remained above baseline for up to 4 days. Levels of HSP-72 mRNA, determined by dot-blot analysis, reached a maximum at 2 h and returned to baseline within 8 h. Both actinomycin D and cycloheximide blocked HSP-72 induction. Because heating causes intracellular acidification and increases in cAMP and [Ca2+]i, we studied the effect of pHi, cellular cAMP, and [Ca2+]i on HSP-72 induction. The reduction of pHi to 6.9 by acid loading did not affect the basal level of HSP-72 in unheated cells. Treatment with pertussis toxin, cholera toxin, or forskolin, but not 8-bromo-cAMP, 3-isobutyl-1-methylxanthine, or N-[2-(p-bromocinnamylamino)ethyl]-5-isoquinolinesulfonamide potentiated heat-induced HSP-72 production. Inhibition of the heat-induced increase in [Ca2+]i attenuated, but failed to completely block, heat-induced HSP-72 production, mRNA synthesis, and the heat-shock transcriptional factor-heat-shock element binding complex formation, which suggests there are Ca(2+)-dependent and -independent processes involved in HSP-72 synthesis. Our results show that an increase in [Ca2+]i or activation of G proteins, but not pHi and cAMP, enhances HSP-72 induction.

Peptide transporter-independent, stress protein-mediated endosomal processing of endogenous protein antigens for major histocompatibility complex class I presentation

The peptide transporter-defective cell line RMA-S expressing the wild-type simian virus 40 large T antigen (wtT-Ag) from a transfected gene did not present two well-defined, H-2 class I (Db)-restricted epitopes of T-Ag to cytotoxic T lymphocytes (CTL). Hence, "endogenous" processing and presentation of the wtT-Ag depended on a functional peptide transporter heterodimer. In contrast, both T-Ag epitopes were efficiently presented to CTL by transfected RMA-S cells expressing a truncated, cytoplasmic T-Ag variant (cT-Ag) or a karyophilic, amino-terminal 272-amino acid T-Ag fragment. Transporter-independent "endogenous" processing of mutant T-Ag molecules correlated with their association with the constitutively expressed heat shock protein 73 (hsp73). Class I-restricted presentation of both epitopes processed from these hsp73-associated protein antigens was sensitive to NH4Cl and chloroquine. These data indicate that selected intracellular proteins access an alternative, hsp73-mediated pathway for class I-restricted presentation that operates independent of peptide transporters in an endosomal compartment.

Analysis of HSF-1 phosphorylation in A549 cells treated with a variety of stresses

In the absence of stress, heat shock transcription factor-1 (HSF-1) exists as a monomer. After the treatment of cells with variety of stresses, HSF-1 forms a trimer and binds to the heat shock element (HSE), a motif consisting of three consecutive NGAAN sequences located in an inverted orientation upstream of the heat shock genes. HSF-1 is then phosphorylated causing transactivation of heat shock mRNAs. Treatment of cells with some of the stresses has been shown to increase HSF binding to HSE without detectably increasing the synthesis of heat shock mRNAs. Here we used antibody specific to HSF-1 to detect its phosphorylation status following exposure of A549, a human lung carcinoma cell line to a variety of stresses in order to correlate HSF-1 phosphorylation with its transactivation ability. Our studies show that HSF-1 is phosphorylated following heat shock (43 degrees C for 1 h), hypoxia (5 h exposure to 0.02% oxygen), 8% ethanol (1 h exposure at 37 degrees C), or 200 microM sodium arsenite (1 h exposure at 37 degrees C). All such stresses have previously been shown to increase the synthesis of heat shock proteins (hsps). However, there are no detectable increases in HSF-1 phosphorylation after the treatment of cells with X-irradiation (2-8 Gy) or 100 microM canavanine, an amino acid analogue (1 h exposure at 37 degrees C). Treatment of cells with X-irradiation increases HSF binding to HSE without increasing the synthesis of hsps, while treatment of cells with canavanine has been shown to increase the synthesis of hsps.(ABSTRACT TRUNCATED AT 250 WORDS)

