Selective release from cultured mammalian cells of heat-shock (stress) proteins that resemble glia-axon transfer proteins

Cultured rat embryo cells were stimulated to rapidly release a small group of proteins that included several heat-shock proteins (hsp110, hsp71, hscp73) and nonmuscle actin. The extracellular proteins were analyzed by two-dimensional polyacrylamide gel electrophoresis. Heat-shocked cells released the same set of proteins as control cells with the addition of the stress-inducible hsp110 and hsp71. Release of these proteins was not blocked by either monensin or colchicine, inhibitors of the common secretory pathway. A small amount of the glucose-regulated protein grp78 was externalized by this pathway. The extracellular accumulation of these proteins was inhibited after they were synthesized in the presence of the lysine analogue aminoethyl cysteine. It is likely that the analogue-substituted proteins were misfolded and could not be released from cells, supporting our conclusion that a selective release mechanism is involved. Remarkably, actin and the squid heat-shock proteins homologous to rat hsp71 and hsp110 are also among a select group of proteins transferred from glial cells to the squid giant axon, where they have been implicated in neuronal stress responses (Tytell et al.: Brain Res., 363:161-164, 1986). Based in part on the similarities between these two sets of proteins, we hypothesized that these proteins were released from labile cortical regions of animal cells in response to perturbations of homeostasis in cells as evolutionarily distinct as cultured rat embryo cells and squid glial cells.     

Newcastle disease virus stimulates the cellular accumulation of stress (heat shock) mRNAs and proteins.

A biological agent, Newcastle disease virus, stimulated the synthesis of stress proteins in cultured chicken embryo cells. Previously, only physical and chemical agents were known to induce these proteins. The levels of translatable stress mRNAs were elevated in cells infected with avirulent or virulent strains; however, stress protein synthesis was stimulated strongly only in cells infected by avirulent strains. As did several other paramyxoviruses, avirulent strains of Newcastle disease virus stimulated the synthesis of glucose-regulated proteins as well as stress proteins. Possible stimuli of the synthesis of these two sets of proteins in paramyxovirus-infected cells are considered.     

Synthesis of heat-shock proteins in Saccharomyces cerevisiae protoplasts

The effect of cellular capsule elimination in Saccharomyces cerevisiae yeasts (protoplast formation) on the heat-shock protein synthesis and the synthesis of the proteins in protoplasts were studied. The methods of mono- and dimeric electrophoresis have demonstrated that (1) about 18 heat-shock proteins with the molecular masses 26-98 Kd are synthesized in cells at 41 degrees C; (2) protoplast formation per se does not induce the synthesis of heat-shock proteins, but the induction of these proteins in protoplasts at 41 degrees C is similar to the one in intact cells. The protoplast formation induces the synthesis of specific proteins different from heat-shock proteins and the synthesis is inhibited by the heat-shock. The heat-shock induces modification of 88 and 86 Kd heat-shock proteins. It inhibits the synthesis of a number of peptides (15-50 Kd) in cells and protoplasts.     

Expression of heat-shock and glucose-regulated genes: differential effects of glucose starvation and hypertonicity

The hsp and grp gene families encode structurally-related proteins which are overexpressed upon physiological stress and which presumably play critical roles in protecting cells against different environmental insults. While the heat-shock proteins induced by hyperthermia have been localized to the nucleus, the glucose-regulated proteins activated by glucose deprivation have been identified in the endoplasmic reticulum. To further our understanding of the regulation of these genes, we have analyzed the expression of individual members of the two gene families under different environmental states. We have observed that, while related members of the same gene family may be coordinately induced under one physiologic state, they may also be differentially activated under a different environmental condition. Furthermore, the induction may be gradual but persistent or abrupt but transient. We have also found that related members of the two gene families may similarly be coordinately or differentially induced in response to different environmental abuses. Our observations are consistent with the belief that the regulation of the expression of stress proteins is complex.     

