Stress Protein and Crystallin Synthesis During Heat Shock and Transdifferentiation of Embryonic Chick Neural Retina Cells

Embryonic chick neural retina responds to heat shock by the synthesis of "stress" polypeptides with molecular weights of 85 and 70 kd. Both stress proteins are synthesised from newly-transcribed messenger RNA. Sodium arsenite induces an additional stress protein of MW 25 kd. The heat shock response does not change during culture and subsequent transdifferentiation, and crystallin synthesis is not coinducible with the heat-shock proteins. We have also examined the pattern of protein synthesis at various stages of culture in both monolayer and aggregate systems; although changes in the protein synthetic profine are evident, there is no stress protein induction above basal levels at any time. Whilst mammalian α crystallin (B₂ chain) exhibits considerable homology to four small Drosophila heat-shock proteins, no significant antigenic similarity is apparent between δ crystallin and the major avian heat shock proteins. Thus during transdifferentiation, (a) the crystallin proteins do not behave in a manner analogous to stress proteins; moreover (b) crystallin production is not mediated by stress proteins resulting from a culture-induced stress response.     

Heat shock response of the rat lens

The sequence relationship between the small heat shock proteins and the eye lens protein alpha-crystallin (Ingolia, T. D., and E. E. Craig, 1982, Proc. Natl. Acad. Sci. USA, 79: 2360-2364) prompted us to subject rat lenses in organ culture to heat shock and other forms of stress. The effects on protein synthesis were followed by labeling with [35S]methionine and analysis by one- and two-dimensional gel electrophoresis and fluorography. Heat shock gave a pronounced induction of a protein that could be characterized as the stress protein SP71. This protein probably corresponds to the major mammalian heat shock protein hsp70. Also two minor proteins of 16 and 85 kD were induced, while the synthesis of a constitutive heat shock-related protein, P73, was considerably increased. The synthesis of SP71 started between 30 and 60 min after heat shock, reached its highest level after 3 h, and had stopped again after 8 h. In rat lenses that were preconditioned by an initial mild heat shock, a subsequent shock did not cause renewed synthesis of SP71. This effect resembles the thermotolerance phenomenon observed in cultured cells. The proline analogue azetidine-2-carboxylic acid, zinc chloride, ethanol, and calcium chloride did not, under the conditions used, induce stress proteins in the rat lens. Sodium arsenite, however, had very much the same effects as heat shock. Calcium ionophore A23187 specifically and effectively induced the synthesis of the glucose-regulated protein GRP78. No special response to stress on crystallin synthesis was noticed.     

Heat shock effect on glutathione and superoxide dismutase in Tetrahymena pyriformis

Intracellular levels of total glutathione and cytosolic superoxide dismutase activity were assayed in cells from Tetrahymena pyriformis either exposed to sub-lethal (34°C) or to lethal heat shock (39°C). The results showed that glutathione levels decrease to 60% of normal values after a sub-lethal heat shock for 1 hour. This change is part of the heat shock response, since the effect is reversed as soon as cells are brought to their normal growing temperature. Using actinomycin D, which blocks the synthesis of high molecular weight hsp (Galego and Rodrigues-Pousada, 1985), prior to thermal stress, the fall in total glutathione is not observed, suggesting a partial correlation with the synthesis of these stress proteins. Using cells pre-exposed to a sub-lethal heat shock, a subsequent short severe heat shock does not lead to a significant decrease of the glutathione content. Superoxide dismutase (SOD) activity is not significantly induced after either a short period at 34°C or a prolonged treatment at the same temperature.     

Yeast thermotolerance does not require protein synthesis.

Heat shock at 37 degrees C induces synthesis of stress (heat shock) proteins in Saccharomyces cerevisiae and also induces thermotolerance. Amino acid analogs that are powerful inducers of stress protein synthesis failed to induce thermotolerance, suggesting that the stress proteins do not play a causal role in acquired thermotolerance at 37 degrees C. This suggestion was confirmed by the observation that protein synthesis was not required for the induction of thermotolerance at 37 degrees C.     

Specific protection from phenocopy induction by heat shock

Mild heat treatments applied to whole animals or cell cultures of Drosophila prior to lethal heat shocks result in increased survival and protection against phenocopy induction. The optimal condition for the preliminary mild heat treatment is that which induces the synthesis of heat-shock proteins but does not turn off the protein synthesis that is in progress. Recovery of protein synthesis but not RNA synthesis following a drastic heat shock is much enhanced by the pretreatments. The results suggest that the protection for survival and against phenocopy induction is due to storage of messenger RNA.     

