Examination of cadmium-induced expression of the small heat shock protein gene, hsp30, in Xenopus laevis A6 kidney epithelial cells

Cadmium is a highly toxic environmental pollutant that has been classified as a human carcinogen. Toxicological responses to cadmium exposure include respiratory diseases, neurological disorders and kidney damage. In the present study, we have characterized the effect of cadmium on the accumulation of the small heat shock protein (HSP), HSP30, in Xenopus laevis A6 kidney epithelial cells. Incubation of A6 cells with cadmium chloride induced the accumulation of HSP30 protein and hsp30 mRNA. While HSP70 protein and hsp70 mRNA accumulation were also induced, the relative levels of actin remained relatively unaffected. Elevated levels of HSP30 were detected in cells undergoing prolonged exposure of cells to cadmium chloride or in cells recovering from cadmium chloride treatment. Immunocytochemical analysis of cadmium chloride-treated A6 cells revealed HSP30 accumulation primarily in the cytoplasm in a punctate pattern supplemented with larger HSP30 staining structures. Also, HSP30 co-localized with the F-actin cytoskeleton at higher cadmium chloride concentrations. The combination of mild heat shock temperatures plus cadmium chloride concentrations employed in this study resulted in a synergistic accumulation of HSP30 protein and hsp30 mRNA. Finally, in contrast to heat shock, prior exposure of Xenopus A6 cells to cadmium chloride treatment, sufficient to induce the accumulation of HSPs, did not protect the cells against a subsequent thermal challenge.     

Proteasome inhibition induces <Emphasis Type="Italic">hsp30</Emphasis> and <Emphasis Type="Italic">hsp70</Emphasis> gene expression as well as the acquisition of thermotolerance in <Emphasis Type="Italic">Xenopus laevis</Emphasis> A6 cells

Previous studies have shown that inhibiting the activity of the proteasome leads to the accumulation of damaged or unfolded proteins within the cell. In this study, we report that proteasome inhibitors, lactacystin and carbobenzoxy-l-leucyl-l-leucyl-l-leucinal (MG132), induced the accumulation of ubiquitinated proteins as well as a dose- and time-dependent increase in the relative levels of heat shock protein (HSP)30 and HSP70 and their respective mRNAs in Xenopus laevis A6 kidney epithelial cells. In A6 cells recovering from MG132 exposure, HSP30 and HSP70 levels were still elevated after 24 h but decreased substantially after 48 h. The activation of heat shock factor 1 (HSF1) may be involved in MG132-induced hsp gene expression in A6 cells since KNK437, a HSF1 inhibitor, repressed the accumulation of HSP30 and HSP70. Exposing A6 cells to simultaneous MG132 and mild heat shock enhanced the accumulation of HSP30 and HSP70 to a much greater extent than with each stressor alone. Immunocytochemical studies determined that HSP30 was localized primarily in the cytoplasm of lactacystin- or MG132-treated cells. In some cells treated with higher concentrations of MG132 or lactacystin, we observed in the cortical cytoplasm (1) relatively large HSP30 staining structures, (2) colocalization of actin and HSP30, and (3) cytoplasmic areas that were devoid of HSP30. Lastly, MG132 treatment of A6 cells conferred a state of thermotolerance such that they were able to survive a subsequent thermal challenge.     

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.     

Withaferin A Induces Proteasome Inhibition,Endoplasmic Reticulum Stress,the Heat Shock Response and Acquisition of Thermotolerance

