Characterization and inducibility of hsp 70 proteins in the male mouse germ line

The properties and inducibility of the heat shock protein 70 (hsp 70) gene products were examined during differentiation of mouse testicular cells by one and two-dimensional gel electrophoresis and immunoblotting. Low levels of the 72- and 73-kD heat shock proteins normally found in mouse cell lines were detected in the mouse testis. A novel isoform with a relative molecular mass of 73 kD (called 73T) was also observed, in the presence or absence of heat shock. 73T was shown to be produced by germ cells since it was not detected in testes from mutant mice devoid of germ cells. Furthermore, 73T was found only in adult mouse testicular cells, not in testes from animals that lack meiotic germ cells. 73T was synthesized in enriched cell populations of both meiotic prophase and postmeiotic cells, but was not inducible by in vitro heat shock. In the adult testis, low levels of the bona fide 72-kD heat-inducible (hsp72) were induced in response to elevated temperatures. In contrast, in testes from animals in which only somatic cells and premeiotic germ cells were present, there was a substantial induction of hsp 72. It is suggested that hsp 72 is inducible in the somatic compartment and possibly in the premeiotic germ cells, but not in germ cells which have entered meiosis and which are expressing members of the hsp 70 gene family in a developmentally regulated fashion.     

T lymphocyte stress response. II. Protection of translation and DNA replication against some forms of stress by prior hyperthermic stress

We have compared the effects of a mild heat shock and febrile temperatures on heat-shock protein (hsp) synthesis and development of stress tolerance in T lymphocytes. Our previous studies demonstrated that febrile temperatures (less than or equal to 41 degrees C) induced the synthesis of hsp110, hsp90, and the constitutive or cognate form of hsp70 (hscp70; a weak induction of the strongly stress-induced hsp70 was also observed. In the studies reported herein, we demonstrate that a mild heat shock (42.5 degrees C) reverses this ratio; that is, hsp70 and not hscp70 is the predominate member of this family synthesized at this temperature. Modest heat shock also enhanced the synthesis of hsp110 and hsp90. In order to assess the relationship between hsp synthesis and the acquisition of thermotolerance, purified T cells were first incubated at 42.5 degrees C (induction temperature) and then subsequently subjected to a severe heat-shock challenge (45 degrees C, 30 min). T cells first incubated at a mild heat-shock temperature were capable of total protein synthesis at a more rapid rate following a severe heat shock than control cells (induction temperature 37 degrees C). This phenomenon, which has been previously termed translational tolerance, did not develop in cells incubated at the febrile temperature (induction temperature 41 degrees C). Protection of translation also extended to immunologically relevant proteins such as interleukin-2 and the interleukin-2 receptor. Because clonal expansion is a critical event during an immune response, the effects of hyperthermic stress on DNA replication (mitogen-induced T cell proliferation) was also evaluated in thermotolerant T cells. DNA synthesis in control cells (induction temperature 37 degrees C) was severely inhibited following heat-shock challenge at 44 degrees C or 45 degrees C; in contrast, T cells preincubated at 42.5 degrees C rapidly recovered their DNA synthetic capacity. T cells preincubated at a febrile temperature were moderately protected against hyperthermic stress. The acquisition of thermotolerance was also associated with enhanced resistance to chemical (ethanol)-induced stress but not to heavy metal toxicity (cadmium) or dexamethasone-induced immunosuppression. These studies suggest that prior hsp synthesis may protect immune function against some forms of stress (e.g., febrile episode) but would be ineffective against others such as elevated glucocorticoid levels which normally occur during an immune response.     

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.     

A novel hsp70-like protein (P70) is present in mouse spermatogenic cells.

