Effect of heat shock on ribosome synthesis in Drosophila melanogaster.

In Drosophila tissue culture cells, the synthesis of ribosomal proteins was inhibited by a 1-h 37 degrees C heat shock. Ribosomal protein synthesis was repressed to a greater extent than that of most other proteins synthesized by these cells at 25 degrees C. After a 1-h heat shock, when the cells were returned to 25 degrees C, the ribosomal proteins were much slower than most other 25 degrees C proteins to return to pre-heat shock levels of synthesis. Relative to one another, all the ribosomal proteins were inhibited and later recovered to normal levels of synthesis at the same rate and to the same extent. Unlike the ribosomal proteins, the precursor to the large rRNAs was continually synthesized during heat shock, although at a slightly reduced level, but was not processed. It was rapidly degraded, with a half-life of approximately 16 min. Pre-heat shock levels of synthesis, stability, and correct processing were restored only when ribosomal protein synthesis returned to at least 50% of that seen in non-heat-shocked cells.     

Development profile of the heat shock response in early embryos of Drosophila

Drosophila melanogaster embryos reared at 22 degrees C were subjected to a mild heat shock (40 min at 37 degrees C) at various ages in order to determine whether there are changes in the heat shock response during embryogenesis. The effects of the heat shock were measured by assaying (1), subsequent developmental abnormalities (2), developmental time (3), hatchability, and (4), the ability to synthesize the heat shock proteins as assayed by 35S-methionine pulse labeling followed by protein separations using both one-and two-dimensional polyacrylamide gel electrophoresis. Our data show that, first, proteins with molecular weights similar to those of six of the seven major heat shock proteins are normally found in the embryo at control temperatures (22 degrees C); second, that the pregastrula embryo (stages 2-6) is not capable of displaying any aspect of the heat shock response upon treatment, although it may possess all of the so-called heat shock proteins; third, that the complete heat shock response is acquired very rapidly by early gastrula embryos; and fourth, that the heat shock treatment brings about developmental delays and/or abnormalities, depending on the developmental stage of the embryo at the time of the treatment. These developmental abnormalities appear to stem from the failure of early embryos to completely inhibit their synthesis of non-heat-shock proteins. In the light of these findings, it becomes important not to base conclusions about the putative presence of a heat shock response in a particular tissue or developmental stage solely on the presence or absence of the heat shock proteins.     

Heat shock response of the archaebacterium Methanococcus voltae.

The general properties of the heat shock response of the archaebacterium Methanococcus voltae were characterized. The induction of 11 heat shock proteins, with apparent molecular weights ranging from 18,000 to 90,000, occurred optimally at 40 to 50 degrees C. Some of the heat shock proteins were preferentially enriched in either the soluble (cytoplasm) or particulate (membrane) fraction. Alternative stresses (ethanol, hydrogen peroxide, NaCl) stimulated the synthesis of subsets of the heat shock proteins as well as unique proteins. Western blot (immunoblot) analysis, in which antisera to Escherichia coli heat shock proteins (DnaK and GroEL) were used, did not detect any immunologically cross-reactive proteins. In addition, Southern blot analysis did not reveal any homology between M. voltae and four highly conserved heat shock genes, mopB and dnaK from E. coli and hsp70 genes from Drosophila species and Saccharomyces cerevisiae.     

Thermoinduced radioresistance of Escherichia coli cells and heat shock proteins

Radioresistance of E. coli cells is slightly increased (dose modification factor (DMF) = 1.2) with temperature elevated from 4 degrees to 43 degrees C at the time of gamma-irradiation. However, an appreciable effect of the thermoinduced radioresistance (DMF = 1.7) was observed when the wild-type cells were exposed to gamma-radiation at 15-43 degrees C (but not at 4 degrees C) after 30-min preincubation at 43 degrees C. This effect was absent in htpR mutants, defective in induction of heat shock proteins, and coupled with the decreased post-irradiation DNA degradation in gamma-irradiated htpR+ cells. It is suggested that heat shock proteins are involved in the thermoinduced radioresistance.     

Heat shock induces a decrease in incorporation of 8-azidoadenosine 5'-triphosphate into a 42 kilodalton protein in Drosophila salivary glands

The ATP photoaffinity analogue 8-azidoadenosine 5'-triphosphate (8N3ATP) was used to identify changes which occur in ATP binding proteins in Drosophila salivary glands following heat shock. Photolabeling experiments were done on salivary gland homogenates. Photoincorporation of 8N3ATP was observed in several proteins in both 25 degrees C control and 35 degrees C heat-shocked samples. A 42 kDa protein showed a decrease in the level of photoincorporation observed at saturation with the analogue following heat shock. A 2 min heat shock is enough to induce the effect. Protection against photolabeling was observed with low concentrations (5 microM) of ATP, while excess GTP did not protect, demonstrating that the nucleotide binding site is specific for ATP. The change is rapid enough to suggest that it is one of the earliest cellular changes in response to heat shock.     