In the present study, withaferin A (WA), a steroidal lactone with anti-inflammatory and anti-tumor properties, inhibited proteasome activity and induced endoplasmic reticulum (ER) and cytoplasmic HSP accumulation in Xenopus laevis A6 kidney epithelial cells. Proteasomal inhibition by WA was indicated by an accumulation of ubiquitinated protein and a decrease in chymotrypsin-like activity. Additionally, immunoblot analysis revealed that treatment of cells with WA induced the accumulation of HSPs including ER chaperones, BiP and GRP94, as well as cytoplasmic/nuclear HSPs, HSP70 and HSP30. Furthermore, WA-induced an increase in the relative levels of the protein kinase, Akt, while the levels of actin were unchanged compared to control. Northern blot experiments determined that WA induced an accumulation in bip, hsp70 and hsp30 mRNA but not eIF-1α mRNA. Interestingly, WA acted synergistically with mild heat shock to enhance HSP70 and HSP30 accumulation to a greater extent than the sum of both stressors individually. This latter phenomenon was not observed with BiP or GRP94. Immunocytochemical analysis indicated that WA-induced BiP accumulation occurred mainly in the perinuclear region in a punctate pattern, while HSP30 accumulation occurred primarily in a granular pattern in the cytoplasm with some staining in the nucleus. Prolonged exposure to WA resulted in disorganization of the F-actin cytoskeleton as well as the production of relatively large HSP30 staining structures that co-localized with F-actin. Finally, prior exposure of cells to WA treatment, which induced the accumulation of HSPs conferred a state of thermal protection since it protected the F-actin cytoskeleton against a subsequent cytotoxic thermal challenge.     

Intracellular delivery of HSP70 using HIV-1 Tat protein transduction domain

Heat shock protein 70 (HSP70) is an intracellular stress protein that confers cytoprotection to a variety of cellular stressors. Several lines of evidence have suggested that augmentation of the heat shock response by increasing the expression of HSP70 represents a potential therapeutic strategy for the treatment of critically ill patients. The Tat protein of human immunodeficiency virus 1 (HIV-1) has been used previously to deliver functional cargo proteins intracellularly when added exogenously to cultured cells. We generated a Tat-HSP70 fusion protein using recombinant methods and treated HSF -/- cells with either Tat-HSP70 or recombinant HSP70 prior to exposure to hyperoxia or lethal heat shock. We showed that biologically active, exogenous HSP70 can be delivered into cells using the HIV-1 Tat protein, and that the Tat-mediated delivery of HSP70 confers cytoprotection against thermal stress and hyperoxia and may represent a novel approach to augmenting intracellular HSP70 levels.     

Simulated diving after heat stress potentiates the induction of heat shock protein 70 and elevates glutathione in human endothelial cells

Heat stress prior to diving has been shown to confer protection against endothelial damage due to decompression sickness. Several lines of evidence indicate a relation between such protection and the heat shock protein (HSP)70 and HSP90 and the major cellular red-ox determinant, glutathione (GSH). The present study has used human endothelial cells as a model system to investigate how heat stress and simulated diving affect these central cellular defense molecules. The results demonstrated for the first time that a simulated dive at 2.6 MPa (26 bar) had a potentiating effect on the heat-induced expression of HSP70, increasing the HSP70 concentration on average 54 times above control level. In contrast, a simulated dive had no significant potentiating effect on the HSP90 level, which might be due to the higher baseline level of HSP90. Both 2 and 24-h dive had similar effects on the HSP70 and HSP90, suggesting that the observed effects were independent of duration of the dive. The rapid HSP response following a 2-h dive with a decompression time of 5 min might suggest that the effects were due to compression or pressure per se rather than decompression and may involve posttranslational processing of HSP. The exposure order seemed to be critical for the HSP70 response supporting the suggestion that the potentiating effect of dive was not due to de novo synthesis of HSP70. Neither heat shock nor a simulated dive had any significant effect on the intracellular GSH level while a heat shock and a subsequent dive increased the total GSH level approximately 62%. Neither of these conditions seemed to have any effect on the GSH red-ox status.     

Heat Shock Proteins hsp90 and hsp70 Protect Neuronal Cells from Thermal Stress but Not from Programmed Cell Death

Abstract: Prior exposure to a mild thermal stress can protect neuronal cells from a subsequent more severe stress including high temperature, ischemia, glutamate toxicity, or stimuli inducing apoptosis. Although the protective effect of thermal stress correlates with the elevated expression of the heat shock proteins (hsps), the protective effect of individual hsps has never been directly demonstrated in neuronal cells. Here we show that the constitutive overexpression of either of the major hsps, hsp90 or hsp70, can protect neuronal cells from thermal stress but not from stimuli that induce apoptosis. The possible mechanisms by which thermal stress can protect neuronal cells from apoptosis are discussed.     

