Cellular localization of Drosophila 83-kilodalton heat shock protein in normal, heat-shocked, and recovering cultured cells with a specific antibody

To gain insight on the possible functions of heat shock proteins (hsp's) in Drosophila, we have purified the 83-kilodalton hsp (hsp 83) from cultured cells and studied its intracellular localization by immunofluorescence in normal, heat-shocked, and recovering cells. The specificity of the antibody was assessed by one- and two-dimensional gel immunoblotting and by partial proteolytic digestion. The anti-hsp 83 antibody does not show any significant cross-reactivity with hsp's of different avian or mammalian cell lines, but cross-reacts with hsp's of similar molecular masses in other dipteran insects. The partial proteolytic peptide maps of Drosophila hsp 83 differ from those of mouse hsp 89 and chicken hsp 84. Immunoblotting of Drosophila Kc cells heat shocked at different temperatures indicates a maximal expression of hsp 83 at 33 degrees C. By immunofluorescence, hsp 83 is shown to have a strictly cytoplasmic localization. In unstressed cells, it is distributed in the entire cytoplasm with a slight enrichment in the perinuclear region. After heat shock, it seems to concentrate at the cell periphery close to the plasma membrane and it gradually redistributes to the whole cytoplasm during cellular recovery at normal temperatures.     

hsp70: Nuclear concentration during environmental stress and cytoplasmic storage during recovery

The intracellular distribution of the major Drosophila heat-shock protein hsp70 was determined by indirect immunofluorescence with monoclonal antibodies. During heat shock the protein concentrates strongly in nuclei while a small quantity remains cytoplasmic. During recovery hsp70 leaves the nuclei and becomes distributed throughout the cytoplasm. With a second heat shock it is rapidly transported back into the nucleus. Nuclear translocation depends not on the temperature per se, but on the physiological state of the cell since it also occurs after exposure to an anoxic atmosphere at normal temperatures. We also provide evidence that hsps protect cells from the toxic effects of anoxia, as well as heat, and conclude that nuclear translocation of hsp70 is related to its function in protecting the organism from both forms of environmental stress.     

The intracellular location of yeast heat-shock protein 26 varies with metabolism

An antibody highly specific for heat-shock protein (hsp)26, the unique small hsp of yeast, and mutants carrying a deletion of the HSP26 gene were used to examine the physical properties of the protein and to determine its intracellular distribution. The protein was found in complexes with a molecular mass of greater than 500 kD. Thus, it has all of the characteristics, including sequence homology and induction patterns, of small hsps from other organisms. When log-phase cells growing in glucose were heat shocked, hsp26 concentrated in nuclei and continued to concentrate in nuclei when these cells were returned to normal temperatures for recovery. However, hsp26 did not concentrate in nuclei under a variety of other conditions. For example, in early stationary-phase cells hsp26 is induced at normal growth temperatures. This protein was generally distributed throughout the cells, even after heat shock. Similarly, in cells genetically engineered to synthesize hsp26 in the presence of galactose, hsp26 did not concentrate in nuclei, with or without a heat shock. To determine if the failure of hsp26 to concentrate in the nucleus of these cells was due to the fact that the protein had been produced at 25 degrees C or to a difference in the physiological state of the cell, we investigated the distribution of the heat-induced protein in cells grown under several different conditions. In wild-type cells grown in galactose or acetate and in mitochondrial mutants grown in glucose or galactose, hsp26 also failed to concentrate in nuclei with a heat shock. We conclude that the intracellular location of hsp26 in yeast depends upon the physiological state of the cell and not simply upon the presence or absence of heat stress. Our findings may explain why previous investigations of the intracellular localization of small hsps in a variety of organisms have yielded seemingly contradictory results.     

The dynamic state of heat shock proteins in chicken embryo fibroblasts

Subcellular fractionation and immunofluorescence microscopy have been used to study the intracellular distributions of the major heat shock proteins, hsp 89, hsp 70, and hsp 24, in chicken embryo fibroblasts stressed by heat shock, allowed to recover and then restressed. Hsp 89 was localized primarily to the cytoplasm except during the restress when a portion of this protein concentrated in the nuclear region. Under all conditions, hsp 89 was readily extracted from cells by detergent. During stress and restress, significant amounts of hsp 70 moved to the nucleus and became resistant to detergent extraction. Some of this hsp 70 was released from the insoluble form in an ATP-dependent reaction. Hsp 24 was confined to the cytoplasm and, during restress, aggregated to detergent-insoluble perinuclear phase-dense granules. These granules dissociated during recovery and hsp 24 could be solubilized by detergent. The nuclear hsps reappeared in the cytoplasm in cells allowed to recover at normal temperatures. Sodium arsenite also induces hsps and their distributions were similar to that observed after a heat shock, except for hsp 89, which remained cytoplasmic. We also examined by immunofluorescence the cytoskeletal systems of chicken embryo fibroblasts subjected to heat shock and found no gross morphological changes in cytoplasmic microfilaments or microtubules. However, the intermediate filament network was very sensitive and collapsed around the nucleus very shortly after a heat shock. The normal intermediate filament morphology reformed when cells were allowed to recover from the stress. Inclusion of actinomycin D during the heat shock--a condition that prevents synthesis of the hsps--did not affect the intermediate filament collapse, but recovery of the normal morphology did not occur. We suggest that an hsp(s) may aid in the formation of the intermediate filament network after stress.     

