Showing papers on "Heat shock protein published in 1986"

The heat-shock response

Abstract: PERSPECTIVES AND SUMMARY . . . . . 1151 CHARACTERIZATION OF THE RESPONSE 1153 Comparison: Different Organisms and Stages of Development. ll53 The Proteins Induced by Heat ... . 1155 RNAs Induced by Heat 1167 OTHER INDUCTIONS OF HSPs 1168 Developmental Inductions .. . ... . . . . . . .. .. .. . ... ...... . .... . .. . . . 1168 Other Inducers 1 1 69 Is There a Common Mechanism? ........ ... 1170 GENOME ORGANIZATION 1172 REGULATION OF THE RESPONSE 1173 Transcription 1173 Translation . . . . .. ..... ......... .. . . .. .. .. .... . .. ...... . . . .. . . . . .. .. .. . .. .. .. . . . . . . . . . 1177 RNA Processing 1178 TOLERANCE TO HEAT AND OTHER FORMS OF STRESS . . . 1179 Heat-Induced Lethality and Thermotolerance . . . . . . . . . . . . . 1179 Phenocopies 1182 CONCLUDING REMARKS 1184

Abnormal proteins serve as eukaryotic stress signals and trigger the activation of heat shock genes

Abstract: Heat shock protein (hsp) genes, a group of ubiquitous genes, are activated by various metabolic stresses. The suggestion that denaturation of intracellular proteins may be produced by the metabolic stresses and then signal the activation of the hsp genes was examined by co-injection of purified proteins and hsp genes into frog oocytes. Activation of hsp genes was observed if the proteins were denatured prior to injection but not if they were introduced in their native form. Furthermore, the activation of hsp genes by abnormal proteins and by heat shock appears to occur by a common mechanism. A model for the transcriptional regulation of the genes is based on competition for degradation between abnormal intracellular proteins and a labile regulatory factor.

Stress protein systems of mammalian cells.

Abstract: Living organisms are known to react to a heat stress by the selective induction in the synthesis of several polypeptides. In this review we list the major stress proteins of mammalian cells that are induced by heat shock and other environments and categorize these proteins into specific subgroups: the major heat shock proteins, the glucose-regulated proteins, and the low-molecular-weight heat shock proteins. Characteristics of the localization and expression of proteins in each of these subgroups are presented. Specifically, the nuclear/nucleolar locale of certain of the major heat shock proteins is considered with respect to their association with RNA and the recovery of cells after a heat exposure. The induction of these major heat shock proteins and the repression of the glucose-regulated proteins as a result of reoxygenation of anoxic cells or by the addition of glucose to glucose-deprived cultures is described. Changes in the expression of these protein systems during embryogenesis and differentiation in mammalian and nonmammalian systems is summarized, and the protective role that some of these proteins appear to play in protecting the animal against the lethal effects of a severe heat treatment and against teratogenesis is critically examined.

Hydrogen peroxide-inducible proteins in Salmonella typhimurium overlap with heat shock and other stress proteins.

Abstract: Hydrogen peroxide treatment induces the synthesis of 30 proteins in Salmonella typhimurium. Five of these proteins are also induced by heat shock, including the highly conserved DnaK protein. The induction of one of these five proteins by heat shock is dependent on oxyR, a positive regulator of hydrogen peroxide-inducible genes, while the induction of the other four by heat shock is oxyR independent. Five of the 30 hydrogen peroxide-inducible proteins have been identified, and their structural genes have been mapped. Other stresses such as nalidixic acid, ethanol, or cumene hydroperoxide treatment also induce subsets of the 30 hydrogen peroxide-inducible proteins as well as additional proteins. Hydrogen peroxide-inducible proteins are shown to be largely different from those proteins induced by aerobiosis. In addition, the expression of the katG (catalase) gene is shown to be regulated by oxyR at the level of mRNA.

Heat shock proteins: the search for functions.