Heat shock causes the collapse of the intermediate filament cytoskeleton in Drosophila embryos

Heat shock has a dramatic effect on the organization of the cytoplasm, causing the intermediate filament cytoskeleton to aggregate at the nucleus. This has previously been shown in cultured Drosophila and mammalian cells. In this paper we analyze the heat lability of the intermediate filament cytoskeleton in early Drosophila embryos by indirect immunofluorescence. At all stages of embryogenesis tested, the intermediate filament cytoskeleton, which is maternally provided, is severely disturbed by 30 min heat shock at 37 degrees C. After the nuclei have migrated to the subcortical cytoplasm, it collapses around them. Nuclei in all heat-shocked embryos are considerably enlarged and become displaced. Embryos before cellular blastoderm stage, in which heat shock protein synthesis is not inducible, are irreversibly arrested in development by heat shock. Embryos at or after cellular blastoderm, which do synthesize heat shock proteins in response to stress, are also immediately arrested in development but continue development when returned to 25 degrees C. We discuss the possibility that cytoplasmic events such as the intermediate filament cytoskeleton rearrangement may be involved in heat shock-mediated phenocopy induction.     

Escherichia coli dnaK null mutants are inviable at high temperature.

DnaK, a major Escherichia coli heat shock protein, is homologous to major heat shock proteins (Hsp70s) of Drosophila melanogaster and humans. Null mutations of the dnaK gene, both insertions and a deletion, were constructed in vitro and substituted for dnaK+ in the E. coli genome by homologous recombination in a recB recC sbcB strain. Cells carrying these dnaK null mutations grew slowly at low temperatures (30 and 37 degrees C) and could not form colonies at a high temperature (42 degrees C); furthermore, they also formed long filaments at 42 degrees C. The shift of the mutants to a high temperature evidently resulted in a loss of cell viability rather than simply an inhibition of growth since cells that had been incubated at 42 degrees C for 2 h were no longer capable of forming colonies at 30 degrees C. The introduction of a plasmid carrying the dnaK+ gene into these mutants restored normal cell growth and cell division at 42 degrees C. These null mutants showed a high basal level of synthesis of heat shock proteins except for DnaK, which was completely absent. In addition, the synthesis of heat shock proteins after induction in these dnaK null mutants was prolonged compared with that in a dnaK+ strain. The well-characterized dnaK756 mutation causes similar phenotypes, suggesting that they are caused by a loss rather than an alteration of DnaK function. The filamentation observed when dnaK mutations were incubated at a high temperature was not suppressed by sulA or sulB mutations, which suppress SOS-induced filamentation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Control of DNA topology during thermal stress in hyperthermophilic archaea: DNA topoisomerase levels, activities and induced thermotolerance during heat and cold shock in Sulfolobus

Plasmid topology varies transiently in hyperthermophilic archaea during thermal stress. As in mesophilic bacteria, DNA linking number (Lk) increases during heat shock and decreases during cold shock. Despite this correspondence, plasmid DNA topology and proteins presumably involved in DNA topological control in each case are different. Plasmid DNA in hyperthermophilic archaea is found in a topological form from relaxed to positively supercoiled in contrast to the negatively supercoiled state typical of bacteria, eukaryotes and mesophilic archaea. We have analysed the regulation of DNA topological changes during thermal stress in Sulfolobus islandicus (kingdom Crenarchaeota), which harbours two plasmids, pRN1 and pRN2. In parallel with plasmid topological variations, we analysed levels of reverse gyrase, topoisomerase VI (Topo VI) and the small DNA-binding protein Sis7, as well as topoisomerase activities in crude extracts during heat shock from 80 degrees C to 85-87 degrees C, and cold shock from 80 degrees C to 65 degrees C. Quantitative changes in reverse gyrase, Topo VI and Sis7 were not significant. In support of this, inhibition of protein synthesis in S. islandicus during shocks did not alter plasmid topological dynamics, suggesting that an increase in topoisomerase levels is not needed for control of DNA topology during thermal stress. A reverse gyrase activity was detected in crude extracts, which was strongly dependent on the assay temperature. It was inhibited at 65 degrees C, but was greatly enhanced at 85 degrees C. However, the intrinsic reverse gyrase activity did not vary with heat or cold shock. These results suggest that the control of DNA topology during stress in Sulfolobus relies primarily on the physical effect of temperature on topoisomerase activities and on the geometry of DNA itself. Additionally, we have detected an enhanced thermoresistance of reverse gyrase activities in cultures subject to prolonged heat shock (but not cold shock). This acquired thermotolerance at the enzymatic level is abolished when cultures are treated with puromycin, suggesting a requirement for protein synthesis.     

