Regulation of heat shock transcription factor 1 by stress-induced SUMO-1 modification

Heat shock transcription factor 1 (HSF1) mediates the induction of heat shock protein gene expression in cells exposed to elevated temperature and other stress conditions. In response to stress HSF1 acquires DNA binding ability and localizes to nuclear stress granules, but the molecular mechanisms that mediate these events are not understood. We report that HSF1 undergoes stress-induced modification at lysine 298 by the small ubiquitin-related protein called SUMO-1. Antibodies against SUMO-1 supershift the HSF1 DNA-binding complex, and modification of HSF1 in a reconstituted SUMO-1 reaction system causes conversion of HSF1 to the DNA-binding form. HSF1 colocalizes with SUMO-1 in nuclear stress granules, which is prevented by mutation of lysine 298. Mutation of lysine 298 also results in a significant decrease in stress-induced transcriptional activity of HSF1 in vivo. This work implicates SUMO-1 modification as an important modulator of HSF1 function in response to stress.

Interaction between protein phosphatase 5 and the A subunit of protein phosphatase 2A: evidence for a heterotrimeric form of protein phosphatase 5

Members of the phosphoprotein phosphatase family of serine/threonine phosphatases are thought to exist in different native oligomeric complexes. Protein phosphatase 2A (PP2A) is composed of a catalytic subunit (PP2Ac) that complexes with an A subunit, which in turn also interacts with one of many B subunits that regulate substrate specificity and/or (sub)cellular localization of the enzyme. Another family member, protein phosphatase 5 (PP5), contains a tetratricopeptide repeat domain at its N terminus, which has been suggested to mediate interactions with other proteins. PP5 was not thought to interact with partners homologous to the A or B subunits that exist within PP2A. However, our results indicate that this may not be the case. A yeast two-hybrid screen revealed an interaction between PP5 and the A subunit of PP2A. This interaction was confirmed for endogenous proteins in vivo using immunoprecipitation analysis and for recombinant proteins by in vitro binding experiments. Our results also indicate that the tetratricopeptide repeat domain of PP5 is required and sufficient for this interaction. In addition, immunoprecipitated PP5 contains associated B subunits. Thus, our results suggest that PP5 can exist in a PP2A-like heterotrimeric form containing both A and B subunits.

Gonadotropins decrease estrogen receptor-beta messenger ribonucleic acid stability in rat granulosa cells

We have previously shown that the preovulatory LH surge down-regulates estrogen receptor-beta (ERbeta) messenger RNA (mRNA) levels selectively in the granulosa cells of preovulatory follicles. To gain insight into the underlying mechanisms, we examined whether the LH-induced loss of ERbeta mRNA expression in rat granulosa cells is attributable to the hormone-induced changes at the level of transcription and/or mRNA degradation. When the rate of ERbeta gene transcription was assessed in cultured granulosa cells, by nuclear run-off assays, we observed only a marginal effect of hCG on ERbeta gene transcription. In contrast, when ERbeta mRNA levels were estimated in granulosa cells that were cultured in the presence of 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), an RNA synthesis inhibitor, we observed a significant inhibitory effect of human CG (hCG) on ERbeta mRNA expression at a magnitude similar to that observed in the absence of DRB. Forskolin (FSK) and 2-O-tetradecanol-phorbol-13-acetate (TPA), pharmacological agents that mimic LH actions in granulosa cells, also showed similar effects. Thus, these results suggest that LH decreases ERbeta mRNA expression in the granulosa cells of preovulatory follicles, primarily by destabilizing the preexisting ERbeta mRNA. We next determined the decay rate of the ERbeta mRNA in granulosa cells that were cultured in the presence of DRB and additional hCG, FSK, or TPA for various time periods, by estimating ERbeta mRNA levels, using semiquantitative RT-PCR assays and subsequent linear regression analyses. The half-life of the ERbeta mRNA in the presence of vehicle was 17.87 +/- 1.2 h (n = 4). hCG dramatically decreased the half-life of the ERbeta mRNA (4.85 +/- 0.49 h, n = 4). Similarly, both FSK and TPA decreased the half-life of the ERbeta mRNA to 3.57 +/- 0.31 h and 4.02 +/- 0.13 h, respectively. We extended these findings by examining whether the LH-induced down-regulation of the ERbeta mRNA is cycloheximide-sensitive. When granulosa cells were cultured in the presence of cycloheximide, a protein synthesis inhibitor, the inhibitory effects of hCG, FSK, and TPA on ERbeta mRNA levels were abolished. Similar results were obtained in the presence or absence of DRB, indicating that the hormone-induced destabilization of the ERbeta mRNA is coupled with translation processes. Taken together, our results demonstrate that LH decreases ERbeta mRNA expression, predominantly at the posttranscriptional level, in a cycloheximide-sensitive manner.

Sumo-1 modification regulates the DNA binding activity of heat shock transcription factor 2, a promyelocytic leukemia nuclear body associated transcription factor

Heat shock transcription factor 2 (HSF2) is a transcription factor that regulates heat shock protein gene expression, but the mechanisms regulating the function of this factor are unclear. Here we report that HSF2 is a substrate for modification by the ubiquitin-related protein SUMO-1 and that HSF2 colocalizes in cells with SUMO-1 in nuclear granules. Staining with anti-promyelocytic leukemia antibodies indicates that these HSF2-containing nuclear granules are PML bodies. Our results identify lysine 82 as the major site of SUMO-1 modification in HSF2, which is located in a "wing" within the DNA-binding domain of this protein. Interestingly, SUMO-1 modification of HSF2 results in conversion of this factor to the active DNA binding form. This is the first demonstration that SUMO-1 modification can directly alter the DNA binding ability of a transcription factor and reveals a new mechanism by which SUMO-1 modification can regulate protein function.