The induction of stress-related proteins by lead

Differential inductive effects of lead on protein synthesis in rat fibroblasts and kidney epithelial cells were examined. The lead was administered as lead glutamate, a complex known to introduce lead into cells. Lead exposure induced the synthesis of three proteins which constitute two separate stress protein subgroups. Two of these proteins have been previously identified as the glucose-regulated proteins because their synthesis is induced by reagents which perturb glucose utilization. The third protein is inducible by several sulfhydryl-binding reagents including lead. This third protein has been compared with a protein, p32/6.3, of very similar size and isoelectric point, which has been associated with lead-induced intranuclear inclusion bodies. However, several features, including one-dimensional peptide maps, indicated that the third protein and p32/6.3 are not identical. The three lead-induced proteins are distinguished from the major group of stress proteins by their relative insensitivity to heat stress. Lead glutamate, on the other hand, induces neither the heat shock protein 70 nor metallothionein, both of which are strongly induced by several metals including cadmium, zinc, and mercury.     

A step towards understanding plant responses to multiple environmental stresses: a genome‐wide study

In natural habitats, especially in arid areas, plants are often simultaneously exposed to multiple abiotic stresses, such as salt, osmotic and heat stresses. However, most analyses of gene expression in stress responses examine individual stresses. In this report, we compare gene expression in individual and combined stresses. We show that combined stress treatments with salt, mannitol and heat induce a unique pattern of gene expression that is not a simple merge of the individual stress responses. Under multiple stress conditions, expression of most heat and salt stress‐responsive genes increased to levels similar to or higher than those measured in single stress conditions, but osmotic stress‐responsive genes increased to lower levels. Genes up‐regulated to higher levels under multiple stress condition than single stress conditions include genes for heat shock proteins, heat shock regulators and late embryogenesis abundant proteins (LEAs), which protect other proteins from damage caused by stresses, suggesting their importance in multiple stress condition. Based on this analysis, we identify candidate genes for engineering crop plants tolerant to multiple stresses.     

Selective substrate supply in the regulation of yeast de novo sphingolipid synthesis

The heat stress response of Saccharomyces cerevisiae is characterized by transient cell cycle arrest, altered gene expression, degradation of nutrient permeases, trehalose accumulation, and translation initiation of heat shock proteins. Importantly heat stress also induces de novo sphingolipid synthesis upon which many of these subprograms of the heat stress response depend. Despite extensive data addressing the roles for sphingolipids in heat stress, the mechanism(s) by which heat induces sphingolipid synthesis remains unknown. This study was undertaken to determine the events and/or factors required for heat stress-induced sphingolipid synthesis. Data presented indicate that heat does not directly alter the in vitro activity of serine palmitoyltransferase (SPT), the enzyme responsible for initiating de novo sphingolipid synthesis. Moreover deletion of the small peptide Tsc3p, which is thought to maximize SPT activity, specifically reduced production of C(20) sphingolipid species by over 70% but did not significantly decrease overall sphingoid base production. In contrast, the fatty-acid synthase inhibitor cerulenin nearly completely blocked sphingoid base production after heat, indicating a requirement for endogenous fatty acids for heat-mediated sphingoid base synthesis. Consistent with this, genetic studies show that fatty acid import does not contribute to heat-induced de novo synthesis under normal conditions. Interestingly the absence of medium serine also ameliorated heat-induced sphingoid base production, indicating a requirement for exogenous serine for the response, and consistent with this finding, disruption of synthesis of endogenous serine did not affect heat-induced sphingolipid synthesis. Serine uptake assays indicated that heat increased serine uptake from medium by 100% during the first 10 min of heat stress. Moreover treatments that increase serine uptake in the absence of heat including acute medium acidification and glucose treatment also enhanced de novo sphingoid base synthesis equivalent to that induced by heat stress. These data agree with findings from mammalian systems that availability of substrates is a key determinant of flux through sphingolipid synthesis. Moreover data presented here indicate that SPT activity can be driven by several factors that increase serine uptake in the absence of heat. These findings may provide insights into the many systems in which de novo synthesis is increased in the absence of elevated in vitro SPT activity.     