Expression profiles of low molecular mass heat shock proteins by Mycobacterium avium and Mycobacterium intracellulare

Closely related non-tuberculous mycobacterial species, Mycobacterium avium and Mycobacterium intracellulare, were compared for the profiles of their production of low molecular mass heat shock proteins at 45 degrees C, by performing polyacrylamide gel electrophoresis analysis of bacterial cell lysate proteins. All of the M. intracellulare but not M. avium strains potently increased the production of the 18-kDa heat shock protein, when cultured at 45 degrees C. Half of the M. intracellulare strains with high sensitivity to 45 degrees C produced not only the 18-kDa heat shock protein but also the 16-kDa heat shock protein at 45 degrees C. These findings indicate that M. avium and M. intracellulare differentially respond to 45 degrees C heat shock in terms of the production of low molecular mass heat shock proteins.     

Interaction of heat and salt shock in cultured tobacco cells

Cultured tobacco cells (Nicotiana tabacum L. var Wisconsin-38) developed tolerance to otherwise nonpermissive 54°C treatment when heat-shocked at 38°C (2 h) but not at 42°C. Heat-shocked cells (38°C) exhibited little normal growth when the 54°C stress came immediately after heat shock and normal growth when 54°C stress was administered 8 hours after heat shock. Heat shock extended the length of time that the cells tolerated 54°C. Tobacco cells developed tolerance to otherwise lethal 2% NaCl treatment when salt-shocked (1.2% NaCl for 3 hours). The time course for salt tolerance development was similar to that of thermotolerance. Heat-shocked cells (38°C) developed tolerance of nonpermissive salt stress 8 hours after heat shock. Alternatively, cells heat-shocked at 42°C exhibited immediate tolerance to lethal salt stress followed by a decline over 8 hours. Radioactive methionine incorporation studies demonstrated synthesis of heat shock proteins at 38°C. The apparent molecular weights range from 15 to 115 kilodaltons with a protein complex in the 15 to 20 kilodalton range. Synthesis of heat shock proteins appeared to persist at 42°C but with large decreases in incorporation into selected heat shock protein. During salt shock, the synthesis of normal control proteins was reduced and a group of salt shock proteins appeared 3 to 6 h after shock. Similarities between the physiology and salt shock proteins/heat shock proteins suggest that both forms of stress may share common elements.     

Heat shock response of Neurospora crassa: protein synthesis and induced thermotolerance.

At elevated temperatures, germinating conidiospores of Neurospora crassa discontinue synthesis of most proteins and initiate synthesis of three dominant heat shock proteins of 98,000, 83,000, and 67,000 Mr and one minor heat shock protein of 30,000 Mr. Postemergent spores produce, in addition to these, a fourth major heat shock protein of 38,000 Mr and a minor heat shock protein of 34,000 Mr. The three heat shock proteins of lower molecular weight are associated with mitochondria. This exclusive synthesis of heat shock proteins is transient, and after 60 min of exposure to high temperatures, restoration of the normal pattern of protein synthesis is initiated. Despite the transiency of the heat shock response, spores incubated continuously at 45 degrees C germinate very slowly and do not grow beyond the formation of a germ tube. The temperature optimum for heat shock protein synthesis is 45 degrees C, but spores incubated at other temperatures from 40 through 47 degrees C synthesize heat shock proteins at lower rates. Survival was high for germinating spores exposed to temperatures up to 47 degrees C, but viability declined markedly at higher temperatures. Germinating spores survived exposure to the lethal temperature of 50 degrees C when they had been preexposed to 45 degrees C; this thermal protection depends on the synthesis of heat shock proteins, since protection was abolished by cycloheximide. During the heat shock response mitochondria also discontinue normal protein synthesis; synthesis of the mitochondria-encoded subunits of cytochrome c oxidase was as depressed as that of the nucleus-encoded subunits.     

Acquired thermotolerance and heat shock proteins in thermophiles from the three phylogenetic domains.

