Subcellular distribution of human RDM1 protein isoforms and their nucleolar accumulation in response to heat shock and proteotoxic stress

The RDM1 gene encodes a RNA recognition motif (RRM)-containing protein involved in the cellular response to the anti-cancer drug cisplatin in vertebrates. We previously reported a cDNA encoding the full-length human RDM1 protein. Here, we describe the identification of 11 human cDNAs encoding RDM1 protein isoforms. This repertoire is generated by alternative pre-mRNA splicing and differential usage of two translational start sites, resulting in proteins with long or short N-terminus and a great diversity in the exonic composition of their C-terminus. By using tagged proteins and fluorescent microscopy, we examined the subcellular distribution of full-length RDM1 (renamed RDM1alpha), and other RDM1 isoforms. We show that RDM1alpha undergoes subcellular redistribution and nucleolar accumulation in response to proteotoxic stress and mild heat shock. In unstressed cells, the long N-terminal isoforms displayed distinct subcellular distribution patterns, ranging from a predominantly cytoplasmic to almost exclusive nuclear localization, suggesting functional differences among the RDM1 proteins. However, all isoforms underwent stress-induced nucleolar accumulation. We identified nuclear and nucleolar localization determinants as well as domains conferring cytoplasmic retention to the RDM1 proteins. Finally, RDM1 null chicken DT40 cells displayed an increased sensitivity to heat shock, compared to wild-type (wt) cells, suggesting a function for RDM1 in the heat-shock response.     

Human cyclophilin 40 is a heat shock protein that exhibits altered intracellular localization following heat shock

The unactivated steroid receptors are chaperoned into a conformation that is optimal for binding hormone by a number of heat shock proteins, including Hsp90, Hsp70, Hsp40, and the immunophilin, FKBP52 (Hsp56). Together with its partner cochaperones, cyclophilin 40 (CyP40) and FKBP51, FKBP52 belongs to a distinct group of structurally related immunophilins that modulate steroid receptor function through their association with Hsp90. Due to the structural similarity between the component immunophilins, FKBP52 and cyclophilin 40, we decided to investigate whether CyP40 is also a heat shock protein. Exposure of MCF-7 breast cancer cells to elevated temperatures (42 degrees C for 3 hours) resulted in a 75-fold increase in CyP40 mRNA levels, but no corresponding increase in CyP40 protein expression, even after 7 hours of heat stress. The use of cycloheximide to inhibit protein synthesis revealed that in comparison to MCF-7 cells cultured at 37 degrees C, those exposed to heat stress (42 degrees C for 3 hours) displayed an elevated rate of degradation of both CyP40 and FKBP52 proteins. Concomitantly, the half-life of the CyP40 protein was reduced from more than 24 hours to just over 8 hours following heat shock. As no alteration in CyP40 protein levels occurred in cells exposed to heat shock, an elevated rate of degradation would imply that CyP40 protein was synthesized at an increased rate, hence the designation of human CyP40 as a heat shock protein. Application of heat stress elicited a marked redistribution of CyP40 protein in MCF-7 cells from a predominantly nucleolar localization, with some nuclear and cytoplasmic staining, to a pattern characterized by a pronounced nuclear accumulation of CyP40, with no distinguishable nucleolar staining. This increase in nuclear CyP40 possibly resulted from a redistribution of cytoplasmic and nucleolar CyP40, as no net increase in CyP40 expression levels occurred in response to stress. Exposure of MCF-7 cells to actinomycin D for 4 hours resulted in the translocation of the nucleolar marker protein, B23, from the nucleolus, with only a small reduction in nucleolar CyP40 levels. Under normal growth conditions, MCF-7 cells exhibited an apparent colocalization of CyP40 and FKBP52 within the nucleolus.     

