Heat-shock protein 72 cell-surface expression on human lung carcinoma cells is associated with an increased sensitivity to lysis mediated by adherent natural killer cells

 The cell-surface expression patterns of major histocompatibility complex (MHC) class I, class II and heat-shock protein 72 (HSP72) molecules were measured on human lung (LX-1) and mammary (MX-1) carcinoma cells. No major differences were found in the MHC cell-surface expression pattern of both cell lines. However, they differ significantly in their capacity to express HSP72 on their cell surface. Under physiological conditions LX-1 cells express HSP72 molecules on more than 90% of the cells, whereas MX-1 cells exhibit no significant HSP72 cell-surface expression (less than 5%). These expression patterns remained stable in all further cell passages tested. The sensitivity to lysis mediated by an interleukin-2 (IL-2)-stimulated, adherent natural killer (NK) cell population could be correlated with the amount of cell-surface-expressed HSP72 molecules. By antibody-blocking studies, using HSP72-specific monoclonal antibody (mAb), a strong inhibition of lysis was only found with LX-1 cells but not with MX-1 cells. In contrast to the cell-surface expression, the cytoplasmic amount of HSP72 in MX-1 cells was twice as high compared to LX-1 cells under physiological conditions. After nonlethal heat-shock the rate of induction and the total cytoplasmic amounts of HSP72 were comparable in both cell lines. The clonogenic cell viability of LX-1 cells after incubation at temperatures ranging from 41°C to 44°C was significantly elevated compared to that of MX-1 cells. In conclusion we state the following: (i) HSP72 cell-surface expression on human carcinoma cells is independent of the cytoplasmic amount of HSP72; (ii) the cell-surface expression of HSP72 is associated with an increased sensitivity of tumour cells to lysis mediated by an IL-2-stimulated, adherent NK cell population; (iii) thermoresistance is not related to the cytoplasmic HSP72 level but might be related to the amount of HSP72 expressed on the cell surface. Received: 20 June 1996 / Accepted: 25 September 1996     

Thermotolerance and the heat-shock response in Candida albicans

At elevated temperatures, yeast cells of Candida albicans synthesized nine heat-shock proteins (HSPs) with apparent molecular masses of 98, 85, 81, 76, 72, 54, 34, 26 and 18 kDa. The optimum temperature for the heat-shock response was 45 degrees C although HSPs were detected throughout the range 41-46 degrees C. Protein synthesis was not observed in cells kept at 48 degrees C. Yeast cells survived exposure to an otherwise lethal temperature of 55 degrees C when they had previously been exposed to 45 degrees C. The thermotolerance induced during incubation at 45 degrees C required protein synthesis, since protection was markedly reduced by trichodermin. Mercury ions induced a set of three stress proteins, one of which corresponded in size to an HSP, and cadmium ions evoked one stress protein seemingly unrelated to the HSPs observed after temperature shift.     

Phosphorylation at tyrosine-524 influences nuclear accumulation of HSP72 with heat stress

Nuclear accumulation of heat shock protein (HSP) 72 occurs after cardiac ischemia. This nuclear accumulation of HSP72 with stress occurs in other tissues and species. We postulated that nuclear accumulation of HSP72 was important for the protective effect of HSP72 and that phosphorylation of a single tyrosine (Y(524)) regulated nuclear accumulation of HSP72. Western blots of immunoprecipitated HSP72 from Cos-1 cells demonstrated that tyrosine becomes phosphorylated after heat shock. Treatment with the tyrosine kinase inhibitor geldanamycin blocked nuclear accumulation of HSP72 with heat shock. Two epitope-tagged constructs were made: M17 converting Y(524) to aspartic acid (pseudophosphorylation) and M18 converting Y(524) to phenylalanine. When transfected into Cos-1 cells, M17 accumulates more rapidly and M18 less rapidly than wild-type (WT) HSP72 in the nucleus following heat shock. Cells expressing M18 had less viability after heat shock at 43.5 degrees C than other constructs. After heat shock at 45 degrees C, cells expressing M17 had superior survival compared with WT and M18. These data suggest that phosphorylation at Y(524) facilitates nuclear accumulation of HSP72 following heat stress, and substitution of aspartic acid at Y(524) enhances resistance to heat-shock injury.     