Subcellular localization of the 84,000 dalton heat-shock protein in mouse neuroblastoma cells: evidence for a cytoplasmic and nuclear location

Using affinity-purified antibodies, the 84,000 dalton heat-shock protein (hsp) has been localized in mouse N2A neuroblastoma cells by immunocytochemical techniques. Immunofluorescence microscopy showed that hsp84 was present both in the cytoplasm and in the nucleus. The nucleoli were found to be unlabelled. Immunogold labelling on ultrathin cryosections revealed that hsp84 was evenly distributed throughout the entire cytoplasm. No preferential association of hsp84 with the plasma membrane or with membranes from organelles was observed. In the nucleus the hsp84 was present in both the euchromatin and heterochromatin. In the nucleolus only the fibrillar part was labelled and virtually no gold particles were observed in the granular part. A long-term hyperthermic treatment of 3 h at 42.5 degrees C was found to induce an accumulation of hsp84 inside the nucleus. No alterations in hsp84 distribution were observed during a treatment of the cells with 75 microM sodium arsenite for 3 h. Drastic alterations were observed in the nucleoli after both stress treatments. The granular part had totally disappeared and only remnants of the fibrillar part which contained hsp84, were found. Besides the nuclear accumulations of hsp84 during heat shock, no additional changes in the hsp84 location in stressed cells were observed. During a recovery from the heat shock by replacing the cells at 37 degrees C, a decrease in the nuclear location of hsp84 was observed, indicating the reversibility of this process. The significance of these results for the role of hsp84 in normal and in stressed cells is discussed.     

Intracellular localization of Xenopus small heat shock protein, hsp30, in A6 kidney epithelial cells

Small heat shock proteins (shsps) are molecular chaperones that are inducible by environmental stress. In this study, immunocytochemical analysis and laser scanning confocal microscopy revealed that the shsp family, hsp30, was localized primarily in the cytoplasm of Xenopus A6 kidney epithelial cells after heat shock or sodium arsenite treatment. Heat shock-induced hsp30 was enriched in the perinuclear region with some immunostaining in the nucleus but not in the nucleolus. In sodium arsenite-treated cells hsp30 was enriched towards the cytoplasmic periphery as well as showing some immunostaining in the nucleus. At higher heat shock temperatures (35 degrees C) or after 10 microM sodium arsenite treatment, the actin cytoskeleton displayed some disorganization that co-localized with areas of hsp30 enrichment. Treatment of A6 cells with 50 microM sodium arsenite induced a collapse of the cytoskeleton around the nucleus. These results coupled with previous studies suggest that stress-inducible hsp30 acts as a molecular chaperone primarily in the cytoplasm and may interact with cytoskeletal proteins.     

A major heat-shock protein defined by a monoclonal antibody.

A monoclonal antibody reacts with a polypeptide of 68 000 mol. wt. (p68) that accumulates to high levels during heat shock. The intracellular distribution of this antigen in normal and heat-shocked cells has been studied. It is a major component of non-stressed cells, where it is located predominantly in the cytoplasm, but also occurs in the nucleus. The nuclear accumulation is growth regulated, in that exponentially growing cells have strong nuclear immunofluorescence and confluent cells little. It is concentrated at the leading edge of motile fibroblasts and co-distributes with actin-containing microfilaments. Heat shock causes cytoplasmic and nuclear accumulation and there is new deposition in the periphery of cells. In normal cells the antigen in the nucleus is located in the nuclear lamina and matrix which increases during heat shock. The distribution of this molecule and the structures with which it interacts suggests that it is important in mediating the effects of heat shock.     

Two developmental stages of Neurospora crassa utilize similar mechanisms for responding to heat shock but contrasting mechanisms for recovery.