Abstract: Not so long ago, in the olden (golden ?) days, scientists interested in the biochemistry and cell biology of proteins attempted to explain an enzyme's catalytic and regulatory functions and the cytoskeleton's properties in terms of protein structure. But SDS PAGE, monoclonal antibodies, and cDNA libraries (nucleic acid sequences reverse transcribed from mRNAs and inserted into the genomes of bacteriophage or plasmids) changed things, and many of us now study proteins the other way around. We know structure, in the form of subunit molecular weights, isoelectric points, modifications by phosphate, sugars, methylations, etc., and in some cases, even primary sequences and the precise localization in the cell or tissue. What we search for is function. Such a search has been in progress over the past several years to discover what heat shock proteins (HSPs) l do. Here, I define an HSP by two criteria: (a) its synthesis is strongly stimulated by an environmental stress, in particular, that resulting from a change in temperature a few degrees centigrade above the normal physiological one, and (b) its gene contains a conserved sequence of 14 base pairs in the 5' noncoding region, the Pelham box (62). This sequence serves as the promoter for HSP mRNA transcription. The response of cells to a heat shock was first described about 25 years ago during a study of temperature effects on Drosophila embryos (65). A dramatic change was seen in the puffing pattern of polytene chromosomes in salivary glands, and this was later shown to be the result of very active gene transcription that led to the synthesis of a small set of proteins. For about 15 years, this selective induction of proteins by a heat shock was thought to be unique to the fly. In 1978, however, an analogous response in avian and mammalian tissue culture cells to heat shock was discovered in my laboratory (33), and others reported a similar activity in E. coli (39, 78) and Tetrahymena (21). Reports of proteins induced after heat shocking a variety of species quickly followed and we now recognize that virtually all organisms-from E, coli to man-have HSPs (see reference 68 for a more complete history). The major HSPs have been strongly conserved in structure through evolution, clearly indicating that they play a vital role in survival of the organism. Their presence appears to enhance the cell's ability to recover from stress but

Specific interaction between the p53 cellular tumour antigen and major heat shock proteins

Abstract: The protein p53 is capable of participating in neoplastic transformation and can form specific complexes with the large-T antigen of simian virus 40 (SV40). This interaction probably results in the stabilization of p53 (refs 7,8) and may contribute to SV40-mediated transformation. Several non-SV40-transformed cells also exhibit a stabilized p53 which is present in elevated levels. Recently, this stabilization was shown to coincide with the ability to precipitate a polypeptide (p68) of relative molecular mass (Mr) 68,000-70,000 by anti-p53 monoclonal antibodies. We now report that this co-precipitation indeed represents a specific complex between the two proteins; the complex sediments on a sucrose gradient as a relatively broad peak of 10-14S and can be dissociated in vitro. Furthermore, p68 is the HSP70 heat shock protein cognate, found in elevated levels in a p53-overproducing cell line. On heat-shock treatment of such overproducers, p53 also forms a complex with the related highly inducible HSP68.

Heat shock and the heat shock proteins.

Abstract: As all biologists appreciate, there is constant interaction between life and the environment, and temperature plays a critical role. It establishes distribution limits, it affects rates of function as well as the survival of organisms. Notoriously sensitive to temperature is plant growth. Critical steps in plant life such as germination, flowering and breaking of dormancy can be manipulated by the application of certain temperature treatments. Animal life is mainly limited to a narrow range of temperatures, from a few degrees below the freezing point of water to approximately 50 'C. Animals nevertheless differ in the range of temperatures that they can tolerate. Temperature tolerance may however change with time and a certain degree of adaptation is possible. The limits of temperature tolerance for a given animal are not fixed. Indeed, it has been known for some time that exposure to a near lethal temperature often leads to a degree of adaptation so that a previously lethal temperature is tolerated. This particular response to heat shock has attracted considerable attention from molecular biologists over the last decade, which has resulted in a rapid accumulation of data providing considerable insights, not only into the molecular basis of acquired thermotolerance, but into stress physiology in general. The heat shock response is now known to occur in bacteria and in plants as well as in animals, and is a rapid but transient reprogramming of cellular activities to ensure survival during the stress period, to protect essential cell components against heat damage and to permit a rapid resumption of normal cellular activities during the recovery period.