Phorbol ester, calcium ionophore, or serum added to quiescent rat embryo fibroblast cells all result in the elevated phosphorylation of two 28,000-dalton mammalian stress proteins

Rat embryo fibroblast cells grown under stress (e.g. heat shock, arsenite, or amino acid analogue treatment) show elevated levels of a number of proteins with apparent molecular masses between 28,000-110,000 daltons (i.e. stress proteins). It is shown that the smaller 28,000-dalton stress proteins, which do not contain methionine, are comprised of at least four isoforms, all of which appear related as determined by one-dimensional peptide mapping. [32P]H3PO4 labeling of normal and stressed cells demonstrates that three of the four 28-kDa isoforms are phosphoproteins. In the course of other studies phosphorylation of two 28,000-dalton proteins was observed in quiescent rat embryo fibroblasts following the addition of either the phorbol diester, phorbol-12-myristate-13 acetate, a calcium ionophore, A23187, or simply fresh serum. It is shown here that these two 28,000-dalton proteins are in fact two of the 28 kDa mammalian stress proteins.     

Cell cycle-specific effects of sodium arsenite and hyperthermic exposure on incorporation of radioactive leucine and phosphate by stress proteins from mouse lymphoma cell nuclei

Cultured mouse lymphoma cells incorporated [3H]leucine and [32P]phosphate into nuclear stress proteins within 3 h after exposure to either elevated temperature (45 degrees C) or sodium arsenite. Radiolabeled proteins were detected by autoradiography after two-dimensional polyacrylamide gel electrophoresis. To determine the cell cycle stage specificity of labeling, nuclei were isolated and sorted into two cell cycle phases using a fluorescent activated cell sorter. After either heat shock or sodium arsenite treatment, the majority of [3H]leucine incorporation into stress proteins occurred during the G0 + G1 phase with minimal labeling in the G2 phase. On the other hand, 32P labeling of stress proteins occurred in both the G0 + G1 and G2 phases after exposure to sodium arsenite, while incorporation of 32P was limited after heat stress. Following sodium arsenite treatment, a distinct set of four stress proteins (80-84 kDa) was detected with [3H]leucine only in G0 + G1 phase, but with [32P]phosphate these stress proteins were labeled in both G0 + G1 and G2. There was differential [32P]phosphate labeling between proteins of the 80-84 kDa set during cell cycling. Individual proteins of this set were isolated from gel plugs after sodium arsenite or heat-shock treatment. Coelectrophoresis of proteins from the two treatment groups showed that they had similar electrophoretic mobilities. All four proteins of the 80-84 kDa set (sodium arsenite induced) possessed similar polypeptide maps after digestion with V8 protease. Cytofluorometric analysis demonstrated a reduction in the number of nuclei in both S and G2 phases of the cell cycle two h after heat shock, but not following sodium arsenite treatment. However, there was a significant depression in the number of nuclei in S and G2 4 h after exposure to sodium arsenite and very modest labeling with 32P of stress proteins was observed at this time.     

Independent regulation of prostaglandin production and the stress response in human fibroblasts.

The stress, or heat shock response of eukaryotic cells is characterized by dramatic changes in the metabolism of responding cells, most notably the increased synthesis of a group of proteins known as heat shock proteins. In this study, we examined the relationship of prostaglandin synthesis/release to the stress response. Stress protein synthesis was induced with sodium arsenite, and prostaglandin E2 and prostacyclin (measured as 6-keto PGF1 alpha) levels were determined by enzyme immunoassay. The stress response was monitored by the incorporation of [35S]methionine and separation of protein by one-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Prostaglandin synthesis and the stress response were both induced by sodium arsenite. However, aspirin, a cyclooxygenase inhibitor, inhibited arsenite-induced prostaglandin synthesis but did not inhibit stress protein synthesis. Conversely, the calcium ionophore A23187 also stimulated prostaglandin synthesis, but did not induce the stress response. The results of this study indicate that sodium arsenite, a stress response inducer, stimulates prostaglandin production, but this appears to be a correlative rather than causative occurrence in the stress response. Determination of the cytotoxicity of arsenite indicated a high correlation of stimulation of prostaglandin release with cytotoxicity.     

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.     

The stress protein response in cultured neurons: characterization and evidence for a protective role in excitotoxicity.