Mouse spermatogenic cells contain relatively large amounts of a 70-kilodalton protein (P70) that is closely related to hsp70, the major inducible heat shock protein. When hsp70 from spermatogenic cells is heat induced, it migrates to the same location as does P70 on two-dimensional polyacrylamide gels, indicating that it has an apparently identical mass and isoelectric point. P70 reacts strongly and specifically with an anti-Drosophila hsp70 monoclonal antibody that is specific for products of the hsp70 gene family. Both P70 and hsp70 are also ATP-binding proteins and are purified by using ATP-affinity chromatography. However, P70 and hsp70 are unique proteins on the basis of peptide map analysis and are regulated differently in germ cells. P70 appears to be a novel heat shock protein of spermatogenic cells which is synthesized in association with germ cell differentiation.     

Hsp70 accelerates the recovery of nucleolar morphology after heat shock.

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.     

Patterns of protein synthesis in various cells after extreme heat shock

The analysis of proteins synthesized in rat thymocytes and mouse teratocarcinoma PCC-4 Aza 1 and myeloma Sp2/0 cells after 1 h of treatment at 42 or 44 degrees C was carried out. Shock at 42 degrees C reduced the total synthetic rate of proteins in all three cell lines and induced "classical" heat-shock protein with a mass of 70 kDa (hsp 70). Heat shock at 44 degrees C resulted in almost complete inhibition of protein synthesis; only a small amount of hsp 70 was synthesized. Meanwhile a new 48-kDa polypeptide (pI = 7.5) was found in the cells exposed to severe heat shock. This protein was compared by peptide mapping with other known polypeptides of the same size: heat-shock protein from chicken embryo cells and mitogen-stimulated polypeptide from human lymphoid cells. The peptide maps were not identical. It was also shown that after a shock at 44 degrees C teratocarcinoma cells were able to accumulate anomalous amounts of hsp 70 despite hsp 70 synthesis inhibition. The data show that reaction of various cells to extreme heat shock depends heavily on cell type.     

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.     

Transformation of BALB/3T3 cells by simian virus 40 causes a decreased synthesis of a collagen-binding heat-shock protein (hsp47)

The synthesis of a major collagen-binding heat-shock protein of molecular weight 47,000 (hsp47) was shown previously to be decreased after transformation of chick embryo fibroblasts by Rous sarcoma virus (Nagata, K., and Yamada, K. M. (1986) J. Biol. Chem. 261, 7531-7536; and Nagata, K., Saga, S., and Yamada, K. M. (1986) J. Cell Biol. 103, 223-229). In this paper, further study demonstrated that the total amount and the synthesis of hsp47 are also decreased by a factor of three in BALB/3T3 cells transformed by simian virus 40 (SV40). Higher synthesis was observed for BALB/3T3 cells in the resting state compared to those in the proliferating state. The synthesis of hsp47 in SV40-transformed cells, however, was consistently lower than that in normal cells irrespective of the cell density. Pulse label and chase experiments revealed that hsp47 was stable in the cells for at least 6 h and that there was no difference between normal and transformed BALB/3T3 cells in terms of the half-life. Decreases in the amount and the synthesis of hsp47 by transformation apparently correlate with the decreased synthesis of collagen in transformed cells. Immunoprecipitation using rat monoclonal antibody against hsp47 demonstrated the association of hsp47 with intracellular procollagen. Immunofluorescence studies using anti-hsp47 monoclonal antibody and anti-collagen antibody confirmed the co-localization of hsp47 and procollagen in both nonshocked and heat-shocked cells. Furthermore, we determined the biochemical characteristics of hsp47 of heat-shocked cells.     

Induction of hsp 72/73 by herbimycin A, an inhibitor of transformation by tyrosine kinase oncogenes

Herbimycin A, which has been known to inactivate and degrade p60v-src tyrosine kinase, induced an elevated synthesis of a protein with a molecular size of 70 kDa in A431 human epidermoid carcinoma cells. This protein showed the same migration distance on SDS-polyacrylamide gel electrophoresis as that of the protein induced in the cells by heat shock treatment, and this 70-kDa protein was identified as a member of the heat shock protein 70 family (hsp70) through immunoprecipitation with anti-hsp72/73 antibody and partial digestion with V8 protease. The induced level of the 70-kDa protein was dependent on the length of period and the concentration of herbimycin A treatment. Cellular fractionation and indirect immunofluorescence analyses revealed that the 70-kDa protein induced by herbimycin A was localized in the cytoplasm, in contrast to the nuclear distribution of hsp70 induced by heat treatment. Induction of hsp70 by herbimycin A was also observed in several other cells, including HeLa S3 cells, chicken embryo fibroblasts, NIH3T3 cells, and Rous sarcoma virus-transformed NIH3T3 cells.     