Molecular basis of competition between HSF2 and catalytic subunit for binding to the PR65/A subunit of PP2A

We recently identified the existence of a novel interaction between heat shock transcription factor 2 (HSF2) and the PR65/A subunit of protein phosphatase 2A (PP2A) and showed that HSF2 is able to compete with the PP2A catalytic subunit for binding to PR65. To elucidate the mechanistic basis of this competition between HSF2 and catalytic subunit at the molecular level we have sought to characterize sequences within PR65 that are important for interaction with HSF2. The results identify the intra-repeat loop within HEAT repeat 11 of PR65 as critical for interaction with HSF2. Analysis of point mutants within this loop region of PR65 identify lysine 416 as a residue critical for interaction with HSF2. Interestingly, this same lysine residue of PR65 is important for its binding to catalytic subunit. These results suggest that HSF2's ability to interfere with catalytic subunit binding to PR65 is due to competition between HSF2 and catalytic subunit for at least one amino acid residue of PR65, lysine 416. These data support the hypothesis that HSF2 represents a new type of PP2A regulatory protein.

Age-related alterations in the activation of heat shock transcription factor 1 in rat hepatocytes

The induction of hsp70 transcription by heat shock is significantly reduced in hepatocytes isolated from old rats compared to hepatocytes isolated from young/adult rats, and the decline in hsp70 transcription is correlated with a decrease in the induction of heat shock transcription factor 1 (HSF1) binding to the heat shock element. However, the decreased HSF1 binding activity to DNA is not due to reduced levels of HSF1 that are available for activation by heat shock. In fact, the levels of HSF1 are two- to threefold higher in hepatocytes from old rats, and the age-related increase in the levels of HSF1 protein in hepatocytes appears to arise from a decrease in the degradation of the HSF1 because HSF1 mRNA levels do not change and the synthesis of HSF1 decreases approximately 50% with age. No evidence was found for an impairment in HSF1 oligomerization in hepatocytes from old rats, e.g., the level of HSF1 trimers, the nuclear translocation of HSF1, and the phosphorylation of HSF1 after heat shock are similar in hepatocytes isolated from young/adult and old rats. However, the thermostability of the DNA binding activity of HSF1 was significantly reduced with age in a cell-free system as well as in isolated hepatocytes.

Fine mapping of the friend retrovirus resistance gene, Rfv3, on mouse chromosome 15

Rfv3 is a host resistance gene that operates through an unknown mechanism to control the development of the virus-neutralizing antibody response required for recovery from infection with Friend retrovirus. The Rfv3 gene was previously mapped to an approximately 20-centimorgan (cM) region of chromosome 15. More refined mapping was not possible, due to a lack of microsatellite markers and leakiness in the Rfv3 phenotype, which prevented definitive phenotyping of individual recombinant mice. In the present study, we overcame these difficulties by taking advantage of seven new microsatellite markers in the Rfv3 region and by using progeny tests to accurately determine the Rfv3 phenotype of recombinant mice. Detailed linkage analysis of relevant crossovers narrowed the location of Rfv3 to a 0.83-cM region. Mapping of closely linked genes in an interspecific backcross panel allowed us to exclude two previous candidate genes, Ly6 and Wnt7b. These studies also showed for the first time that the Hsf1 gene maps to the Rfv3-linked cluster of genes including Il2rb, Il3rb, and Pdgfb. This localization of Rfv3 to a region of less than 1 cM now makes it feasible to attempt the cloning of Rfv3 by physical methods.

Regulation of protein phosphatase 2A activity by heat shock transcription factor 2

Heat shock transcription factor (HSF) mediates the stress-induced expression of heat shock protein genes (hsp). However, HSF is required for normal cell function even in the absence of stress and is important for cell cycle progression, but the mechanism that mediates these effects of HSF is unknown. Here, it is shown that a member of the HSF family, HSF2, interacts with the PR65 (A) subunit of protein phosphatase 2A (PP2A). HSF2 binding to PR65 blocks its interaction with the catalytic subunit, due to competition between HSF2 and catalytic subunit for the same binding site in PR65. In addition, overexpression of HSF2 stimulates PP2A activity in cells, indicating the relevance of HSF2 as a regulator of PP2A in vivo. These results identify HSF2 as a dual function protein, capable of regulating both hsp expression and PP2A activity. This could function as a mechanism by which hsp expression is integrated with the control of cell division or other PP2A-regulated pathways.

Regulation of HSF1 activation and Hsp expression in mouse tissues under physiological stress conditions

The studies described above illustrate several important points concerning the study of the cellular stress response. First, they indicate that there are important differences between the nature of the stress response observed in tumor cell lines and that of primary cells of mouse tissues. Therefore, caution should be exercised to avoid overextending and overinterpreting the results of studies using these cell lines until evidence can be obtained from in vivo studies on intact animals or primary cells of tissues. Second, they reveal the existence of cell-type-dependent differences between cell types of the same organism, thus potentially calling into question the supposed universal cytoprotective nature of the cellular stress response. Future studies can address this question by determining the underlying mechanisms that regulate these cell-type-dependent differences in the stress response, and by determining whether there are biological reasons that some cell types exhibit differences in either the temperature set-point or magnitude of the stress response.

