Factors influencing the heat shock response of Xenopus laevis embryos

We have further characterized the heat shock response of Xenopus laevis embryos. Xenopus embryos respond to heat shock by consistently synthesizing four major heat shock proteins (hsps) of 62, 70, 76, and 87 kilodaltons. In addition to these hsps, heat-shocked embryos also exhibit the synthesis of several minor hsps. The synthesis of these hsps is often variable. We have monitored the effects of different temperatures and lengths of heat shock on the pattern and intensity of hsp synthesis. In general, the four major hsps are induced more strongly at higher temperatures and during increasing intervals of heat shock. The temperature and duration of heat shock can affect the synthesis of the minor hsps, however. Some hsps are synthesized at lower temperatures only (i.e., below 37 degrees C), whereas others are synthesized only at higher temperatures (i.e., above 37 degrees C). We have extensively examined the characteristics of hsp 35 synthesis, one of the most variably synthesized hsps. This hsp is characteristically synthesized at temperatures above 35 degrees C and usually during the first 40 min of heat shock, after which it becomes undetectable. In some experiments, its synthesis is restimulated during later intervals of heat shock. Hsp 35 is also under developmental regulation. It is not synthesized by heat-shocked embryos until the late blastula to early gastrula stage. After this brief period of inducibility, its synthesis is dramatically reduced in mid- to late gastrulae, but reappears in heat-shocked neurulae. We have previously demonstrated that hsp 35 is related to the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH). The induction of hsp 35 synthesis is inversely correlated with the constitutive levels of GAPDH specific activity. In this paper we document further correlations between the synthesis of hsp 35 and GAPDH specific activity during early Xenopus development.     

Acquisition of the heat-shock response and thermotolerance during early development of Xenopus laevis

The ability to synthesize a 68,000- to 70,000-Da protein (hsp) in heat-shocked early Xenopus laevis embryos is dependent on the stage of development. Whereas late blastula and later stage embryos synthesize hsp68-70 after heat shock, cleavage stages are incompetent with respect to hsp synthesis. In vitro translation experiments and RNA blot analyses demonstrate that enhanced synthesis of hsp68-70 is associated with an accumulation of hsp68-70 mRNA. Examination of the effect of heat shock on preexisting actin mRNA reveals that heat shock promotes a reduction in the levels of actin mRNA in cleavage embryos but has no discernible effect on actin mRNA levels in neurula embryos. Finally, the acquisition of the heat-shock response (i.e., synthesis of hsp68-70 and accumulation of hsp70 mRNA) during early Xenopus development is correlated with the acquisition of thermotolerance.     

Glucocorticoid-mediated attenuation of the hsp70 response in trout hepatocytes involves the proteasome

The physiological implication of elevated cortisol levels on cellular heat-shock protein 70 (hsp70) response was examined using primary cultures of rainbow trout (Oncorhynchus mykiss) hepatocytes. Trout hepatocytes treated with cortisol, the predominant glucocorticoid in teleosts, responded to the heat shock (+15 degrees C for 1 h) with a significant drop in hsp70 accumulation over a 24-h recovery period. [(35)S]methionine incorporation and pulse-chase studies confirmed that this cortisol impact was due to decreased hsp70 synthesis and not enhanced protein breakdown. Cortisol also significantly decreased glucocorticoid receptor (GR) expression in trout hepatocytes. This receptor downregulation was inhibited by the proteasomal inhibitors, lactacystin and MG-132, implying a role for the proteasome in GR downregulation by cortisol. Inhibiting the proteasome did not significantly modify heat-induced hsp70 accumulation in the absence of cortisol but significantly elevated hsp70 expression in the presence of cortisol in heat-shocked trout hepatocytes. Taken together, our results suggest proteasome-mediated GR degradation as a mechanism for the attenuation of hsp70 response by cortisol in heat-shocked hepatocytes.     