In vitro study of the stress response of human skin cells to GSM-1800 mobile phone signals compared to UVB radiation and heat shock

The evolution of mobile phone technology is toward an increase of the carrier frequency up to 2.45 GHz. Absorption of radiofrequency (RF) radiation becomes more superficial as the frequency increases. This increasingly superficial absorption of RF radiation by the skin, which is the first organ exposed to RF radiation, may lead to stress responses in skin cells. We thus investigated the expression of three heat-shock proteins (HSP70, HSC70, HSP27) using immunohistochemistry and induction of apoptosis by flow cytometry on human primary keratinocytes and fibroblasts. A well-characterized exposure system, SXC 1800, built by the IT'IS foundation was used at 1800 MHz, with a 217 Hz modulation. We tested a 48-h exposure at an SAR of 2 W/kg (ICNIRP local exposure limit). Skin cells were also irradiated with a 600 mJ/cm2 single dose of UVB radiation and subjected to heat shock (45 degrees C, 20 min) as positive controls for apoptosis and HSP expression, respectively. The results showed no effect of a 48-h GSM-1800 exposure at 2 W/kg on either keratinocytes or fibroblasts, in contrast to UVB-radiation or heat-shock treatments, which injured cells. We thus conclude that the GSM-1800 signal does not act as a stress factor on human primary skin cells in vitro.     

Phenotypic plasticity of HSP70 and HSP70 gene expression in the Pacific oyster (Crassostrea gigas): implications for thermal limits and induction of thermal tolerance

Pacific oysters, Crassostrea gigas, living at a range of tidal heights, routinely encounter large seasonal fluctuations in temperature. We demonstrate that the thermal limits of oysters are relatively plastic, and that these limits are correlated with changes in the expression of one family of heat-shock proteins (HSP70). Oysters were cultured in the intertidal zone, at two tidal heights, and monitored for changes in expression of cognate (HSC) and inducible (HSP) heat-shock proteins during the progression from spring through winter. We found that the "control" levels (i.e., prior to laboratory heat shock) of HSC77 and HSC72 are positively correlated with increases in ambient temperature and were significantly higher in August than in January. The elevated level of HSCs during the summer was associated with moderate, 2-3 degrees C, increases in the upper thermal limits for survival. We measured concomitant increases in the threshold temperatures (T(on)) required for induction of HSP70. Total hsp70 mRNA expression reflected the seasonal changes in the expression of inducible but not cognate members of the HSP70 family of proteins. A potential cost of increased T(on) in the summer is that there was no extension of the upper thermal limits for survival (i.e., induction of thermotolerance) after sublethal heat shock at temperatures that were sufficient to induce thermotolerance during the winter months.     

Analytical assays of human HSP27 and thermal-stress survival of Escherichia coli cells that overexpress it

HSP27 is a small heat-shock protein (sHSP). Such proteins are produced in all organisms. These small HSPs exhibit chaperone-like activity that can bind to unfolded polypeptides and prevent uncontrolled protein aggregation in vitro. Cellular anti-apoptosis function and enhanced cell survival are correlated with increased expression of HSPs. This study presents a thermal-stress survival model for cells using the Escherichia coli expression system for which human HSP27, a recombinant protein, is inducible. Results show that E. coli cells overexpressing human HSP27 have enhanced tolerance to 50 degrees C thermal stress.     