Characterization of the stress-inducing effects of homocysteine

The mechanism by which homocysteine causes endothelial cell (EC) injury and/or dysfunction is not fully understood. To examine the stress-inducing effects of homocysteine on ECs, mRNA differential display and cDNA microarrays were used to evaluate changes in gene expression in cultured human umbilical-vein endothelial cells (HUVEC) exposed to homocysteine. Here we show that homocysteine increases the expression of GRP78 and GADD153, stress-response genes induced by agents or conditions that adversely affect the function of the endoplasmic reticulum (ER). Induction of GRP78 was specific for homocysteine because other thiol-containing amino acids, heat shock or H2O2 did not appreciably increase GRP78 mRNA levels. Homocysteine failed to elicit an oxidative stress response in HUVEC because it had no effect on the expression of heat shock proteins (HSPs) including HSP70, nor did it activate heat shock transcription factor 1. Furthermore homocysteine blocked the H2O2-induced expression of HSP70. In support of our findings in vitro, steady-state mRNA levels of GRP78, but not HSP70, were elevated in the livers of cystathionine beta-synthase-deficient mice with hyperhomocysteinaemia. These studies indicate that the activation of stress response genes by homocysteine involves reductive stress leading to altered ER function and is in contrast with that of most other EC perturbants. The observation that homocysteine also decreases the expression of the antioxidant enzymes glutathione peroxidase and natural killer-enhancing factor B suggests that homocysteine could potentially enhance the cytotoxic effect of agents or conditions known to cause oxidative stress.

Quercetin inhibits heat shock protein induction but not heat shock factor DNA-binding in human breast carcinoma cells

The flavonoid quercetin inhibits the heat-induced synthesis of heat shock proteins (hsps) in a variety of cell lines. To determine whether quercetin could inhibit hsp expression in breast cancer cells, we used the human breast cancer cell line, MDA-MB-231. Treatment of these cells with quercetin decreased the heat-induced synthesis of hsp27 and hsp70. However, inhibition of hsp expression did not correspond with the reduced ability of heat shock transcription factors (HSFs) to bind DNA. Furthermore, while quercetin treatment inhibited HSF2 expression, it only slightly affected HSF1 expression in breast cancer cells. In contrast, quercetin inhibited both HSF DNA-binding activity and HSF expression in HeLa cells. Our studies suggest that quercetin's action is cell-type specific, and in breast cancer cells may involve regulation of HSF transcriptional activity, rather than regulation of its DNA-binding activity.

Overexpression of HSF2-beta inhibits hemin-induced heat shock gene expression and erythroid differentiation in K562 cells

Acquisition of heat shock factor 2 (HSF2) DNA binding activity is accompanied by induced transcription of heat shock genes in hemin-treated K562 cells undergoing erythroid differentiation. Previous studies revealed that HSF2 consists of two alternatively spliced isoforms, HSF2-alpha and HSF2-beta, whose relative abundance is developmentally regulated and varies between different tissues. To investigate whether the molar ratio of HSF2-alpha and HSF2-beta isoforms is crucial for the activation of HSF2 and whether the HSF2 isoforms play functionally distinct roles during the hemin-mediated erythroid differentiation, we generated cell clones expressing different levels of HSF2-alpha and HSF2-beta. We show that in parental K562 cells, the HSF2-alpha isoform is predominantly expressed and HSF2 can be activated upon hemin treatment. In contrast, when HSF2-beta is expressed at levels exceeding those of endogenous HSF2-alpha, the hemin-induced DNA binding activity and transcription of heat shock genes are repressed, whereas overexpression of HSF2-alpha results in an enhanced hemin response. Furthermore, the hemin-induced accumulation of globin, known as a marker of erythroid differentiation, is decreased in cells overexpressing HSF2-beta. We suggest that HSF2-beta acts as a negative regulator of HSF2 activity during hemin-mediated erythroid differentiation of K562 cells.

Regulation of hsp expression during rodent spermatogenesis

Spermatogenesis is the process by which immature male germ cells, through a complex series of events involving mitosis, meiosis, and cellular differentiation, eventually become mature spermatozoa capable of fertilizing an ovum. This process involves the developmental progression of male germ cells through a number of spermatogenetic cell types, each of which is characterized by unique features of morphology, cellular associations, and specialized functions. The unique features of each germ cell type are dictated, to a large degree, by the patterns of protein expression characteristic of each cell type. This review will examine two different aspects of the regulated expression of heat shock proteins in spermatogenic cells. First, we will review studies showing that the expression of several different members of both the hsp70 as well as hsp90 families of heat shock proteins is regulated during the differentiation of these cells. Second, we will review studies which have examined the induction of hsp expression in spermatogenic cells following exposure to elevated temperatures. Next, we will review the role of the transcription factors, heat shock factor 1 (HSF1) and HSF2 in the regulation of expression of hsps in the testis. One interesting and unique function of the male reproductive system in many species is the maintenance of the testes at a temperature below that of the other tissues of the animal. The importance of precise thermoregulation of the testis is evidenced by the fact that even slight elevations of scrotal temperature are associated with infertility. The results of recent studies have suggested a potential involvement of the cellular stress response in the mechanism responsible for these inhibitory effects of elevated testis temperature on spermatogenesis. Possible mechanisms are discussed.

Characterization of hypothermia-induced cellular stress response in mouse tissues

Cells respond to adverse environmental conditions by expressing heat shock proteins, which serve to protect cells from harmful effects of the stress conditions. In this study we demonstrated that mice subjected to whole body hypothermia induced the cellular stress response, resulting in the increased expression of hsp72 mRNA in brain, heart, kidney, liver, and lung. We performed a detailed analysis of the major parameters of the stress response and found that cold induction of hsp expression is mediated by heat shock factor 1 (HSF1), which is also responsible for heat induction of the cellular stress response. However, there are differences in the mechanisms of HSF1 activation by hypothermia versus hyperthermia, as hypothermia does not cause the hyperphosphorylation of HSF1 that is characteristic of heat-activated HSF1.

