Showing papers on "Heat shock protein published in 1994"

The Biology of heat shock proteins and molecular chaperones.

Abstract: In contrast to such “shocks” for which the genome is unprepared, are those a genome must face repeatedly, and for which it is prepared to respond in a programmed manner. Examples are the “heat shock” responses in eukaryotic organisms, and the “SOS” responses in bacteria. Each of these initiates a highly programmed sequence of events within the cell that serves to cushion the effects of the shock. Some sensing mechanism must be present in these instances to alert the cell to imminent danger, and to set in motion the orderly sequence of events that will mitigate this danger. The responses of genomes to unanticipated challenges are not so precisely programmed. Nevertheless, these are sensed, and the genome responds in a discernible but initially unforeseen manner. Barbara McClintock–Nobel lecture , 8 December 1983 These prophetic words by Barbara McClintock eloquently capture the essence of the heat shock response. At the time these words were written, it was known that all organisms shared a common response to physiological stress. Some of the genes encoding heat shock proteins had just been cloned and the basis of heat shock gene regulation was in the early stages of investigation. However, the function of the heat shock response and the role of heat shock proteins were still a mystery. This mystery slowly began to unravel, and by the 1980s, some information on the function of the heat shock proteins as proteases or unfolded polypeptide-binding proteins had already accumulated. These early stages of elucidation of the biochemical...

Protein disaggregation mediated by heat-shock protein Hsp104.

Abstract: The heat-inducible members of the Hsp100 (or Clp) family of proteins share a common function in helping organisms to survive extreme stress, but the basic mechanism through which these proteins function is not understood. Hsp104 protects cells against a variety of stresses, under many physiological conditions, and its function has been evolutionarily conserved, at least from Saccharomyces cerevisiae to Arabidopsis thaliana. Homology with the Escherichia coli ClpA protein suggests that Hsp104 may provide stress tolerance by helping to rid the cell of heat-denatured proteins through proteolysis. But genetic analysis indicates that Hsp104 may function like Hsp70 as a molecular chaperone. Here we investigate the role of Hsp104 in vivo using a temperature-sensitive Vibrio harveyi luciferase-fusion protein as a test substrate. We find that Hsp104 does not protect luciferase from thermal denaturation, nor does it promote proteolysis of luciferase. Rather, Hsp104 functions in a manner not previously described for other heat-shock proteins: it mediates the resolubilization of heat-inactivated luciferase from insoluble aggregates.

Hypoxia induces accumulation of p53 protein, but activation of a G1-phase checkpoint by low-oxygen conditions is independent of p53 status.

Abstract: It has been convincingly demonstrated that genotoxic stresses cause the accumulation of the tumor suppressor gene p53. One important consequence of increased p53 protein levels in response to DNA damage is the activation of a G1-phase cell cycle checkpoint. It has also been shown that G1-phase cell cycle checkpoints are activated in response to other stresses, such as lack of oxygen. Here we show that hypoxia and heat, agents that induce cellular stress primarily by inhibiting oxygen-dependent metabolism and denaturing proteins, respectively, also cause an increase in p53 protein levels. The p53 protein induced by heat is localized in the cytoplasm and forms a complex with the heat shock protein hsc70. The increase in nuclear p53 protein levels and DNA-binding activity and the induction of reporter gene constructs containing p53 binding sites following hypoxia occur in cells that are wild type for p53 but not in cells that possess mutant p53. However, unlike ionizing radiation, the accumulation of cells in G1 phase by hypoxia is not strictly dependent on wild-type p53 function. In addition, cells expressing the human papillomavirus E6 gene, which show increased degradation of p53 by ubiquitination and fail to accumulate p53 in response to DNA-damaging agents, do increase their p53 levels following heat and hypoxia. These results suggest that hypoxia is an example of a "nongenotoxic" stress which induces p53 activity by a different pathway than DNA-damaging agents.

Heat-shock proteins as molecular chaperones.

Abstract: Functional proteins within cells are normally present in their native, completely folded form. However, vital processes of protein biogenesis such as protein synthesis and translocation of proteins into intracellular compartments require the protein to exist temporarily in an unfolded or partially folded conformation. As a consequence, regions buried when a polypeptide is in its native conformation become exposed and interact with other proteins causing protein aggregation which is deleterious to the cell. To prevent aggregation as proteins become unfolded, heat-shock proteins protect these interactive surfaces by binding to them and facilitating the folding of unfolded or nascent polypeptides. In other instances the binding of heat-shock proteins to interactive surfaces of completely folded proteins is a crucial part of their regulation. As heat shock and other stress conditions cause cellular proteins to become partially unfolded, the ability of heat-shock proteins to protect cells against the adverse effects of stress becomes a logical extension of their normal function as molecular chaperones.

