Heat shock proteins: functions and role in adaptation to hyperthermia

The results are generalized of many-year studies into the adaptive role of heat shock proteins in different animals, including the representatives of cold- and warm-blooded species that inhabit regions with different thermal conditions. Adaptive evolution of the response to hyperthermia can lead to different results depending on the species. The thermal threshold of induction of the heat shock proteins in desert thermophylic species is, as a rule, higher than in the moderate climate species. In addition, thermoresistant species are often characterized by a certain level of heat shock proteins in cells even at a physiologically normal temperature. Although adaptation to hyperthermia is achieved in most cases without changes in the number of heat shock genes, they can be amplified in some cases in termophylic species. The role of mobile elements in evolution of the heat shock genes was shown and approach was developed for directional introduction of mutations in the promoter regions of these genes.     

Heat Shock Proteins: Functions and Role in Adaptation to Hyperthermia

The results are generalized of many-year studies into the adaptive role of heat shock proteins in different animals, including the representatives of cold- and warm-blooded species that inhabit regions with different thermal conditions. Adaptive evolution of the response to hyperthermia can lead to different results depending on the species. The thermal threshold of induction of the heat shock proteins in desert thermophylic species is, as a rule, higher than in the moderate climate species. In addition, thermoresistant species are often characterized by a certain level of heat shock proteins in cells even at a physiologically normal temperature. Although adaptation to hyperthermia is achieved in most cases without changes in the number of heat shock genes, they can be amplified in some cases in termophylic species. The role of mobile elements in evolution of the heat shock genes was shown and approach was developed for directional introduction of mutations in the promoter regions of these genes.__________Translated from Ontogenez, Vol. 36, No. 4, 2005, pp. 265–273.Original Russian Text Copyright © 2005 by Evgen’ev, Garbuz, Zatsepina.     

The heat shock response

The response of cells to a heat shock or other stresses is the activation of a small number of genes which were previously inactive or transcribed at low levels. This response has been observed in a wide variety of bacterial, plant, and animal species. Evidence is accumulating that at least some of the proteins found in diverse species are similar, indicating a conservation of the response and the proteins in evolution. In a number of organisms a strong positive correlation has been found between the presence of heat shock proteins and ability of the organism to withstand thermal stress. This review attempts to assess the available data concerning the homology of proteins in different species, the localization of the proteins in cells, and the relationship between heat shock proteins and thermoresistance.     

The evolution of heat shock genes and expression patterns of heat shock proteins in the species from temperature contrasting habitats

Heat shock genes are the most evolutionarily ancient among the systems responsible for adaptation of organisms to a harsh environment. The encoded proteins (heat shock proteins, Hsps) represent the most important factors of adaptation to adverse environmental conditions. They serve as molecular chaperones, providing protein folding and preventing aggregation of damaged cellular proteins. Structural analysis of the heat shock genes in individuals from both phylogenetically close and very distant taxa made it possible to reveal the basic trends of the heat shock gene organization in the context of adaptation to extreme conditions. Using different model objects and nonmodel species from natural populations, it was demonstrated that modulation of the Hsps expression during adaptation to different environmental conditions could be achieved by changing the number and structural organization of heat shock genes in the genome, as well as the structure of their promoters. It was demonstrated that thermotolerant species were usually characterized by elevated levels of Hsps under normal temperature or by the increase in the synthesis of these proteins in response to heat shock. Analysis of the heat shock genes in phylogenetically distant organisms is of great interest because, on one hand, it contributes to the understanding of the molecular mechanisms of evolution of adaptogenes and, on the other hand, sheds the light on the role of different Hsps families in the development of thermotolerance and the resistance to other stress factors.     

Activation of Ca2+-dependent processes during heat shock: role in cell thermoresistance

In this brief review, it is proposed that some Ca2+-dependent processes are induced upon subjecting cells to hyperthermic temperature, and play an essential role in the final cell responses. The triggering signal does not involve external Ca2+. Instead, it is most likely to be generated by a redistribution of Ca2+ between the internal pools. A role for heat-induced Ca2+-dependent processes is supported by findings that Ca2+-active agents such as chelators, ionophores, or anticalmodulin drugs modify the cytotoxic action of hyperthermia and that some heat shock proteins are calmodulin-binding proteins. Furthermore, within minutes at hyperthermic temperature, changes are observed in the pattern of phosphoproteins suggesting that heat shock activates kinase or phosphatase activities, processes which are often mediated by Ca2+. Suggestive evidence that these phosphorylation events are determinants of cell thermoresistance is provided by the fact that one of these proteins whose phosphorylation changes rapidly upon hyperthermia is a heat shock protein (HSP28) and that the content of HSP28 is elevated not only in thermotolerant cells but also in a family of thermoresistant variants isolated after mutagenesis of Chinese hamster cells.     