At the heat shock temperature of 45 degrees C, there is a transient induction of the synthesis of heat shock proteins and repression of normal protein synthesis in cells of Neurospora crassa. Both conidiospores and mycelial cells resume normal protein synthesis after 60 min at high temperature. At the RNA level, however, these two developmental stages responded with different kinetics to elevated temperature. Heat shock RNAs (for hsp30 and hsp83) accumulated and declined more rapidly in spores than in mycelia, and during recovery spores accumulated mRNA that encoded a normal protein (the proteolipid subunit of the mitochondrial ATPase), whereas mycelia showed no increase in this normal RNA (for at least 120 min). Therefore, the resumption of normal protein synthesis in spores may depend upon accumulation of new mRNAs. In contrast, mycelial cells appeared to change their translational preference during continued incubation at elevated temperature, from a discrimination against normal mRNAs to a resumption of their translation into normal cellular proteins, exemplified by the ATPase proteolipid subunit whose synthesis was measured in the heat-shocked cells.     

Heat shock proteins affect RNA processing during the heat shock response of Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, the splicing of mRNA precursors is disrupted by a severe heat shock. Mild heat treatments prior to severe heat shock protect splicing from disruption, as was previously reported for Drosophila melanogaster. In contrast to D. melanogaster, protein synthesis during the pretreatment is not required to protect splicing in yeast cells. However, protein synthesis is required for the rapid recovery of splicing once it has been disrupted by a sudden severe heat shock. Mutations in two classes of yeast hsp genes affect the pattern of RNA splicing during the heat shock response. First, certain hsp70 mutants, which overproduce other heat shock proteins at normal temperatures, show constitutive protection of splicing at high temperatures and do not require pretreatment. Second, in hsp104 mutants, the recovery of RNA splicing after a severe heat shock is delayed compared with wild-type cells. These results indicate a greater degree of specialization in the protective functions of hsps than has previously been suspected. Some of the proteins (e.g., members of the hsp70 and hsp82 gene families) help to maintain normal cellular processes at higher temperatures. The particular function of hsp104, at least in splicing, is to facilitate recovery of the process once it has been disrupted.     

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.     

Two closely linked transcription units within the 63B heat shock puff locus of D. melanogaster display strikingly different regulation

We report the isolation and characterization of a cloned DNA of D. melanogaster, Dm4L, that is derived from the major heat shock puff site at 63B. This segment contains two closely linked genes that are each present once per Drosophila haploid genome. One of these, the hsp 83 gene, encodes an abundant heat shock mRNA that, unlike other major heat shock mRNAs, is also abundant in uninduced (23 degrees) kco cells. Although only a slight increase in the level of total hsp 83 RNA can be detected after heat shock in Kco cells, the level of hsp 83 poly(A)+ mRNA increases more than 6-fold and the level of pulse-labeled hsp 83 RNA in total cellular RNA increases 11-fold relative to uninduced cells. In contrast, the levels of total, poly(A)+, and pulse-labeled RNA homologous to the second gene, 63B-T2, are approximately the same in both induced and uninduced cells. Hence, even though these genes are separated by only one thousand base pairs, and, from in situ hybridization to polytene chromosomes, both lie within the heat shock puff, they display strikingly different regulatory properties, These results demonstrate that close linkage of a gene to a heat shock puff is not sufficient to render its expression heat inducible.     

Accumulation of a specific subset of D. melanogaster heat shock mRNAs in normal development without heat shock

During normal development in D. melanogaster, messenger RNAs for three of the seven heat shock proteins (hsp83, hsp28 and hsp26) accumulate in adult ovaries and are abundant in embryos until blastoderm. The three mRNAs appear to originate in nurse cells and subsequently pass, during stages 10-11, into the oocyte. Little if any of the four other heat shock mRNAs is present in unshocked ovaries or embryos at any time examined. Pre-blastoderm embryos fail to accumulate these heat shock mRNAs even if subjected to heat shock. The accumulation in normal oogenesis of mRNAs for only three of the seven heat shock proteins indicates the existence of differential, possibly multiple controls of heat shock gene expression, and suggests that heat shock proteins hsp83, hsp28 and hsp26 function in the oocyte or early embryo.     

Heat shock and developmental regulation of the Drosophila melanogaster hsp83 gene.