Heat shock proteins transfer peptides during antigen processing and CTL priming

Abstract: Recently emerging evidence indicates that the heat shock proteins (HSPs) gp96, hsp90, and hsp70 associate with antigenic peptides derived from cellular proteins. This evidence forms the basis of the following two hypotheses: 1) that HSPs constitute a relay line in which the peptides, after generation in the cytosol by the action of proteases, are transferred from one HSP to another, until they are finally accepted by MHC class I molecules in the endoplasmic reticulum, and 2) that the binding of peptides by HSPs constitutes a key step in the priming of cytotoxic T lymphocytes (CTLs) in vivo. The following chain of events is suggested: HSPs are released from virus-infected cells or tumor cells in vivo during lysis of cells during infection or by the action of antibodies or nonspecific effectors. The HSPs, which are now complexed with antigenic peptides derived from the cognate cells, are taken up by macrophage or other specialized antigen-presenting cells, possibly by a receptor-mediated mechanism. The HSP-borne peptide is then routed to the endogenous presentation pathway in the antigen-presenting cell and is displayed in the context of that cell's MHC class I, where it is finally recognized by the precursor CTLs. Thus it is suggested that, as with antigen presentation by MHC class II molecules, presentation by MHC class I molecules is also carried out primarily by the host antigen-presenting cells. This mechanism explains the phenomenon of cross-priming and has implications for the development of immunological strategies against cancer and infectious diseases.

Comparison of tumor-specific immunogenicities of stress-induced proteins gp96, hsp90, and hsp70.

Abstract: Stress-induced proteins (or heat shock proteins (HSPs)) of 96 kDa size (gp96) have been shown previously to elicit specific immunity to tumors from which they are isolated. In this report, we show that in contrast to Meth A-derived gp96, gp96 preparations derived from normal tissues did not elicit immunity to Meth A sarcoma at any dose tested. Further, in light of recent studies showing that other major cellular HSPs hsp90 and hsp70 also elicit tumor-specific immunity, we have compared the relative immunogenicities of gp96, hsp90, and hsp70 derived from the Meth A sarcoma. The proteins gp96 and hsp70 were observed to be highly and equally immunogenic, whereas the immunogenicity of hsp90 was approximately 10% of that of gp96 or hsp70. It is suggested that the poor immunogenicity of hsp90 results from its lack of a measurable ATPase activity, which has been implicated in the ability of HSPs to transfer peptide to acceptor molecules. This is the first study that documents the lack of immunogenicity of gp96 preparations derived from normal tissues and compares the immunogenicity of each of the three major cellular HSPs in one tumor system.

Cellular requirements for tumor-specific immunity elicited by heat shock proteins: Tumor rejection antigen gp96 primes CD8+ T cells in vivo

Abstract: Purified preparations of 96-kDa heat shock proteins (gp96) have been previously shown to elicit tumor-specific immunity to the tumor from which gp96 is obtained but not to antigenically distinct chemically induced tumors. The cellular requirements of gp96-elicited immunity have been examined. It is observed that depletion of CD8+, but not CD4+, T cells in the priming phase abrogates the immunity elicited by gp96. The CD8+ T cells elicited by immunization with gp96 are active at least up to 5 weeks after immunization. Depletion of macrophages by treatment of mice with carrageenan during the priming phase also results in loss of gp96-elicited immunity. In the effector phase, all three compartments, CD4+ and CD8+ T cells and macrophages, are required. Immunity elicited by whole irradiated tumor cells shows a different profile of cellular requirements. In contrast to immunization with gp96, depletion of CD4+, but not CD8+, T cells during priming with whole tumor cells abrogates tumor immunity. Further, ablation of macrophage function during priming or effector phases has no effect on tumor immunity elicited by whole cells. Our results suggest the existence of a macrophage-dependent and a macrophage-independent pathway of tumor immunity. Our observations also show that in spite of exogenous administration, vaccination with gp96 preparations elicits a CD8+ T-cell response in vivo, and it is therefore a useful method of vaccination against cancer and infectious diseases.