Effect of caloric restriction on the expression of heat shock protein 70 and the activation of heat shock transcription factor 1

The regulation of heat shock protein 70 (hsp70) expression is an excellent example of a cellular mechanism that has evolved to protect all living organisms from various types of physiological stresses; therefore, the reported age-related alterations in the ability of cells to express hsp70 in response to stress could seriously compromise the ability of a senescent organism in respond to changes in its environment. Because caloric restriction (CR) is the only experimental manipulation known to retard aging and increase the survival of rodents, it was of interest to analyze the effect of CR on the age-related alteration in the induction of hsp70 expression in rat hepatocytes. The effect of CR on the nuclear transcription of hsp70 gene in rat hepatocytes in response to various levels of heat shock was determined, and it was found that the age-related decline in the transcription of hsp70 at all temperatures studied was reversed by CR. Because the heat shock transcription factor (HSF) mediates the heat-induced transcription of hsp70, the effect of CR on the induction of HSF binding activity by heat shock was studied and found to arise from HSF1, which has been shown to be involved in the induction of HSF binding activity in other cell types. The age-related decrease in the induction of HSF1 binding activity in rat hepatocytes was reversed by CR, and did not appear to be due to an accumulation of inhibitory molecules with age. Interestingly, the level of HSF1 protein was significantly higher in hepatocytes isolated from old rats fed ad libitum compared to hepatocytes obtained from rats fed the CR diet even though the levels of HSF1 binding activity were lower for hepatocytes isolated from the old rats fed ad libitum. The levels of the mRNA transcript for HSF1 was not significantly altered by age or CR. Thus, the changes in HSF1 binding activity with age and CR do not arise from changes in the level of HSF1 protein available for activation.

Cis-regulatory elements conferring cyclic 3',5'-adenosine monophosphate responsiveness of the progesterone receptor gene in transfected rat granulosa cells

We have previously shown that both pituitary gonadotropins and forskolin induce progesterone receptor (PR) messenger RNA expression at the level of transcription in granulosa cells of the rat ovary. To determine the DNA regulatory elements that are important for cAMP-induced transcription of the PR gene in the ovary, we examined the cAMP-induced activity of promoter sequences in rat granulosa cells transfected with various fusion constructs containing PRB promoter sequences linked to the luciferase reporter gene. When cells were transfected with a luciferase fusion construct containing the 1375-base pair 5'-flanking region of the rat PRB gene, forskolin treatment substantially increased luciferase activity. Analysis of a series of 5'-deletion mutants indicated that a minimal PRB promoter containing 116 base pairs of upstream sequence (-116/3) was sufficient to increase luciferase activity in response to forskolin in transfected rat granulosa cells. This promoter contains a consensus CCAAT site in reverse orientation (5'-ATTGG-3') and a consensus GC box (5'-GGGGCGGGCC-3'), but no known cAMP-responsive element. Site-specific mutation of the GC box notably decreased both basal and cAMP-induced activity of this minimal PRB promoter. In addition, site-specific mutation of the CCAAT binding site within this proximal promoter of the PRB gene substantially decreased cAMP-induced activity, but did not significantly affect the basal activity of this promoter. Either mutation alone failed to abolish cAMP inducibility. In contrast, double mutation of both the GC box and the CCAAT box completely abolished cAMP inducibility, suggesting that the GC box and the CCAAT box act together to mediate cAMP-induced transcription of the PRB gene. Gel shift analysis shows that the minimal PRB promoter sequences form multiple complexes with nuclear proteins of granulosa cells, all of which are specifically competed by oligonucleotides containing the GC box and the CCAAT box. Taken together, our results suggest a functional role for transcription factors binding the GC box and the CCAAT box in mediating cAMP-induced transcription of the rat PRB promoter in rat granulosa cells.

Tissue-dependent expression of heat shock factor 2 isoforms with distinct transcriptional activities

Heat shock factor 2 (HSF2) functions as a transcriptional regulator of heat shock protein gene expression in mammalian cells undergoing processes of differentiation and development. Our previous studies demonstrated high regulated expression and unusual constitutive DNA-binding activity of the HSF2 protein in mouse testes, suggesting that HSF2 functions to regulate heat shock protein gene expression in spermatogenic cells. The purpose of this study was to test whether HSF2 regulation in testes is associated with alterations in the HSF2 polypeptide expressed in testes relative to other mouse tissues. Our results show that mouse cells express not one but two distinct HSF2 proteins and that the levels of these HSF2 isoforms are regulated in a tissue-dependent manner. The testes express predominantly the 71-kDa HSF2-alpha isoform, while the heart and brain express primarily the 69-kDa HSF2-beta isoform. These isoforms are generated by alternative splicing of HSF2 pre-mRNA, which results in the inclusion of an 18-amino-acid coding sequence in the HSF2-alpha mRNA that is skipped in the HSF2-beta mRNA. HSF2 alternative splicing is also developmentally regulated, as our results reveal a switch in expression from the HSF2-beta mRNA isoform to the HSF2-alpha isoform during testis postnatal developmental. Transfection analysis shows that the HSF2-alpha protein, the predominant isoform expressed in testis cells, is a more potent transcriptional activator than the HSF2-beta isoform. These results reveal a new mechanism for the control of HSF2 function in mammalian cells, in which regulated alternative splicing is used to modulate HSF2 transcriptional activity in a tissue-dependent manner.