Effect of ATP on the Release of hsp 70 and hsp 40 from the Nucleus in Heat-Shocked HeLa Cells

We have recently found a novel 40-kDa heat-shock protein (hsp 40) in mammalian and avian cells and reported that the N-terminal amino acid sequence of mammalian hsp 40 has homology with the bacterial DnaJ heat-shock protein. Also, hsp 40 has been shown to be translocated from the cytoplasm into the nuclei/nucleoli by heat shock and colocalized with hsc 70 (p73) in the nucleoli of exactly the same cells. We here investigated the effect of ATP on the release of hsp 70 (both constitutive p73 and inducible p72) and hsp 40 from the nuclei/nucleoli of heat-shocked HeLa cells which were permeabilized with Nonidet-P40 using immunoflourescence and immunoblotting. Hsp 70 in the nucleoli was released by the addition of ATP but not by ADP, GTP, nonhydrolyzable ATP, nor high salt buffer. In contrast, hsp 40 was not released from the nucleoli with any of these treatments or any combination of these treatments. Thus, hsp 40 might dissociate spontaneously from the nucleoli after hsp 70 has been released in an ATP-dependent manner. Using cell fractionation methods, we showed that while the majority of hsp 40 is localized in the cytoplasm, a small portion of it is located in the microsome fraction in non-heat-shocked control cells and in cells which recovered from heat shock.     

Loss of heat-shock acquisition of thermotolerance in yeast is not correlated with loss of heat-shock proteins

Yeast cells when subjected to a primary heat shock, defined as a temperature shift from 23 to 37 degrees C for 30 min, acquired tolerance to heat stress (52 degrees C/5 min). Primary heat shocked cells incubated at 23 degrees C for up to 3 h, progressively lost thermotolerance but retained high levels of the major heat-shock proteins as observed on polyacrylamide gels. On the other hand, a temperature shift back up to 37 degrees C for 30 min fully restored thermotolerance. The major high-molecular-mass heat-shock proteins (hsp) identified were of approximate molecular mass 100 kDa (hsp 100), 80 kDa (hsp 80) and 70 kDa (hsp 70). The results indicate that loss of heat-shock acquisition of thermotolerance is not correlated with loss of heat-shock proteins.     

Induction of the heat shock response and translational thermotolerance in day 15 ovine trophectoderm

The objectives of this study were to determine the ability of trophectoderm from preimplantation ovine embryos to synthesize hsp70 in response to heat shock and to identify conditions which induce translational thermotolerance in this tissue. Day 15 embryos were collected, and proteins synthesized in 1.5-mm sections of trophectoderm were radioactively labeled with (35)S-methionine. One-dimensional SDS-PAGE gels, two-dimensional gel electrophoresis and Western blots were utilized to characterize the heat shock response and to examine the induction of translational thermotolerance. Increased synthesis of the 70 kDa heat shock proteins and a protein with an approximate molecular weight of 15 to 20 kDa was observed with heat shock (> or = 42 degrees C). Total protein synthesis decreased (P < 0.05) with increased intensity of heat shock. At 45 degrees C, protein synthesis was suppressed with little or no synthesis of all proteins including hsp70. Recovery of protein synthesis following a severe heat shock (45 degrees C for 20 min) occurred faster (P < 0.05) in trophectoderm pretreated with a mild heat shock (42 degrees C for 30 min) than trophectoderm not pretreated with mild heat. In summary, trophoblastic tissue obtained from ovine embryos exhibit the characteristic "heatshock" response similar to that described for other mammalian systems. In addition, a sublethal heat shock induced the ability of the tissue to resume protein synthesis following severe heat stress. Since maintaining protein synthesis is crucial to embryonic survival, manipulation of the heat-shock response may provide a method to enhance embryonic survival.     

The plasma membrane of yeast acquires a novel heat-shock protein (hsp30) and displays a decline in proton-pumping ATPase levels in response to both heat shock and the entry to stationary phase.

Recent studies have revealed that the action of the proton-translocating ATPase of the plasma membrane of yeast is an important determinant of several stress tolerances and affects the capacity of cells to synthesise heat shock proteins in response to heat shock [Panaretou, B. & Piper, P. W. (1990) J. Gen. Microbiol. 136, 1763-1770; Coote, P. J., Cole, M. B. & Jones, M. V. (1991) J. Gen. Microbiol. 137, 1701-1708]. This study investigated the changes to the protein composition of the Saccharomyces cerevisiae plasma membrane that result from a heat shock to dividing cultures and the entry to stationary growth caused by carbon source limitation. Plasma membranes were prepared from exponential, heat-shocked and stationary yeast cultures. The proteins of these membrane preparations were then analysed by polyacrylamide gel electrophoresis and immunoblot measurement of ATPase levels. The protein composition of plasma membranes displayed two prominent changes in response to both heat shock and the entry to stationary phase: (a) a reduction in the level of the plasma membrane ATPase; and (b) the acquisition of a previously uncharacterised 30 kDa heat-shock protein (hsp30). The ATPase decline with heat shock probably exerts an important influence over the ability of the cell to maintain ATPase activity, and therefore intracellular pH, during extended periods of stress. Through in vivo pulse-labelling of plasma membrane proteins synthesised before and during heat shock, followed by subcellular fractionation, it was shown that hsp30 is the only protein induced by the yeast heat-shock response that substantially copurifies with plasma membranes. It might therefore exert a stress-protective function specifically at this membrane.     

