HeLa cells synthesize a specific heat shock protein upon exposure to heat shock at 42 degrees C but not at 45 degrees C

Upon exposure to heat shock, HeLa cells synthesize a small set of proteins having the molecular weights of 70,000, 73,000, 78,000, 85,000, 92,000, and 105,000. In addition to these proteins, we found an unusual heat shock protein induced by heat shock at 42 degrees C, but not at 45 degrees C. The 42 degrees C-specific protein, the molecular weight of which was 90,000, was not produced in control cells and the induction of the protein was completely inhibited by actinomycin D. The protein was not induced by other treatments that induced most heat shock proteins. Thus, this 42 degrees C-specific protein seems to have a peculiar induction mechanism and a specific function in the cells.     

Thermal resistance in fungi: the role of heat shock proteins and trehalose

The parallel synthesis of heat shock proteins and trehalose in response to heat shock did not allow the role of these compounds in the acquisition of thermotolerance by fungal cells to be established for a long time. This review analyses experimental data obtained with the use of mutant fungal strains and shows differences in the thermoprotective functions of trehalose and heat shock proteins in relation to cell membranes and macromolecules. The main emphasis has been placed on data demonstrating the thermoprotective role of trehalose in fungi, the present-day understanding of its biological functions, and mechanisms of trehalose interaction with subcellular structures and cell macromolecules.     

Thermotolerance induced at a mild temperature of 40 degrees C protects cells against heat shock-induced apoptosis

Apoptosis constitutes a response of organisms to various physiological or pathological stimuli, and to different stresses. The ability of thermotolerance induced at a mild temperature of 40 degrees C to protect against activation of the apoptotic cascade by heat shock was investigated. When Chinese hamster ovary and human adenocarcinoma cervical cells were pretreated at 40 degrees C for 3 h, they were resistant to subsequent lethal heat shock at 43 degrees C. Induction of thermotolerance at 40 degrees C led to increased expression of heat shock proteins 27, 32, 72, and 90. Heat shock induced apoptotic events at the mitochondrial level, involving a decrease in membrane potential, translocation of Bax to mitochondria, and liberation of cytochrome c into the cytosol. These events were diminished in thermotolerant cells. Heat shock (42-45 degrees C) caused activation of initiator caspase-9 and effector caspases-3, -6, and -7, relative to controls at 37 degrees C. Activation of caspases was decreased in thermotolerant cells. Heat shock caused fragmentation of the caspase substrate, inhibitor of caspase-activated DNase. Fragmentation was diminished in thermotolerant cells. Thermotolerance afforded protection against heat shock-induced nuclear chromatin condensation, but not against necrosis.     

Heat shock proteins and heat adaptation of the whole organism

Moseley, Pope L. Heat shock proteins andheat adaptation of the whole organism. J. Appl.Physiol. 83(5): 1413-1417, 1997.Adaptation toheat may occur through acclimatization or thermotolerance; however, thelinkage of these phenomena is poorly understood. The importance of heatshock proteins (HSPs) in thermotolerance and differences in theiraccumulation in organisms adapted to the heat suggest a role for HSPsin acclimatization as well. The role of HSPs in heat adaptation of thewhole organism and the interrelationships among heat adaptation,endotoxin tolerance, and cytokine resistance through HSPs are reviewed.

     

Thermal biology of horseshoe crab embryos and larvae: A role for heat shock proteins