Response of mice to continuous 5-day passive hyperthermia resembles human heat acclimation

Chronic repeated exposure to hyperthermia in humans results in heat acclimation (HA), an adaptive process that is attained in humans by repeated exposure to hyperthermia and is characterized by improved heat elimination and increased exercise capacity, and acquired thermal tolerance (ATT), a cellular response characterized by increased baseline heat shock protein (HSP) expression and blunting of the acute increase in HSP expression stimulated by re-exposure to thermal stress. Epidemiologic studies in military personnel operating in hot environments and elite athletes suggest that repeated exposure to hyperthermia may also exert long-term health effects. Animal models demonstrate that coincident exposure to mild hyperthermia or prior exposure to severe hyperthermia can profoundly affect the course of experimental infection and injury, but these models do not represent HA. In this study, we demonstrate that CD-1 mice continuously exposed to mild hyperthermia (ambient temperature ~37°C causing ~2°C increase in core temperature) for 5 days and then exposed to a thermal stress (42°C ambient temperature for 40 min) exhibited some of the salient features of human HA, including (1) slower warming during thermal stress and more rapid cooling during recovery and (2) increased activity during thermal stress, as well as some of the features of ATT, including (1) increased baseline expression of HSP72 and HSP90 in lung, heart, spleen, liver, and brain; and (2) blunted incremental increase in HSP72 expression following acute thermal stress. This study suggests that continuous 5-day exposure of CD-1 mice to mild hyperthermia induces a state that resembles the physiologic and cellular responses of human HA. This model may be useful for analyzing the molecular mechanisms of HA and its consequences on host responsiveness to subsequent stresses.     

Kinetics study of endogenous heat shock protein 70 expression

The purpose of this study was to determine the kinetics of HSP70 expression in response to mild thermal stress. The rationale is to produce a basis for design of optimal heating methods to induce HSP70 expression for preconditioning in cardiac surgery. Bovine aortic endothelial cells were heated at 42 degrees C for 0.5 to 5 hours followed by 37 degrees C recovery for 1 to 48 hours. Quantitative analysis of western blot results showed HSP70 expression kinetics is a coupled function of heating temperature and time and of post-heating duration. Bimodal HSP70 expression kinetics were identified which may be an important cause of the "second window of protection" observed by other researchers.     

模拟失重大鼠心肌与血管组织的热应激诱导HSP70表达

为研究模拟失重是否可以引起大鼠心肌与血管组织HSP70的诱导表达发生改变,用尾部悬吊大鼠模型模拟失重,以研究失重对生理的影响,用Northern杂交与Western印迹分析检测4周模拟失重大鼠热应激后并在室温下恢复1h(SUS-H1)或2h(SUS-H2_心肌,血管组织HSP70表达的变化,结果表明,热应激后,各组大鼠心肌组织的HSP72 mRNA表达的均显著增加,但SUS－H2大鼠心肌组织的表达显著低于CON－H2组;各组大鼠心肌组织HSP72表达也均显著增加,但SUS－H1与SUS－H2大鼠的表达与相应对照组相比,则仅呈降低趋势,其底动脉血管组织的HSP72 mRNA与HSP72诱导表达均显著增高,而在股动脉则两者仅呈降低趋势,上述结果提示,模拟失重可导致大鼠心肌发生类似衰老的心肌改变;身体前,后部血管组织HSP70的诱导表达变化可能与血管的分化性适应方向一致。     

Correlation of HSP70 expression and cell viability following thermal stimulation of bovine aortic endothelial cells

Thermal preconditioning protocols for cardiac cells were identified which produce elevated HSP70 levels while maintaining high cell viability. Bovine aortic endothelial cells were heated with a water bath at temperatures ranging from 44 to 50 degrees C for periods of 1-30 min. Thermal stimulation protocols were determined which induce HSP70 expression levels ranging from 2.3 to 3.6 times the control while maintaining cell viabilities greater than 90%. An Arrhenius injury model fit to the cell damage data yielded values of A = 1.4 X 10(66) s(-1) and Ea = 4.1 X 10(5) J/mol. Knowledge of the injury parameters and HSP70 kinetics will enhance dosimetry guideline development for thermal stimulation of heat shock proteins expression in cardiac tissue.     

