Showing papers on "Heat shock protein published in 1984"

Major heat shock gene of Drosophila and the Escherichia coli heat-inducible dnaK gene are homologous.

Abstract: The Escherichia coli dnaK gene is homologous to the major heat shock-induced gene in Drosophila (Hsp70). The primary DNA sequence of the entire protein-coding region of the dnaK gene was determined and compared with that of the Hsp70 gene of Drosophila. The two sequences are homologous; the dnaK gene could encode a 69,121-Da polypeptide, 48% identical to the hsp70 protein of Drosophila. The homology between the Hsp70 gene of Drosophila and the E. coli dnaK gene illustrates the remarkable conservation of the heat shock genes in evolution. In contrast to Drosophila and Saccharomyces cerevisiae, both of which contain multigene families related to the Hsp70 gene, hybridization analyses indicate that E. coli contains only a single Hsp70-related gene, dnaK. Hybridization between the DNA of an archaebacterium Methanosarcina barkeri and the Hsp70 genes of Drosophila, Saccharomyces, and E. coli has been detected, suggesting the existence of Hsp70-related genes in the three "primary kingdoms": eukaryotes, eubacteria, and archaebacteria.

Hsp70 accelerates the recovery of nucleolar morphology after heat shock.

Abstract: The major heat-shock protein, hsp70, is synthesized by cells of many organisms in response to stress. In the present study, Drosophila hsp70 was expressed from cloned genes in mouse L cells and monkey COS cells and detected by immunofluorescence using monoclonal antibodies. Hsp70 is found mostly but not exclusively in the nucleus of unstressed cells. For several hours after a short heat shock, however, it is strongly concentrated in nucleoli. Nucleoli are transiently damaged by such a heat shock: their morphology changes and assembly and export of ribosomes is blocked for several hours. This block can be visualized by addition of actinomycin D: under normal conditions pre-ribosomes are chased out of nucleoli, and the latter shrink dramatically, but no such shrinking is seen in heat-shocked cells. High levels of hsp70 can be produced in unstressed COS cells by transfecting them with an appropriate expression plasmid. Such cells show a more rapid recovery of nucleolar morphology following a heat shock than do untransfected cells. Furthermore, heat shock does not prevent shrinkage of their nucleoli in the presence of actinomycin, which indicates that ribosome export also recovers rapidly when pre-synthesized hsp70 is present. I suggest that an important function of hsp70 is to catalyze reassembly of damaged pre-ribosomes and other RNPs after heat shock.

Two protein-binding sites in chromatin implicated in the activation of heat-shock genes.

Abstract: The resistance to exonuclease digestion of two regions of chromatin at the 5′ end of heat-shock genes in Drosophila implies they have protein bound to them. The pattern of resistance before and after induction of gene expression suggests that heat-shock genes are activated by the sequential binding of at least two protein factors.

Acquisition of Thermotolerance in Soybean Seedlings : Synthesis and Accumulation of Heat Shock Proteins and their Cellular Localization.

Abstract: When soybean Glycine max var Wayne seedlings are shifted from a normal growth temperature of 28°C up to 40°C (heat shock or HS), there is a dramatic change in protein synthesis. A new set of proteins known as heat shock proteins (HSPs) is produced and normal protein synthesis is greatly reduced. A brief 10-minute exposure to 45°C followed by incubation at 28°C also results in the synthesis of HSPs. Prolonged incubation (e.g. 1-2 hours) at 45°C results in greatly impaired protein synthesis and seedling death. However, a pretreatment at 40°C or a brief (10-minute) pulse treatment at 45°C followed by a 28°C incubation provide protection (thermal tolerance) to a subsequent exposure at 45°C. Maximum thermoprotection is achieved by a 2-hour 40°C pretreatment or after 2 hours at 28°C with a prior 10-minute 45°C exposure. Arsenite treatment (50 micromolar for 3 hours) also induces the synthesis of HSP-like proteins, and also provides thermoprotection to a 45°C HS; thus, there is a strong positive correlation between the accumulation of HSPs and the acquisition of thermal tolerance under a range of conditions. During 40°C HS, some HSPs become localized and stably associated with purified organelle fractions ( e.g. nuclei, mitochondria, and ribosomes) while others do not. A chase at 28°C results in the gradual loss over a 4-hour period of the HSPs from the organelle fractions, but the HSPs remain selectively localized during a 40°C chase period. If the seedlings are subjected to a second HS after a 28°C chase, the HSPs rapidly (complete within 15 minute) relocalize in the organelle fractions. The relative amount of the HSPs which relocalize during a second HS increases with higher temperatures from 40°C to 45°C. Proteins induced by arsenite treatment are not selectively localized with organelle fractions at 28°C but become organelle-associated during a subsequent HS at 40°C.