A mouse tumor-specific transplantation antigen is a heat shock-related protein

Abstract: A tumor-specific transplantation antigen has been purified to homogeneity from the cytosol of a methylcholanthrene-induced tumor, Meth A. The purified antigen is highly immunogenic and specific against challenge with Meth A, providing greater than 95% inhibition of tumor growth in immunized syngeneic mice. Immunofluorescence analysis of Meth A showed that the antigen is a highly abundant cytosolic protein but that it is also present at the cell surface and, therefore, accessible to the host's immune system. The antigen consists of two polypeptide isoforms present in equimolar amounts, having similar masses (84 and 86 kDa), pI values (4.95 and 4.90), and amino acid compositions. Both are phosphoproteins, and neither is glycosylated. The NH2-terminal sequences of the two isoforms are identical except that each chain contains a portion of unique sequence. Comparison of the NH2-terminal and CNBr-fragment sequence data to the sequences of the yeast and Drosophila heat shock proteins (Hsp90 and Hsp83, respectively) reveals that 73 of 91 residues compared are identical. In addition, an anti-Meth A tumor antigen serum that defects the isoforms from a variety of tumors also immunoprecipitates proteins of identical mass and pI from both normal and heat-shocked mouse embryo cells.

Two mammalian heat shock proteins, HSP90 and HSP100, are actin-binding proteins

Abstract: Two high molecular weight heat shock proteins, HSP90 (Mr, 90,000) and HSP100 (Mr, 100,000), were separately purified from extracts of cultured cells of a mouse lymphoma cell line, L5178Y. Both of the HSPs exist in homodimeric form under physiological conditions. Their physicochemical properties are quite similar to each other. Each of the purified HSPs was shown to coprecipitate with rabbit skeletal muscle actin under actin-polymerizing conditions. Both HSP90 and HSP100 increased the low-shear viscosity of filamentous actin solutions in a dose-dependent manner, which suggests that these HSPs cross-link actin filaments. Although some molecular properties and the effects described above on actin solution of HSP90 and HSP100 resemble those of alpha-actinin, the HSPs were distinguished from alpha-actinin by various means, including visualization of molecular shapes by electron microscopy with the aid of the low-angle rotary shadowing technique. Immunofluorescence staining by specific antisera against HSP90 revealed that HSP90 was localized in ruffling membranes in addition to the cytoplasmic space.

Expression of human HSP70 during the synthetic phase of the cell cycle

Abstract: Expression of the major heat shock and stress-induced protein, HSP70, is under complex regulatory control in human cells. In addition to being induced by physiological stress such as heat shock or transition metals, the HSP70 gene is induced by serum stimulation and immortalizing products of the adenovirus E1A 13S and polyoma large tumor antigen genes. Here we show that expression of the human HSP70 gene is tightly regulated during the cell cycle. Using selective mitotic detachment, a noninductive method to obtain synchronous populations of HeLa cells, we show that levels of HSP70 mRNA rapidly increase 10- to 15-fold upon entry into S phase and decline by late S and G2. A transient increase in HSP70 synthesis is detected during early S phase. The subcellular localization of HSP70 varies throughout the cell cycle; the protein is diffusely distributed in the nucleus and cytoplasm in G1, localized in the nucleus in S, and again diffusely distributed in G2 cells. We suggest that the temporal pattern of HSP70 expression during S phase, the nuclear localization, and activation by trans-acting immortalizing proteins indicate a role for HSP70 in the nucleus of replicating cells.

Sequence and organization of genes encoding the human 27 kDa heat shock protein

Abstract: The 27 kDa human heat shock protein (hsp27) is encoded by a gene family of 4 members. Two genomic fragments hybridizing to cDNA encoding hsp27 have been isolated, characterized, and sequenced. One clone is a member of a cluster of three genes linked within a 14-18 kb region of the genome and encodes a transcript interrupted by two intervening sequences. A single open reading frame encodes a polypeptide of 22,300 deduced molecular weight. The 5' flanking region contains two transcription start sites and sequences homologous to the Drosophila consensus heat inducible control element. Induction of both potential transcripts follows heat shock in vivo. Accurate heat inducible transcription occurs at both start sites after injection into Xenopus oocytes. The second genomic clone is a processed pseudogene lacking promoter elements and is unlinked with the other members of the hsp27 gene family. The amino acid sequence of human hsp27 shows striking homology with mammalian alpha crystallin, and contains a region towards the carboxy terminus which shares homology with the small hsp of Drosophila and other organisms.

An ancient developmental induction: heat-shock proteins induced in sporulation and oogenesis.