In contrast to the hsp70 gene, whose expression is normally at a very low level and increases by more than 2 orders of magnitude during heat shock, the hsp83 gene in Drosophila melanogaster is expressed at high levels during normal development and increases only severalfold in response to heat shock. Developmental expression of the hsp83 gene consists of a high level of tissue-general, basal expression and a very high level of expression in ovaries. We identified regions upstream of the hsp83 gene that were required for its developmental and heat shock-induced expression by assaying beta-galactosidase activity and mRNA levels in transgenic animals containing a series of 5' deletion and insertion mutations of an hsp83-lacZ fusion gene. Deletion of sequences upstream of the overlapping array of a previously defined heat shock consensus (HSC) sequence eliminated both forms of developmental expression of the hsp83 gene. As a result, the hsp83 gene with this deletion mutation was regulated like that of the hsp70 gene. Moreover, an in vivo polymer competition assay revealed that the overlapping HSC sequences of the hsp83 gene and the nonoverlapping HSC sequences of the hsp70 gene had similar affinities for the factor required for heat induction of the two heat shock genes. We discuss the functional similarity of hsp70 and hsp83 heat shock regulation in terms of a revised view of the heat shock-regulatory sequence.     

Immunoelectron microscope localization of Mr 90000 heat shock protein and Mr 70000 heat shock cognate protein in the salivary glands of Chironomus thummi

The Mr 90000 heat shock protein (hsp 90) and one of the Mr 70000 heat shock cognate proteins (hsc 70) were localized by immunoelectron microscopy in salavary gland cells of normal and heat-shocked larvae of Chironomus thummi using polyclonal antibodies raised against Drosophila proteins. Immunoblotting after separation of proteins by gel electrophoresis shows that these antibodies cross-react with the corresponding proteins of Chironomus. Hsp 90 was localized both in the cytoplasm and in the nucleus, where it is associated with intrachromosomal and extrachromosomal ribonucleoprotein (RNP) fibrils, as well as with the peripheral region of compact chromatin. After heat shock the concentration of hsp 90 increases in the nucleus. This increase is prevented by actinomycin D administration during the heat shock. Hsp 90 is associated with the chromatin of puffs repressed by heat shock and with the RNP fibrils of actively transcribing heat shock puffs. Hsc 70 is mainly found in RNP fibrils and in the periphery of compact chromatin. During heat shock the concentration of hsc 70 decreases in the cytoplasm while it becomes more abundant in association with chromatin and intrachromosomal and extrachromosomal RNP fibrils. These results suggest a translocation of the existing protein from the cytoplasm toward the nucleus. They are supported by observations of the effect of heat shock carried out in the presence of actinomycin D.by D.P. Bazett-Jones     

Effects of cycloheximide on thermotolerance expression, heat shock protein synthesis, and heat shock protein mRNA accumulation in rat fibroblasts.

A single hyperthermic exposure can render cells transiently resistant to subsequent high temperature stresses. Treatment of rat embryonic fibroblasts with cycloheximide for 6 h after a 20-min interval at 45 degrees C inhibits protein synthesis, including heat shock protein (hsp) synthesis, and results in an accumulation of hsp 70 mRNA, but has no effect on subsequent survival responses to 45 degrees C hyperthermia. hsp 70 mRNA levels decreased within 1 h after removal of cycloheximide but then appeared to stabilize during the next 2 h (3 h after drug removal and 9 h after heat shock). hsp 70 mRNA accumulation could be further increased by a second heat shock at 45 degrees C for 20 min 6 h after the first hyperthermic exposure in cycloheximide-treated cells. Both normal protein and hsp synthesis appeared increased during the 6-h interval after hyperthermia in cultures which received two exposures to 45 degrees C for 20 min compared with those which received only one treatment. No increased hsp synthesis was observed in cultures treated with cycloheximide, even though hsp 70 mRNA levels appeared elevated. These data indicate that, although heat shock induces the accumulation of hsp 70 mRNA in both normal and thermotolerant cells, neither general protein synthesis nor hsp synthesis is required during the interval between two hyperthermic stresses for Rat-1 cells to express either thermotolerance (survival resistance) or resistance to heat shock-induced inhibition of protein synthesis.     

Effect of Heat Shock on Intracellular Calcium Mobilization in Neuroblastoma × Glioma Hybrid Cells

