Synthesis of heat shock proteins in quail red blood cells following brief, physiologically relevant increases in whole body temperature

Cultured RBCs from quail respond to thermal stress (heat shock) by a rapid and dramatic change in gene expression. This change in gene expression includes the new and/or enhanced non-coordinate synthesis of a small group of heat shock polypeptides (HSPs) having molecular masses of 90,000, 70,000 and 26,000. RBCs obtained from hyperthermic quail exhibit a change in gene expression similar to that observed in RBCs heat-shocked in vitro. Since in vitro studies have linked the synthesis of HSPs in heat-stressed cells with thermotolerance, the similar change in gene expression in RBCs from hyperthermic quail suggests that, here too, this cellular response may be an important homeostatic mechanism by which avian RBCs cope with and/or survive hyperthermic conditions.     

Heat shock protein expression in thermotolerant and thermosensitive lines of cotton

The expression of heat shock proteins (HSPs) was compared between genetically characterized heat tolerant and heat sensitive lines of cotton (Gossypium hirsutum andG. barbadense) using electrophoretic analysis ofin vivo labelled proteins. No differences were observed between the two lines with regard to: the temperature at which HSP synthesis was induced (37°C); the temperature at which HSP synthesis was maximal (45°C); the rates of recovery from HSP synthesis; the duration of HSP synthesis; or the major size classes of HSPs expressed in these two lines. Several HSPs were identified on 2D gels which were expressed uniquely in either the tolerant or sensitive cotton line. However, the HSP pattern displayed in a heat tolerant BC-3 individual was that of the heat sensitive parent.Abbreviations HSPs heat shock proteins - IEF isoelecticfocusing     

Expression of heat shock and cold shock proteins in the gorgonian Leptogorgia virgulata

In this study, we analyzed the response of the temperate, shallow-water gorgonian, Leptogorgia virgulata, to temperature stress. Proteins were pulse labeled with (35)S-methionine/cysteine for 1 h to 2 h at 22 degrees C (control), or 38 degrees C, or for 4 h at 12.5 degrees C. Heat shock induced synthesis of unique proteins of 112, 89, and 74 kDa, with 102, 98 and 56 kDa proteins present in the control as well. Cold shock from 22 degrees C-12.5 degrees C induced the synthesis of a 25 kDa protein, with a 44 kDa protein present in the control as well. Control samples expressed unique proteins of 38, and 33 kDa. Non-radioactive proteins expressed under the same conditions as above, as well as natural field conditions, were tested for reactivity with antibodies to heat shock proteins (HSPs). HSP60 was the major protein found in L. virgulata. Although HSP47, HSP60, and HSP104 were present in all samples, the expression of HSP60 was enhanced in heat stressed colonies, while HSP47 and HSP104 expression were greatest in cold shocked samples. Inducible HSP70 was expressed in cold-shocked, heat-shocked, and field samples. Constitutively expressed HSP70 was absent from all samples. The expression of HSP90 was limited to heat shocked colonies. The expression of both HSP70 and HSP104 suggests that the organism may also develop a stress tolerance response.     

The effect of heat shock on primary cultures of brain capillary endothelium: inhibition of assembly of zonulae occludentes and the synthesis of heat-shock proteins