Common control of the heat shock gene and early adenovirus genes: evidence for a cellular E1A-like activity.

Abstract: We have employed an antiserum specific to the 70-kilodalton human heat shock protein and a cDNA clone specific to the mRNA for this protein to analyze the expression of the gene under noninducing conditions. Expression of the heat shock gene can be detected in the absence of heat induction, and this uninduced level of expression depends greatly on the particular cell type. For instance, the basal expression of the heat shock gene is at least 50 times higher in HeLa cells than in WI38 cells at both the mRNA and protein levels. We have previously shown that the inducer of transcription of the early adenovirus genes, the E1A gene product, also induces the heat shock gene, suggesting that these genes may be subject to the same regulation. We have, therefore, investigated the control of the adenovirus genes in relation to the cellular control of the heat shock gene. We find that human cells that allow a high level of uninduced expression of the heat shock gene (i.e., HeLa cells) also allow expression of the early adenovirus genes in the absence of the E1A inducer. The same is also true for the mouse F9 teratocarcinoma cell line. F9 stem cells, which constitutively express the heat shock protein, allow early adenovirus gene expression in the absence of E1A; upon differentiation induced by retinoic acid and cyclic AMP, the cells become restrictive and early viral gene expression requires the E1A gene product. Coordinately, upon differentiation there is also a loss of heat shock protein expression.

Activating protein factor binds in vitro to upstream control sequences in heat shock gene chromatin

Abstract: DNA sequences, important for the control of Drosophila heat shock gene expression, are packaged in chromatin in a nuclease hypersensitive configuration. Recently, two protein-binding (exonuclease-resistant) sites which cover the TATA box sequence and an upstream control element were shown to occur in vivo amidst the 5' terminal hypersensitive regions of several heat shock genes. Protein-binding at the TATA box is independent of heat shock, but the binding at the upstream element is heat shock dependent, and it was proposed that a heat shock activator protein, HAP, positively regulates the genes. Here, I report the detection of HAP activity in heat shocked cell extracts by reconstituting specific binding to hsp82 gene chromatin in vitro. Inhibition of the binding by free DNA from the 5' region of heat shock genes implies a coordinate regulation of the gene family through HAP interaction with the upstream heat shock consensus sequence. Furthermore, the special ease of induction of the hsp82 gene over other heat shock genes can be explained in molecular terms by the higher affinity of HAP for the hsp82 binding site, which contains a 28 base sequence with almost perfect dyad symmetry, GAAGCCTCTAGAAG/TTTCTAGAGACTTC.

Quantitation and intracellular localization of the 85K heat shock protein by using monoclonal and polyclonal antibodies.

Abstract: Two monoclonal antibodies have been produced against the human 85,000-molecular-weight heat shock protein (hsp85). One of these, 16F1, cross-reacts with the murine homolog and is shown by peptide map immunoblots to be directed against an epitope different from that recognized by the other monoclonal antibody, 9D2. Both monoclonal antibodies recognize only a single Mr-85,000 species in two-dimensional immunoblots. Immunoprecipitation did not reveal an association of this heat shock protein with any other protein in HeLa cells. Immunoperoxidase staining showed a purely cytosolic distribution at both light and electron microscopic levels and no association with membranes, mitochondria, or other organelles. The 9D2 monoclonal and a polyclonal antimurine hsp85 antibody were used to identify the antigens and to quantitate their levels in a variety of normal tissues by immunoautoradiography. Relative abundance in the various tissues as determined by Coomassie blue staining correlates reasonably well with the immunoreactivity. Testis and brain, for example, have high hsp85 levels, whereas heart and skeletal muscle have little or none. The Mr-85,000 sodium dodecyl sulfate-polyacrylamide gel band in testis and brain lysates was further confirmed to be hsp85 by one-dimensional partial proteolytic peptide mapping. Based on these data and our previous observations showing that synthesis and levels of the protein are altered by depriving cultured cells of glucose, we speculate that intracellular hsp85 levels depend on differences in the intermediary metabolism of glucose in the various tissues. Furthermore, it appears that high basal levels of this heat shock protein may not necessarily protect cells against heat shock, since testis is one of the most heat-sensitive tissues and has the highest hsp85 level.