Inhibition of heat shock protein synthesis and protein glycosylation by stepdown heating

Mammalian cells exhibit increased sensitivity to hyperthermic temperatures of 38-43 degrees C after an acute high-temperature heat shock; this phenomenon is known as the stepdown heating (SDH) effect. We characterized the SDH effect on (1) the synthesis of major heat shock proteins, HSP110, 90, 72/70, 60 (35S-amino acids label), (2) on heat-induced protein glycosylation (3H-D-mannose label), and (3) on thermotolerance expression, using cell survival as an endpoint. Partitioning of label between soluble and insoluble cell fractions was separately examined. Synthesis of high molecular weight HSPs (HSP110, 90, and 72/70) was increased both by acute (10 min, 45 degrees C) and chronic (1-6 h, 41.5 degrees C) hyperthermia, primarily in the soluble cytosol fraction. SDH (10 min, 45 degrees C + 1 to 6 h, 41.5 degrees C) completely inhibited labeling of HSP110, partially inhibited HSP90 labeling, and had virtually no effect on HSP72/70 synthesis, when compared with chronic hyperthermia alone. At the cell survival level, SDH increased sevenfold the rate of cell killing at 41.5 degrees C, but reduced the expression of thermotolerance by only a factor of two. This suggests that SDH sensitization did not result from changes in HSP72/70 synthesis, nor solely from inhibition of thermotolerance. 35S-labeled HSP60 and HSP50 were found primarily in the cellular pellet fraction after both acute and chronic hyperthermia. SDH completely inhibited 35S-labeling of both HSP60 and HSP50. Labeling of GP50 with 3H-D-mannose was also completely inhibited by SDH. Moreover, SDH progressively reduced N-acetylgalactosaminyl-transferase activity. The data demonstrate that heat sensitization by SDH is accompanied by complex and selectively inhibitory patterns of HSP synthesis and protein glycosylation. Profound inhibition of HSP110, HSP60, and HSP50/GP50 labeling suggests that these may be associated with mechanisms of SDH sensitization.     

Enhanced constitutive expression of the 27-kDa heat shock proteins in heat-resistant variants from Chinese hamster cells

Four heat-resistant variants were isolated after treatment of Chinese hamster lung cells with the mutagen ethyl methane sulfonate, followed by a single-step selection procedure consisting in a severe hyperthermic treatment of 4 h at 44 degrees C. The isolated clones had a stable resistant phenotype for at least 150 generations during which they showed a 5,000-fold increased survival to a 4-h treatment at 44 degrees C when compared to wild-type cells. Comparative two-dimensional electrophoretic analyses of proteins revealed that, like induced thermotolerant wild-type cells (i.e., cells induced to a transient physiological state of thermotolerance by a sublethal heat conditioning treatment administered 18 h before), the heat-resistant variants had, at normal temperature, an increased content of a heat-shock protein with Mr of 27,000 (HSP27). In three of the four heat-resistant variants, the increased content of HSP27 was correlated with a two-fold increase in the constitutive level of the mRNA encoding HSP27. Chinese hamster HSP27 is composed of three species that differ in their relative isoelectric point, among which the two most acidic forms are phosphoproteins. In both the heat-resistant variant and wild-type cells, heat shock induces a rapid enhancement of the phosphorylation of HSP27: maximal phosphorylation occurs within 10 min upon changing the incubation temperature from 35 degrees to 44 degrees C. A concomitant shift in silver-staining intensity is rapidly detectable between the three isoforms, which seems to indicate that the two phosphorylated species represent post-translational modifications of the more basic species. It is concluded that most likely the enhanced expression of HSP27 is linked to the resistant phenotype of the variants. The study provides supporting evidence that both the content and phosphorylation status of HSP27 are determining factors in the ability of cells to survive hyperthermic treatments.     