Subjecting primary cultures of bovine brain microvessel endothelial cells to thermal stress (heat shock) results in: (1) an inhibition of further tight junction assembly, (2) the disappearance and/or disassembly of tight junctions, (3) a 30-fold increase in the number of plasmic fracture (PF)-face intramembrane particles, and (4) the new and/or enhanced synthesis of at least three heat-shock polypeptides (HSPs) with molecular masses of approximately 100,000, 90,000 and 70,000. Endothelial cells which are heat-shocked and allowed to recover at 37 degrees C exhibit, within the first 2 h, a marked depression in the synthesis of HSPs and the new and/or enhanced synthesis of a 47,000 dalton "recovery" polypeptide. In later periods of recovery (2-4 h), the synthesis of this polypeptide is even more pronounced and is accompanied by the new and/or enhanced synthesis of a polypeptide(s) with a molecular mass of 35 to 37,000. The appearance of these "recovery protein(s)" in the endothelial cells is concomitant with a decrease in the number of PF-face intramembrane particles and the resumption of tight junction assembly. Results of this study suggest that some of the HSPs synthesized by thermally-stressed cultures of brain endothelial cells may activate or be directly involved in a mechanism(s) to ensure survival of these cells by decreasing membrane fluidity and stabilizing the plasma membrane of these cells. Moreover, our results also suggest that the recovery of these cells from the stress of heat shock is accompanied by the synthesis of "recovery" proteins which, in some manner, may be directly involved in, or necessary for, rapidly reversing the membrane-stabilizing effect of heat shock by promoting membrane fluidity and the apparent amplified synthesis and assembly and/or reassembly of tight junctions.     

Inhibition of heat shock protein synthesis and thermotolerance by cycloheximide

Chinese hamster ovary (CHO) cells were exposed to a 43 degrees C, 15-min heat shock to study the relationship between protein synthesis and the development of thermotolerance. The 43 degrees C heat shock triggered the synthesis of three protein families having molecular weights of 110,000, 90,000, and 65,000 (HSP). These proteins were synthesized at 37 and 46 degrees C. This heat shock also induced the development of thermotolerance, which was measured by incubating the cells at 46 degrees C 4 h after the 43 degrees C heat treatment. CHO cells were also exposed to 20 micrograms/ml of cycloheximide for 30 min at 37 degrees C, 15 min at 43 degrees C, and 4 h at 37 degrees C. This treatment inhibited the enhanced synthesis of the Mr 110,000, 90,000, and 65,000 proteins. The cycloheximide was then washed out and the cells were incubated at 46 degrees C. HSP synthesis did not recover during the 46 degrees C incubation. This cycloheximide treatment also partially inhibited the development of thermotolerance. These results suggest that for CHO cells to express thermotolerance when exposed to the supralethal temperature of 46 degrees C protein synthesis is necessary.     

Detailed characterization of heat shock protein synthesis and induced thermotolerance in seedlings of Sorghum bicolor L.

Tolerance of both protein synthesis and seedling growth to apreviously lethal high temperature can be induced by prior exposureto a sub-lethal temperature during which the synthesis of heatshock proteins (HSPs) occurs. In this study, a thermal gradientbar was used to measure the physiological effects of temperatureon seedlings of sorghum (Sorghum bicolor L.) in conjunctionwith studies of gene expression. The duration of HSP synthesis,both during continued high temperature treatment or on returnto normal temperatures, was found to be very finely modulatedand was dependent on the severity of the initial heat shock.The synthesis of heat shock proteins and the induction of thermotolerancewere rapid, reversible and reinducible phenomena. Maximal thermotolerancewas obtained after treatments that induced the full complementof HSPs. Subsequent treatments that repressed HSP synthesis,also abolished thermotolerance. The presence of HSPs, however,was not sufficient for the tissue to be in a thermotolerantstate and the results suggest that either their de novo synthesis,or some other factor, is required for the induction of thermotolerance.Pre-existing HSPs did not inhibit the synthesis of new HSPs.Although the kinetics of the synthesis of HSPs and the developmentof thermotolerance show a tight correlation, the kinetics ofthe decay of thermotolerance and the degradation of HSPs werenot linked. The functional state or distribution of HSPs maywell change during the recovery process. Key words: Heat shock, thermotolerance, Sorghum bicolor, growth, protein synthesis     

Expression of heat shock proteins in response to high and low temperature extremes in diapausing pharate larvae of the gypsy moth,Lymantria dispar