Regulation of heat shock protein 70 gene expression by c-myc.

Abstract: The myc gene seems to have a causal role in tumour formation in man, mouse and avian systems1–3. The myc gene product has been localized to the nucleus4,5, suggesting that it may be involved in the regulation of gene expression. The level of expression of the mammalian heat shock protein 70 (HSP70) gene is elevated in several tumour cell lines6, implying that a cellular function expressed in these tumour lines can stimulate HSP70 production. We report here that the gene product of a rearranged mouse c-myc gene is capable of stimulating expression of chimaeric genes containing a Drosophila hsp70 promoter region and 5′-flanking sequences. This stimulation is dependent on sequences located more than 200 bases 5′ of the normal start of hsp70 transcription.

Induction of glucose-regulated proteins during anaerobic exposure and of heat-shock proteins after reoxygenation

Abstract: In this report we examine the effects of chronic anaerobic exposure and subsequent reoxygenation on protein synthesis patterns in Chinese hamster ovary cells. It is observed by two-dimensional gel electrophoresis (isoelectric focusing/NaDodSO4/PAGE) that the transition from an atmospheric environment to an anaerobic state transiently induces the major heat-shock proteins (at 68 and 89 kDa). As the period of anaerobiosis increases, this heat-shock induction disappears and a new set of proteins (at 76 and 97 kDa) is induced. By two-dimensional gel electrophoresis and partial proteolytic mapping, these new proteins, which are induced by anaerobic exposures exceeding 12 hr, are identical to 76 and 97 kDa (p76 and p97, respectively) proteins induced by extended periods of glucose deprivation (greater than 14 hr) when oxygen is present. Furthermore, the induction of these proteins under anoxia occurs in the presence of glucose, and increasing the glucose content of the starting media does not affect the induction. When anaerobic p76 and p97 induced cells are returned to atmospheric oxygen, p76 and p97 are repressed, while the heat-shock proteins are again transiently induced. This work further suggests the importance of deprivation and release environments in controlling the expression of these two stress protein systems. It is suggested that their natural expression may be determined by comparable circumstances.

lon gene product of Escherichia coli is a heat-shock protein.

Abstract: The product of the pleiotropic gene lon is a protein with protease activity and has been tentatively identified as protein H94.0 on the reference two-dimensional gel of Escherichia coli proteins. Purified Lon protease migrated with the prominent cellular protein H94.0 in E. coli K-12 strains. Peptide map patterns of Lon protease and H94.0 were identical. A mutant form of the protease had altered mobility during gel electrophoresis. An E. coli B/r strain that is known to be defective in Lon function contained no detectable H94.0 protein under normal growth conditions. Upon a shift to 42 degrees C, however, the Lon protease was induced to high levels in K-12 strains and a small amount of protein became detectable at the H94.0 location in strain B/r. Heat induction of Lon protease was dependent on the normal allele of the regulatory gene, htpR, establishing lon as a member of the high-temperature-production regulon of E. coli.

Heat shock regulatory gene htpR influences rates of protein degradation and expression of the lon gene in Escherichia coli.