Oxidative stress induces a subset of heat shock proteins in rat hepatocytes and MH1C1 cells

Lipoperoxidative damage caused by exposure of isolated hepatocytes or cultivated hepatoma cells to ADP-iron or to 4-hydroxynonenal induces the synthesis of some proteins which are different under these two conditions but are always a subset of the proteins induced in each type of cells upon heat-shock (heat-shock proteins). For at least one of these proteins (hsp 31), induced by 4-hydroxynonenal, the increase is dose-dependent and the effect of heat and the chemical seems to be additive. Lipoperoxidation may be implicated in the induction of some of the heat shock proteins, but reproduces only incompletely the response of protein synthesis typical of heat-shock conditions.     

Plasminogen structural domains exhibit different functions when associated with cell surface GRP78 or the voltage-dependent anion channel

Both the voltage-dependent anion channel and the glucose-regulated protein 78 have been identified as plasminogen kringle 5 receptors on endothelial cells. In this study, we demonstrate that kringle 5 binds to a region localized in the N-terminal domain of the glucose-regulated protein 78, whereas microplasminogen does so through the C-terminal domain of the glucose-regulated protein 78. Both plasminogen fragments induce Ca(2+) signaling cascades; however, kringle 5 acts through voltage-dependent anion channel and microplasminogen does so via the glucose-regulated protein 78. Because trafficking of voltage-dependent anion channel to the cell surface is associated with heat shock proteins, we investigated a possible association between voltage-dependent anion channel and glucose-regulated protein 78 on the surface of 1-LN human prostate tumor cells. We demonstrate that these proteins co-localize, and changes in the expression of the glucoseregulated protein 78 affect the expression of voltage-dependent anion channel. To differentiate the functions of these receptor proteins, either when acting singly or as a complex, we employed human hexokinase I as a specific ligand for voltage-dependent anion channel, in addition to kringle 5. We show that kringle 5 inhibits 1-LN cell proliferation and promotes caspase-7 activity by a mechanism that requires binding to cell surface voltage-dependent anion channel and is inhibited by human hexokinase I.     

Changes in intracellular levels of Ap3A and Ap4A in cysts and larvae of Artemia do not correlate with changes in protein synthesis after heat-shock.

Artemia larvae respond to a brief heat-shock between 28 degrees and 40 degrees C with an increase in the synthesis of two groups of proteins of Mr 68,000 and 89,000. At 40 degrees C synthesis of all other proteins is strongly repressed. Cysts, which are naturally thermotolerant, synthesise both heat-shock proteins at temperatures up to 47 degrees C but maintain normal protein synthesis. During pre-emergence development, Ap3A is present in cysts at a concentration twice that of Ap4A. The maximum level of 7.6 pmol/10(6) cells is reached shortly before hatching of the larvae. After hatching, the levels of both nucleotides decline. A 40 degrees C heat-shock produces a 1.8-fold increase in both nucleotides within 20 min in cysts and larvae. A 2.8-fold increase results from a 47 degrees C heat-shock to cysts. The rates of increase parallel but do not precede the increases in the heat-shock proteins. Since non-heat-shocked cysts possess higher levels of Ap3A and Ap4A than do heat-shocked larvae, the observed heat-induced changes in gene expression cannot be explained simply in terms of the intracellular concentrations of these nucleotides.     

Human fibroblast-conditioned medium contains a 100K dalton glucose-regulated cell surface protein

This report describes the identification and partial characterization of a 100K dalton “glucose-regulated” cell surface protein of human diploid fibroblasts (HDF). This protein is released into and can be recovered virtually intact from the surrounding culture medium. At the present level of analysis, the protein recovered from the culture medium (“conditioned medium”) is indistinguishable from the protein extracted directly from the cell surface by 1 M urea treatment. Both proteins have molecular weights of 100K daltons when analyzed by gel electrophoresis. The protein is readily labeled at the cell surface via lactoperoxidase-catalyzed iodination, and the label can be chased into the released form of this protein in conditioned medium. Antiserum raised against the medium form of the protein reacts with the surface form of the protein but does not react with fibronectin, the major cell surface protein of HDF. Conditioned medium from SV40-transformed human fibroblasts does not contain the 100K protein, but instead contains a component that has a slightly lower molecular weight (97K daltons). The lower molecular weight band does not iodinate at the cell surface and is apparently an underglycosylated form of the 100K protein. Its molecular weight is shifted back to 100K by growing transformed cells in medium containing excess glucose. After the shift, the component becomes accessible to the radioiodine label. We suggest that the 100K protein is a glucose-regulated protein (Shiu, Pouyssegur and Pastan, 1977; Pouyssegur and Yamada, 1978) that is released into the culture medium. An underglycosylated form of the same glycoprotein is released from transformed cells.     