Male germ cell-specific alteration in temperature set point of the cellular stress response

Heat shock factor (HSF), a transcriptional regulator with heat-activatable DNA binding ability, mediates the stress-induced expression of eukaryotic heat shock protein genes. Previous results from this laboratory demonstrated that a preparation of mixed male germ cell types from mouse testis exhibited a lower temperature threshold for activation of HSF1 DNA binding relative to other mouse cell types (Sarge, K.D., Bray, A.E., and Goodson, M.L. (1995) Nature 374, 126). The purpose of the present study was to determine whether the phenomenon of reduced HSF1 activation temperature is common to all testis cell types, both somatic and germ cell types, or whether it is a special property of male germ cells. The results show that a purified population of pachytene spermatocytes, one of the male germ cell types, exhibits a profile of reduced HSF1 activation temperature identical to that observed for the mixed germ cell preparation, with a threshold HSF1 activation temperature of 35 degrees C. Activation of HSF1 DNA binding in male germ cells by incubation at 38 degrees C is accompanied by the classic cellular stress response parameters of heat-induced HSF1 phosphorylation and increased expression of the hsp72 stress protein. In contrast, a preparation of somatic testis cell types exhibits HSF1 activation only at temperatures of 42 degrees C and above, a profile identical to that observed for mouse liver cells and mammalian cell lines. These results demonstrate that the phenomenon of reduced HSF1 activation temperature is a unique property of male germ cell types within the mammalian testis and demonstrate that HSF1 activated at this lower temperature threshold is fully capable of mediating a productive cellular stress response in these cell types.

Regulated expression of heat shock factor 1 isoforms with distinct leucine zipper arrays via tissue-dependent alternative splicing

HSF1 mediates the stress induced expression of heat shock proteins, referred to as the cellular stress response. Previous results indicated that mammalian cells express two distinct HSF1 protein isoforms, with molecular sizes of 69 kDa (HSF1-beta) and 71 kDa (HSF1-alpha). The purpose of this study was to determine the mechanism by which these two HSF1 protein isoforms are generated. Our results show that mammalian cells express two distinct HSF1 mRNA isoforms which arise via alternative splicing of the HSF1 pre-mRNA. The two HSF1 mRNA isoforms differ by a single 66 bp exon of the HSF1 gene which is spliced into the HSF1-alpha mRNA isoform but skipped in the HSF1-beta mRNA isoform. This 66 bp exon encodes a 22 amino acid sequence, whose molecular weight (2.3 kDa) matches the difference in size between the HSF1-beta and HSF1-alpha protein isoforms (69 and 71 kDa). Further analysis reveals that this extra 22 amino acid sequence, whose insertion site in the HSF1-alpha isoform is located immediately adjacent to a C-terminal leucine zipper motif (leucine zipper 4) previously shown to be involved in maintenance of HSF1 in the non-DNA-binding control form, contains an additional, previously unidentified leucine zipper motif (leucine zipper 5). Our results also show that the levels of the two HSF1 isoforms are regulated in a tissue dependent manner, with testis expressing higher levels of the HSF1-beta isoform while heart and brain express higher levels of the HSF1-alpha isoform. These results demonstrate a new mechanism by which HSF1 expression is regulated in mammalian cells and suggest a potential role for the HSF1 isoforms in mediating tissue-dependent regulation of the cellular stress response.

Heat-inducible DNA binding of purified heat shock transcription factor 1

The heat-induced expression of heat shock proteins, called the cellular stress response, is mediated by heat shock transcription factor 1 (HSF1). HSF1 exists in unstressed cells in an inactive form, which is converted to the DNA binding from upon exposure of cells to elevated temperature. We have developed a protocol for isolation of the non-DNA binding form of recombinant mouse HSF1, involving expression and affinity purification of HSF1 as a fusion with the glutathione S-transferase protein in Escherichia coli, followed by specific protease cleavage to release pure HSF1 protein. We report here that the purified inactive HSF1 can be converted to the DNA binding form by heat treatment in vitro. Chemical cross-linking analysis demonstrates that this conversion is accompanied by oligomerization of HSF1 from a monomeric to a trimeric native structure, similar to that observed for HSF1 in heat-shocked cells. These results indicate that elements residing in the HSF1 polypeptide are sufficient both for maintenance of this factor in the non-DNA binding from and for its heat-induced conversion to the DNA binding form and support a role for HSF1 as the "molecular thermostat" in eukaryotic cells, which senses adverse environmental conditions and activates the cellular stress response.

Effects of neurohormonal stress and aging on the activation of mammalian heat shock factor 1

The mammalian heat shock response has been investigated extensively using tissue culture cells with only a limited amount of information available on animals and intact tissues. The neurohormonal stress response mediated by the hypothalamic-pituitary-adrenal axis leads to the activation of heat shock factor (HSF) in rat adrenal tissue. Here we show through the use of antibodies specific to each member of the HSF family that restraint-induced stress in intact Wistar rats and adrenocorticotropic hormone treatment of hypophysectomized animals leads to the activation of HSF1 monomers to trimers with DNA-binding activity. Because HSF1 is also the target factor for metabolic and environmental stress, these data reveal an intersection of pathways leading to HSF1 activation. Comparison of the biochemical properties and levels of HSF1 in the Wistar and Fischer 344 rat strains reveals that HSF1 is constitutively present in an activated DNA-binding state in the adrenals of Fischer 344 rats. During aging, the levels of HSF1 remain constant, yet the transcription factor from aged animals exhibits a decreased ability to bind DNA.

