The human heat-shock protein family. Expression of a novel heat-inducible HSP70 (HSP70B'') and isolation of its cDNA and genomic DNA.

The human heat-shock protein multigene family comprises several highly conserved proteins with structural and functional properties in common, but which vary in the extent of their inducibility in response to metabolic stress. We have isolated and characterized a novel human HSP70 cDNA, HSP70B' cDNA, and its corresponding gene sequence. HSP70B' cDNA hybrid-selected an mRNA encoding a more basic 70 kDa heat-shock protein that both the major stress-inducible HSP70 and constitutively expressed HSC70 heat-shock proteins, which in common with other heat-shock 70 kDa proteins bound ATP. The complete HSP70B' gene was sequenced and, like the major inducible HSP70 gene, is devoid of introns. The HSP70B' gene has 77% sequence similarity to the HSP70 gene and 70% similarity to HSC70 cDNA, with greatest sequence divergence towards the 3'-terminus. The HSP70B' gene represents a functional gene, as indicated by Northern-blot analysis with specific oligonucleotides, hybrid-selected translation with a specific 3' cDNA sequence and S1 nuclease protection experiments. In contrast with HSP70 mRNA, which is present at low concentrations in HeLa cells and readily induced by heat or CdCl2 treatment in both fibroblasts and HeLa cells, HSP70B' mRNA was induced only at higher temperature and showed no basal expression. The differences in patterns of induction may be due to the special features of the promoter region of the HSP70B' gene.     

Spontaneous high expression of heat-shock proteins in mouse embryonal carcinoma cells and ectoderm from day 8 mouse embryo

When submitted to a heat-shock, mouse embryonal carcinoma (EC) and fibroblast cells show very different behavior. All the EC cells so far analyzed express very high levels of several heat-shock proteins (HSP) in the absence of stress and independent of their origin and culture conditions. In such cells, the 89-kd, 70-kd and 59-kd HSP are the most prominent proteins after actin. In addition, the 89-kd and 59-kd HSP are not stimulated by an arsenite shock in contrast to what is observed with fibroblasts or cells of the parietal yolk sac type. Arsenite induces the synthesis of a 105-kd polypeptide in fibroblasts but not in EC cells. In vitro differentiation of F9 cells induced by retinoic acid and dibutyryl cAMP is accompanied by a decrease in the spontaneous relative abundance of HSP and restores the arsenite-induced synthesis of the 105-kd polypeptide. EC cells are usually believed to be similar to inner cell mass cells of mouse blastocyst. Furthermore, data in the literature together with our own results suggest that the same three HSP are also spontaneously expressed in high amounts in the early mouse embryo.     

热休克蛋白调控机制

热休克蛋白是生物体体应对温度、pH、渗透压等不利环境刺激时合成的一种保护蛋白。在环境应激时,调控因子可以在转录水平上调控热休克基因的表达,恢复或加速清除细胞内已经变性的蛋白质,使细胞处于稳态并产生耐受性。大量研究发现,热休克调控因子对微生物应激耐受性发挥重要作用,具有广阔的应用前景。综述了6类热休克调控因子的调控机制以及相互作用,对调控因子HrcA、σ^B和CtsR进行了重点阐述,旨在为进一步构建热休克调控网络提供有价值的参考。     

Cellular HSP90 (HSP86) mRNA level and in vitro differentiation of mouse embryonal carcinoma (F9) cells

Treatment of mouse embryonal carcinoma (F9) cells with retinoic acid, an inducer of F9 cell differentiation, greatly increased the level of mRNA specific to one of the heat-shock proteins (HSP86). Experiments including the one employing differentiation-resistant mutant F9 cells suggested that the increase represents early molecular events associated with the embryonal differentiation. The increased HSP86 mRNA declined to the original level during further incubation. The presence of cyclic AMP, which stimulates conversion of the retinoic acid-induced primitive endoderm cells to parietal endoderm cells, prevented the decline. These results suggest that not only the elevation of HSP86 mRNA level represents early molecular events in F9 cell differentiation but also that sustaining the elevated level (by cyclic AMP) is associated with further differentiation of the embryonal cells.     