Involvement of differential gene expression and mRNA stability in the developmental regulation of the hsp 30 gene family in heat-shocked Xenopus laevis embryos

Four complete hsp 30 genes have been isolated from Xenopus laevis: hsp 30A, hsp 30B (a pseudogene), hsp 30C, and hsp 30D. The hsp 30A and hsp 30C genes are first heat inducible at the early tailbud stage, as determined by RNase protection and RT-PCR assays. In this study, we determined by RT-PCR that the hsp 30D gene was first heat inducible (33^oC for 1 h) at the mid-tailbud stage, approximately 1 day later in development than hsp 30A and hsp 30C. Furthermore, using Northern blot analysis, we detected the presence of very low levels of hsp 30 mRNA at the heat-shocked late blastula stage. The relative levels of these pre-tailbud (PTB) hsp 30 mRNAs increased at the gastrula and neurula stage followed by a dramatic enhancement in heat shocked tail-bud and tadpole stage embryos (50- to 100- fold relative to late blastula). Interestingly, treatment of blastula or gastrula embryos at high temperatures (37^oC for 1 h) or with the protein synthesis inhibitor, cycloheximide, followed by heat shock, led to enhanced accumulation of the pre-tailbud (PTB) hsp 30 mRNAs. hsp 70, hsp 87, and actin messages were not stabilized at high temperatures or by cycloheximide treatment. Finally, hsp 30D mRNA was not detected by RT-PCR analysis of cycloheximidetreated, heat-shocked blastula stage embryos, confirming that it is not a member of the PTB hsp 30 mRNAs. This study indicates that differential gene expression and mRNA stability are involved in the regulation of hsp 30 gene expression during early Xenopus laevis development. © 1995 Wiley-Liss, Inc.     

Control of ribosome biosynthesis in plant cell cultures under heat-shock conditions. Ribosomal RNA

The immediate block of ribosome biosynthesis in heat-shocked tomato cell cultures is primarily caused by the complete inhibition of pre-rRNP processing. Depending on the heat-shock conditions synthesis of pre-rRNP goes on, though at a reduced level. Synthesis and/or preservation of pre-rRNP during heat shock as well as its efficient processing in the recovery period are thoroughly improved by preconditioning of cells to the hyperthermic treatment. Such preinduced cultures are characterized by their content of preformed heat-shock proteins, whose dominant representative (hsp 70) becomes highly enriched in the characteristic granular rRNP material observed in nucleoli of heat-shocked cells. This is shown by immune fluorescence staining and microautoradiography.     

Induction of four heat-shock proteins and their mRNAs in rat after whole-body hyperthermia

When the body temperature of rats was brought to 42 degrees C, four heat-shock proteins, with molecular weights of 70,000, 71,000, 85,000, and 100,000 (hsp 70, hsp 71, hsp 85, and hsp 100, respectively), were induced in various tissues of the rats. The hsp 70 was strongly induced by hyperthermia, and its accumulation was detected by Coomassie blue staining. The hsp 71 was abundant in various tissues of rats that were not heat-shocked. Analysis of translation products of liver mRNAs from heat-shocked rats also showed increased synthesis of the four heat-shock proteins, indicating that these hsp-mRNAs were induced after hyperthermia. Induction of the hsp-mRNAs was transient after hyperthermia. The four heat-shock proteins produced in various tissues after hyperthermia may be involved in homeostatic control in the heat-shock response of the rat.     