Abstract: Upon a shift to high temperature, Escherichia coli increase their rate of protein degradation and also the expression of a set of "heat shock" genes. Nonsense mutants of htpR (also called hin), suppressed by a temperature-sensitive suppressor, show lower expression of heat shock genes at 30 degrees C and fail to respond to a shift to 42 degrees C. These mutants were found to have a lower capacity to degrade abnormal or incomplete proteins than that of wild-type cells. This reduction in proteolysis equals or exceeds that in lon mutants, which encode a defective ATP-dependent protease, protease La, and is particularly large in htpR lon double mutants. The activity of protease La was higher in wild-type cells than in htpR mutants grown at 30 degrees C and increased upon shift to 42 degrees C only in the wild type. To determine whether htpR influences transcription of the lon gene, a lon-lacZ operon fusion was utilized. Introduction of the htpR mutation reduced transcription from the lon promoter at 30 degrees C and 37 degrees C. This defect was corrected by a plasmid (pFN97) carrying the wild-type htpR allele. Induction of the heat shock response with ethanol had little or no effect in htpR mutants but stimulated lon transcription 2-3 fold in wild-type cells and htpR cells carrying pFN97. Thus, lon appears to be a heat shock gene, and increased synthesis of protease La under stressful conditions may help to prevent the accumulation of damaged cellular protein.

Drosophila DNA topoisomerase I is associated with transcriptionally active regions of the genome

Abstract: The distribution of DNA topoisomerase I within Drosophila polytene chromosomes was observed by immunofluorescent staining with affinity-purified antibodies The enzyme is preferentially associated with active loci, as shown by prominent staining of puffs The heat shock loci 87A-87C are stained after, but not before, heat shock induction A detailed comparison of the distribution of topoisomerase I with that of RNA polymerase II reveals a similar, although not identical, pattern of association Topoisomerase I is also found in association with the nucleolus, the site of transcription by RNA polymerase I

Developmental control of the heat shock response in Xenopus

Abstract: Xenopus cells express two major proteins on heat shock, designated hsp 70 and hsp 30. Several cDNA clones for the corresponding mRNAs were identified and sequenced. Inducibility and abundance of heat shock mRNAs in various cell types and developmental stages was determined by nuclease S1-mapping. The only cells found to contain hsp 70 mRNA without heat shock are the oocytes. The level of this stored hsp 70 mRNA is not increased by heat shock. After fertilization, hsp 70 mRNA becomes undetectable; it appears as a heat-inducible mRNA for the first time at gastrulation. After this stage, all somatic cell types accumulate hsp 70 mRNA to similar levels on heat shock, presumably by transcriptional activation of the hsp 70 genes. In contrast, hsp 30 mRNA is not detectable, even after heat shock, in oocytes or embryos that induce hsp 70 mRNA to high levels. Heat inducibility appears late in development--at the tadpole stage. However, the level of induced mRNA varies considerably in different adult tissues. This indicates that the Xenopus heat shock genes are not coordinately controlled. A long-term developmental control appears to be superimposed on the temporary heat inducibility of the heat shock genes: stage- or cell-type-specific conditions can lead to constitutive or repressed heat shock genes.

Induction of Heat Shock Protein Messenger RNA in Maize Mesocotyls by Water Stress, Abscisic Acid, and Wounding

Abstract: Exposure of the excised growing region of the mesocotyl of young corn seedlings to heat shock stimulated the production of specific heat shock proteins and the intensification of synthesis of two proteins with a molecular weight of approximately 70,000. Water stress and abscisic acid also stimulated synthesis of these 70,000-dalton proteins, and other unique proteins distinct from those induced by heat shock. Growing tissues of intact corn mesocotyls exposed to heat shock, water stress, or abscisic acid accumulated mRNA species homologous to a cloned genomic probe of the 5' end of the 70,000-dalton Drosophila heat shock protein gene. Since cut segments of the mesocotyl under unstressed conditions produced a similar mRNA, we suggest that the hsp 70 gene is activated in corn by a variety of diverse stresses. Production of the mRNA is rapid, but transient, being induced within 3 hours of the imposition of the stress, but declining after reaching a maximum at 9 hours.

Altered expression of heat shock proteins in embryonal carcinoma and mouse early embryonic cells.