Characterization of a cDNA clone, encoding a 70 kDa heat shock protein from the dermatophyte pathogen Trichophyton rubrum

Trichophyton rubrum is an anthropophilic fungus causing up to 90% of chronic cases of dermatophytosis. To characterize T. rubrum proteins at the molecular level, we established a cDNA library of this pathogen. Here we describe a recombinant cDNA clone identical to eukaryotic 70kDa heat-shock proteins (HSPs). Western blot analysis using an anti HSP70 monoclonal antibody detected a recombinant fusion protein in Escherichia coli transformed with the expression vector containing the cloned cDNA insert. Southern blot analysis of T. rubrum genomic DNA detected no other members of the HSP70 gene family. Further analysis revealed the presence of two introns within the ORF of the HSP70 gene. In Northern blot analysis, the cDNA clone was hybridized to a RNA species of about 3.5kb which was constitutively expressed by cells cultured at 27 degrees C and was strongly up-regulated after culture at 37 degrees C. In summary, we have cloned the first member of the HSP family of dermatophytes and characterized it as a member of the Dnak subfamily of 70kDa HSPs.     

Conjugated linoleic acid isomers have differential effects on triglyceride secretion in Hep G2 cells

Treatment for 2 h with 200 microM cadmium chloride, followed by recovery, caused apoptosis and induced heat-shock protein 70 (HSP70) expression in U-937 promonocytic cells. However, pre-incubation with the GSH depleting agent L-buthionine-[S,R]-sulfoximine (BSO, 1 mM for 24 h) caused necrosis instead of apoptosis and failed to induce HSP70 expression. This failure was a consequence of necrosis instead of GSH depletion, since BSO allowed or even potentiated HSP70 induction when used in combination with heat shock (2 h at 42.5 degrees C) or with 50 microM cadmium, which caused apoptosis. The administration of N-acetyl-L-cysteine (NAC) at the beginning of recovery after BSO/200 microM cadmium treatment prevented the execution of necrosis and restored the execution of apoptosis, but did not restore HSP70 induction, indicating that the inhibition by BSO of HSP70 expression is an early regulated event. This contrasted with the capacity of NAC to prevent the alterations caused by BSO/200 microM cadmium in other proteins, namely the suppression of Bax expression and the increase in Bcl-2 and HSP-60 expression. Finally, it was observed that treatment with 200 microM cadmium rapidly increased the HSP70 mRNA level and stimulated heat-shock factor 1 (HSF1) trimerization and binding, and that these effects were prevented by pre-incubation with BSO. Taken together, these results indicate that the stress response is compatible with apoptosis but not with necrosis in cadmium-treated promonocytic cells. The suppression of the stress response is specifically due to the early inhibition of HSF1 activation.     

Geranylgeranylaceton induces heat shock protein 72 in skeletal muscle cells

Effects of an antiulcer drug, geranylgeranylaceton (GGA), and/or heat-stress on 72 kDa heat shock protein (HSP72) expression and protein content in cultured skeletal muscle cells were studied. Mouse skeletal muscle cells (C(2)C(12)) were subjected to either 1) control (cultured at 37 degrees C without GGA), 2) GGA administration (10(-11) - 10(-8) M), 3) heat-stress at 41 degrees C for 60 min, or 4) GGA administration combined with heat-stress. Expression of HSP72 was up-regulated by GGA administration. Heat-stress further enhanced the GGA-related up-regulation of HSP72. Administration of GGA caused an increase of muscular protein content as a dose-dependent manner. Protein synthesis was also stimulated by heat-stress alone in myotubes. It was suggested that GGA stimulates the differentiation of myoblasts and protein synthesis. These observations may also suggest that the administration of GGA could be one of the useful tools to gain muscular mass not only in athletes, but also in patients during rehabilitation.     

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.     