Examination of heat shock protein mRNA accumulation in early Xenopus laevis embryos

Elevation of the incubation temperature of Xenopus laevis neurulae from 22 to 33-35 degrees C induced the accumulation of heat shock protein (hsp) 70 mRNA (2.7 kilobases (kb)) and a putative hsp 87 mRNA (3.2 kb). While constitutive levels of both hsp mRNAs were detectable in unfertilized eggs and cleavage-stage embryos, heat-induced accumulation was not observed until after the mid-blastula stage. Exposure of Xenopus laevis embryos to other stressors, such as sodium arsenite or ethanol, also induced a developmental stage-dependent accumulation of hsp 70 mRNA. To characterize the effect of temperature on hsp 70 mRNA induction, neurulae were exposed to a range of temperatures (27-37 degrees C) for 1 h. Heat-induced hsp 70 mRNA accumulation was first detectable at 27 degrees C, with relatively greater levels at 30-35 degrees C and lower levels at 37 degrees C. A more complex effect of temperature on hsp 70 mRNA accumulation was observed in a series of time course experiments. While continuous exposure of neurulae to heat shock (27-35 degrees C) induced a transient accumulation of hsp 70 mRNA, the temporal pattern of hsp 70 mRNA accumulation was temperature dependent. Exposure of embryos to 33-35 degrees C induced maximum relative levels of hsp 70 mRNA within 1-1.5 h, while at 30 and 27 degrees C peak hsp 70 mRNA accumulation occurred at 3 and 12 h, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Intracellular localization and partial amino acid sequence of a stress-inducible 40-kDa protein in HeLa cells.

We earlier discovered a novel 40-kDa protein (hsp40) induced by heat shock and other stresses in mammalian and avian cells. In this report, we purified the hsp40 in HeLa cells, using modified two-dimensional gel electrophoresis, and determined the amino terminal amino acid sequence of this protein. The hsp40 is homologous to DnaJ, an Escherichia coli heat-shock protein, as well as to DnaJ-homologous proteins in yeast such as SCJ1, Sec63/Np11, YDJ1 and SIS1. Indirect immunofluorescence staining using an anti-hsp40 polyclonal antibody demonstrated that hsp40 was localized faintly throughout the cell in non-heat-shocked cells and was accumulated in nuclei and nucleoli in heat-shocked cells. The intracellular localization of hsp40 was very similar to that of hsp70, suggesting that these two hsps colocalize in heat-shocked HeLa cells.     

Purification and Partial Amino Acid Sequence of the Major 70,000-Dalton Heat Shock Protein in Neurospora crassa

Fracella, F., Mohsenzadeh, S., and Rensing, L. 1993. Purification and partial amino acid sequence of the major 70,000-Dalton heat shock protein in Neurospora crassa. Experimental Mycology , 17, 362-367. The major heat shock protein of 70 kDa (hsp70) from heat-shocked mycelial extracts of Neurospora crassa was purified to near homogeneity employing DEAE anion-exchange chromatography followed by affinity chromatography on ATP-agarose. The isolated hsp70 migrates as a single band on one-dimensional sodium dodecyl sulfate polyacrylamide gels (SDS-PAGE), with a molecular mass of ∼69 kDa. On two-dimensional gels it is resolved into two polypeptides with isoelectric points in the acidic range of ∼pH 5.2. The first 53 amino terminal amino acids of the major protein were sequenced and compared with hsp70 of other species. The amino acids aspartic acid, arginine, and phenylalanine occur at positions 27, 28, and 44 (from the methionine terminus) in contrast to the main consensus sequence. These three differing amino acids are shared by yeast, and, in addition, the first two by Arabidopsis, petunia, and maize.     

Involvement of ATP in the nuclear and nucleolar functions of the 70 kd heat shock protein.

The major heat shock protein, hsp70, is an ATP-binding protein which is synthesized in very large amounts in response to stress. In unstressed, or recovered, mammalian cells it is found in both nucleus and cytoplasm. Under these conditions, its interaction with nuclei is weak, and it is readily released from them upon lysis of cells in isotonic buffer. After heat shock, hsp70 binds tightly first to some nuclear component(s) and then to nucleoli. It can be released from these binding sites rapidly and specifically in vitro by as little as 1 microM ATP, but not by non-hydrolysable ATP analogues. Studies of hsp70 deletion mutations show that the ability of mutants to be released by ATP correlates with their ability to migrate to heat-shocked nucleoli and aid their repair in vivo. We propose a model in which ATP-driven cycles of binding and release of hsp70 help to solubilize aggregates of proteins or RNPs that form after heat shock. Cells also contain proteins related to hsp70 that are synthesized in the absence of stress. The most abundant of these shows the same behaviour as hsp70 after heat shock, and thus may perform a related function in both normal and stressed cells.     