Effect of chronic hypoxia on proliferation, apoptosis, and HSP70 expression in mouse bronchiolar epithelial cells

Heat shock proteins (HSPs) can be induced by various stresses and play an important role in cell cycle progression. HSP70 has been shown to act as an inhibitor of apoptosis. We studied HSP70 expression in bronchial epithelial cells of C57BL/6 mice and homozygous HPS70 knockout mice (hsp70.1-/-) exposed to chronic hypoxic stress. We also investigated changes in cellular proliferation and apoptosis in relation to HSP70. Lungs were removed from mice after a three-week period of exposure to 10 % O(2). Immunoblots for HSP70 and immunohistochemical staining for HSP70 and Ki-67 were performed. Apoptosis was assessed using the TUNEL assay. The three-week period of hypoxic stress did not change HSP70 levels in total lung tissue, but a significant reduction in HSP70 expression was observed in bronchiolar epithelial cells. In wild type mice, both HSP70 and Ki-67 expression were significantly reduced in bronchiolar epithelial cells. In homozygous HPS70 knockout mice (hsp70.1-/-), apoptosis of bronchiolar epithelial cells was significantly increased. Our results suggest that HSP70 may exert anti-apoptotic effects in mouse bronchiolar epithelial cells.     

Expression of the HSP 70 gene family in rat hepatoma cell lines of different growth rates

We have studied the expression of different members of the HSP 70 gene family in MH1C1, FAO, and 3924A hepatoma cell lines, which possess different growth rates and show different levels of histone H3 gene expression. The cells have been subjected to mild (42 degrees C/1 h) or severe (45 degrees C/25 min) heat shock that causes a decrease in cell proliferation and histone H3 gene expression correlated to the severity of stress: previous mild heat shock protects against the effects of the subsequent severe exposure. All cell lines, irrespective of their growth rate, show a high constitutive expression of the HSC 73 gene, which is barely detectable in normal liver, and a good induction of the heat-inducible HSP 70 gene, which, however, seems to be induced less than in the normal tissue. The relative amount of grp 78 mRNA is high in all hepatoma cells lines, but only FAO cells maintain a significant expression of the albumin gene. The basic diversity in HSP 70 family gene expression between normal and tumors is still maintained in hepatoma cell lines, but the growth-related, quantitative differences among the transplantable hepatomas that we previously found in the animal (Bardella et al., Br. J. Cancer 55, 642-645, 1987; Cairo et al., Hepatology 9, 740-746, 1989), seem to be lost, or at least strongly blunted, in vitro.     

Global Changes in the Rat Heart Proteome Induced by Prolonged Morphine Treatment and Withdrawal

Morphine belongs among the most commonly used opioids in medical practice due to its strong analgesic effects. However, sustained administration of morphine leads to the development of tolerance and dependence and may cause long-lasting alterations in nervous tissue. Although proteomic approaches enabled to reveal changes in multiple gene expression in the brain as a consequence of morphine treatment, there is lack of information about the effect of this drug on heart tissue. Here we studied the effect of 10-day morphine exposure and subsequent drug withdrawal (3 or 6 days) on the rat heart proteome. Using the iTRAQ technique, we identified 541 proteins in the cytosol, 595 proteins in the plasma membrane-enriched fraction and 538 proteins in the mitochondria-enriched fraction derived from the left ventricles. Altogether, the expression levels of 237 proteins were altered by morphine treatment or withdrawal. The majority of changes (58 proteins) occurred in the cytosol after a 3-day abstinence period. Significant alterations were found in the expression of heat shock proteins (HSP27, α-B crystallin, HSP70, HSP10 and HSP60), whose levels were markedly up-regulated after morphine treatment or withdrawal. Besides that morphine exposure up-regulated MAPK p38 (isoform CRA_b) which is a well-known up-stream mediator of phosphorylation and activation of HSP27 and α-B crystallin. Whereas there were no alterations in the levels of proteins involved in oxidative stress, several changes were determined in the levels of pro- and anti-apoptotic proteins. These data provide a complex view on quantitative changes in the cardiac proteome induced by morphine treatment or withdrawal and demonstrate great sensitivity of this organ to morphine.