Eggs of the American horseshoe crab, Limulus polyphemus L., develop on sandy estuarine beaches during the spring and summer, and are potentially vulnerable to thermal stress during the 3-4 weeks of development to the first instar (trilobite) larval stage. In many marine taxa, heat shock (stress) proteins (Hsp's) help individuals acclimate to stresses by restoring the proper folding of cellular proteins whose shape has been altered by temperature shock or other forms of environmental stress. We examined the survival of embryos and first instar (trilobite) larvae following heat shock, and compared the levels of Hsp70 in heat shocked and control animals. Animals acclimated to 13 or 22 °C had close to 100% survival when heat shocked for 3 h at 35 or 40 °C, but exposure to 45 °C for 3 h was lethal. To study the effect of heat shock on Hsp70 production under environmentally realistic conditions, animals were acclimated to either 13 or 22 °C, heat-shocked at 35 °C for 3 h, and soluble proteins were extracted following 0, 2, 4, or 6 h recovery at 22 °C. The relative amounts of Hsp70 in horseshoe crab embryos and larvae were examined using SDS-PAGE and Western blotting. Relative to controls animals held at a constant temperature, there was a slight elevation of Hsp70 only among heat shocked trilobite larvae in the 6 h recovery treatment. Hsp70 levels did not differ significantly between control and heat shocked embryos. Horseshoe crabs have adapted to living in a thermally stressful environment by maintaining a high baseline (constitutive) level of cellular stress proteins such as Hsp70, rather than by synthesizing inducible Hsp's when stressful temperatures are encountered. This may be an effective strategy given that the heat shocks encountered by intertidal embryos and larvae occur regularly as a function of diurnal and tidal temperature changes.     

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.     

Development of thermotolerance and changes in intracellular pH in CHO cells heated at 45.0 degrees C at pH 6.6

Chinese hamster ovary (CHO) cells were given short heat pulses (5 to 20 min) at 45.0 degrees C and incubated at 37 degrees C for up to 20 h under either pH 7.3 or 6.6 conditions. Thermotolerance developed under both pH conditions, but at a slower rate in the pH 6.6 medium. Intracellular pH (pHi) was measured with the dye, 1,4-diacetoxy-2,3-dicyanobenzene, combined with flow cytometry. Time-dependent changes in the intracellular pH occurred under either pH condition. CHO cells incubated under normal pH conditions had a transient increase in the pHi. This pHi elevation was followed by a rapid intracellular acidification of approximately 0.15 to 0.25 pH units. The timing of both the increases and decreases in the pHi was dependent on the magnitude of the initial heat dose. With heat doses less than or equal to 10 min, the pHi returned to normal unheated levels after the acidification phase. Although cells incubated under low pH (6.6) conditions showed similar pHi alterations, differences in the kinetics were measured. The intracellular pH increased immediately after heating. In addition, when intracellular acidification occurred, the rate of acidification was significantly reduced. With heat doses longer than 5 min under the low pH conditions, the pHi did not return to normal unheated levels.     

Cross-tolerance in the tidepool sculpin: the role of heat shock proteins

Cross-tolerance, or the ability of one stressor to transiently increase tolerance to a second heterologous stressor, is thought to involve the induction of heat shock proteins (Hsp). We thus investigated the boundaries of cross-tolerance in tidepool sculpins (Oligocottus maculosus) and their relationship to Hsp70 levels. Survival of sculpins exposed to severe osmotic (90 ppt, 2 h) and hypoxic (0.33 mg O(2)/L, 2 h) stressors increased from 68% to 96%, and from 47% to 76%, respectively, following a +12 degrees C heat shock. The magnitude of this heat shock was critical for protection. A +10 degrees C heat shock did not confer cross-tolerance, while a +15 degrees C heat shock was deleterious. Sculpins required between 8 and 48 h of recovery following the +12 degrees C heat shock to develop cross-tolerance. There was no association between Hsp70 levels before the onset of the secondary stressor and cross-tolerance. However, branchial Hsp70 levels following osmotic shock were highly correlated with the time frame of cross-tolerance. Thus, Hsp70 induction by the priming stressor may be less important than the ability of the cell to mount an Hsp response to subsequent stressors. The time frame of cross-tolerance is similar to the interval between low tides, suggesting the possible relevance of this response in nature.     

Simian virus 40 and polyoma virus induce synthesis of heat shock proteins in permissive cells.