Abstract: In a previous paper, we have shown that in the absence of stress, mouse embryonal carcinoma cells, like mouse early embryo multipotent cells, synthesize high levels of 89- and 70-kilodalton heat shock proteins (HSP)(O. Bensaude and M. Morange, EMBO J. 2:173-177, 1983). We report here the pattern of proteins synthesized after a short period of hyperthermia in various mouse embryonal carcinoma cell lines and early mouse embryo cells. Among the various cell lines tested, two of them, PCC4-Aza R1 and PCC7-S-1009, showed an unusual response in that stimulation of HSP synthesis was not observed in these cells after hyperthermia. However, inducibility of 68- and 105-kilodalton HSP can be restored in PCC7-S-1009 cells after in vitro differentiation triggered by retinoic acid. Similarly, in the early mouse embryo, hyperthermia does not induce the synthesis of nonconstitutive HSP at the eight-cell stage, but induction of the 68-kilodalton HSP does occur at the blastocyst stage. Such a transition in the expression of HSP has already been described for Drosophila melanogaster and sea urchin embryos and recently for mouse embryos. It may be a general property of early embryonic cells.

A gene regulating the heat shock response in Escherichia coli also affects proteolysis

Abstract: The htpR locus in Escherichia coli encodes a regulator of the heat shock response. Cells containing the htpR165 mutation are defective in the induction of synthesis of heat-shock proteins at high temperature. We show that these cells are also defective in degrading two proteins that are normally unstable in htpR+ cells. The proteolytic defect is manifest at both 30 degrees C and 42 degrees C. We used a marker rescue technique to map this defect to the htpR locus. Although both proteolytic substrates are partially stabilized in lon- strains, we argue that the defect in proteolysis exhibited by the htpR165 strain does not mimic the lon- state. The htpR165 strain synthesizes Lon at the normal rate at 30 degrees C and does not show the phenotypes of mucoidy and radiation sensitivity associated with lon- strains.

Heat shock regulatory gene (htpR) of Escherichia coli is required for growth at high temperature but is dispensable at low temperature.

Abstract: Nonsense mutations affecting the positive regulatory gene (htpR) of heat shock response have been obtained in a strain of Escherichia coli carrying no suppressor. The mutants can grow only at temperatures below 34 degrees C-35 degrees C. Heat, ethanol, and coumermycin induce major heat shock proteins in the wild-type but not in the htpR mutants. In contrast, the level of heat shock proteins synthesized at low temperature is unaffected. The htpR gene product is thus required for induction of heat shock proteins by heat or other stresses but not for their "basal-level" synthesis. Nucleotide sequence has been determined for the wild-type and the mutant alleles of htpR. The coding region appears to consist of 852 nucleotide pairs that correspond to 284 amino acids. Sequences commonly considered as signals for transcriptional initiation and termination were found flanking the coding region. Within this region, six amber, one opal, and two missense mutations were identified; the nonsense mutations are scattered along the gene, some being very close to the presumed amino terminus. These results indicate that the absence of htpR gene product is directly responsible for the failure to respond to heat shock or other stresses and for the inability to grow at high temperature. We propose that htpR represents a new class of genes that are essential for growth only at high temperatures (greater than 35 degrees C). Implications of the sequence homologies found among htpR, rpoD, and nusA proteins are discussed.

Use of peptide tagging to detect proteins expressed from cloned genes: deletion mapping functional domains of Drosophila hsp 70.

Abstract: We have developed a technique which allows specific detection of proteins expressed from cloned genes. The method involves fusion of an oligonucleotide coding for part of the neuropeptide substance P to the 3' end of the gene; the protein can then be detected with a monoclonal antibody that recognises this peptide. We have used this method to determine the properties of deletion mutants of the major Drosophila heat shock protein, hsp70, expressed in monkey COS cells. The results suggest that this protein has two distinct domains. Both are capable of accumulating in the nucleus of unstressed cells, but only the more highly conserved N-terminal domain is able to bind to nucleoli following a heat shock. This implies that nucleolar binding and nuclear migration are distinct properties of the protein, and suggests that the former may be of functional importance. In addition, we observed a novel effect of heat shock on cellular metabolism: protein fragments that are normally rapidly degraded are stabilized. The effect persists for several hours after the heat shock, but does not require expression of heat shock proteins. Together with previously published data, these results suggest an intimate relationship between protein degradation and the heat shock response.