We used purified cultures of cerebellar granule cells to investigate the possible protective role of stress proteins in an in vitro model of excitotoxicity. Initial experiments used one- and two-dimensional polyacrylamide gel electrophoresis to confirm the induction of typical stress protein size classes by heat shock, sodium arsenite, and the calcium ionophore A23187. Immunoblot analysis and immunocytochemistry verified the expression of the highly inducible 72 kd heat shock protein (HSP72). Granule cell cultures exposed to glutamate showed evidence of cellular injury that was prevented by the noncompetitive NMDA antagonist MK-801, yet glutamate did not induce a detectable stress protein response. Nonetheless, preinduction of heat shock proteins was associated with protection from toxic concentrations of glutamate. These results imply that the HSP72 expression observed in in vivo models of excitotoxicity may not be directly related to the effects of excitatory amino acids. However, the ability of stress protein induction to protect against injury from glutamate may offer a novel approach toward ameliorating damage from excitotoxins.     

Induction of thermotolerance and enhanced heat shock protein synthesis in chinese hamster fibroblasts by sodium arsenite and by ethanol

Synthesis of a family of proteins called “heat shock” proteins is enhanced in cells in response to a wide variety of environmental stresses. This suggests that these proteins may have functions essential to cell survival under stressful conditions. A causative relationship between heat shock protein synthesis and development of thermotolerance would imply that agents known to induce heat shock protein synthesis, such as sodium arsenite, also induce thermotolerance. Conversely, agents known to induce thermotolerance, such as ethanol, would also enhance heat shock protein synthesis. To test this hypothesis, I have examined the effect of sodium arsenite or ethanol treatment on protein synthesis and cell survival in Chinese hamster ovary HA-1 cells. After either sodium arsenite or ethanol treatment, the synthesis of heat shock proteins was greatly enhanced over that of untreated cells. In parallel, cell survival was increased as much as 10⁴-fold when cells exposed to either agent were challenged by a subsequent heat treatment. The synthesis of heat shock proteins correlated well with the development of thermotolerance. A qualitative analysis of individual proteins suggests that the synthesis of 70,000 and 87,000 molecular weight proteins most closely mirrored the development of thermotolerance. The results, therefore, strongly reinforce the hypothesis that a causal relationship exists between the enhanced synthesis of heat shock protein and cell survival under specific stresses.     

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

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

The effects of environmental stress on steroid receptor levels and steroid-induced morphogenesis in Achlya ambisexualis

Incubation of Achlya ambisexualis at elevated temperature (heat shock) or in the presence of sodium arsenite resulted in an inhibition of steroid hormone-induced responsiveness. The effect of heat shock was time- and temperature-dependent and more severe than the effect of sodium arsenite. Incubation at 37 degrees C for 30 min completely abolished the steroid-induced response and full recovery was not observed until 6 h after a return to the normal growth temperature of 22 degrees C. Heat shock and arsenite treatment had no effect on the cellular uptake of the steroid hormone, but heat shock resulted in a time- and temperature-dependent loss in the cellular level of steroid receptors. In contrast, arsenite treatment had little effect on the concentration of steroid receptors. However, both heat shock and arsenite treatment produced a long-term (4 h) and transient (1 h) inhibition of total protein synthesis, respectively. The recovery of steroid-induced responsiveness following heat shock was observed after both protein synthesis and steroid hormone receptor levels had returned to normal values.     

Heat shock gene expression and cytoskeletal alterations in mouse neuroblastoma cells

The cytoskeleton of neuroblastoma cells, clone Neuro 2A, is altered by two stress conditions: heat shock and arsenite treatment. Microtubules are reorganized, intermediate filaments are aggregated around the nucleus, and the number of stress fibers is reduced. Since both stress modalities induce similar cytoskeletal alterations, no thermic denaturation of one or more cytoskeletal components can be involved in this process. Heat shock proteins are induced both by heat and by arsenite. However, cells treated with arsenite synthesize hsp28 which is not detected in heat-treated cells. Synthesis of all hsps is prevented by addition of actinomycin D or cycloheximide. Under these conditions no alterations are observed in the organization of microtubules and intermediate filaments during heat or arsenite treatment. However, these drugs are not able to prevent the rapid loss of stress fibers. A re-formation of the cytoskeleton during the recovery period proceeds within 3 h and is also found to occur in the presence of a protein synthesis inhibitor. These data suggest that reorganization of microtubules and intermediate filaments during a stress treatment requires the synthesis of a new protein(s), probably hsp(s).     