Abnormal proteins as the trigger for the induction of stress responses: heat, diamide, and sodium arsenite

Thermotolerance and synthesis of heat shock proteins are induced in cells in response to a variety of environmental stresses. We examined the suggestion of Hightower (1980) that modifications of intracellular proteins may be the triggering event that induces heat shock protein synthesis and thermotolerance. We did so by modifying cellular proteins, using diamide, a sulfhydryl oxidizing agent, and dithio-bis (succinimidyl propionate), an agent that cross-links bifunctional amino groups. Both of these agents induced heat shock proteins and thermotolerance in CHO (HA-1) cells. Furthermore, we observed cross-resistance and self-tolerance with three seemingly unrelated stimuli (diamide, heat, and sodium arsenite). This observation suggests that the induction of protective responses to these stimuli is mediated by a common mechanism. The results support the hypothesis that production of abnormal proteins by various stresses induces the stress responses as well as tolerance.     

The molecular chaperone Hsp78 confers compartment-specific thermotolerance to mitochondria

Hsp78, a member of the family of Clp/Hsp100 proteins, exerts chaperone functions in mitochondria of S. cerevisiae which overlap with those of mitochondrial Hsp70. In the present study, the role of Hsp78 under extreme stress was analyzed. Whereas deletion of HSP78 does not affect cell growth at temperatures up to 39 decrees C and cellular thermotolerance at 50 degrees C, Hsp78 is crucial for maintenance of respiratory competence and for mitochondrial genome integrity under severe temperature stress (mitochondrial thermotolerance). Mitochondrial protein synthesis is identified as a thermosensitive process. Reactivation of mitochondrial protein synthesis after heat stress depends on the presence of Hsp78, though Hsp78 does not confer protection against heat-inactivation to this process. Hsp78 appears to act in concert with other mitochondrial chaperone proteins since a conditioning pretreatment of the cells to induce the cellular heat shock response is required to maintain mitochondrial functions under severe temperature stress. When expressed in the cytosol, Hsp78 can substitute for the homologous heat shock protein Hsp104 in mediating cellular thermotolerance, suggesting a conserved mode of action of the two proteins. Thus, proteins of the Clp/Hsp100-family located in the cytosol and within mitochondria confer compartment-specific protection against heat damage to the cell.     

Protein response of insect cells to bioreactor environmental stresses

Protein expression of Spodoptera frugiperda (Sf9) insect cells was characterized upon exposure to environmental stresses typically present in bioreactors including heat shock, oxygen deprivation, shear stress, change of pH, and salinity or ethanol shock. This study fills the void in knowledge as to how bioreactor hydrodynamics, anoxia, small changes in pH as well as salinity alterations due to pH control or exposure to ethanol used in asepsis treatments affect protein expression in Sf9 cells. Heat shock at 43 degrees C induced proteins at 83 kDa, 68-78 kDa and six small heat shock proteins (hsps) at 23-15.5 kDa. Anaerobic conditions in CO2 atmosphere reduced significantly the normal protein synthesis and induced a small subset of heat shock proteins at 70 kDa. Oxygen deprivation in nitrogen atmosphere transiently induces the 70 kDa proteins and had minor effects on the normal protein synthesis. Exposure to increased salinity or ethanol concentration failed to trigger the stress response, but may extensively inhibit the induction of normal proteins even though there was a negligible change in cell viability. Shear stress that had a major reducing effect on cell viability did not change the protein synthesis profile of Sf9 cells. Both long and short term exposures to small pH changes had negligible effects on protein synthesis.     

Localization of the 70000 Dalton Heat-induced protein in the nuclear matrix of BHK cells

The exposure of exponentially growing BHK cells to supranormal temperatures (41–44 °C, for 15 min to 1 h) induces the synthesis of a new set of proteins, the heat shock proteins, while the synthesis of proteins made before heat shock is repressed at 43 °C. Among the two major heat shock proteins induced, of molecular weight 70 K and 68 K, only the 70 kD protein is found bound to the nuclear matrix. This protein is resolved differently from the normal matrix proteins by isoelectric focusing and, when blotted, does not react with antibodies directed against nuclear matrices. These results show that the 70 kD heat shock protein is a new protein transferred from the cytoplasm to the nucleus, where it binds to the nuclear matrix, suggesting a structural role for this protein.     