Synthesis, modification and structural binding of heat‐shock proteins in tomato cell cultures

Abstract: Synthesis of about 30 acidic and 18 basic heat-shock proteins (hsps) is induced in suspension cultures of tomato (Lycopersicon peruvianum) if subjected to supraoptimal temperature conditions (35-40 degrees C). A characteristic aspect of the plant heat-shock response is the formation of cytoplasmic granular aggregates, heat-shock granules, containing distinct heat-shock proteins as major structural components and, in addition, several hitherto undetected minor acidic and basic heat-shock proteins. Structural binding of heat-shock proteins, i.e. assembly of heat-shock granules, is dependent on the persistance of supraoptimal temperature conditions. Despite the ongoing synthesis also at 25 degrees C, e.g. in pulse heat-shocked cultures, these proteins are accumulated exclusively in soluble form. Individual heat-shock proteins are characterized by their kinetics of synthesis and are classified by their compartmentation behaviour into class A proteins (exclusively found in soluble form, e.g. hsps 95 and 80), class B proteins (5-10% bound to heat-shock granules, e.g. hsps 70, 68), class C proteins (30-80% bound to heat-shock granules, e.g. hsps 21, 17, 15) and class D proteins, which are minor heat-shock proteins only detected in structure-bound form. Major representatives are modified proteins, i.e. hsps 95, 80, 70 and 68 are phosphorylated and hsps 80, 74, 70 and 17 are methylated proteins (numbers 70, 80 etc. refer to 10(-3) Mr). Under heat-shock conditions synthesis of the proteins detected in control cells (25 degrees C proteins) exhibits two patterns. There are proteins with continued and proteins with discontinued synthesis. Synthesis of most of the latter proteins is resumed very rapidly after shift-down to 25 degrees C, even in the presence of actinomycin D. We conclude that reversible segregation of distinct mRNA species from the translation apparatus contributes to the heat-shock-specific pattern of protein synthesis in plants also.

A generegulating theheatshockresponse inEscherichia coli also affects proteolysis

Abstract: ThehtpRlocus inEscherichia coli encodes a regulator oftheheatshockresponse. Cells containing the htpRl65 mutation aredefective intheinduction ofsynthesis of heat-shock proteins athightemperature. Weshowthat these cells arealso defective indegrading twoproteins that arenor- mally unstable inhtpR' cells. Theproteolytic defect ismani- fest atboth30'Cand420C. We usedamarker rescue tech- nique tomapthis defect tothehtpR locus. Although bothpro- teolytic substrates arepartially stabilized inlon-strains, we argue that thedefect inproteolysis exhibited bythehtpRl65 strain doesnotmimicthelon-state. ThehtpRl65 strain syn- thesizes Lonatthenormal rate at30'Canddoesnotshowthe phenotypes ofmucoidy andradiation sensitivity associated with lon-strains. htpR165 mutation iscorrelated withboththerateofsynthe- sis ofheat shock proteins atthepeak oftheresponse andthe permissive growth temperature. Anefficient suppressor functional atall temperatures restores boththeheatshock response andhigh temperature growth (10, 15). Thus, ineffi- cient suppression ofthehtpRl65 mutation blocks theheat shock response. Cell death ensues athigh temperature. Inthis report, weshowthat thehtpRl65 mutation confers anadditional phenotype; htpRmutant cells aredefective in proteolysis atboth30'Cand420C. Bothproteolytic sub- strates tested arealso partially stabilized inlon-strains (16- 19). We compare thecharacteristics oflon-cells with htpRJ65 cells. Inaddition, possible relationships between thetwophenotypes ofthehtpRl65 mutant areconsidered. WhenEscherichia coli cells aretransferred tohigh tempera- ture, therate ofsynthesis ofasmall number ofproteins in- creases (1,2).Thisphysiological response totemperature shift, theheatshock response, appears tobeuniversal, asit hasbeenobserved inall cell types tested (3, 4).Since many other stimuli, including anoxia, ethanol, andother chemical agents, induce thesynthesis ofheatshockproteins invari- ousorganisms, theresponse maybepart ofageneral cellular mechanism foradaptation tostress (5,6).Otheragents knowntoinduce heatshock protein synthesis inE.coli in- clude UV light, ethanol, aminoacidstarvation, naladixic acid, andcoumermycin (7). Theheat shock response inE.coli wasinitially defined by ananalysis ofthechanges inrates ofsynthesis ofindividual proteins after shift tohigh temperature (1,2).Todate, 17 proteins havebeencharacterized asheatshock proteins (7, 8).Immediately after shift tohigh temperature, therates of synthesis ofindividual heat shock proteins increase 5-to20- fold, depending ontheprotein. Theincreased rate ofsynthe- sis peaks at5-10minandthendeclines by30minafter tem- perature upshift toanewsteady-state rateofsynthesis, somewhat greater thanthat atlowtemperature (9). Whereit hasbeenexamined, theincreased synthesis ofheatshock proteins hasbeenshowntobeaccompanied byanincrease intherate ofsynthesis oftheir mRNAs(refs. 10-12; unpub- lished results). Thus, initiation oftheheat shock response is