Dephosphorylation of cofilin accompanies heat shock-induced nuclear accumulation of cofilin

Cofilin is a widely distributed 21-kDa actin-modulating protein that forms intranuclear actin/cofilin rods in cultured fibroblastic cells exposed to heat shock or 10% dimethyl sulfoxide. In this study, cofilin was shown to be phosphorylated on a serine residue in cultured rat fibroblastic 3Y1 cells. Two-dimensional gel electrophoresis revealed that about 50% of the cofilin was phosphorylated in 3Y1 cells at 37 degrees C. Exposure of the cells to heat shock at 43 degrees C induced dephosphorylation of cofilin. The dephosphorylation of cofilin was detected about 30 min after the temperature shift and was completed within 120 min. Moreover, treatment of cells with 10% dimethyl sulfoxide also caused the dephosphorylation of cofilin. However, incubation of the cells with an isotonic NaCl solution, which induced cytoplasmic actin/cofilin rods, did not induce dephosphorylation of cofilin. Other cellular stress agents such as 6% ethanol or 50 microM sodium arsenite, which caused some heat shock responses in cells, did not induce dephosphorylation of cofilin. Thus, cofilin dephosphorylation was closely correlated with its nuclear accumulation. Incubation of the enucleated 3Y1 cells at 43 degrees C still induced dephosphorylation of cofilin, suggesting that the dephosphorylation occurred mostly in the cytoplasm in intact cells. It is likely that cofilin is dephosphorylated in the cytoplasm prior to its nuclear accumulation.     

Arsenite stabilizes IkappaBalpha and prevents NF-kappaB activation in IL-1 beta-stimulated Caco-2 cells independent of the heat shock response

Recent studies suggest that sodium arsenite downregulates NF-kappaB activity by inhibiting phosphorylation and subsequent degradation of IkappaBalpha. Many effects of sodium arsenite are secondary to induction of heat shock proteins. The role of the heat shock response in arsenite-induced inhibition of NF-kappaB, however, is not known. We examined the involvement of the heat shock response in arsenite-induced inhibition of NF-kappaB activity in IL-1beta-stimulated Caco-2 cells, a human colorectal adenocarcinoma cell line with enterocytic properties. Treatment of the cells with IL-1beta resulted in increased IkappaB kinase activity, reduced levels of IkappaBalpha and increased NF-kappaB DNA binding activity. Sodium arsenite blocked all of these responses to IL-1beta without inducing changes in heat shock factor activity or heat shock protein levels. Results from additional experiments showed that the protective effect of sodium arsenite on IkappaBalpha was not influenced by the oxygen radical scavenger catalase or by inhibitors of the MAP-kinase signaling pathway. The present results suggest that sodium arsenite stabilizes IkappaBalpha and prevents NF-kappaB activation in IL-1beta-stimulated Caco-2 cells independent of the heat shock response. In addition, stabilization of IkappaBalpha by sodium arsenite does not require oxygen radical formation or activation of the MAP kinase signaling pathway.     

Both near ultraviolet radiation and the oxidizing agent hydrogen peroxide induce a 32-kDa stress protein in normal human skin fibroblasts

We have analyzed the pattern of protein synthesis in solar near ultraviolet (334 nm, 365 nm) and near visible (405 nm) irradiated normal human skin fibroblasts. Two hours after irradiation we find that one major stress protein of approximately 32 kDa is induced in irradiated cells. This protein is not induced by ultraviolet radiation at wavelengths shorter than 334 nm and is not inducible by heat shock treatment of these cells. Although sodium arsenite, diamide, and menadione all induced a 32-kDa protein, they also induced the major heat shock proteins. In contrast, the oxidizing agent, hydrogen peroxide, induced the low molecular weight stress protein without causing induction of the major heat shock proteins. A comparison of the 32-kDa proteins induced by sodium arsenite, H2O2, and solar near ultraviolet radiation using chemical peptide mapping shows that they are closely related. These results imply that the pathways for induction of the heat shock response and the 32-kDa protein are not identical and suggest that, at least in the case of radiation and treatment with H2O2, the 32-kDa protein might be induced in response to cellular oxidative stress. This conclusion is supported by the observation that depletion of endogenous cellular glutathione prior to solar near ultraviolet irradiation lowers the fluence threshold for induction of the 32-kDa stress protein.     