Abstract: Every eukaryotic and prokaryotic organism tested to date synthesizes a small number of heat-shock proteins in response to heat and other forms of stress. A particular pattern of heat-shock gene expression was observed during ascospore development in Saccharomyces: heat-shock proteins hsp26 and hsp84 were strongly induced nor inducible by heat shock. Instead, two proteins related to hsp70 were induced. A strikingly similar pattern of expression occurs during oogenesis in Drosophila, suggesting that it may be one of the earliest developmental pathways to evolve in eukaryotic cells.

Lymphokine and nonlymphokine mRNA levels in stimulated human T cells. Kinetics, mitogen requirements, and effects of cyclosporin A.

Abstract: Northern and dot blotting with a panel of DNA probes were used to monitor the levels of specific mRNAs in mitogen-stimulated human T cells. The induction of IL-2 and IFN mRNAs required the synergistic action of PMA and either PHA or OKT3 mAb. In contrast, several nonlymphokine genes, the protooncogenes c-fos and c-myc, and the IL-2-R gene, were induced by either PHA or PMA alone. PHA increased the background levels of a 70 kD heat shock protein mRNA, but did not affect the observed background of c-myb mRNA. For all mRNAs that were induced, isolated CD4 and CD8 T cell subsets behaved similarly. Exogenous IL-2 had little (IFN) or no (IL-2) effect on lymphokine mRNAs, but significantly increased c-myc, IL-2-R and heat shock protein mRNAs. Therefore, the stimuli for lymphokine mRNAs differed from those required for several inducible nonlymphokine genes. IL-2 and IFN mRNAs exhibited some important similarities with c-myc, however. The levels of IL-2, IFN, and c-myc mRNA followed similar kinetics, peaking at 3 h in restimulated blasts and at 12 h in unstimulated T cells. The subsequent downregulation of lymphokine and c-myc mRNAs was retarded by cycloheximide. The induction of IL-2, IFN, and c-myc mRNAs was blocked by the immunosuppressive drug CsA, but not by the inactive analog CsH, and this block occurred at the level of nuclear transcription. Since the exogenous stimuli for lymphokine and c-myc gene expression differ, we suggest that intracellular controls must be shared to account for the similarities in their kinetics of expression and CsA sensitivity.

Human HSP70 promoter contains at least two distinct regulatory domains.

Abstract: The expression of the human HSP70 gene is induced by a wide range of physiological stresses, including exposure to heat shock and heavy metals, or under nonstress conditions, such as in response to serum stimulation. We have previously demonstrated that in either case the regulated expression is at the primary level of transcription. To determine whether transcription is mediated through a single or multiple genetic elements, we have dissected the sequences upstream of the transcription start site of the human HSP70 gene by constructing chimeric genes retaining variable amounts of 5' flanking regions fused to the bacterial gene encoding chloramphenicol acetyltransferase. Transcription from the chimeric genes was determined by S1 nuclease analysis of separate stable transfectants. The sequences required for heat shock and cadmium induction lie between -107 and -68. Within this region is the sequence CTGGAATATTCCCG, which is identical in 12/14 positions with the heat shock element of Drosophila heat shock genes, and a separate sequence, CGNCCCGG, which is homologous to the core of the human metallothionein II metal-responsive element. The sequences required for serum-stimulated transcription are distinct from the heat shock element. The sequence CCAAT at -68 is required for high levels of correctly initiated transcripts, and a purine-rich sequence, GAAGGGAAAAG, at -58 is required for serum stimulation. The human HSP70 promoter contains at least two regulatory domains--a distal domain responsive to heat shock or cadmium and a proximal domain responsive to stimulation by serum.

The dynamic state of heat shock proteins in chicken embryo fibroblasts.