Analysis of the induction of general stress proteins of Bacillus subtilis.

Abstract: In Bacillus subtilis stress proteins are induced in response to different environmental conditions such as heat shock, salt stress, glucose and oxygen limitation or oxidative stress. These stress proteins have been previously grouped into general stress proteins (Gsps) and heat-specific stress proteins (Hsps). In this investigation the N-terminal sequences of 13 stress proteins of B. subtilis were determined. The quantification of the mRNA and the analysis of the protein synthesis pattern support the initial hypothesis that the chaperones DnaK and GroEL are Hsps in B. subtilis. In contrast, the recently described proteins GsiB, Ctc and RsbW belong to a class of Gsps that are induced by various stresses including heat shock. The main part of the Gsps described in this study failed to be induced in the sigB deletion mutant ML6 in response to heat shock. However, all the five Hsps were induced in this mutant in response to heat shock. These data indicate that SigB plays a crucial role in the induction of general stress genes, but is dispensable for the induction of Hsps.

A molecular chaperone, ClpA, functions like DnaK and DnaJ

Abstract: The two major molecular chaperone families that mediate ATP-dependent protein folding and refolding are the heat shock proteins Hsp60s (GroEL) and Hsp70s (DnaK). Clp proteins, like chaperones, are highly conserved, present in all organisms, and contain ATP and polypeptide binding sites. We discovered that ClpA, the ATPase component of the ATP-dependent ClpAP protease, is a molecular chaperone. ClpA performs the ATP-dependent chaperone function of DnaK and DnaJ in the in vitro activation of the plasmid P1 RepA replication initiator protein. RepA is activated by the conversion of dimers to monomers. We show that ClpA targets RepA for degradation by ClpP, demonstrating a direct link between the protein unfolding function of chaperones and proteolysis. In another chaperone assay, ClpA protects luciferase from irreversible heat inactivation but is unable to reactivate luciferase.

Induction of apoptosis by quercetin: involvement of heat shock protein.

Abstract: Quercetin, a widely distributed bioflavonoid, inhibits the growth of tumor cells. The present study was designed to investigate the possible involvement of apoptosis and heat shock protein in the antitumor activity of quercetin. Treatment with quercetin of K562, Molt-4, Raji, and MCAS tumor cell lines resulted in morphological changes, including propidium iodide-stained condensed nuclei (intact or fragmented), condensation of nuclear chromatin, and nuclear fragmentation. Agarose gel electrophoresis of quercetin-treated tumor cells demonstrated a typical ladder-like pattern of DNA fragments. In addition, the hypodiploid DNA peak of propidium iodide-stained nuclei was revealed by flow cytometry. Quercetin induced apoptosis in cells at G1 and S in a dose- and time-dependent manner. The apoptosis-inducing activity of quercetin was enhanced by cycloheximide and actinomycin D. A nuclease inhibitor, aurintricarboxylic acid, inhibited quercetin-induced apoptosis, whereas deprivation of intracellular calcium by EGTA had no effect. 12-O-Tetradecanoylphorbol-13-acetate and H-7 did not affect the induction of apoptosis by quercetin. The synthesis of HSP70 was inhibited by quercetin when determined by immunocytochemistry, Western blot analysis, and Northern blot analysis. Quercetin-treated tumor cells were not induced to show aggregation of HSP70 in the nuclei and nucleolus in response to heat shock, resulting in apoptosis. By contrast, when tumor cells were first exposed to heat shock, no apoptosis was induced by quercetin. In addition, pretreatment of tumor cells with HSP70 antisense oligomer that specifically inhibited the synthesis of HSP70 enhanced the subsequent induction of apoptosis by quercetin. These results suggest that quercetin displays antitumor activity by triggering apoptosis and that HSP70 may affect quercetin-induced apoptosis.