Polypeptides encoded by polyadenylated and non-polyadenylated messenger RNAs from normal and heat shocked HeLa cells

There is an increased synthesis of proteins in the molecular weight region of 100,000 72,000-74,000 and 37,000 two hours after treatment of HeLa cells for 10 min at 45 degrees C. In vitro translation, using a rabbit reticulocyte cell-free protein synthesising system, of HeLa cell cytoplasmic RNA shows that the prominent 72,000-74,000 Mr heat shock protein band comprises seven polypeptide species (namely alpha d beta gamma delta epsilon zeta) and these polypeptides are directly encoded by both polyadenylated and nonpolyadenylated mRNA.     

Simultaneous exposure of Xenopus A6 kidney epithelial cells to concurrent mild sodium arsenite and heat stress results in enhanced hsp30 and hsp70 gene expression and the acquisition of thermotolerance

In this study, we examined the effect of concurrent low concentrations of sodium arsenite and mild heat shock temperatures on hsp30 and hsp70 gene expression in Xenopus A6 kidney epithelial cells. RNA blot hybridization and immunoblot analysis revealed that exposure of A6 cells to 1–10 µM sodium arsenite at a mild heat shock temperature of 30 °C enhanced hsp30 and hsp70 gene expression to a much greater extent than found with either stress individually. In cells treated simultaneously with 10 µM sodium arsenite and different heat shock temperatures, enhanced accumulation of HSP30 and HSP70 protein was first detected at 26 °C with larger responses at 28 and 30 °C. HSF1 activity was involved in combined stress-induced hsp gene expression since the HSF1 activation inhibitor, KNK437, inhibited HSP30 and HSP70 accumulation. Immunocytochemical analysis revealed that HSP30 was present in a granular pattern primarily in the cytoplasm in cells treated simultaneously with both stresses. Finally, prior exposure of A6 cells to concurrent sodium arsenite (10 µM) and heat shock (30 °C) treatment conferred thermotolerance since it protected them against a subsequent thermal challenge (37 °C). Acquired thermotolerance was not observed with cells treated with the two mild stresses individually.     

Dephosphorylation of S6 and expression of the heat shock response in Drosophila melanogaster.

A basic ribosomal phosphoprotein of 30,000 molecular weight was rapidly dephosphorylated in cultured Drosophila melanogaster cells heat shocked at 37 degrees C. The protein was associated with the 40S ribosomal subunit and had an electrophoretic mobility similar to that of purified rat liver protein S6 on basic two-dimensional polyacrylamide gels as well as a similar partial proteolysis peptide map. In logarithmically growing cultures, this D. melanogaster S6 protein appeared to have a single phosphorylated species consisting of 30 to 40% of the total cellular S6. Thus, the nearly complete dephosphorylation of this protein observed in heat shock involves a large fraction of the cellular S6. The significance of this dephosphorylation in the expression of the heat shock response was investigated by examining the phosphorylation status of S6 in recovery from heat shock and in response to chemical inducers of the heat shock response. During recovery from a 30-min heat shock, the recovery of normal protein synthesis was almost complete in 2 to 4 hr, whereas there was no significant rephosphorylation of S6 for 8 h. Two chemical inducers of the heat shock response, canavanine and sodium arsenite, induced the synthesis of heat shock proteins in D. melanogaster cells. Sodium arsenite also caused an inhibition of normal protein synthesis similar to that observed in heat shock. Neither agent, however, caused significant dephosphorylation of S6. These results suggest that the dephosphorylation of S6, although invariably observed in heat-shocked cells, may in some cases be dissociated from both the induction of heat shock protein synthesis and the turnoff of normal protein synthesis which occur in a heat shock response.