Abstract: Subcellular fractionation and immunofluorescence microscopy have been used to study the intracellular distributions of the major heat shock proteins, hsp 89, hsp 70, and hsp 24, in chicken embryo fibroblasts stressed by heat shock, allowed to recover and then restressed. Hsp 89 was localized primarily to the cytoplasm except during the restress when a portion of this protein concentrated in the nuclear region. Under all conditions, hsp 89 was readily extracted from cells by detergent. During stress and restress, significant amounts of hsp 70 moved to the nucleus and became resistant to detergent extraction. Some of this hsp 70 was released from the insoluble form in an ATP-dependent reaction. Hsp 24 was confined to the cytoplasm and, during restress, aggregated to detergent-insoluble perinuclear phase-dense granules. These granules dissociated during recovery and hsp 24 could be solubilized by detergent. The nuclear hsps reappeared in the cytoplasm in cells allowed to recover at normal temperatures. Sodium arsenite also induces hsps and their distributions were similar to that observed after a heat shock, except for hsp 89, which remained cytoplasmic. We also examined by immunofluorescence the cytoskeletal systems of chicken embryo fibroblasts subjected to heat shock and found no gross morphological changes in cytoplasmic microfilaments or microtubules. However, the intermediate filament network was very sensitive and collapsed around the nucleus very shortly after a heat shock. The normal intermediate filament morphology reformed when cells were allowed to recover from the stress. Inclusion of actinomycin D during the heat shock--a condition that prevents synthesis of the hsps--did not affect the intermediate filament collapse, but recovery of the normal morphology did not occur. We suggest that an hsp(s) may aid in the formation of the intermediate filament network after stress.

A major collagen-binding protein of chick embryo fibroblasts is a novel heat shock protein.

Abstract: Heat shock proteins of chick embryo fibroblasts were analyzed on SDS polyacrylamide gradient gels and were found to include not only three previously well-characterized proteins of 25,000, 73,000, and 89,000 D, but also a 47,000-D protein. Two-dimensional gel electrophoresis revealed that this protein was unusually basic (pI = 9.0) and corresponded to a recently characterized, major gelatin- and collagen-binding protein. The induction of synthesis of this 47,000-D membrane glycoprotein after heat stress of fibroblasts was particularly apparent in preparations isolated by gelatin-affinity chromatography. Regulation of this 47,000-D phosphoprotein was more sensitive than that of three major heat shock proteins in that a substantial stimulation of synthesis occurred at even 42 degrees C, as well as at higher temperature. Phosphorylation of the 47,000-D protein was not altered after heat shock. These studies establish this phosphorylated membrane glycoprotein as a member of the heat shock/stress protein family, and they add collagen binding to the unexpectedly diverse spectrum of biochemical activities induced by exposure of cells to stress.

Global control in Salmonella typhimurium: two-dimensional electrophoretic analysis of starvation-, anaerobiosis-, and heat shock-inducible proteins.

Abstract: The response of Salmonella typhimurium to various forms of environmental stress was examined by using O9Farrell two-dimensional gel electrophoresis. Polypeptides (a total of 110) which quantitatively increased during various starvations, anaerobiosis, or heat shock were identified and cataloged in reference to a standard polypeptide map. Although significant overlap was noted during comparison of proteins induced by different starvations, only a few proteins produced during heat shock or anaerobiosis were also identified as starvation inducible. Images

Inducible overproduction of the mouse c-myc protein in mammalian cells

Abstract: We have made Chinese hamster ovary (CHO) cell lines that contain up to 2000 copies of the coding region of the mouse c-myc gene fused to the promoter of the Drosophila gene (hsp70) encoding a Mr 70,000 heat shock protein. Incubation of these cells at 43 degrees C results in an estimated 100-fold induction of c-myc mRNA. Translation of this mRNA occurs when the cells are returned to 37 degrees C, and during the first 3 hr of recovery at 37 degrees C, the c-myc protein is one of the most abundantly synthesized proteins in the cells. The products of the induced c-myc gene are phosphoproteins of apparent Mr 64,000, 66,000, and 75,000. Induced cells die, suggesting that elevated levels of c-myc are cytotoxic. Amplification of genes placed under control of the Drosophila hsp70 promoter may provide a general method for inducibly over expressing proteins in mammalian cells.

The chicken ubiquitin gene contains a heat shock promoter and expresses an unstable mRNA in heat-shocked cells.

Abstract: A chicken genomic library was screened to obtain genomic clones for ubiquitin genes. Two genes that differ in their genomic location and organization were identified. One gene, designated Ub I, contains four copies of the protein-coding sequence arranged in tandem, while the second gene, Ub II, contains three. The origin of the two major mRNAs that are induced after heat shock in chicken embryo fibroblasts was determined by generating DNA probes from the 5'-and 3'-noncoding regions of the two genes. Both mRNAs are transcribed from Ub I, the larger being the unspliced precursor of the smaller. A 674-base-pair intron was located within the 5'-noncoding region of Ub I. The second gene, Ub II, does not appear to code for an RNA species in normal or heat-shocked chicken embryo fibroblasts. The expression of ubiquitin mRNA during heat shock and recovery was examined. Addition of actinomycin D before heat shock completely abolished the response of ubiquitin mRNA to the stress. Analysis of the stability of the mRNA during recovery revealed that the mRNA accumulated during the heat shock is rapidly degraded with a half-life of approximately 1.5 h, suggesting a specialized but transient role for ubiquitin during heat shock.