Chemical Induction of Stress Proteins Does Not Induce Splicing Thermotolerance under Conditions Producing Survival Thermotolerance

Cell survival during a severe heat stress can be enhanced when heat shock proteins are induced prior to the severe heat treatment. Induction can be accomplished either by heat or chemical treatments. The increase in survival at these severe elevated temperatures after pretreatment has been referred to as thermotolerance, which we now refer to as survival thermotolerance. It has also been shown previously that mild heat treatment allows splicing in cells subjected to a severe heat treatment, now referred to as splicing thermotolerance. The experiments shown here demonstrate that even though chemical induction of the heat shock proteins leads to survival thermotolerance, this same treatment does not induce splicing thermotolerance. These are the first results that demonstrate at least two distinct aspects of thermotolerance.     

Arsenate induces stress proteins in cultured rat myoblasts

The induction of stress proteins was examined in rat myoblast cultures by two-dimensional gel electrophoresis. Data obtained by this analysis led to the following observations. (a) Arsenate, which behaves as a phosphate analogue in cellular phosphate-transfer reactions, stresses cultured rat cells and induces the synthesis of a unique set of proteins. (b) Most of the proteins synthesized after the addition of arsenate are identical to proteins synthesized in rat myoblasts in response to heat shock or arsenite stress. (c) However, both arsenic salts induce the synthesis of two unique proteins not induced by heat shock. (d) Five 25-30-kdalton stress proteins of rat cells do not contain methionine residues. (e) A majority of the proteins synthesized in stressed myogenic cells are also induced by stress in other rat cells such as hepatoma cells, pituitary tumor cells, and fibroblasts. The 25-30-kdalton stress-related proteins identified in myogenic cells, on the other hand, are induced in fibroblasts but not hepatoma or pituitary cells.     

Heat-stable and heat-labile thymidylate synthases B of Bacillus subtilis: comparison of the nucleotide and amino acid sequences

Heat treatment of wild-type Escherichia coli cells led to a transient relaxation of negatively supercoiled plasmid DNA and there was no recovery of DNA torsional strain in the DNA in gyrA mutant cells. After heat treatment, DnaK and GroEL proteins were synthesized continuously in the gyrA mutant cells, whereas they were synthesized only transiently in wild-type cells. Thus, change in superhelical density of the DNA correlated with the temperature-induced expression of heat shock proteins. Inhibitors of DNA gyrase (nalidixic acid, novobiocin), an organic solvent (ethanol) and a psychotropic drug (chlorpromazine) all stimulated relaxation of cellular DNA over the same concentration range that induces heat shock proteins. As DNA relaxation was induced by heat treatment or chemicals in an rpoH mutant, the process is not the result of induced synthesis of heat shock proteins.     

Establishment of thermotolerance in maize by exposure to stresses other than a heat shock does not require heat shock protein synthesis

Maize (Zea mays) seedlings were pretreated prior to heat shock with either a progressive water stress of −0.25 megapascal PEG/hour from 0 to −1.25 megapascal over a 6-hour time period, or various concentrations of copper, cadmium, or zinc for 4 days. When the subsequent heat shock of 40 or 45°C was administered for 3 hours, the seedlings showed an induced thermotolerance to these temperatures, which were otherwise lethal to control (water grown) seedlings. Thermotolerance was exhibited by both the root and the shoot of pretreated seedlings, even though the water and heavy metal stresses were applied only to the roots. Neither of these pretreatments had induced the synthesis of detectable levels of heat shock proteins (Hsps) at the time of heat shock. Pretreatment of seedlings with a progressive heat shock of 2°C/hour from 26 to 36°C, which did induce Hsps 18, 70, and 84, resulted in tolerance of a severe water stress of −1.5, −1.75, or −2.0 megapascal for 24 hours. But these seedlings producing Hsps were no better protected against water stress than those pretreated with a progressive water stress which did not produce Hsps. Hsps appear not to act as general stress proteins and their presence is not always required for the establishment of 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.     

Heat shock triggers rapid protein phosphorylation in soybean seedings

Heat shock arrests the synthesis of many cellular proteins and simultaneously initiates expression of a unique set of proteins, termed heat shock proteins. We have found that heat shock rapidly triggers phosphorylation of a set of proteins in soybean seedlings. Although the kinetics of phosphorylation and the heat shock response are similar, the major identified phosphorylation products do not comigrate with heat shock proteins on polyacrylamide gels. Cadmium, which is known to induce the heat shock response, stimulates phosphorylation of the same set of proteins. The rapidity of phosphorylation suggests that it may play a pivotal role in sensing and transducing elevated temperature stress in plants.