Diapausing pharate first instars of the gypsy moth, Lymantria dispar, respond to high temperature (37–41°C) by suppressing normal protein synthesis and synthesizing a set of seven heat shock proteins with M_rs of 90,000, 75,000, 73,000, 60,000, 42,000, 29,000, and 22,000 as determined by SDS-PAGE. During recovery at 25°C from heat shock, synthesis of the heat shock proteins gradually decreases over a period of 6 h, while normal protein synthesis is restored. A subset of these same heat shock proteins is also expressed during recovery at 4°C or 25°C from brief exposures to low temperature (-10 to 20°C), and its expression is more intense with increased severity of cold exposure. During recovery at 4°C after 24 h at ?20°C, both 90,000 and 75,000 M_r heat shock proteins are expressed for more than 96 h. While normal protein synthesis is suppressed during heat shock and recovery from heat shock, normal protein synthesis coincides with synthesis of the heat shock proteins during recovery from low temperatures, thus implying that expression of the heat shock proteins is not invariably linked to suppression of normal protein synthesis. Western transfer, using a monoclonal antibody that recognizes the inducible form of the human 70,000 M_r heat shock protein, demonstrates that immunologically related proteins in the gypsy moth are expressed at 4°C and during recovery from cold and heat shock.     

植物热激蛋白的功能及其基因表达的调控

本文介绍了植物热激蛋白的产生、分布和分类。着重论述了热激反应的特点、植物热激蛋白的功能、热激基因表达与调控的研究进展     

Application of heat shock proteins as stress markers in aquatic organisms using endemic Baikal amphipods as an example

When heat shock proteins (HSPs) are used as biomarkers in monitoring studies of aquatic ecosystems, it is necessary to take into account the specificity of synthesis of these proteins in various organisms. This especially applies to endemic species and species with narrow ranges of adaptation for specific conditions in certain water bodies. In this study, we assessed the possibility to use HSPs as molecular stress markers in species with a narrow niche breadth using endemic Baikal amphipods (Crustacea, Amphipoda) as an example. The effect of stress induced by toxicants and temperature has been assessed. Proteins of families HSP70 and lowmolecular-weight HSP related to α-crystallins were used as biomarkers. Temperature-and toxicant-induced stresses induced low-molecular-weight HSP synthesis in the endemic amphipod species studied. However, induction of HSP70 synthesis in the same species after temperature stress has not been detected. The specificity of synthesis of HSP70 is discussed. The results obtained in this study suggest that low-molecular-weight HSPs can be used as stress markers in Baikal species and species with a narrow niche breadth.     

The role of oxidative stress in the induction of Drosophila heat-shock proteins

The role of oxidative stress in the induction of heat-shock proteins (HSPs) was studied in Drosophila Kc cells by comparing the effects of two different inducers, temperature stress and reoxygenation following a period of anoxia, on cellular respiration, thiol status, and the accumulation of HSPs. A heat shock from 25 to 37 degrees C caused a 60% increase in the rate of O2 uptake but caused little oxidative stress as indicated by a constant level of reduced glutathione, a slight increase in oxidized glutathione, and no change in protein sulfhydryls. Heat shock resulted in a pronounced accumulation of HSPs which was not inhibited by anoxic conditions. A different HSP inducer, reoxygenation following anoxia, resulted in an overall inhibition of respiration, the appearance of CN -insensitive O2 uptake, a 50% decrease in the level of reduced glutathione and a fourfold increase in the ratio of oxidized to reduced glutathione. Despite these indicators of oxidative stress, HSP synthesis was less pronounced than observed during heat shock and was not affected by antioxidants. Oxidative stress may induce HSP synthesis in some cases but is not responsible for HSP synthesis during a heat shock.     