Differential gene expression of HSC70/HSP70 in yellowtail cells in response to chaperone-mediated autophagy

A cell line derived from the tailfin of the marine teleost yellowtail fish Seriola quinqueradiata was established to examine cellular temperature regulation in an ectothermic animal. Three cytosolic members of the HSP70 family, heat-shock cognate proteins HSC70-1, HSC70-2 and heat-shock protein HSP70, were isolated from cultured yellowtail cells as stress-responsive biomarkers. Expression of hsp70 was heat-inducible, in contrast to the hsc70-1 gene product, which was expressed constitutively. In addition, expression of hsc70-2 was only induced under severe heat-shock conditions. Subcellular fractionation and immunocytochemistry showed localization of HSC70/HSP70 in the lysosomes, indicating that chaperone-mediated autophagy is induced by heat shock. Thus, chaperone-mediated autophagy is assisted by HSC70/HSP70, and heat-inducible expression of the genes encoding these proteins may be responsible for survival and adaptation under heat-shock conditions in fish cells.     

Mice lacking HSP90beta fail to develop a placental labyrinth

The 90 kDa heat-shock proteins (HSP90s) play important roles during stress situations as general chaperones and under physiological conditions in the conformational activation of specific protein substrates. Vertebrates express two cytosolic HSP90s (HSP90alpha and HSP90beta) ubiquitously. We have mutated the Hsp90beta gene in murine embryonic stem cells and generated Hsp90beta mutant mice. Heterozygous animals were phenotypically normal. Interestingly, homozygous embryos developed normally until embryonic day 9.0/9.5. Then, although Hsp90beta is expressed ubiquitously, they exhibited phenotypic abnormalities restricted to the placenta. The mutant concepti failed to form a fetal placental labyrinth and died a day later. Fusion between the allantois and the chorionic plate occurred, allantoic blood vessels invaded the chorion, but then did not expand. Mutant trophoblast cells failed to differentiate into trilaminar labyrinthine trophoblast. Despite conspicuous similarities between HSP90alpha and HSP90beta at the molecular level, our data suggest that HSP90beta has a key role in placenta development that cannot be performed by the endogenous HSP90alpha alone. Analysis of chimeric concepti consisting of mutant embryos and tetraploid embryos or ES cells revealed that wild-type allantois was able to induce mutant trophoblast to differentiate. In contrast, trophoblast wild type at the Hsp90beta locus was unable to differentiate when in contact with mutant allantois. Therefore, the primary defect caused by the Hsp90beta mutation resided in the allantois. The allantois mesoderm is thought to induce trophoblast differentiation. Our results show that Hsp90beta is a necessary component of this induction process.     

Heat-shock proteins 70 kDa and 19 kDa are not required for induction of embryogenesis of Brassica napus L. cv. topas microspores

It is currently accepted that 'stress' triggers induction of microspore embryogenesis, and for Brassica napus L. cv. Topas it is heat-shock. It has been postulated that the heat-shock proteins (HSPs) generated during heat stress have a central role in the induction mechanism. To test this hypothesis we developed a microspore induction procedure, using colchicine instead of heat treatment. The level of HSP70 increased significantly during and following the microspore heat treatment while sHSP19 expression was induced at the onset of heat-shock and declined after 8 h. In contrast, induction of embryogenesis with colchicine was not accompanied by elevation of HSP70 nor by induction of sHSP19, indicating that these HSPs are not required for induction of microspore embryogensis in this model system. These data refute the current hypothesis that HSPs have an essential role in triggering microspore embryogenesis.     

Optimal choice between feedforward and feedback control in gene expression to cope with unpredictable danger

All organisms face risks of unpredictable danger caused by harmful physical environments, pathogens, parasites or predators. Organisms may have several alternative ways of coping with such dangers. These differ in cost, effectiveness and activation time. We study the conditions under which it is optimal to use different alternatives for damage control. As an example we consider a microbe (such as E. coli), which may experience heat shocks that cause denaturation of proteins in the cell. To restore the denatured proteins the organism produces heat-shock proteins (HSP). There are two different pathways for production of HSP. Some HSP are produced immediately after a heat shock (feedforward control), but additional HSP may be produced thereafter, stimulated by the presence of denatured proteins (feedback control). Feedforward is based solely on heat-shock intensity without accurate information on the resulting amount of denatured proteins. We examine the optimal combination of the two pathways that minimizes the sum of the damage caused by the presence of untreated denatured proteins and the production cost of HSP. The optimal response depends on the time delay for feedback control, the effectiveness of HSP in processing denatured proteins, the production cost of HSP, the severity of damage by denatured proteins and the probability distribution of the abundance of denatured protein conditional on heat-shock intensity. We find that feedforward control should always be used. Additional HSP may be produced by feedback control when the abundance of denatured protein is large whilst no feedback control should be used when it is small. All the HSP are produced by feedforward control when the maximum is close to the mean of denatured protein abundance conditional on the heat-shock intensity.     