Thermophilic organisms from each of the three phylogenetic domains (Bacteria, Archaea, and Eucarya) acquired thermotolerance after heat shock. Bacillus caldolyticus grown at 60 degrees C and heat shocked at 69 degrees C for 10 min showed thermotolerance at 74 degrees C, Sulfolobus shibatae grown at 70 degrees C and heat shocked at 88 degrees C for 60 min showed thermotolerance at 95 degrees C, and Thermomyces lanuginosus grown at 50 degrees C and heat shocked at 55 degrees C for 60 min showed thermotolerance at 58 degrees C. Determinations of protein synthesis during heat shock revealed differences in the dominant heat shock proteins for each species. For B. caldolyticus, a 70-kDa protein dominated while for S. shibatae, a 55-kDa protein dominated and for T. lanuginosus, 31- to 33-kDa proteins dominated. Reagents that disrupted normal protein synthesis during heat shock prevented the enhanced thermotolerance.     

Heat-shock proteins in membrane vesicles of Bacillus subtilis

Fractionation of B. subtilis cells after heat shock, from 37 degrees C to 54 degrees C, shows an increase in synthesis of proteins localized in cell membranes and a decrease in synthesis of proteins localized in cytosol. There is no such effect of heat shock at temperature of 45 degrees C. Autoradiograms of electrophoretically separated proteins, labelled during heat shock at 54 degrees C, reveal 26 heat-shock proteins (hsps) in membrane vesicles and 11 hsps in cytosol, five of which are common to both fractions. Heat shock at 45 degrees C induces 18 hsps localized in membrane vesicles and 13 hsps localized in cytosol, six of which are common to both fractions. Results are interpreted as showing a relevant role of membrane proteins in cell response to shock at high temperature, pointing to two steps of defense against heat stress.     

Inverse response of leukocyte heat shock proteins and DNA damage to exercise and heat

Elevated ambient temperature may exert an additional impact on the exercise-induced expression of heat shock proteins (HSP) and DNA damage in leukocytes. The protective functions of HSP include antioxidative and antiapoptotic effects and may prevent damage to DNA. Twelve athletes completed a continuous run (75% VO2max) on the treadmill, six at 28 degrees C and six at 18 degrees C room temperature. Leukocyte expression of HSP27 and inducible HSP70 was analyzed on mRNA- (RT-PCR) and protein-level (flow cytometry), while DNA damage was quantified by the comet assay. High ambient temperature induced an additional accumulation of HSP-mRNA and -protein in leukocytes compared with the exercise-induced expression at 18 degrees C. HSP27 showed a special heat sensitivity. Surprisingly, the increase of DNA damage was less pronounced after exercise at 28 degrees C compared to 18 degrees C although heat shock in vitro clearly induced DNA damage. The inverse relation between HSP and DNA damage may indicate functions of HSP which protect against exercise-induced DNA-damage in terms of thermotolerance or apoptosis.     

Genotoxicity evaluation of heat shock in gold fish (Carassius auratus)

Genotoxicity evaluation of heat shock was carried out in Carassius auratus. The genotoxicity end points studied were nuclear anomalies (micronucleus assay), chromosomal aberrations, DNA damage (comet assay) and cell proliferation. The heat shock temperatures used were 34 degrees C, 36 degrees C and 38 degrees C. The results demonstrated that heat shock causes the induction of micronucleus at all the three temperature studied. Heat shock also inhibited cell proliferation at 38 degrees C and caused aberrations in the metaphase chromosomes at 34 degrees C and 36 degrees C. Comet assay demonstrated single strand DNA damage at all the three temperatures. The results obtained indicate that heat shock is a genotoxicant.     

A family of related proteins is encoded by the major Drosophila heat shock gene family.

At least four proteins of 70,000 to 75,000 molecular weight (70-75K) were synthesized from mRNA which hybridized with a cloned heat shock gene previously shown to be localized to the 87A and 87C heat shock puff sites. These in vitro-synthesized proteins were indistinguishable from in vivo-synthesized heat shock-induced proteins when analyzed on sodium dodecyl sulfate-polyacrylamide gels. A comparison of the pattern of this group of proteins synthesized in vivo during a 5-min pulse or during continuous labeling indicates that the 72-75K proteins are probably not kinetic precursors to the major 70K heat shock protein. Partial digestion products generated with V8 protease indicated that the 70-75K heat shock proteins are closely related, but that there are clear differences between them. The partial digestion patterns obtained from heat shock proteins from the Kc cell line and from the Oregon R strain of Drosophila melanogaster are very similar. Genetic analysis of the patterns of 70-75K heat shock protein synthesis indicated that the genes encoding at least two of the three 72-75K heat shock proteins are located outside of the major 87A and 87C puff sites.