Application of heat shock proteins as stress markers in aquatic organisms using endemic Baikal amphipods as an example

When heat shock proteins (HSPs) are used as biomarkers in monitoring studies of aquatic ecosystems, it is necessary to take into account the specificity of synthesis of these proteins in various organisms. This especially applies to endemic species and species with narrow ranges of adaptation for specific conditions in certain water bodies. In this study, we assessed the possibility to use HSPs as molecular stress markers in species with a narrow niche breadth using endemic Baikal amphipods (Crustacea, Amphipoda) as an example. The effect of stress induced by toxicants and temperature has been assessed. Proteins of families HSP70 and low-molecular-weight HSP related to alpha-crystallins were used as biomarkers. Temperature- and toxicant-induced stresses induced low-molecular-weight HSP synthesis in the endemic amphipod species studied. However, induction of HSP70 synthesis in the same species after temperature stress has not been detected. The specificity of synthesis of HSP70 is discussed. The results obtained in this study suggest that low-molecular-weight HSPs can be used as stress markers in Baikal species and species with a narrow niche breadth.     

植物热激蛋白的功能及其基因表达的调控

本文介绍了植物热激蛋白的产：生、分布和分类。着重论述了热激反应的特点、植物热激蛋白的功能、热激基因表达与调控的研究进展。     

Heat shock applied early in sporulation affects heat resistance of Bacillus megaterium spores.

Cells of Bacillus megaterium 27 were challenged by a 30-min heat shock at 45 degrees C during various sporulation stages and then shifted back to a temperature permissive for sporulation (27 degrees C), at which they developed spores. Heat shock applied at 120 min after the end of the exponential phase induced synthesis of heat shock proteins (HSPs) in the sporangia and delayed the inactivation of spores at 85 degrees C. Several HSPs, mainly HSP 70, could be detected in the cytoplasm of these spores. An analogous HSP, the main HSP induced by increased temperature during growth, belongs to the GroEL group according to its N-terminal sequence. The identity of this protein was confirmed by Western blot (immunoblot) analysis with polyclonal antibodies against B. subtilis GroEL. Sporangia treated by heat shock immediately or 240 min after exponential phase also synthesized HSPs, but none of them could be detected in the spores in an appreciable amount. These spores showed only a slightly increased heat resistance.     

Heat shock gene expression in Xenopus laevis A6 cells in response to heat shock and sodium arsenite treatments

Continuous exposure of a Xenopus laevis kidney epithelial cell line, A6, to either heat shock (33 degrees C) or sodium arsenite (50 microM) resulted in transient but markedly different temporal patterns of heat-shock protein (HSP) synthesis and HSP 70 and 30 mRNA accumulation. Heat-shock-induced synthesis of HSPs was detectable within 1 h and reached maximum levels by 2-3 h. While sodium arsenite induced the synthesis of some HSPs within 1 h, maximal HSP synthesis did not occur until 12 h. The pattern of HSP 70 and 30 mRNA accumulation was similar to the response observed at the protein level. During recovery from heat shock, a coordinate decline in HSPs and HSP 70 and 30 mRNA was observed. During recovery from sodium arsenite, a similar phenomenon occurred during the initial stages. However, after 6 h of recovery, HSP 70 mRNA levels persisted in contrast to the declining HSP 30 mRNA levels. Two-dimensional polyacrylamide gel electrophoresis revealed the presence of 5 HSPs in the HSP 70 family, of which two were constitutive, and 16 different stress-inducible proteins in the HSP 30 family. In conclusion, heat shock and sodium arsenite induce a similar set of HSPs but maximum synthesis of the HSP is temporally separated by 12-24 h.     

