Effect of heat shock on the intracellular distribution of proteins

Exposure of cells to heat induces thermotolerance, a transient resistance to subsequent heat challenges. It has been shown that thermotolerance is correlated in time with the enhanced synthesis of heat shock proteins. In this study, the association of induced heat shock proteins with various cellular fractions was investigated and the heat-induced changes in skeletal protein composition in thermotolerant and control cells was compared. All three major heat shock proteins induced in Chinese hamster fibroblasts after a 46 degrees C, 4-min heat treatment (70, 87, and 110 kDa) were purified with the cytoplasmic fraction, whereas only the 70-kDa protein was also found in other cell fractions, including that containing the cellular skeleton. Immediately after a second heat treatment at 45 degrees C for 45 min, the 110-kDa protein from thermotolerant cells also purified extensively with the cellular skeletal fraction. In this regard, the 110-kDa protein behaved similarly to many other cellular proteins, since we observed an overall temperature-dependent increase in the total labeled protein content of the high-salt-resistant cellular skeletal fraction after heat shock. Pulse-chase studies demonstrated that this increased protein content gradually returned to normal levels after a 3-hr incubation at 37 degrees C. The alteration or recovery kinetics of the total labeled protein content of the cellular skeletal fraction after heat shock did not correlate with the dramatic increase in survival observed in thermotolerant cells. The relationship between heat shock proteins and thermotolerance, therefore, does not correlate directly with changes in the heat-induced cellular alterations leading to differences in protein fractionation.     

Characterization and purification of the small 28,000-dalton mammalian heat shock protein

We describe the biochemical characterization and purification of the small 28,000-dalton heat shock protein (28-kDa protein) of mammalian cells. Metabolic pulse labeling of heat shock-treated cells with either [3H]leucine or H3 32PO4 and analysis of the labeled proteins by two-dimensional gel electrophoresis revealed increased levels of three 28-kDa proteins differing only in their relative isoelectric point. Using both peptide mapping and immunological analysis, we demonstrate that all three proteins are related isoforms, with two of the isoforms containing phosphate. Cell fractionation studies revealed that the 28-kDa protein localizes predominantly within the nuclear pellet very shortly after the heat shock treatment. With increasing times of recovery of the heat-treated cells back at 37 degrees C, the majority of the 28-kDa protein was now observed to fractionate within the soluble fraction of the cells. Both gel filtration and velocity sedimentation studies revealed that the 28-kDA protein exists as a higher order structure with an approximate S20,w value of 10-18 S, a Stokes radius of about 60-70 A, and an estimated native molecular mass of at least 500,000 daltons. We describe a relatively simple and rapid purification of the proteins employing both ion-exchange and gel filtration chromatography.     

Heat-induced preferential synthesis and redistribution of HSP 70 and 28 families in Chinese hamster ovary cells

We observed that members of two HSP families (70 and 28 kDa) preferentially redistributed into the nucleus after heating at 45.5 degrees C for 10 min. The rates of synthesis and redistribution of these proteins were different for each member of HSP families during incubation period at 37 degrees C after heat shock. The maximum rates of synthesis of HSP 70 and HSP 28 families, except HSP 28c, were 6-9 hr after heat shock, whereas the maximum rates of redistribution were 3-6 hr after heat shock. These results suggest that the rates of redistribution of these proteins may be dependent on the amount of intracellular proteins as well as the alteration of binding affinity of nucleoproteins following heat shock.     

Differences in thermotolerance induced by heat or sodium arsenite: correlation between redistribution of a 26-kDa protein and development of protein synthesis-independent thermotolerance in CHO cells

In previous studies, we have demonstrated the differences in thermotolerance induced by heat and sodium arsenite (Lee et al., Radiat. Res. 121, 295-303, 1990). In this study, we investigated whether a 26-kDa protein might play an important role in evincing these differences. Chinese hamster ovary (CHO) cells treated for either 1 h with 100 microM sodium arsenite (ARS) or 10 min at 45.5 degrees C became thermotolerant to a test heat treatment at 43 degrees C administered 6 or 12 h later, respectively. After the test heating at 43 degrees C for 1.5 h, the level of 26-kDa protein in the nucleus was decreased by 92% in nonthermotolerant cells, 78% in ARS-induced thermotolerant cells, and 3% in heat-induced thermotolerant cells. Inhibiting protein synthesis with cycloheximide (CHM, 10 micrograms/ml) after ARS treatment eliminated thermotolerance to 43 degrees C and delayed restoration of the 26-kDa protein in the nucleus. In contrast, CHM neither prevented the development of thermotolerance nor inhibited the restoration of the 26-kDa protein in heat-induced thermotolerant cells. However, when cells were exposed to cold (4 degrees C), immediately after initial heating, restoration of the 26-kDa protein and development of thermotolerance did not occur. These results demonstrate a good correlation between the restoration and/or the presence of this 26-kDa protein and the development of protein synthesis-independent thermotolerance.     