Deficient induction of human hsp70 heat shock gene transcription in Y79 retinoblastoma cells despite activation of heat shock factor 1

One of the basic features of the inducible heat shock response is the activation of heat shock factor which results in the rapid transcriptional induction of the heat shock genes. Although it is widely considered that the heat shock response is ubiquitous, several reports have indicated that the transcriptional response can vary in both intensity and kinetics and often in a tissue-specific manner. Of interest have been studies on the expression of heat shock genes in the brain, particularly observations that certain cultured neuronal cells exhibit a diminished heat shock response. We demonstrate that transcription of the gene encoding a 70-kDa heat shock protein (hsp70) is diminished upon heat shock in Y79 human retinoblastoma cells (which are of neuronal origin) despite both the activation of heat shock factor 1 and induced transcription of another heat shock gene, hsp90 alpha. This uncoupling of stress-induced transcription of the hsp70 and hsp90 alpha genes, which are typically coordinately regulated in response to stress, appears to be due to the selective inability of trans-acting factors, including heat shock factor 1, to bind in vivo to the hsp70 promoter as the result of a chromatin-mediated effect.

Characterization of constitutive HSF2 DNA-binding activity in mouse embryonal carcinoma cells

Two distinct murine heat shock transcription factors, HSF1 and HSF2, have been identified. HSF1 mediates the transcriptional activation of heat shock genes in response to environmental stress, while the function of HSF2 is not understood. Both factors can bind to heat shock elements (HSEs) but are maintained in a non-DNA-binding state under normal growth conditions. Mouse embryonal carcinoma (EC) cells are the only mammalian cells known to exhibit HSE-binding activity, as determined by gel shift assays, even when maintained at normal physiological temperatures. We demonstrate here that the constitutive HSE-binding activity present in F9 and PCC4.aza.R1 EC cells, as well as a similar activity found to be present in mouse embryonic stem cells, is composed predominantly of HSF2. HSF2 in F9 EC cells is trimerized and is present at higher levels than in a variety of nonembryonal cell lines, suggesting a correlation of these properties with constitutive HSE-binding activity. Surprisingly, transcription run-on assays suggest that HSF2 in unstressed EC cells does not stimulate transcription of two putative target genes, hsp70 and hsp86. Genomic footprinting analysis indicates that HSF2 is not bound in vivo to the HSE of the hsp70 promoter in unstressed F9 EC cells, although HSF2 is present in the nucleus and the promoter is accessible to other transcription factors and to HSF1 following heat shock. Thus trimerization and nuclear localization of HSF2 do not appear to be sufficient for in vivo binding of HSF2 to the HSE of the hsp70 promoter in unstressed F9 EC cells.

Expression of heat shock factor 2 in mouse testis: potential role as a regulator of heat-shock protein gene expression during spermatogenesis

We have examined the expression and function of heat shock transcription factor 2 (HSF2) in spermatogenic cells of mouse testis. The results of in situ RNA hybridization analysis, RNA filter hybridization, and reverse transcription-polymerase chain reaction (RT-PCR) analysis indicate that HSF2 mRNA expression in testis is subject to developmental and cell type-dependent, as well as stage-dependent, regulation. Localized expression of HSF2 mRNA in testis first appears between Day 14 and Day 21 of postnatal development. In adult testis, HSF2 mRNA is found at highest levels in spermatocytes and round spermatids. Immunocytochemical staining and gel mobility shift analysis demonstrate that HSF2 protein is localized to the nuclei of spermatocytes and round spermatids and that this transcription factor exists in testis in a constitutively active DNA-binding state. We further demonstrate that the constitutive HSF2 DNA-binding activity present in testis is able to interact with promoter sequences of the hsp70.2 gene, a testis-specific member of the hsp70 gene family. Taken together, our results show that the expression and functional properties of HSF2 are regulated in spermatogenic cell types of the mouse testis, supporting a role for this transcription factor as a regulator of hsp gene expression during spermatogenesis.

Arachidonate is a potent modulator of human heat shock gene transcription

Cell and tissue injury activate the inflammatory response through the action(s) of arachidonic acid and its metabolites, leading to the expression of acute-phase proteins and inflammatory cytokines. At the molecular level, little is known how arachidonic acid regulates the inflammatory response. As inflammation is also associated with local increase in tissue temperatures, we examined whether arachidonic acid was directly involved in the heat shock response. Extracellular exposure to arachidonic acid induced heat shock gene transcription in a dose-dependent manner via acquisition of DNA-binding activity and phosphorylation of heat shock factor 1 (HSF1). In addition, exposure of cells to low concentrations of arachidonic acid, which by themselves did not induce HSF1 DNA-binding activity, reduced the temperature threshold for HSF1 activation from elevated temperatures which are not physiologically relevant (> 42 degrees C) to temperatures which can be attained during the febrile response (39-40 degrees C). These results indicate that elevated heat shock gene expression is a direct consequence of an arachidonic acid-mediated cellular response.