Structural organization of the spinach endoplasmic reticulum-luminal 70-kilodalton heat-shock cognate gene and expression of 70-kilodalton heat-shock genes during cold acclimation.

The 70-kD heat-shock proteins (HSP70s) are encoded by a multigene family in eukaryotes. In plants, the 70-kD heat-shock cognate (HSC70) proteins are located in organellar and cytosolic compartments of cells in most tissues. Previous work has indicated that HSC70 proteins of spinach (Spinacia oleracea) are actively synthesized during cold-acclimating conditions. We have isolated, sequenced, and characterized cDNA and genomic clones for the endoplasmic reticulum (ER) luminal HSC70 protein (immunoglobulin heavy chain-binding protein; BiP) of spinach. The spinach ER-luminal HSC70 is a constitutively expressed gene consisting of eight exons. Spinach BiP mRNA appears to be up-regulated during cold acclimation but is not expressed during water stress or heat shock. In contrast to the differential regulation of mRNA, the ER-luminal HSC70 protein levels remain constant in response to various environmental stresses. Two other members of the spinach 70-kD heat-shock (HS70) multigene family also show differential expression in response to a variety of environmental stresses. A constitutively expressed cytosolic HSC70 protein in spinach appears also to be up-regulated in response to both cold-acclimating and heat-shock treatments. Spinach also contains a cold-shock-induced HS70 gene that is not expressed during heat shock or water stress. Since HSP70s are considered to be involved with the chaperoning and folding of proteins, the data further support the concept that they may be important for maintaining cellular homeostasis and proper protein biogenesis during cold acclimation of spinach.     

Interferon pretreatment lowers the threshold for maximal heat-shock response in mouse cells

Interferons (IFNs) are proteins which have antiviral and antiproliferative properties and are known to affect various immunological processes. Some of these activities have been shown to be potentiated by increased temperatures. When cells are subjected to a rise in temperature, the synthesis of the heat-shock proteins (HSPs) is 'switched on.' In this report we demonstrate a synergistic effect of IFN and stress (arsenite treatment or elevated temperature) on the heat-shock response. On the one hand, IFN pretreatment enhances the accumulation of HSP mRNAs and the corresponding protein synthesis after a mild stress and, on the other hand, it amplifies the decrease of the total protein synthesis after a severe stress. Thus in IFN pretreated cells the range of temperatures leading to the heat-shock response is shifted towards common physiological values.     

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.     

Heat-shock response in cultured chick embryo chondrocytes. Osteonectin is a secreted heat-shock protein.

We investigated the induction of specific protein expression by heat shock in dedifferentiated and hypertrophic chick embryo chondrocytes in a culture system that allows 'in vitro' differentiation of cartilage cells [Castagnola, P., Moro, G., Descalzi-Cancedda, F. and Cancedda, R. (1986) J. Cell. Biol. 102, 2310-2317]. As control, we used cultures of embryonic fibroblasts from the whole body and from the skin. In the cell lysates of all cultures we identified four major heat-shock proteins (HSP), with a molecular size corresponding to HSP families previously described (HSP 90, HSP 70, HSP 47 and HSP 26). Some of these proteins were constantly induced when the temperature was raised, others were expressed in a more variable manner. Differences also existed in the relative amount of the HSP synthesized by the four cultures. When we specifically investigated HSP species released into the culture medium, we observed a 43-45 kDa protein constantly expressed and secreted in large amount by the cells. On the basis of its biochemical characteristic and its precipitation by specific antibodies, this protein has been identified as osteonectin (SPARC, BM-40).     

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.