Cell-specific expression of heat shock proteins in chicken reticulocytes and lymphocytes

We have found that chicken reticulocytes respond to elevated temperatures by the induction of only one heat shock protein, HSP70, whereas lymphocytes induce the synthesis of all four heat shock proteins (89,000 mol wt, HSP89; 70,000 mol wt, HSP70; 23,000 mol wt, HSP23; and 22,000 mol wt, HSP22). The synthesis of HSP70 in lymphocytes was rapidly induced by small increases in temperature (2 degrees-3 degrees C) and blocked by preincubation with actinomycin D. Proteins normally translated at control temperatures in reticulocytes or lymphocytes were not efficiently translated after incubation at elevated temperatures. The preferential translation of mRNAs that encode the heat shock proteins paralleled a block in the translation of other cellular proteins. This effect was most prominently observed in reticulocytes where heat shock almost completely repressed alpha- and beta-globin synthesis. HSP70 is one of the major nonglobin proteins in chicken reticulocytes, present in the non-heat-shocked cell at approximately 3 X 10(6) molecules per cell. We compared HSP70 from normal and heat-shocked reticulocytes by two-dimensional gel electrophoresis and by digestion with Staphylococcus aureus V8 protease and found no detectable differences to suggest that the P70 in the normal cell is different from the heat shock-induced protein, HSP70. P70 separated by isoelectric focusing gel electrophoresis into two major protein spots, an acidic P70A (apparent pl = 5.95) and a basic P70B (apparent pl = 6.2). We observed a tissue-specific expression of P70A and P70B in lymphocytes and reticulocytes. In lymphocytes, P70A is the major 70,000-mol-wt protein synthesized at normal temperatures whereas only P70B is synthesized at normal temperatures in reticulocytes. Following incubation at elevated temperatures, the synthesis of both HSP70A and HSP70B was rapidly induced in lymphocytes, but synthesis of only HSP70B was induced in reticulocytes.     

Induction of heat shock proteins in Chinese hamster ovary cells and development of thermotolerance by intermediate concentrations of puromycin

During 4 hr after puromycin (PUR: 20 micrograms/ml) treatment, the synthesis of three major heat shock protein families (HSPs: Mr = 110,000, 87,000, and 70,000) was enhanced 1.5-fold relative to that of untreated cells, as studied by one-dimensional gel electrophoresis. The increase of unique HSPs, if studied with two-dimensional gels, would probably be much greater. In parallel, thermotolerance was observed at 10(-3) isosurvival as a thermotolerance ratio (TTR) of either 2 or greater than 5 after heating at either 45.5 degrees C or 43 degrees C, respectively. However, thermotolerance was induced by only intermediate concentrations (3-30 micrograms/ml) of puromycin that inhibited protein synthesis by 15-80%; a high concentration of PUR (100 micrograms/ml) that inhibited protein synthesis by 95% did not induce either HSPs or thermotolerance. Also, thermotolerance was never induced by any concentration (0.01-10 micrograms/ml) of cycloheximide that inhibited protein synthesis by 5-94%. Furthermore, after PUR (20 micrograms/ml) treatment, the addition of cycloheximide (CHM: 10 micrograms/ml), at a concentration that reduces protein synthesis by 94%, inhibited both thermotolerance and synthesis of HSP families. Thus, thermotolerance induced by intermediate concentrations of PUR correlated with an increase in newly synthesized HSP families. This thermotolerance phenomenon was compared with another phenomenon termed heat resistance and observed when cells were heated at 43 degrees C in the presence of CHM or PUR immediately after a 2-hr pretreatment with CHM or PUR. Heat protection increased with inhibition of synthesis of both total protein and HSP families. Moreover, this heat protection decayed rapidly as the interval between pretreatment and heating increased to 1-2 hr, and did not have any obvious relationship to the synthesis of HSP families. Therefore, there are two distinctly different pathways for developing thermal resistance. The first is thermotolerance after intermediate concentrations of PUR treatment, and it requires incubation after treatment and apparently the synthesis of HSP families. The second is resistance to heat after CHM or PUR treatment immediately before and during heating at 43 degrees C, and it apparently does not require synthesis of HSP families. This second pathway not requiring the synthesis of HSP families also was observed by the increase in thermotolerance at 45.5 degrees C caused by heating at 43 degrees C after cells were incubated for 2-4 hr following pretreatment with an intermediate concentration of PUR.