A repetitive antigen of Plasmodium falciparum that is homologous to heat shock protein 70 of Drosophila melanogaster

Abstract: We describe an antigen of Plasmodium falciparum, defined by a cDNA clone designated Ag63. The antigen is an abundant, soluble cytoplasmic polypeptide of Mr 75,000 present in all stages of asexual development in the blood and in gametocytes, but not in sporozoites. The sequence of the cDNA clone revealed that, like many other antigens of P. falciparum, it contains tandemly repeated amino acid sequences, in this case Gly-Gly-Met-Pro. However, the rest of the sequence is 70% homologous at the amino acid level to the heat shock protein hsp70 of Drosophila melanogaster.

Synthesis of Heat Shock Proteins in Rat Brain Cortex After Transient Ischemia

Abstract: Cell-free protein synthesis and two-dimensional gel autoradiography were used to characterize early postischemic protein synthesis in rat neocortex. Severe forebrain ischemia was induced for 30 min (four-vessel occlusion model) and followed by 3 h of recirculation. Polysomes were isolated from the cerebral cortex, translated in vitro in a reticulocyte system, and analyzed by two-dimensional gel electrophoresis. The translation products of postischemic polysomes included a major new protein family (70 kDa) with multiple isoelectric variants that was found to comigrate with the 68- to 70-kDa "heat shock" protein synthesized from polysomes of hyperthermic rats. Two other stress proteins (93 and 110 kDa) also appeared to be synthesized in increased amounts after ischemia. A complement of proteins that was indistinguishable from that of controls was also synthesized after ischemia, indicating that messenger ribonucleic acid coding for most brain proteins is preserved after ischemia and is bound to polysomes.

Selective gene expression in focal cerebral ischemia.

Abstract: Regional patterns of protein synthesis were examined in rat cortex made ischemic by the occlusion of the right common carotid and middle cerebral arteries. At 2 h of ischemia, proteins were pulse labeled with intracortical injections of a mixture of [3H]leucine, [3H]isoleucine, and [3H]proline. Newly synthesized proteins were analyzed by two-dimensional gel fluorography, and the results correlated with local CBF, measured with [14C]iodoantipyrine as tracer. Small blood flow reductions (CBF = 50-80 ml 100 g-1 min-1) were accompanied by a modest inhibition in synthesis of many proteins and a marked increase in one protein (Mr 27,000). With further reduction in blood flow (CBF = 40 ml 100 g-1 min-1), synthesis became limited to a small group of proteins (Mr 27,000, 34,000, 73,000, 79,000, and actin) including two new polypeptides (Mr 55,000 and 70,000). Severe ischemia (CBF = 15-25 ml 100 g-1 min-1) caused the isoelectric modification of several proteins (Mr 44,000, 55,000, and 70,000) and induced synthesis of another protein (Mr 40,000). Two polypeptides (Mr 27,000 and 70,000) dominated residual protein synthesis in severe ischemia. The changes in protein synthesis induced by different grades of ischemia most likely comprise a variation of the so-called "heat shock" or "stress" response found in all eukaryotic cells subjected to adverse conditions. Since heat shock genes are known to confer partial protection against anoxia and a variety of other noxious insults, their induction may be a factor in limiting the extent of ischemic tissue damage.