Characterization of a new high-temperature-induced 66-kDa heat-shock protein,antigenically related to heat-shock protein 72

M-14 human melanoma cells, following severe hyperthermic exposures, synthesized a heat-shock protein of 66 kDa (hsp 66), in addition to the major “classic” heat-shock proteins. This hsp 66 was not expressed following mild hyperthermic exposures sufficient to trigger the synthesis of the other heat-shock proteins. The induction of hsp 66 was observed also in Li human glioma cells treated at 45°C for 20 min. By contrast, hsp 66 was not induced in seven other human cell lines (both melanoma and nonmelanoma) when they were subjected to the same hyperthermic treatment. Immunological recognition experiments showed that hsp 66 cross-reacted with the inducible hsp 72, but not with the constitutive hsp 73. The possibility that hsp 66 is a breakdown product of hsp 72 was ruled out by the fact that Poly(A)⁺ RNA extracted from cells treated at 45°C for 20 min was able to direct the synthesis of hsp 66 (together with hsp 72) in a message-dependent rabbit reticulocyte lysate, as well as in microinjected Xenopus oocytes. By contrast, only the hsp 72 was expressed using Poly(A)⁺ RNA extracted from cells heated at 42°C for 1 h. Affinity chromatography experiments on ATP-agarose showed that hsp 66 did not bind ATP in vitro, hsp 66 was localized both in the cytoplasm (cytosol, mitochondria, and microsome fraction) and in the nuclei of cells recovered from a severe heat shock: this intracellular distribution closely corresponded to that of hsp 72. The nuclear-associated hsp 66 was found to be tightly bound to nuclear structures and could not be extracted by incubation in ATP-containing buffer. © 1996 Wiley-Liss, Inc.     

The 70-kilodalton heat-shock proteins of the SSA subfamily negatively modulate heat-shock-induced accumulation of trehalose and promote recovery from heat stress in the yeast, Saccharomyces cerevisiae.

In the yeast, Saccharomyces cerevisiae, the disaccharide trehalose is a stress-related metabolite that accumulates upon exposure of cells to heat shock or a variety of non-heat inducers of the stress response. Here, we describe the influence of mutations in individual heat-shock-protein genes on trehalose metabolism. A strain mutated in three proteins of the SSA subfamily of 70-kDa heat-shock proteins (hsp70) overproduced trehalose during heat shock at 37 degrees C or 40 degrees C and showed abnormally slow degradation of trehalose upon temperature decrease from 40 degrees C to 27 degrees C. The mutant cells were unimpaired in the induction of thermotolerance; however, the decay of thermotolerance during recovery at 27 degrees C was abnormally slow. Since both a high content of trehalose and induced thermotolerance are associated with the heat-stressed state of cells, the abnormally slow decline of trehalose levels and thermotolerance in the mutant cells indicated a defect in recovery from the heat-stressed state. A similar albeit minor defect, as judged from measurements of trehalose degradation during recovery, was detected in a delta hsp104 mutant, but not in a strain deleted in the polyubiquitin gene, UB14. In all our experiments, trehalose levels were closely correlated with thermotolerance, suggesting a thermoprotective function of trehalose. In contrast, heat-shock proteins, in particular hsp70, appear to be involved in recovery from the heat-stressed state rather than in the acquisition of thermotolerance. Cells partially depleted of hsp70 displayed an abnormally low activity of neutral trehalase when shifted to 27 degrees C after heat shock at 40 degrees C. Trehalase activity is known to be under positive control by cAMP-dependent protein kinases, suggesting that hsp70 directly or indirectly stimulate these protein-kinase activities. Alternatively, hsp70 may physically interact with neutral trehalase, thereby protecting the enzyme from thermal denaturation.     