Inhibition of the heat shock response and synthesis of glucose-regulated proteins in Ca2+-deprived rat hepatoma cells

Rat hepatoma cells become refractory to the induction of heat shock proteins and highly resistant to severe hyperthermia when incubated in Ca2+-free medium. The Ca2+-depleted cells synthesize polypeptides identified as the glucose-regulated proteins, but these proteins do not appear to be directly involved in the inhibition of the heat shock response. The results suggest that a Ca2+-dependent metabolic process is involved in the generation of the heat shock signal and/or mediates a step in the subsequent cascade of events that leads to the induction of heat shock protein synthesis and cell death.     

Characterization of the thermotolerant cell. II. Effects on the intracellular distribution of heat-shock protein 70, intermediate filaments, and small nuclear ribonucleoprotein complexes

Here we further characterize a number of properties inherent to the thermotolerant cell. In the preceding paper, we showed that the acquisition of the thermotolerant state (by a prior induction of the heat-shock proteins) renders cells translationally tolerant to a subsequent severe heat-shock treatment and thereby results in faster kinetics of both the synthesis and subsequent repression of the stress proteins. Because of the apparent integral role of the 70-kD stress proteins in the acquisition of tolerance, we compared the intracellular distribution of these proteins in both tolerant and nontolerant cells before and after a severe 45 degrees C/30-min shock. In both HeLa and rat embryo fibroblasts, the synthesis and migration of the major stress-induced 72-kD protein into the nucleolus and its subsequent exit was markedly faster in the tolerant cells as compared with the nontolerant cells. Migration of preexisting 72-kD into the nucleolus was shown to be dependent upon heat-shock treatment and independent of active heat-shock protein synthesis. Using both microinjection and immunological techniques, we observed that the constitutive and abundant 73-kD stress protein similarly showed a redistribution from the cytoplasm and nucleus into the nucleolus as a function of heat-shock treatment. We show also that other lesions that occur in cells after heat shock can be prevented or at least minimized if the cells are first made tolerant. Specifically, the heat-induced collapse of the intermediate filament cytoskeleton did not occur in cells rendered thermotolerant. Similarly, the disruption of intranuclear staining patterns of the small nuclear ribonucleoprotein complexes after heat-shock treatment was less apparent in tolerant cells exposed to a subsequent heat-shock treatment.     

Induction of glucose-regulated proteins in Xenopus laevis A6 cells

We have characterized the induction of glucose-regulated proteins (GRPs) in Xenopus laevis A6 cells, a kidney epithelial cell line. Exposure of A6 cells to medium in which 2-deoxyglucose replaced galactose resulted in enhanced synthesis of two proteins at 78 and 98 kd. The 78 kd protein was determined by two-dimensional PAGE to consist of two isoelectric variants with pls of 5.3 and 5.2 whereas the 98 kd protein resolved into a single spot with a pl of 5.1. The 78 kd protein cross-reacted with antiserum against chicken GRP78 (glucose-regulated protein), suggesting that the Xenopus protein shares homology with a previously characterized GRP. This was supported by the finding that a rat GRP78 probe hybridized with a 2-deoxyglucose-inducible mRNA. Synthesis of the two proteins was also induced by tunicamycin, 2-deoxygalactose, and dithiothreitol. However, the GRPs were not induced by glucosamine or calcium ionophore A23187 at concentrations and exposure periods that have previously been shown to elicit a GRP response in mammalian and avian cells. Enhanced synthesis of the two GRPs by 2-deoxyglucose was transient, reaching maximal levels by 12-24 h and decreasing to near control levels by 48 h. Removal of the stress at the point of peak synthesis resulted in decreased synthesis of both proteins within 6 h and a return to control levels within 24 h of recovery. These data suggest that Xenopus cells have a GRP response that is similar, but not identical, to that found in mammalian cells.     