Abstract: The effect of heat shock on agonist-stimulated intracellular Ca²⁺ mobilization and the expression of heat shock protein 72 (hsp72) in neuroblastoma × glioma hybrid cells (NG 108–15 cells) were examined. Hsp72 was expressed at 6 h after heat shock (42.5°C, 2 h), reached a maximum at 12 h, and decreased thereafter. Bradykinin-induced [Ca²⁺], rise was attenuated to 28% of control by heat shock at 2 h after heat shock, and reversion to the control level was seen 12 h later. When the cells were treated with quercetin or antisense oligodeoxyribonucleotide against hsp72 cDNA, the synthesis of hsp72 was not induced by heat shock, whereas bradykinin-induced [Ca²⁺]_i rise was abolished and the [Ca²⁺]_i rise was not restored. Recovery from this stressed condition was evident when cells were stimulated by the Ca²⁺-ATPase inhibitor thapsigargin, even in the presence of either quercetin or antisense oligodeoxyribonucleotide. Inositol 1,4,5-trisphosphate (IP₃) production was not altered by heat shock at 12 h after heat shock, whereas IP₃ receptor binding activity was reduced to 45.3%. In the presence of quercetin or antisense oligodeoxyribonucleotide, IP₃ receptor binding activity decreased and reached 27.2% of the control 12 h after heat shock. Our working thesis is that heat shock transiently suppresses the IPs-mediated intracellular Ca²⁺ signal transduction system and that hsp72 is involved in the recovery of bradykinin-induced [Ca²⁺]_i rise.     

Expression of the Tribolium castaneum （Coleoptera： Tenebrionidae） hsp83 gene and its relation to oogenesis during ovarian maturation

Heat shock proteins (HSP) can protect organisms and cells from thermal damage. In this study, we cloned the full length cDNA encoding the HSP83 protein (the homologue of HSP90) of Tribolium castaneum (red flour beetle). The isolated cDNA contains the full coding sequence, a partial 5′ untranslated region of 55 bp and the complete 3′ untranslated region. We found the hsp83 gene is located on chromosome 5 of the T. castaneum genome. The predicted HSP83 protein sequence has a high similarity (on average 86.77%) with that of other insect species. The expression of the hsp83 gene in the whole body and in the ovary could be induced with heat stress (40°C for 1 h) in newly hatched (within 3 h post emergence) and mature (10 days post emergence) beetles. Under normal conditions, the hsp83 expression in the ovary is about 3-fold higher than in the whole body at both stages. No significant difference in hsp83 expression was observed between the two ovarian developmental stages regardless if the beetles were treated with heat shock or not. The expression of the HSP83 protein in the whole body could also be induced with heat stress in newly hatched and mature beetles. However, in the ovary, HSP83 was only expressed in the follicle cells of mature beetles and not in newly hatched beetles, regardless if the beetles were treated with heat shock or not. Furthermore, the females were not able to produce mature oocytes after knock-down of the hsp83 expression by injecting dsRNA. These results suggest that the HSP83 protein is involved in protection against heat stress and could be involved in oogenesis during ovarian maturation of T. castaneum.     

Regulation of HSP70 synthesis by messenger RNA degradation.

When Drosophila cells are heat shocked, hsp70 messenger RNA (mRNA) is stable and is translated at high efficiencies. During recovery from heat shock, hsp70 synthesis is repressed and its messenger RNA (mRNA) is degraded in a highly regulated fashion. Dramatic differences in the timing of repression and degradation are observed after heat treatments of different severities. The 3' untranslated region (UTR) of the hsp70 mRNA was sufficient to transfer this regulated degradation to heterologous mRNAs. Altering the translational efficiency of the message or changing its natural translation-termination site did not alter its pattern of regulation, although in some cases it changed the absolute rate of degradation. We have previously shown that hsp70 mRNA is very unstable when it is expressed at normal growth temperatures (from a metallothionein promoter). We report here that the 3' untranslated region of the hsp70 mRNA is responsible for this instability as well. We postulate that a mechanism for degrading hsp70 mRNA pre-exists in Drosophila cells, that it is inactivated by heat shock and that it is the reactivation of this mechanism that is responsible for hsp70 repression during recovery. This degradation system may be the same as that used by other unstable mRNAs.     

Intracellular localization of hsp90 is influenced by developmental stage and environmental estrogens in rainbow trout Oncorhynchus mykiss

In this study, we investigated the intracellular localization of heat shock proteins hsp90 and hsp70 in adult and juvenile rainbow trout (Oncorhynchus mykiss) and in juvenile trout exposed to estrogen or one of its mimics, 4-nonylphenol (4-NP). Livers were harvested from each group and analyzed directly or separated into nuclear and nonnuclear fractions. We found that hsp70 was predominantly nonnuclear in mature and juvenile fish regardless of treatment. Mature fish had significantly greater levels of hsp90 outside the nucleus, while juvenile fish had similar levels of hsp90 inside and outside the nucleus. Treatment with estradiol or 4-NP resulted in a translocation of hsp90 out of the nucleus in juvenile fish. To our knowledge, this is the first study to demonstrate a development- and/or estrogen-dependent shift in intracellular localization of hsp90 in fish. This change in subcellular distribution points to important roles for this hsp in fish estrogen signaling and development.