Heat protectors and heat-induced preferential redistribution of 26 and 70 kDa proteins in Chinese hamster ovary cells

An overall increase of 40% in nuclear-associated protein has been shown to be one of the sequellae of exposure of eukaryotic cells to elevated temperatures. Several investigators have shown that the increased protein/DNA ratios correlated well with the degree of cytotoxicity. In previous investigations, we have shown that cycloheximide, which protects the cell from the killing effects of heat, produces a dramatic reduction of the bulk nuclear-associated proteins after heating. In this investigation, we studied a previously unobserved efflux of a 26 kDa protein after heat shock and the preferential accumulation of the 70 kDa protein. The 26 kDa protein was shown not to be a member of previously described heat shock protein families. Preferential reduction of a 26 kDa protein and accumulation of a 70 kDa protein was observed in nuclei isolated from Chinese hamster ovary cells after heating at 43 degrees C. After heat treatment, the 26 kDa protein in the nucleus was decreased to a level 0.1-0.3 times the original amount in unheated cells, and the 70 kDa protein in the nucleus increased by a factor of 1.6-1.8. The normal levels of these two proteins were restored when cells were incubated at 37 degrees C following heat shock. Cells treated with heat protectors, cycloheximide and histidinol, demonstrated approximately the same redistribution in nuclear 26 and 70 kDa proteins immediately after heating as those not exposed to these drugs. On the other hand, restoration to control levels was much faster in the protector-treated cells, suggesting that "repair" of heat-induced damage is an important factor in the cells ability to survive this insult. Return to normal protein levels did not require new protein synthesis.     

Differences in preferential synthesis and redistribution of HSP70 and HSP28 families by heat or sodium arsenite in Chinese hamster ovary cells

Since both heat and sodium arsenite induce thermotolerance, we investigated the differences in synthesis and redistribution of stress proteins induced by these agents in Chinese hamster ovary cells. Five major heat shock proteins (HSPs; Mr 110, 87, 70, 28, and 8.5 kDa) were preferentially synthesized after heat for 10 min at 45.5 degrees C, whereas four major HSPs (Mr 110, 87, 70, and 28 kDa) and one stress protein (33.3 kDa) were preferentially synthesized after treatment with 100 microM sodium arsenite (ARS) for 1 hr. Two HSP families (HSP70a,b,c, and HSP28a,b,c) preferentially relocalized in the nucleus after heat shock. In contrast, only HSP70b redistributed into the nucleus after ARS treatment. Furthermore, the kinetics of synthesis of each member of HSP70 and HSP28 families and their redistribution were different after these treatments. The maximum rates of synthesis of HSP70 and HSP28 families, except HSP28c, were 6-9 hr after heat shock, whereas those of HSP70b and HSP28b,c were 0-2 hr after ARS treatment. In addition, the maximum rates of redistribution of HSP70 and HSP28 families occurred 3-6 hr after heat shock, whereas that of HSP70b occurred immediately after ARS treatment. The degree of redistribution of HSP70b after ARS treatment was significantly less than that after heat treatment. These results suggest that heat treatment but not sodium arsenite treatment stimulates the entry of HSP70 and HSP28 families into the nucleus.     

Heat shock protein synthesis and thermotolerance in Salmonella typhimurium

The resistance of stationary phase Salmonella typhimurium to heating at 55 degrees C was greater in cells grown in nutritionally rich than in minimal media, but in all media tested resistance was enhanced by exposing cells to a primary heat shock at 48 degrees C. Chloramphenicol reduced the acquisition of thermotolerance in all media but did not completely prevent it in any. The onset of thermotolerance was accompanied by increased synthesis of major heat shock proteins of molecular weight about 83, 72, 64 and 25 kDa. When cells were shifted from 48 degrees C to 37 degrees C, however, thermotolerance was rapidly lost with no corresponding decrease in the levels of these proteins. There is thus no direct relationship between thermotolerance and the cellular content of the major heat shock proteins. One minor protein of molecular weight about 34 kDa disappeared rapidly following a temperature down-shift. Its presence in the cell was thus correlated with the thermotolerant state.     