Regulation of the levels of small heat-shock proteins during differentiation of C2C12 cells

Levels of the small heat-shock proteins (sHSPs) HSP27 and alphaB-crystallin during differentiation of mouse C2C12 cells were determined using specific immunoassays. Increases of these proteins were about 3-fold and 10-fold, respectively. Under the same conditions, however, the level of HSP70 in C2C12 cells barely increased, indicating selective accumulation of HSP27 and alphaB-crystallin with differentiation. While expression of mRNA for alphaB-crystallin was also markedly increased and that for HSP27 was but to a lesser extent, mRNA for HSP70 could barely be detected during differentiation. Activation of the heat-shock factor was not observed, in contrast to the case with heat-stressed undifferentiated cells. Various inhibitors of protein kinases affected the differentiation and the associated increase of sHSPs. Rapamycin, an inhibitor of p70 S6 kinase, completely inhibited the differentiation and suppressed the accumulation of HSP27 and alphaB-crystallin. SB203580, an inhibitor of p38 MAP kinase, also inhibited differentiation, but the accumulation of alphaB-crystallin was rather enhanced. PD98059, an inhibitor of MAP kinase kinase, significantly increased expression of a differentiation marker for muscle cells, creatine kinase M isozyme, as well as accumulation of alphaB-crystallin. These results suggest that accumulation of sHSPs during differentiation of C2C12 cells is regulated in a complex manner.     

Spontaneous apoptosis and expression of cell surface heat-shock proteins in cultured EL-4 lymphoma cells

Abstract. The expression of heat-shock proteins (HSPs) is enhanced in stressed cells and can protect cells from stress-induced injury. However, existing data about the relationship between apoptosis and HSP expression is contradictory. In this paper, a mouse lymphoma cell death model system is used to detect simultaneously both the process of apoptosis and the level of HSP expression. The model was established after discovering that spontaneous apoptosis and spontaneous cell surface HSP expression occurs in EL-4 mouse lymphoma cells during normal optimal culture conditions. The data show that apoptotic EL-4 cells had higher levels of hsp25, hsp60, hsp70 and hsp90 exposed on the plasma membrane surface than viable cells. The level of surface HSPs was found to increase through several stages of early and late apoptotic death as measured by flow cytometry, with the highest levels observed during the loss of cell membrane phospholipid asymmetry. Heat shock and actinomycin D significantly increased the proportion of apoptotic cells in culture. However, hyperthermia only stimulated a weak and temporary increase in surface HSP expression, whereas actinomycin D strongly elevated the level of surface and intracellular HSPs, particularly in live cells. These results show an associative relationship between apoptosis and HSP expression. The relationship between the progression of cell death and HSP expression suggests a role for membrane HSP expression in programmed cell death.     

The effect of ts-mutation on expression of genes induced by heat shock in Drosophila melanogaster. III. Synthesis of proteins cognate to HSP70

2D-electrophoresis performed as described by O'-Farrel has revealed clear-cut differences in the pattern of proteins synthesized in the cells of wild-type flies and in the cells of ts-lethal. The cells of the mutant studied after heat-shock exhibit not only the lack of HSP83 and HSP35 but also the absence of a few of the heat-shock proteins belonging to the HSP70 group. Moreover, in the cells of the mutant an intensive synthesis of a protein with mol. weight 72 KDa was observed after heat-shock. This protein belongs to highly abundant heat-shock cognate proteins (HSCP) which are usually not induced by temperature elevation.     

Mutants of tobacco mosaic virus with temperature-sensitive coat proteins induce heat shock response in tobacco leaves.

We analyzed, with respect to heat shock proteins (HSPs), systemically reacting tobacco leaves inoculated with Tobacco mosaic virus (TMV), wild-type vulgare, and temperature-sensitive coat protein (CP) mutants Ni 118 (P20L) and flavum (D19A), kept at 23 or 30 degrees C. HSP18 and HSP70 mRNAs and proteins were induced with temperature-sensitive CP mutants after 1 to 2 days at 30 degrees C. After 4 to 6 days, HSP70 was also induced at 23 degrees C. The induction of HSPs paralleled the amount of insoluble TMV CP in leaf extracts, indicating that denatured TMV CP by itself induces a heat-shock response.