The heat shock genes: A family of highly conserved genes with a superbly complex expression pattern

The heat shock genes (hsp genes) are a family of truly ubiquitous genes which have been highly conserved throughout evolution. The protein products of these genes, the heat shock proteins (hsps) are thought to play a protective role in cells (although this may not be their only function). The genes and their products have been the subjects of intense research both at the cellular and molecular levels over the past few years. This review deals with the conservation of the heat shock response and with the expression of the hsp genes under different conditions: they are usually activated as a group by different forms of stress, but can be expressed individually or in subsets at different stages during normal development and the expression of one of them is evoked by the products of different transforming genes. Experimental approaches which have provided information or which have led to hypotheses regarding the molecular details of the mechanisms regulating the expression of the genes are discussed.     

昆虫的热休克反应和热休克蛋白

热休克（热激heatshock）是指短暂、迅速地向高温转换所诱导出的一种固定的应激反应。诱导该反应的温度在种与种之间有所不同。热休克反应最明显的特征是：伴随着正常蛋白质合成的抑制,一部分特殊蛋白质的诱导和表达增加,即为热休克蛋白（heatshockproteins,HSPs）。尽管热休克蛋白的合成也能被其它形式的应激反应所诱导,将它们认为是应激蛋白可能更恰当,但人们习惯上仍将这类蛋白质称为热休克蛋白。由于热休克反应和热休克蛋白是在果蝇（Drosophiliamelanogaster）中最初发现的,故在昆虫中,特别是果蝇等双翅目昆虫中研究得较深入…     

Renaturation of denatured lambda repressor requires heat shock proteins

The temperature-sensitive bacteriophage lambda cI857 repressor protein rapidly renatures after thermal inactivation. E. coli mutants in the heat shock protein genes dnaK, dnaJ, and grpE do not efficiently reactivate heat-denatured repressor. Our results suggest that protein refolding is promoted by heat shock proteins and that such a process is the basis of the homeostatic role played by these proteins in the heat shock response.     

Potentiation of thermal injury in mouse cells by interferon

Mouse cells, when exposed to high temperature (43 degrees), shut off overall protein synthesis and continue to synthesize "heat shock proteins". Such heat shocked cells, upon reincubation at 37 degrees C, recover and proliferate. However, when mouse cells are pretreated with mouse interferon (IFN) and then exposed to 43 degrees, more than 99% of the cell population fail to recover. Synthesis of the major heat shock protein is unaffected in cells treated with IFN. Experiments designed to assess the role of intracellular glutathione (GSH) during cells' recovery from hyperthermia indicated that there is an irreversible depletion of glutathione when IFN treated cells are heat shocked. Neither depletion of GSH, nor potentiation of thermal injury was observed in a IFN-resistant line of mouse cells.     

热休克与ConA激活对T淋巴细胞的双重作用

为模拟天然免疫条件下,病毒等抗原对T淋巴细胞激活同时伴有体温升高的环境,我们建立了人外周血T淋巴细胞体外激活和热休克的模型。热休克对ConA激活细胞中多肽的合成既有协同也有抑制作用。ConA激活细胞受热休克的影响较静止细胞小,而其热休克蛋白(HSP)的诱导合成则较强,为了解HSP在淋巴细胞中的作用提供了线索。     

The influence of brood size upon metabolic rate and body temperature in nestling Blue tits Parus caeruleus and House sparrows Passer domesticus

Metabolic rate and body temperature in nestling Blue tits and House sparrows were measured in broods of different size and age. Surface-volume ratio effects were found in both poikilothermic and homoiothermic Blue tits at ambients of 15°C but not at 20°C. The possibility of incipient hyperthermia amongst young nestlings maintaining sub-adult body temperatures is discussed. For the House sparrows heat retention by the nest was of greater importance than the surface-volume effect. Differences in nest structure between the two species are described and related to the thermal requirements of nestlings in large as against small broods.     

cDNA microarray analysis reveals the capacity of the cold-adapted Antarctic fish <Emphasis Type="Italic">Trematomus bernacchii</Emphasis> to alter gene expression in response to heat stress

During their many millions of years of evolution in the extreme and stable cold, Antarctic notothenioid fishes have acquired profoundly cold-adapted physiologies. Gene expression profiling via cDNA microarray was used to determine the extent to which one species of notothenioid, Trematomus bernacchii, has retained the ability to alter gene expression in response to heat stress. While an inability to up-regulate the expression of any size class of heat shock proteins (except for a 1.1-fold induction of the co-chaperone Hsp40) was observed, hundreds of additional genes, associated with a broad range of cellular processes, were responsive to heat. Many of these genes are associated with central aspects of the evolutionarily conserved cellular stress response (CSR), which plays a pivotal role in responding to physical and chemical stresses. The inability of T. bernacchii to mount a heat shock response underscores the potential susceptibility of this species to the effects of global warming.