Free messenger ribonucleoprotein complexes of chicken primary muscle cells following modification of protein synthesis by heat-shock treatment

When primary cultures of chicken myoblasts were subjected to incubation at a temperature higher than their normal growing temperature of 36-37 degrees C, the pattern of protein synthesis was altered. This condition of heat shock induced a vigorous production of a number of proteins collectively known as 'heat-shock proteins'. The synthesis of heat-shock proteins was achieved without a significant decrease in the production of a broad spectrum of proteins by muscle cells. The synthesis of three major heat-shock polypeptides with Mr values of 81 000, 65 000 and 25 000 was observed in both mononucleated dividing myoblast cells and terminally differentiated myotubes. Two-dimensional electrophoretic separation of the heat-induced polypeptides synthesized by myogenetic cultures further established that same set of polypeptides with Mr of 65 000 (pI 6.0 and 5.5), 81 000 (pI 6.2) and 25 000 (pI 5.6 and 5.3) were produced in myoblasts and myotubes. The effect of the changes in pattern of protein synthesis on the mRNA and protein moieties of non-polysomal cytoplasmic mRNA-protein complexes (free mRNP) was examined. Free mRNP complexes sedimenting at 20-35 S were isolated from the post-ribosomal supernatant of both normal and heat-shocked myotube cultures by centrifugation in a sucrose gradient. A 10-20S RNA fraction isolated from these complexes stimulated protein synthesis in a cell-free system. The RNA fraction obtained from heat-shocked cells appeared to direct the synthesis of all three major heat-shock proteins. In contrast, synthesis of these polypeptides was not detected when RNA from free mRNP complexes of normal cells was used for translation. The free mRNP complexes of both normal and heat-shocked cells showed a buoyant density of 1.195 g/cm3 in metrizamide gradients. A large number of polypeptides of Mr = 35 000-105 000 were present in the highly purified free mRNP complexes isolated from the metrizamide gradient. Similar sets of polypeptides were found in these complexes from both normal and heat-shocked myotube culture. However, the relative proportion of a 65 000-Mr polypeptide was dramatically increased in the free mRNP complexes of heat-shocked cells. Two-dimensional gel electrophoretic analysis revealed that this polypeptide and the 65 000-Mr heat-shock polypeptide exhibit similar electrophoretic migration properties. These observations suggest that, following heat-shock treatment of chicken myotube cultures, the changes in the pattern of protein synthesis is accompanied by alteration of the mRNA and protein composition of free mRNP complexes.     

Increased synthesis of secreted proteins induces expression of glucose-regulated proteins in butyrate-treated Chinese hamster ovary cells

The effects of increased synthesis of secreted proteins expressed from stably integrated heterologous genes in Chinese hamster ovary (CHO) cells following treatment with sodium butyrate was studied. Butyrate treatment increased expression of mRNA transcribed from the adenovirus major late promoter in combination with the SV40 enhancer for Factor VIII, von Willebrand factor, and erythropoietin. Increased levels of mRNA were compared to increases in intracellular primary translation product and secreted protein. While von Willebrand factor and erythropoietin were efficiently secreted, Factor VIII was not. Increased expression of all these proteins induced expression of the glucose-regulated proteins, GRP78 and GRP94. However, increased Factor VIII synthesis was correlated with an 80-fold increase in GRP78 mRNA and a 10-fold increase in GRP94 mRNA. These data suggest that elevated levels of newly synthesized secretion-competent protein as well as misfolded protein induce the glucose-regulated proteins.     

Adaptive cellular response to hyperthermia: 31P-NMR studies

Dynamic intracellular ATP and Pi levels were measured non-invasively for Chinese hamster V79 cells by 31P-NMR under conditions of thermotolerance and heat-shock protein induction. High densities of cells were embedded in agarose strands, placed within a standard NMR sample tube, and perfused with medium maintained either at 37 or 43 degrees C at pH 7.35. Cell survival and heat-shock protein synthesis were assessed either from parallel monolayer cultures or cells dislodged from the agarose strands post-treatment. Thermotolerance (heat resistance) and heat-shock protein synthesis was induced by a 1 h exposure to 43 degrees C followed by incubation for 5 h at 37 degrees C. After the 5 h incubation at 37 degrees C, marked thermal resistance was observed in regard to survival with concomitant synthesis of two major heat-shock proteins at 70 and 103 kDa. Studies were also conducted where tolerance and heat-shock protein synthesis were partially inhibited by depletion of cellular glutathione (GSH) prior to and during heat treatment. Dynamic measurement of intracellular ATP of cells heated with or without GSH depletion revealed no change in steady-state levels immediately after heating or during the 5 h post-heating incubation at 37 degrees C where thermotolerance and heat-shock proteins develop. These data are consistent with other reported data for mammalian cells and indicate that the steady-state ATP levels in mammalian cells remain unchanged during and after the acquisition of the thermotolerant state.     