Common antigenicity of mouse 42 degrees C-specific heat-shock protein with mouse HSP 105

Mammalian cells incubated at 42 degrees C synthesize a specific heat-shock protein at 42 degrees C (42 degrees C-hsp) that is not induced by heat-shock at 45 degrees C or by other stresses that induce major heat shock proteins (Hatayama et al. (1986) Biochem. Biophys. Res. Commun. 137, 957-963). Antibody raised against a heat-shock protein with molecular weight of 105,000 (hsp 105) purified from mouse FM 3A cells cross-reacted to the 42 degrees C-hsp of the same cells. The antibody reacted only weakly to hsp 105 and 42 degrees C-hsp of human HeLa cells. These results suggested that hsp 105 and 42 degrees C-hsp have the same antigenic determinant, and that 42 degrees C-hsp may have a structure similar to that of hsp 105.     

Analysis of stress-induced gene expression in fish cell lines exposed to heavy meals and heat shock

We have examined the effect of heavy metals on the expression of two major groups of stress-induced proteins in fish cell lines: the 70 kDa heat-shock proteins (hsp70) and metallothioneins (MTs). The rainbow trout hepatoma (RTH) cell line synthesized the hsp70 protein in response to zinc and heat shock, while chinook salmon embryonic (CHSE) cells synthesized this protein in response to these inducers, as well as cadmium. The synthesis of this 70 kDa protein was correlated with the accumulation of hsp70 mRNA as measured by hybridization to a trout hsp70 gene probe. Heavy metals also induced the synthesis of MT in RTH cells. However, heat shock did not result in induction of MT and its mRNA. Unlike RTH cells, CHSE cells did not synthesize MT following exposure to cadmium or zinc. When these cells were treated with 5-azacytidine prior to heavy metal treatment, accumulation of MT mRNA was observed. Northern blot analysis of total RNA from 5-azacytidine treated CHSE cells, using a trout MT (tMT-B) cDNA probe, indicated that the time-course of induction and the maximal level of MT mRNA accumulation in response to cadmium and zinc paralleled that observed in RTH cells. Copper and dexamethasone were ineffective in inducing MT mRNA in 5-azacytidine-treated CHSE cells. These results indicate that MT is specifically induced in response to heavy metal treatment, whereas the synthesis of hsp70 appears to be a general stress response. Furthermore, MT is differentially regulated by heavy metals and dexamethasone in these cell lines and the expression of MT is cell-type-specific.     

Analysis of the expression of the two major proteins of the 70 kilodalton mammalian heat shock family

This study compares the expression after heat shock of the two major variants of the mammalian 70 kilodalton heat shock family in three separate systems. The ability of wild type and temperature sensitive mutant (ts85) FM3A cells to elicit a heat shock response following a 45 degrees C, 12 min exposure was examined. The ts85 cells were found to be both significantly more thermosensitive than parent FM3A cells and to induce a 66kDa heat shock protein (hsp66) not visibly synthesized in the parent line by this exposure. However, a constitutive (synthesized at 37 degrees C) 68kDa heat shock protein (hsp68) is comparably induced in both cell lines after heat. A relationship between the severity of the heat exposure as seen by the cell and hsp66 expression is suggested and tested in Chinese hamster ovary cells. In CHO cells a brief 45 degrees C heat shock induces the constitutive hsp68 (but not hsp66), while longer and more severe exposures are required for the expression of hsp66. The induction of these two proteins is also examined in situ in mouse skeletal muscle. In this case both hsp66 and hsp68 are induced following comparatively mild heat treatments, and the 'threshold' for hsp66 induction observed in cultured cells either does not occur or is greatly reduced. However, once again, hsp68 is naturally synthesized at 37 degrees C while hsp66 appears to be de novo synthesized after heat shock.     