Human heat shock factors 1 and 2 are differentially activated and can synergistically induce hsp70 gene transcription

Two members of the heat shock transcription factor (HSF) family, HSF1 and HSF2, both function as transcriptional activators of heat shock gene expression. However, the inducible DNA-binding activities of these two factors are regulated by distinct pathways. HSF1 is activated by heat shock and other forms of stress, whereas HSF2 is activated during hemin-induced differentiation of human K562 erythroleukemia cells, suggesting a role for HSF2 in regulating heat shock gene expression under nonstress conditions such as differentiation and development. To understand the distinct regulatory pathways controlling HSF2 and HSF1 activities, we have examined the biochemical and physical properties of the control and activated states of HSF2 and compared these with the properties of HSF1. Our results reveal that the inactive, non-DNA-binding forms of HSF2 and HSF1 exist primarily in the cytoplasm of untreated K562 cells as a dimer and monomer, respectively. This difference in the control oligomeric states suggests that the mechanisms used to control the DNA-binding activities of HSF2 and HSF1 are distinct. Upon activation, both factors acquire DNA-binding activity, oligomerize to a trimeric state, and translocate into the nucleus. Interestingly, we find that simultaneous activation of both HSF2 and HSF1 in K562 cells subjected to hemin treatment followed by heat shock results in the synergistic induction of hsp70 gene transcription, suggesting a novel level of complex regulation of heat shock gene expression.

Mouse heat shock transcription factors 1 and 2 prefer a trimeric binding site but interact differently with the HSP70 heat shock element

To understand the function of multiple heat shock transcription factors in higher eukaryotes, we have characterized the interaction of recombinant mouse heat shock transcription factors 1 and 2 (mHSF1 and mHSF2) with their binding site, the heat shock element (HSE). For our analysis, we utilized the human HSP70 HSE, which consists of three perfect 5'-nGAAn-3' sites (1, 3, and 4) and two imperfect sites (2 and 5) arranged as tandem inverted repeats. Recombinant mHSF1 and mHSF2, which exist as trimers in solution, both bound specifically to this HSE and stimulated transcription of a human HSP70-CAT construct in vitro. Footprinting analyses revealed differential binding of mHSF1 and mHSF2 to the HSP70 HSE. Specifically, mHSF1 bound all five pentameric sites, whereas mHSF2 failed to interact with the first site of the HSE but bound to sites 2 to 5. Missing-nucleoside analysis demonstrated that the third and fourth nGAAn sites were essential for mHSF1 and mHSF2 binding. The binding of the initial mHSF1 trimer to the HSE exhibited preference for sites 3, 4, and 5, and then binding of a second trimer occurred at sites 1 and 2. These results suggest that HSF may recognize its binding site through the dyad symmetry of sites 3 and 4 but requires an adjacent site for stable interaction. Our data demonstrate that mHSF1 and mHSF2 bind specifically to the HSE through major groove interactions. Methidiumpropyl-EDTA footprinting revealed structural differences in the first and third repeats of the HSE, suggesting that the DNA is distorted in this region. The possibility that the HSE region is naturally distorted may assist in understanding how a trimer of HSF can bind to what is essentially an inverted repeat binding site.

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

The existence of multiple heat shock factor (HSF) genes in higher eukaryotes has promoted questions regarding the functions of these HSF family members, especially with respect to the stress response. To address these questions, we have used polyclonal antisera raised against mouse HSF1 and HSF2 to examine the biochemical, physical, and functional properties of these two factors in unstressed and heat-shocked mouse and human cells. We have identified HSF1 as the mediator of stress-induced heat shock gene transcription. HSF1 displays stress-induced DNA-binding activity, oligomerization, and nuclear localization, while HSF2 does not. Also, HSF1 undergoes phosphorylation in cells exposed to heat or cadmium sulfate but not in cells treated with the amino acid analog L-azetidine-2-carboxylic acid, indicating that phosphorylation of HSF1 is not essential for its activation. Interestingly, HSF1 and HSF2 overexpressed in transfected 3T3 cells both display constitutive DNA-binding activity, oligomerization, and transcriptional activity. These results demonstrate that HSF1 can be activated in the absence of physiological stress and also provide support for a model of regulation of HSF1 and HSF2 activity by a titratable negative regulatory factor.

Transcriptional regulation of heat shock genes. A paradigm for inducible genomic responses

The heat shock response offers an ideal paradigm to understand how the cell recognizes and responds to acute and chronic exposures to environmental and physiological stress. Of the numerous inducible genomic responses, the heat shock response has contributed fascinating insights into the molecular and cellular mechanisms of adaptation, ranging from the regulation of heat shock gene expression to the function of stress proteins. The recent cloning of multiple heat shock transcription factor (HSF) genes in higher eukaryotes and studies on the biochemical and cellular properties of HSFs have revealed several novel features of the transcriptional response.

Activation of heat shock factor 2 during hemin-induced differentiation of human erythroleukemia cells

Hemin induces nonterminal differentiation of human K562 erythroleukemia cells, which is accompanied by the expression of certain erythroid cell-specific genes, such as the embryonic and fetal globins, and elevated expression of the stress genes hsp70, hsp90, and grp78/BiP. Previous studies revealed that, as during heat shock, transcriptional induction of hsp70 in hemin-treated cells is mediated by activation of heat shock transcription factor (HSF), which binds to the heat shock element (HSE). We report here that hemin activates the DNA-binding activity of HSF2, whereas heat shock induces predominantly the DNA-binding activity of a distinct factor, HSF1. This constitutes the first example of HSF2 activation in vivo. Both hemin and heat shock treatments resulted in equivalent levels of HSF-HSE complexes as analyzed in vitro by gel mobility shift assay, yet transcription of the hsp70 gene was stimulated much less by hemin-induced HSF than by heat shock-induced HSF. Genomic footprinting experiments revealed that hemin-induced HSF and heat shock-induced HSF, HSF2, and HSF1, respectively, occupy the HSE of the human hsp70 promoter in a similar yet not identical manner. We speculate that the difference in occupancy and/or in the transcriptional abilities of HSF1 and HSF2 accounts for the observed differences in the stimulation of hsp70 gene transcription.