1 Progress and Perspectives on the Biology of Heat Shock Proteins and Molecular Chaperones

Abstract: In contrast to such “shocks” for which the genome is unprepared, are those a genome must face repeatedly, and for which it is prepared to respond in a programmed manner. Examples are the “heat shock” responses in eukaryotic organisms, and the “SOS” responses in bacteria. Each of these initiates a highly programmed sequence of events within the cell that serves to cushion the effects of the shock. Some sensing mechanism must be present in these instances to alert the cell to imminent danger, and to set in motion the orderly sequence of events that will mitigate this danger. The responses of genomes to unanticipated challenges are not so precisely programmed. Nevertheless, these are sensed, and the genome responds in a discernible but initially unforeseen manner. Barbara McClintock–Nobel lecture , 8 December 1983 These prophetic words by Barbara McClintock eloquently capture the essence of the heat shock response. At the time these words were written, it was known that all organisms shared a common response to physiological stress. Some of the genes encoding heat shock proteins had just been cloned and the basis of heat shock gene regulation was in the early stages of investigation. However, the function of the heat shock response and the role of heat shock proteins were still a mystery. This mystery slowly began to unravel, and by the 1980s, some information on the function of the heat shock proteins as proteases or unfolded polypeptide-binding proteins had already accumulated. These early stages of elucidation of the biochemical...

Induction of the heat shock response reduces mortality rate and organ damage in a sepsis-induced acute lung injury model

Abstract: ObjectiveTo test the hypothesis that induction of heat shock proteins before the onset of sepsis could prevent or reduce organ injury and death in a rat model of intra-abdominal sepsis and sepsis-induced acute lung injury produced by cecal ligation and perforationDesignProspective, blind, randomize

CIRCE, a novel heat shock element involved in regulation of heat shock operon dnaK of Bacillus subtilis.

Abstract: The dnaK and groESL operons of Bacillus subtilis are preceded by a potential sigma 43 promoter sequence (recognized by the vegetative sigma factor) and by an inverted repeat (IR) consisting of 9 bp separated by a 9-bp spacer. Since this IR has been found in many bacterial species, we suspected that it might be involved in heat shock regulation. In order to test this hypothesis, three different mutational alterations of three bases were introduced within the IR preceding the dnaK operon. These mutations were crossed into the chromosome of B. subtilis, and expression of the dnaK and of the unlinked groESL operons was studied. The dnaK operon exhibited increased expression at low temperature and a reduction in the stimulation after temperature upshift. Furthermore, these mutations reduced expression of the groESL operon at low temperature by 50% but did not interfere with stimulation after heat shock. These experiments show that the IR acts as a negative cis element of the dnaK operon. This conclusion was strengthened by the observation that the IR reduced expression of two different transcriptional fusions significantly after its insertion between the promoter and the reporter gene. Since this IR has been described in many bacterial species as preceding only genes of the dnaK and groESL operons, both encoding molecular chaperones (39 cases are documented so far), we designated this heat shock element CIRCE (controlling IR of chaperone expression). Furthermore, we suggest that this novel mechanism is more widespread among eubacteria than the regulation mechanism described for Escherichia coli and has a more ancient origin. Images

Expression of inducible stress protein 70 in rat heart myogenic cells confers protection against simulated ischemia-induced injury.

Abstract: Myocardial ischemia markedly increases the expression of several members of the stress/heat shock protein (HSP) family, especially the inducible HSP70 isoforms. Increased expression of HSP70 has been shown to exert a protective effect against a lethal heat shock. We have examined the possibility of using this resistance to a lethal heat shock as a protective effect against an ischemic-like stress in vitro using a rat embryonic heart-derived cell line H9c2 (2-1). Myogenic cells in which the heat shock proteins have been induced by a previous heat shock are found to become resistant to a subsequent simulated ischemic stress. In addition, to address the question of how much does the presence of the HSP70 contribute to this protective effect, we have generated stably transfected cell lines overexpressing the human-inducible HSP70. Embryonal rat heart-derived H9c2(2-1) cells were used for this purpose. This stably transfected cell line was found to be significantly more resistant to an ischemic-like stress than control myogenic cells only expressing the selectable marker (neomycin) or the parental cell line H9c2(2-1). This finding implicates the inducible HSP70 protein as playing a major role in protecting cardiac cells against ischemic injury.

Rapid and sensitive pollutant detection by induction of heat shock gene-bioluminescence gene fusions.

Abstract: Heat shock gene expression is induced by a variety of environmental stresses, including the presence of many chemicals. To address the utility of this response for pollutant detection, two Escherichia coli heat shock promoters, dnaK and grpE, were fused to the lux genes of Vibrio fischeri. Metals, solvents, crop protection chemicals, and other organic molecules rapidly induced light production from E. coli strains containing these plasmid-borne fusions. Introduction of an outer membrane mutation, tolC, enhanced detection of a hydrophobic molecule, pentachlorophenol. The maximal response to pentachlorophenol in the tolC+ strain was at 38 ppm, while the maximal response in an otherwise isogenic tolC mutant was at 1.2 ppm. Stress responses were observed in both batch and chemostat cultures. It is suggested that biosensors constructed in this manner may have potential for environmental monitoring.