CALMODULIN-REGULATED BINDING OF THE 90-kDa HEAT SHOCK PROTEIN TO ACTIN FILAMENTS : Biochemistry

Abstract: We have found that the 90-kDa heat shock protein (HSP90) prepared from a mouse lymphoma exists in homodimeric form under physiological conditions and has the ability to bind to F-actin (Koyasu, S., Nishida, E., Kadowaki, T., Matsuzaki, F., Iida, K., Harada, F., Kasuga, M., Sakai, H., and Yahara, I. (1986) Proc. Natl. Acad. Sci. U.S.A., in press). Here we show that calmodulin regulates the binding of HSP90 to F-actin in a Ca2+-dependent manner. The binding of HSP90 to F-actin occurred optimally under physiological solution conditions, i.e. in 2 mM MgCl2 + 100 mM KCl. The binding was saturable in a molar ratio of about 1 HSP90 (dimer) to 10 actins. HSP90 was dissociated from F-actin by the binding of tropomyosin to F-actin. Calmodulin was found to inhibit the binding of HSP90 to F-actin in a Ca2+-dependent manner. Moreover, the equilibrium gel filtration demonstrated that calmodulin binds to HSP90 in the presence of Ca2+, but not in the absence of Ca2+. These data indicate that HSP90 complexed with Ca2+-calmodulin is unable to bind to F-actin. Ca2+-dependent interaction of HSP90 with calmodulin as well as calmodulin-regulated binding of HSP90 to F-actin revealed here may provide new insight into the function of HSP90 and the regulation of actin structure in cells.

Heat shock causes destabilization of specific mRNAs and destruction of endoplasmic reticulum in barley aleurone cells

Abstract: In response to a phytohormone, gibberellic acid, the aleurone layers of barley seeds synthesize and secrete alpha-amylases, which are coded by a set of stable mRNAs. When aleurone layers are subjected to heat shock treatment, the synthesis of alpha-amylase is suppressed while heat shock proteins are induced. The suppression of alpha-amylase synthesis is not the result of translational control as reported in several other systems. Rather, the sequences of alpha-amylase mRNA are rapidly degraded during heat shock as shown by in vitro translation and dot blot hybridization with a cDNA probe. Upon recovery from heat shock, the tissue resumes the synthesis of alpha-amylase in 2-4 hr. However, in the presence of a transcription inhibitor, cordycepin, the resumption of synthesis of alpha-amylase does not take place, indicating that new transcription of alpha-amylase genes is necessary for this recovery process. The degradation of alpha-amylase mRNAs correlates with the rapid destruction of endoplasmic reticulum as observed by electron microscopy, a phenomenon that has not been reported previously as a heat shock response. Since alpha-amylase mRNA is associated with the endoplasmic reticulum via membrane-bound polyribosomes, we suggest that the destruction of the endoplasmic reticulum during heat shock causes the destabilization and the eventual degradation of alpha-amylase mRNA.

Induction of B2 RNA polymerase III transcription by heat shock: enrichment for heat shock induced sequences in rodent cells by hybridization subtraction

Abstract: When hybridization subtraction was used to enrich for sequences induced by heat shock in Chinese hamster cells, B2 sequences were found to be one of the major sequences enriched. With cloned B2 probes, we found that the level of the short, 0.1 to 0.6 kb, polyadenylated RNA polymerase III transcripts of this repetitive genetic element increased approximately 10 to 20 fold after heat shock. Transcription of B2 RNA by RNA polymerase III was rapidly induced after heat shock based on time course studies and nuclear runoff experiments. The induction of B2 RNA was not a nonspecific response to lethality or cellular injury because maximum B2 RNA induction was observed with even nontoxic heating while no induction occurred with other agents such as UV or X-radiation. Since B2 RNA increased after heat shock in several different Chinese hamster and mouse cell lines, induction of B2 RNA by heat shock is probably common in rodent cells. B2 RNA may also be the most abundant transcript induced by heat shock because the level of B2 RNA was substantially higher than several other abundant transcripts induced by heat shock including a rodent HSP70. Our finding of the induction of high levels of RNA polymerase III B2 transcripts in different rodent cells raise the possibility of a role in the heat shock response.

Inhibition of heat shock protein synthesis by heat-inducible antisense RNA

Abstract: We show that antisense RNAs transcribed from genes that are stably integrated into the genome can be used to inhibit the expression of an endogenous cellular gene. Drosophila tissue culture cells were stably transformed with a gene encoding a heat-inducible RNA complementary to the message for hsp26, one of the small heat shock proteins. These cells produced much less hsp26 after heat shock than did untransformed cells. The inhibition was highly specific: expression of the closely related heat shock proteins hsp22, hsp23, and hsp28 was unaffected. By varying the copy number of the antisense gene, the degree of inhibition was varied over a broad range. Reducing the rate of hsp26 synthesis did not appear to affect the synthesis of any other protein during either heat shock or recovery.