Characterization of the thermotolerant cell. I. Effects on protein synthesis activity and the regulation of heat-shock protein 70 expression

Exposure of mammalian cells to a nonlethal heat-shock treatment, followed by a recovery period at 37 degrees C, results in increased cell survival after a subsequent and otherwise lethal heat-shock treatment. Here we characterize this phenomenon, termed acquired thermotolerance, at the level of translation. In a number of different mammalian cell lines given a severe 45 degrees C/30-min shock and then returned to 37 degrees C, protein synthesis was completely inhibited for as long as 5 h. Upon resumption of translational activity, there was a marked induction of heat-shock (or stress) protein synthesis, which continued for several hours. In contrast, cells first made thermotolerant (by a pretreatment consisting of a 43 degrees C/1.5-h shock and further recovery at 37 degrees C) and then presented with the 45 degrees C/30-min shock exhibited considerably less translational inhibition and an overall reduction in the amount of subsequent stress protein synthesis. The acquisition and duration of such "translational tolerance" was correlated with the expression, accumulation, and relative half-lives of the major stress proteins of 72 and 73 kD. Other agents that induce the synthesis of the stress proteins, such as sodium arsenite, similarly resulted in the acquisition of translational tolerance. The probable role of the stress proteins in the acquisition of translational tolerance was further indicated by the inability of the amino acid analogue, L-azetidine 2-carboxylic acid, an inducer of nonfunctional stress proteins, to render cells translationally tolerant. If, however, analogue-treated cells were allowed to recover in normal medium, and hence produce functional stress proteins, full translational tolerance was observed. Finally, we present data indicating that the 72- and 73-kD stress proteins, in contrast to the other major stress proteins (of 110, 90, and 28 kD), are subject to strict regulation in the stressed cell. Quantitation of 72- and 73-kD synthesis after heat-shock treatment under a number of conditions revealed that "titration" of 72/73-kD synthesis in response to stress may represent a mechanism by which the cell monitors its local growth environment.     

Wound-induced PAL activity is suppressed by heat-shock treatments that induce the synthesis of heat-shock proteins

Wounding lettuce leaves induces the de novo synthesis of phenylalanine ammonia-lyase (PAL, EC 4.3.1.5), the accumulation of phenolic compounds, and subsequent tissue browning. A brief heat-shock at 45°C reduces the rise in wound-induced PAL, the accumulation of phenolic compounds, and tissue browning. The activity of PAL measured 24 h after wounding and the content of phenolic compounds (absorbance of methanol extract at 320 nm) measured 48 h after wounding was highly correlated (R² > 0.90) in tissue developing the normal wound response and in tissue subjected to 0–180 s of heat-shock after wounding. The synthesis of a unique set of proteins called heat-shock proteins (hsps) is induced by these heat-shock treatments. Western-blot analyses of proteins isolated from wounded and heat-shocked Iceberg and Romaine lettuce mid-rib leaf tissue was done using antibodies against hsp 23. Only those heat-shock treatments that were effective at inducing the synthesis of hsp 23 were effective in reducing the activity of PAL induced by wounding and the subsequent accumulation of phenolic compounds. Hsps induced in non-wounded, whole leaves by exposure to 45°C for 150 s did not significantly interact with PAL previously synthesized in non-heat-shocked wounded leaves to limit its activity. The preferential synthesis of hsps over that of wound-induced PAL, rather than the presence of hsps, may be responsible for the ability of a heat-shock treatment to reduce the wound-induced increase in PAL activity. Our results support this novel concept, and the possibility that heat-shock treatments can have significant physiological effects on the response of the tissue to other stresses, not because of the specific genes they induce or repress, or the products they cause to be synthesized, but by their secondary action of influencing the synthesis of other proteins (e.g. PAL) by the suppression of non-hsps protein synthesis.