18 Heat Shock Proteins and Stress Tolerance

Abstract: I. INTRODUCTION The capacity of different individuals of the same species to survive short exposures to extreme temperatures (thermotolerance) varies over a remarkable range, commonly over several orders of magnitude. Both differences in growth conditions and differences in genetic background contribute. Although the contributions of genetic background are just beginning to be deciphered, the effects of growth conditions have been the subject of detailed and intense scrutiny. Nutrient availability, oxygen tension, diurnal rhythms, and a host of other variables exert highly reproducible effects on thermotolerance. By far the most closely studied phenomenon, however, is the tolerance afforded by short pretreatments at moderately elevated temperature. When whole organisms or cultured cells are given such pretreatments, their resistance to killing by extreme heat increases dramatically. This increased resistance, known as induced thermotolerance (Fig. 1), is observed in virtually every organism studied. Remarkably, mild heat pretreatments elicit resistance not just to high temperatures, but to an extraordinary variety of other stresses. In addition, exposure to other mild stresses elicits protection not just against higher doses of those particular stresses, but against high temperatures as well. Such tolerance-inducing treatments generally also induce the synthesis of a small number of proteins known as the heat shock proteins (hsps; Fig. 2) (Li and Laszlo 1985; Lindquist 1986; Nagao et al. 1986; Subjeck and Shyy 1986; Sanchez and Lindquist 1990; Nover 1991; Sanchez et al. 1992). Historically, many observations have suggested that hsps play a vital part in induced tolerance. For example, it is striking that hsps...

Protective effects of hsp70 in inflammation

Abstract: Inflammation results from the recruitment to a given tissue or organ and the activation of leucocytes, among which the monocytes-macrophages play a major role. These phagocytic cells produce high levels of reactive oxygen species (ROS) as well as cytokines. Whereas both ROS and cytokines have the potential to regulate the expression of heat shock (HS)/stress proteins (HSP), it appears that these proteins in turn have the ability to protect cells and tissues from the deleterious effects of inflammation. The mechanisms by which such protection occurs include prevention of ROS-induced DNA strand breaks and lipid peroxidation as well as protection from mitochondrial structure and function. In vivo, HS protects organs against a number of lesions associated with the increased production of ROS and/or cytokines. In an animal model for adult respiratory distress syndrome, an acute pulmonary inflammatory condition, HS completely prevented mortality. HSP (hsp70 in particular) may also exert protective effects in the immune system by contributing to the processing and presentation of bacterial and tumoral antigens. The analysis of the expression of hsp70 may prove of diagnostic and prognostic value in inflammatory conditions and therapeutical applications are being considered.

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

Abstract: 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.

14 Expression and Function of the Low-molecular-weight Heat Shock Proteins

Abstract: In this chapter, the name sHSP includes all small heat shock proteins, cognate or heat inducible, defined as those proteins possessing the so-called α-crystallin protein domain. In general, the name used for individual sHSP will be hsp xx , where xx corresponds to the two most significant digits of the apparent molecular weight. However, all mammalian sHSP, excluding αA and αB crystallins, are called hsp27 irrespectively of slight interspecies variation in molecular weight, since they represent equivalent proteins, hsp xx from Drosophila melanogaster are called Dm-hsp xx to differentiate these proteins from the mammalian sHSP. I. INTRODUCTION Studies on the cellular response to heat shock and other physiological stresses have identified important families of proteins that are involved not only in cellular protection against these aggressions, but also in essential biochemical processes in unstressed cells. Among the protein families induced by heat shock, much has been learned about the hsp90, hsp70, and hsp60 families; these families accomplish different kinds of chaperonin function(s). This chapter deals with the family of small heat shock proteins (sHSP) which encompasses a large number of related protein species that share some structural features common to the lens protein α-crystallin and are represented in virtually all organisms, excluding perhaps prokaryotes. Neglected for a long time for several reasons including the fact that they did not appear to be as universally conserved as other heat shock proteins and that they were initially not observed in most mammalian cells, this group of heat shock proteins now generates renewed interest. sHSP are expressed...

Arachidonate is a potent modulator of human heat shock gene transcription.

Abstract: 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.