Members of the Drosophila HSP 70 family share ATP-binding properties

In Drosophila, the hsp 70 family consists of a group of proteins of similar molecular masses (hsps 68, 70 and 72) that exist as multiple isoforms. In this report, it is shown that hsps 68, 70 and 72 from Drosophila cells can be purified by affinity chromatography on ATP-agarose. Furthermore it is demonstrated that the multiple members of the hsp 70 family, which accumulate in large amounts in the nucleus during a heat shock, can be specifically solubilized from the isolated nuclei fraction by ATP. One of the major cognate proteins (hsc 70) also shows similar behavior. These data suggest that most, if not all, of the related Drosophila hsps 70 possess, like their mammalian counterparts, an ATP-binding site which could be related to their function in the stress response.     

c-myc can induce expression of G0/G1 transition genes.

The human c-myc oncogene was linked to the heat shock-inducible Drosophila hsp70 promoter and used to stably transfect mouse BALB/c 3T3 cells. Heat shock of the transfectants at 42 degrees C followed by recovery at 37 degrees C resulted in the appearance of the human c-myc protein which was appropriately localized to the nuclear fraction. Two-dimensional analysis of the proteins of density-arrested cells which had been heat shock treated revealed the induction of eight protein species and the repression of five protein species. All of the induced and repressed proteins were nonabundant. cDNA clones corresponding to genes induced during the G0/G1 transition were used as probes to assay for c-myc inducibility of these genes. Two anonymous sequences previously identified as serum inducible (3CH77 and 3CH92) were induced when c-myc was expressed. In response to serum stimulation, 3CH77 and 3CH92 were expressed before c-myc mRNA levels increased. However, in response to specific induction of c-myc by heat shock of serum arrested cells, 3CH77 and 3CH92 mRNA levels increased after the rise in c-myc mRNA. Therefore, we hypothesize that abnormal expression of c-myc can induce genes involved in the proliferative response.     

Heat-shock cognate protein (hsc71) and related proteins in mouse spermatogenic cells

A monoclonal antibody (13D3) has been developed that recognizes a 71 kilodalton (71 kDa) protein on two-dimensional immunoblots of proteins extracted from a mixture of mouse spermatogenic cells (mainly pachytene spermatocytes and spermatids). This protein was shown by immunoblotting and adenosine triphosphate (ATP)-binding characteristics to be identical to a 71 kDa mouse heat-shock cognate (hsc) protein, hsc71, present in 3T3 cells. Along with a 70 kDa heat-shock inducible protein (hsp70), and a 74 kDa heat-shock cognate protein (hsc74), hsc71 is a product of the mouse HSP70 multigene family. Although antibody 13D3 reacted strongly with hsc71, it reacted only faintly with hsp70 in 3T3 cells, and not at all with hsc74 or a germ cell-specific hsp70-like protein (P70) on immunoblots of mixed germ cells. Antibody 13D3 is unique among known antibodies in its pattern of reaction with these heat-shock proteins. In immunofluorescence studies on isolated germ cells, 13D3 reacted uniformly with the cytoplasm of pachytene spermatocytes, round spermatids, and residual bodies, but only with the midpiece of spermatozoa. Antibody 13D3 recognizes other proteins in addition to hsc71 on two-dimensional immunoblots of condensing spermatids and spermatozoa. Two of the proteins (70 kDa/pI 6.4 and 70 kDa/pI 6.5) were present in condensing spermatids and spermatozoa, and another protein (69 kDa/pI 7.0) was detected only in spermatozoa. The new proteins also were recognized by monoclonal antibody 7.10, which reacts specifically with hsp70, hsc71, hsc74, and P70. Although [35S]methionine was incorporated into the new proteins in condensing spermatids, hsc71, hsc74, and P70 were not labeled. These results suggest that unique heat-shock proteins are synthesized late in spermatogenesis.     

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.