Tissue specificity of the heat-shock response in maize.

Abstract: The tissue specificity of the heat-shock response in maize was investigated. The ability to synthesize heat shock proteins (hsp) at 40°C, as well as the intensity and duration of that synthesis, was analyzed in coleoptiles, scutella, green and etiolated leaves, suspension-cultured cells, germinating pollen grains, and primary root sections at different stages of development. One-dimensional sodium dodecyl sulfate gel electrophoresis of extracted proteins revealed that most of the tissues synthesized the typical set of 10 hsp, but that the exact characteristics of the response depended upon the tissue type. While elongating portions of the primary root exhibited a strong heat shock response, the more mature portions showed a reduced ability to synthesize hsp. Leaves, whether green or etiolated, excised or intact, constitutively synthesized a low level of hsp at 25°C, and high levels could be induced at 40°C. Suspension-cultures of Black Mexican sweet corn synthesized, besides the typical set of hsp, two additional polypeptides. In contrast to all the other tissues, germinating pollen grains could not be induced to synthesize the typical set of hsp but did synthesize two new polypeptides of 92 and 56 kD molecular weight. The heat shock response was transient for most of the tissues which synthesized the standard set of hsp. Hsp synthesis was detected up to 2 to 3 hours, but not at 10 hours of continuous 40°C treatment. The exception was suspension cultured cells, in which hsp synthesis showed only a slight reduction after 10 hours at 40°C. Tissue-specific differences in the heat-shock response suggest that there are differences in the way a given tissue is able to adapt to high temperature. We have confirmed the previous suggestion that maize hsp do not accumulate in substantial quantities. Using two-dimensional gel analysis, hsp could be detected by autoradiography but not by sensitive silver staining techniques.

Heat shock-induced translational control of HSP70 and globin synthesis in chicken reticulocytes.

Abstract: Incubation of chicken reticulocytes at elevated temperatures (43 to 45 degrees C) resulted in a rapid change in the pattern of protein synthesis, characterized by the decreased synthesis of normal proteins, e.g., alpha and beta globin, and the preferential and increased synthesis of only one heat shock protein, HSP70. The repression of globin synthesis was not due to modifications of globin mRNA because the level of globin mRNA and its ability to be translated in vitro were unaffected. The HSP70 gene in reticulocytes was transcribed in non-heat-shocked cells, yet HSP70 was not efficiently translated until the cells had been heat shocked. In non-heat-shocked reticulocytes, HSP70 mRNA was a moderately abundant mRNA present at 1 to 2% of the level of globin mRNA. The rapid 20-fold increase in the synthesis of HSP70 after heat shock was not accompanied by a corresponding increase in the rate of transcription of the HSP70 gene or accumulation of HSP70 mRNA. These results suggest that the elevated synthesis of HSP70 is due to the preferential utilization of HSP70 mRNA in the heat-shocked reticulocyte. The heat shock-induced alterations in the reticulocyte protein-synthetic apparatus were not reversible. Upon return to control temperatures (37 degrees C), heat-shocked reticulocytes continued to synthesize HSP70 at elevated levels whereas globin synthesis continued to be repressed. Despite the presence of HSP70 mRNA in non-heat-shocked reticulocytes, we found that continued transcription was necessary for the preferential translation of HSP70 in heat-shocked cells. Preincubation of reticulocytes with the transcription inhibitor actinomycin D or 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole blocked the heat shock-induced synthesis of HSP70. Because the level of HSP70 mRNA was only slightly diminished in cells treated with actinomycin D, we suggest two possible mechanisms for the preferential translation of HSP70 mRNA: the translation of only newly transcribed HSP70 mRNA or the requirement of a newly transcribed RNA-containing factor.