Coordinated expression and mechanism of induction of HSP32 (heme oxygenase-1) mRNA by hyperthermia in rat organs

Heme oxygenase isozymes, HO-1 and HO-2, catalyze the cleavage of heme b (Fe-protoporphyrin-IX) at the alpha-meso carbon bridge to form the antioxidant, biliverdin IX alpha, and the putative cellular messenger, carbon monoxide. HO-1 is a heat shock (HSP32) or stress protein, while HO-2 is a noninducible enzyme. Presently, we have examined the time course of expression of HSP32 in liver, kidney, and heart of rats exposed to hyperthermia and investigated the mechanism of induction of HO-1 by hyperthermia. We report a coordinated induction response of all organs to elevated ambient temperature (42 degrees C, 20 min). Specifically, the maximum induction of the 1.8 kb HO-1 mRNA was observed 1 h after hyperthermia and reached a value 20-40-fold that of the control; the transcript level approximated the control value by 6 h after heat stress. In contrast, the levels and the ratio of the 1.3 and 1.9 kb HO-2 transcripts were not affected by hyperthermia. As judged by in vitro nuclear transcription run-on assays, thermal stress caused the stimulation of HO-1 gene transcription. The increase in HO-1 mRNA transcription was accompanied by an increase in binding of nuclear factor(s) to the heat shock element in the promoter region of the gene. The increase of the HO-1 mRNA was reflected in increases in both heme oxygenase activity and in immunoreactive HO-1 protein. We suggest that the induction of heme oxygenase by heat stress is a physiologically relevant defense mechanism whereby both the degradation of heme of denatured hemoproteins and the generation of biologically active products of heme catabolism are enhanced.

Inhibitors of tyrosine and Ser/Thr phosphatases modulate the heat shock response

Following heat shock the expression of heat shock genes is regulated by the heat shock transcription factor, HSF, known to bind to arrays of the heat shock element, NGAAN, upstream of the heat shock genes. Phosphorylation of HSF is necessary for its activation. We report that the treatment of Chinese hamster HA-1 cells with 250 nM of okadaic acid (OA), a ser/thr phosphatase inhibitor, leads to an increase in activated HSF after heat shock. This is followed by the activation of the transcription of heat shock genes as assayed by the increase in the synthesis of beta-galactosidase in an HA-1 cell line containing the heat shock promoter ligated to the beta-galactosidase gene. To investigate the specificity of OA, we used other phosphatase inhibitors. We found that treatment of HA-1 cells with 500 microM of sodium vanadate, an inhibitor of tyr/phosphatases, resulted in a three to fivefold reduction in HSF activation and binding to the heat shock element following heat shock. Such reduction in HSF activation virtually abolished beta-galactosidase induction. Reduced HSP synthesis was further confirmed by SDS-PAGE and Western blot analysis using anti-HSP-70 and 28 antibodies. Sodium vanadate treatment of heat shocked cells greatly reduced levels of thermotolerance. These results show that ser/thr and specifically tyr/phosphatase inhibitors modulate the signal transduction pathway of HSF activation.

MAP kinase activation during heat shock in quiescent and exponentially growing mammalian cells

In numerous cases of signal transduction, the mitogen-activated protein kinases (MAP kinases) or extracellular regulated kinases (ERKs) are found to be activated by phosphorylations which result in electrophoretic mobility changes. Activities of MAP kinases in cytosolic extracts can also be monitored by the capacity of such extracts to phosphorylate myelin basic protein. These two assays were used to demonstrate that MAP kinases were rapidly activated during heat shock of both quiescent and exponentially growing mammalian (hamster, rat, mouse and human) cells. Thus, the MAP kinase cascade is likely to also ensure heat-shock signal transduction and contribute to the regulation of the complex array of metabolic changes designated as the heat-shock response.