Evidence for a Competitive-Displacement Model for the initiation of protein synthesis involving the intermolecular hybridization of 5 S rRNA, 18 S rRNA and mRNA

We have previously shown that a 5'-terminal region of mouse 5 S rRNA can base-pair in vitro with two distinct regions of 18 S rRNA. Further analysis reveals that these 5 S rRNA-complementary sequences in 18 S rRNA also exhibit complementarity to the Kozak consensus sequence surrounding the mRNA translational start site. To test the possibility that these 2 regions in 18 S rRNA may be involved in mRNA binding and translational initiation, we have tested, using an in vitro translation system, the effects of DNA oligonucleotides complementary to these 18 S rRNA sequences on protein synthesis. Results show that an oligonucleotide complementary to one 18 S rRNA region does inhibit translation at the step of initiation. We propose a Competitive-Displacement Model for the initiation of translation involving the intermolecular base-pairing of 5 S rRNA, 18 S rRNA and mRNA.

Cloning and characterization of two mouse heat shock factors with distinct inducible and constitutive DNA-binding ability

We have cloned two distinct mouse heat shock transcription factor genes, mHSF1 and mHSF2. The mHSF1 and mHSF2 open reading frames are similar in size, containing 503 and 517 amino acids, respectively. Although mHSF1 and mHSF2 are quite divergent overall (only 38% identity), they display extensive homology in the DNA-binding and oligomerization domains that are conserved in the heat shock factors of Saccharomyces cerevisiae, Kluyveromyces lactis, Drosophila, tomato, and human. The ability of these two mouse heat shock factors to bind to the heat shock element (HSE) is regulated by heat. mHSF1 is expressed in an in vitro translation system in an inactive form that is activated to DNA binding by incubation at temperatures greater than 41 degrees C, the same temperatures that activate heat shock factor DNA binding and the stress response in mouse cells in vivo. mHSF2, on the other hand, is expressed in a form that binds DNA constitutively but loses DNA binding by incubation at greater than 41 degrees C. Both mHSF1 and mHSF2 are encoded by single-copy genes, and neither is transcriptionally regulated by heat shock. However, there is a striking difference in the levels of mHSF1 mRNA in different tissues of the mouse.

Intermolecular hybridization of 5S rRNA with 18S rRNA: identification of a 5'-terminally-located nucleotide sequence in mouse 5S rRNA which base-pairs with two specific complementary sequences in 18S rRNA

Eukaryotic 5S rRNA hybridizes specifically with 18S rRNA in vitro to form a stable intermolecular RNA:RNA hybrid. We have used 5S rRNA/18S rRNA fragment hybridization studies coupled with ribonuclease digestion and primer extension/chain termination analysis of 5S rRNA:18S rRNA hybrids to more completely map those mouse 5S rRNA and 18S rRNA sequences responsible for duplex formation. Fragment hybridization analysis has defined a 5'-terminal region of 5S rRNA (nucleotides 6-27) which base-pairs with two independent sequences in 18S rRNA designated Regions 1 (nucleotides 1157-1180) and 2 (nucleotides 1324-1339). Ribonuclease digestion of isolated 5S rRNA:18S rRNA hybrids with both single-strand- and double-strand-specific nucleases supports the involvement of this 5'-terminal 5S rRNA sequence in 18S rRNA hybridization. Primer extension/chain termination analysis of isolated 5S rRNA:18S rRNA hybrids confirms the base-pairing of 5S rRNA to the designated Regions 1 and 2 of 18S rRNA. Using these results, 5S rRNA:18S rRNA intermolecular hybrid structures are proposed. Comparative sequence analysis revealed the conservation of these hybrid structures in higher eukaryotes and the same but smaller core hybrid structures in lower eukaryotes and prokaryotes. This suggests that the 5S rRNA:16S/18S rRNA hybrids have been conserved in evolution for ribosome function.

In vitro activation of heat shock transcription factor DNA-binding by calcium and biochemical conditions that affect protein conformation

The transcription of heat shock genes in response to physiological stress requires activation of heat shock transcription factor (HSF). Although the transcriptional response is most commonly induced by temperature elevation, the biochemical events involved in HSF activation in vivo can also be triggered at normal physiological temperatures by chemicals that inhibit metabolic processes. We have used a HeLa cell-free system in which HSF DNA-binding is activated by conditions that affect protein conformation, including increasing concentrations of hydrogen ions, urea, or nonionic detergents. Treatment with calcium ions also results in a concentration- and time-dependent activation of HSF in vitro. Pretreatment with each of these biochemical conditions reduces the temperature dependence for HSF activation in vitro. These results suggest that HSF is activated either directly by undergoing a conformational change or indirectly through interactions with unfolded proteins.

A simple and rapid method for the preparation of homologous DNA oligonucleotide hybridization probes from heterologous gene sequences and probes

We describe a simple and rapid method for the preparation of homologous DNA oligonucleotide probes for hybridization analysis and/or cDNA/genomic library screening. With this method, a synthetic DNA oligonucleotide derived from a known heterologous DNA/RNA/protein sequence is annealed to an RNA preparation containing the gene transcript of interest. Any unpaired 3'-terminal oligonucleotides of the heterologous DNA primer are then removed using the 3' exonuclease activity of the DNA Polymerase I Klenow fragment before primer extension/dideoxynucleotide sequencing of the annealed RNA species with AMV reverse transcriptase. From the determined RNA sequence, a completely homologous DNA oligonucleotide probe is then prepared. This approach has been used to prepare a homologous DNA oligonucleotide probe for the successful library screening of the yeast hybRNA gene starting with a heterologous mouse hybRNA DNA oligonucleotide probe.