During the lytic infection of monkey and mouse cells with simian virus 40 and polyoma virus, respectively, the preferentially increased synthesis of two host proteins of 92,000 and 72,000 Mr was observed by 15 to 20 h after infection besides the general stimulation of most cellular proteins. The incubation of uninfected monkey and mouse cell cultures for 30 to 60 min at 43.5 degrees C induced the enhanced synthesis of at least three proteins of 92,000, 72,000 and 70,000 Mr, the last one being the major heat shock protein of mammalian cells. Two-dimensional gel electrophoresis and partial proteolytic digestion confirmed that the same 92,000- and 72,000-Mr proteins are stimulated by virus infection and thermal treatment. In simian virus 40-infected CV-1 cells, we also observed the weak stimulation of a 70,000-Mr protein comigrating in gel electrophoresis with the major heat shock protein. The 92,000-, 72,000- and 70,000-Mr proteins of monkey cells are structurally very similar to the corresponding proteins of mouse cells. In immunoprecipitations, no specific association of these proteins to simian virus 40 T antigens was noticed.     

Small heat shock proteins and adaptation to hypertermia in various Drosophila species

Expression level and kinetics of accumulation of small heat shock proteins (21-27 kDa group) have been investigated in three Drosophila species differing significantly by temperature niche and thermosensitivity. It was shown that low-latitude thermotolerant species D. virilis exceeds the high-latitude thermosensitive closely-related species D. lummei as well as distant thermosensitive species D. melanogaster in terms of small heat shock proteins expression and accumulation after temperature elevation. The data obtained enable to postulate an important role of small heat shock proteins in organism basal thermotolerance and general adaptation to adverse conditions of environment.     

The role of small heat shock proteins in parasites

The natural life cycle of many protozoan and helminth parasites involves exposure to several hostile environmental conditions. Under these circumstances, the parasites arouse a cellular stress response that involves the expression of heat shock proteins (HSPs). Small HSPs (sHSPs) constitute one of the main families of HSPs. The sHSPs are very divergent at the sequence level, but their secondary and tertiary structures are conserved and some of its members are related to α-crystallin from vertebrates. They are involved in a variety of cellular processes. As other HSPs, the sHSPs act as molecular chaperones; however, they have shown other activities apparently not related to chaperone action. In this review, the diverse activities of sHSPs in the major genera of protozoan and helminth parasites are described. These include stress response, development, and immune response, among others. In addition, an analysis comparing the sequences of sHSPs from some parasites using a distance analysis is presented. Because many parasites face hostile conditions through its life cycles the study of HSPs, including sHSPs, is fundamental.     

The evolutionary and ecological role of heat shock proteins

Most heat shock proteins (Hsp) function as molecular chaperones that help organisms to cope with stress of both an internal and external nature. Here, we review the recent evidence of the relationship between stress resistance and inducible Hsp expression, including a characterization of factors that induce the heat shock response and a discussion of the associated costs. We report on studies of stress resistance including mild stress, effects of high larval densities, inbreeding and age on Hsp expression, as well as on natural variation in the expression of Hsps. The relationship between Hsps and life history traits is discussed with special emphasis on the ecological and evolutionary relevance of Hsps. It is known that up‐regulation of the Hsps is a common cellular response to increased levels of non‐native proteins that facilitates correct protein folding/refolding or degradation of non‐functional proteins. However, we also suggest that the expression level of Hsp in each species and population is a balance between benefits and costs, i.e. a negative impact on growth, development rate and fertility as a result of overexpression of Hsps. To date, investigations have focused primarily on the Hsp70 family. There is evidence that representatives of this Hsp family and other molecular chaperones play significant roles in relation to stress resistance. Future studies including genomic and proteonomic analyses will increase our understanding of molecular chaperones in stress research.     

The cell cycle dependence of thermotolerance. II. CHO cells heated at 45.0 degrees C