A normal mitochondrial protein is selectively synthesized and accumulated during heat shock in Tetrahymena thermophila.

We have identified and purified a 58-kilodalton protein of Tetrahymena thermophila whose synthesis during heat shock parallels that of the major heat shock proteins. This protein, hsp58, was found in both non-heat-shocked as well as heat-shocked cells; however, its concentration in the cell increased approximately two- to threefold during heat shock. The majority of hsp58 in both non-heat-shocked and heat-shocked cells was found by both cell fractionation studies and immunocytochemical techniques to be mitochondrially associated. During heat shock, the additional hsp58 was found to selectively accumulate in mitochondria. Nondenatured hsp58 released from mitochondria of non-heat-shocked or heat-shocked cells sedimented in sucrose gradients as a 20S to 25S complex. We suggest that this protein may play a role in mitochondria analogous to the role the major heat shock proteins play in the nucleus and cytosol.     

Analysis of protein binding to heat shock protein 70 in pancreatic islet cells exposed to elevated temperatures or interleukin 1 beta

To elucidate a role for heat shock proteins in islet function, isolated pancreatic islets were labeled with [35S]methionine after control, heat shock, or interleukin 1 beta (IL-1 beta) treatment, extracted in the presence of detergent, and then passed over affinity columns with antibodies against heat shock protein 70 (hsp 70), hsp 70 itself, or ATP conjugated to the columns. In control or IL-1 beta-treated islets, the antibody column efficiently absorbed hsp 70 together with two other proteins of molecular masses 46 and 53 kDa. In extracts from heat-shocked cells, the binding of cellularly synthesized hsp 70 to the antibody column was inefficient but improved by the addition of unlabeled partially purified hsp 70 to the extracts. When assessing the binding of proteins in the extracts to the hsp 70 column, hsp 70 and the 46- and 53-kDa proteins among others all bound to the column. No differences in the patterns of binding to the hsp 70 column between extracts from the different islet exposures were noticed. The 46-kDa protein was identified as actin by immunoblot analysis. ATP-agarose column chromatography revealed a pattern of binding similar to that of the hsp 70 column. It is concluded that hsp 70 contains at least two functional domains, one adjacent to the epitope recognized by the antibody and active in restoring cellular function after heat shock, whereas the other has the ability to bind the 46- and 53-kDa and possibly other proteins. Furthermore, the stress induced by heat shock differs significantly from that after IL-1 beta treatment with respect to the functional behavior of hsp 70.     

Stress-induced, tissue-specific enrichment of hsp70 mRNA accumulation in Xenopus laevis embryos

In this study, we have employed whole-mount, in situ hybridization to study the spatial pattern of hsc70 and hsp70 mRNA accumulation in normal and heat shocked embryos during Xenopus laevis development. Our findings revealed that hsc70 mRNA was constitutively present in a global fashion throughout the embryo and was not heat inducible. Accumulation of hsp70 mRNA, however, was detected only in heat shocked embryos. Furthermore, hsp70 mRNA accumulation was enriched in a tissue-specific manner in X. laevis tailbud embryos within 15 minutes of a 33 degrees C heat shock. Abundant levels of heat shock-induced hsp70 mRNA were detected in the head region, including the lens placode, the cement gland, and in the somitic region and proctodeum. Preferential heat-induced accumulation of hsp70 mRNA was first detected at a heat shock temperature of 30 degrees C. Placement of embryos at 22 degrees C after a 1-hour, 33 degrees C heat shock resulted in decreased hsp70 mRNA with time, but the message persisted in selected tissues, including the lens placode and somites. Treatment of tailbud embryos with either sodium arsenite or zinc chloride induced a tissue-specific enrichment of hsp70 mRNA in the lens placode and somitic region. These studies reveal the complex nature of the heat shock response in different embryonic tissues and suggest the presence of regulatory mechanisms that lead to a stressor-induced, tissue-specific enrichment of hsp70 mRNA.