The expression of heat shock genes during normal development in Drosophila melanogaster (heat shock/abundant transcripts/developmental regulation)

Abstract: Drosophila melanogaster cells and tissues respond to heat shock by dramatically altering their pattern of transcription and translation, leading to the rapid synthesis of a small number of polypeptides, the heat shock proteins (hsps). By using cloned hsp DNA we have detected sequences complementary to heat shock genes in RNA prepared from non-heat-shocked animals of different developmental stages. Hsp 83 mRNA is present at high levels in all stages examined. Hsp 68 and 70 mRNAs are present at very low levels in most stages and at slightly higher concentration in pupae. Hsp 26 and 27 mRNAs are detected in embryos. Hsp 23, 26 and 27 mRNA are barely detectable in early third instar larvae but are major components of late third instar and early pupal RNA. Hsp 22 mRNA is also detected in early pupae. Later in development the levels of the small hsp mRNAs decrease but a further peak in abundance of hsp 26 and 27 mRNAs is found in mature adult females.

Nuclear localization and phosphorylation of three 25-kilodalton rat stress proteins.

Abstract: The nuclear localization and phosphorylation of three 25-kilodalton rat myoblast stress proteins were examined. Data obtained in these analyses led to the following conclusions: (i) all three proteins become localized in the nucleus of stressed cells, (ii) two of the proteins are modified by phosphorylation, and (iii) phosphorylation occurs exclusively on serine residues.

Durable synthesis of high molecular weight heat shock proteins in G0 cells of the yeast and other eucaryotes.

Abstract: We report that eucaryotic cells were induced to synthesize a specific class of heat shock proteins (hsps) when they entered the resting state, G0. This finding was originally made with Saccharomyces cerevisiae cells by taking advantage of the system in which we can distinguish between G1 arrests leading to G0 and those that do not result in G0 (Iida, H., and I. Yahara, 1984, J. Cell Biol. 98:1185-1193). Similar observations were subsequently made with higher eucaryotic cells including chick embryonic fibroblasts (CEF), mouse T lymphocytes, and Drosophila GM1 cells. The induction of hsps in G0 cells was distinct from that in heat-shocked cells in two respects. First, hsps with molecular weight around 25,000 were not induced in G0 cells, whereas most, if not all, high molecular weight (HMW) hsps were commonly induced both in G0 cells and in heat-shocked cells. Second, in contrast to the transient synthesis of hsps in heat-shocked cells, G0 cells continued to synthesize hsps at the stimulated rate for a relatively long period. These results suggest the possibility that high molecular weight hsps might function in a transition from the proliferating state to G0 or in maintaining G0 in the eucaryote.

Herpes simplex virus infection causes the accumulation of a heat-shock protein.

Abstract: A monoclonal antibody, produced from mice immunized with a herpes simplex virus (HSV)-infected cell extract, reacts with a molecule which is present in uninfected cells and which accumulates in large amounts during HSV 2 infection. In uninfected cells this molecule is growth regulated, in that exponentially growing cells have intense nuclear immunofluorescence, whereas confluent quiescent cells have little. It has a mol. wt. of 57 000 (p57) in exponential cells, and one of 61 000 (p61) in quiescent cells. In HSV 2-infected cells, p57 accumulates and nuclear and cytoplasmic immunofluorescence increases. In uninfected cells, p57 also accumulates during heat-shock treatment, and this is associated with a new immunofluorescence throughout the cytoplasm. We suggest that HSV 2 infection induces a cellular stress response which is involved in the shut-off of host cell polypeptide synthesis.