This report extends our investigations of the cell cycle dependence of the expression of thermotolerance to include tolerance expressed by Chinese hamster ovary (CHO) cells exposed to 45.0 degrees C hyperthermia. We examined the response of asynchronous cells following exposure at 45.0 degrees C. A maximum in thermotolerance under these conditions was reached approximately 12 hr after a 15-min exposure to 45.0 degrees C hyperthermia and progressively decreased thereafter. Cells were delayed in S and G2 phase for 24 hr, after which time cell growth resumed. We then characterized the response of CHO cell populations synchronized in G1 or early or late S phase. We observed that the expression of tolerance depended on the position of cells in the cell cycle and was modulated by changes in the sensitivity of cells as they progressed through the cell cycle subsequent to the tolerance induction dose. We measured the variation in the sensitivity of these cells to 45.0 degrees C hyperthermia throughout the cell cycle and found substantial changes as cells progressed through S phase. Cells in early S phase were the most sensitive to heat at this temperature, and as these cells progressed through S phase, they became progressively more resistant. In addition, G1 cells were delayed for approximately 15 to 18 hr by a 15-min, 45.0 degrees C heat pulse, whereas S-phase cells were delayed to a lesser extent. The data presented in this report suggest that the induction of thermotolerance is relatively non-cell-cycle specific, but the magnitude of expression of tolerance depends on the position of cells in the cell cycle at the time of the subsequent challenge heat dose.     

The cell cycle dependence of thermotolerance. I. CHO cells heated at 42 degrees C

We examined the dependence of heat killing and thermotolerance on the position and progression of Chinese hamster ovary (CHO) cells in the cell cycle. We measured cell cycle perturbations and survival of asynchronous and synchronized G1-, S-, and G2-phase cells resulting from continuous heating at 42.0 degrees C for up to 80 hr. Thermotolerance under these conditions was transient in nature, was dependent on the position of cells in the cell cycle, and occurred concurrently with a heat-induced delay of progression of G1- and G2-phase cells. When G1 cells were heated, survival decreased to 25% after 4 hr, at which time the thermotolerance was expressed. For G2 cells survival decreased initially at the same rate (T0 congruent to 3 hr) but thermotolerance was not expressed until approximately 12 hr, at which time the survival was 4%. The rate of decrease in survival was much more rapid for cells heated in mid-S phase (T0 congruent to 0.5 hr), and these cells did not express thermotolerance at a measurable level. Concurrent with the expression of thermotolerance, the progression of cells heated in G1 and G2 was delayed. Following the expression of tolerance, progression resumed at a rate approximately equal to the rate of decrease in survival of the G1 population. Cells heated in mid-S phase continued to progress through the cell cycle until they reached G2, where they were also delayed.     

Adaptation to heat of cardiomyoblasts in culture protects them against heat shock: role of nitric oxide and heat shock proteins

Dosed adaptation to environmental factors is an efficient non-drug means for increasing the resistance of organs or the body as a whole. We demonstrated earlier that nitric oxide (NO) plays an important role in adaptive defense of the organism, in particular due to activation of heat shock protein (HSP) synthesis. A key question remained open—to what extent the formation of adaptive defense depends on central mechanisms and to what extent on the intracellular mechanisms immediately responding to the adapting factor, and whether the NO-dependent activation of HSP synthesis plays a role in adaptation of isolated cells. In the present study we looked into the possibility of producing a protective effect of adaptation to heat in cell culture. A 6-day adaptation to heat limited to 17% the decrease in metabolic activity induced by heat shock in H9c2 cardiomyoblasts. The development of adaptation was associated with increased NO production. Treatment of cells with the inhibitor of NO synthase L-NNA (100 M) prevented the development of adaptive protection. Adaptation of cell culture enhanced synthesis of HSP70 but not HSP27. Blockade of HSP70 synthesis with quercetin (50 M) left unchanged the protective effect of adaptation. Inhibition of NO synthesis restricted the adaptation-induced HSP70 synthesis. Therefore, the formation of adaptation at the cell level may result from a direct action of an environmental factor without participation of neurohumoral factors. Such adaptation involves NO-dependent mechanisms divorced from the activation of HSP70 synthesis.     

Small heat shock proteins and adaptation of various Drosophila species to hyperthermia

The dynamics and the level of accumulation of small heat shock proteins (sHSP group 21–27) after a heat exposure were studied in three Drosophila species differing in thermotolerance. The southern species Drosophila virilis, having the highest thermotolerance, surpassed thermosensitive D. lummei and D. melanogaster in the level of sHSPs throughout the temperature range tested. The results suggest an important role of sHSPs in the molecular mechanisms of adaptation to adverse environmental conditions, particularly to hyperthermia.