Ubiquitin in Chlamydomonas reinhardii. Distribution in the cell and effect of heat shock and photoinhibition on its conjugate pattern

Ubiquitin, a highly conserved 76-amino-acid protein, is involved in the response of many types of eukaryotic cells to stress but little is known about its role in lower plants. In the present study we have investigated the distribution of ubiquitin in the unicellular alga Chlamydomonas reinhardii as well as the effect of heat and light stress on its conjugation to cellular proteins. Immunoelectron microscopy shows that ubiquitin is located in the chloroplast, nucleus, cytoplasm, pyrenoid and on the plasma membrane. The location of ubiquitin within chloroplasts has not been observed previously. In immunoblots of whole cell extracts with an antibody to ubiquitin a prominent conjugate band with an apparent molecular mass of 29 kDa and a broad region of high-molecular-mass conjugates (apparent molecular mass greater than 45 kDa) were observed. Exposure of cells to a 41.5 degrees C heat shock in both the dark and light caused the disappearance of the 29-kDa conjugate and an increase in the high-molecular-mass conjugates. After step down to 25 degrees C the 29-kDa conjugate reappeared while the levels of high-molecular-mass conjugates decreased. In light, the recovery of the 29-kDa band was more rapid than in the dark. Photoinhibition alters the ubiquitin conjugation pattern similarly to heat shock, but to a lesser degree. These observations imply that, in Chlamydomonas, ubiquitin has a role in the chloroplast and in the response to heat and light stress.     

Acquisition of thermotolerance induced by heat and arsenite in HeLa S3 cells: Multiple pathways to induce tolerance?

Recent data indicate that cells may acquire thermotolerance via more than one route. In this study, we observed differences in thermotolerance development in HeLa S3 cells induced by prior heating (15 minutes at 44 degrees C) or pretreatment with sodium-arsenite (1 hour at 37 degrees C, 100 microM). Inhibition of overall protein and heat shock protein (HSP) synthesis (greater than 95%) by cycloheximide (25 micrograms/ml) during tolerance development nearly completely abolished thermotolerance induced by arsenite, while significant levels of heat-induced thermotolerance were still apparent. The same dependence of protein synthesis was found for resistance against sodium-arsenite toxicity. Toxic heat, but not toxic arsenite treatments caused heat damage in the cell nucleus, measured as an increase in the protein mass of nuclei isolated from treated cells (intranuclear protein aggregation). Recovery from this intranuclear protein aggregation was observed during post-heat incubations of the cells at 37 degrees C. The rate of recovery was faster in heat-induced tolerant cells than in nontolerant cells. Arsenite-induced tolerant cells did not show an enhanced rate of recovery from the heat-induced intranuclear protein aggregation. In parallel, hyperthermic inhibition of RNA synthesis was the same in tolerant and nontolerant cells, whereas post-heat recovery was enhanced in heat-induced, but not arsenite-induced thermotolerant cells. The more rapid recovery from heat damage in the nucleus (protein aggregation and RNA synthesis) in cells made tolerant by a prior heat treatment seemed related to the ability of heat (but not arsenite) to induce HSP translocations to the nucleus.     

Heat-induced modulation of lamin B content in two different cell lines

Previous work in our laboratory indicates that the nuclear matrix protein lamin B is a "prompt" heat shock protein, which increases significantly when human U-1 melanoma and HeLa cells are exposed to 45.5 degrees C for 5-40 min. Using Western blotting, we found that the lamin B content in U-1 and HeLa cells increased to a greater extent during post-heat incubation at 37 degrees C than during the heat dose itself. When HeLa cells were heated at 45.5 degrees C for 30 min, and then incubated at 37 degrees C for up to 7 h, lamin B content was increased significantly (1.69-fold maximum increase at 3 h) compared to unincubated heated cells. Also, thermotolerant HeLa cells showed a greater increase (up to 1.72-fold) in lamin B content during subsequent heating compared to nontolerant cells. The increase in lamin B content in thermotolerant cells, or when heated cells were incubated at 37 degrees C, was also observed in U-1 cells. HeLa cells heated in the presence of glycerol (a heat protector) showed a 1.21-1.72-fold increase in lamin B content compared to cells heated for 10-30 min without glycerol. In contrast, lamin B content decreased 1.23-1.85-fold when cells were heated for 10-30 min in the presence of procaine (a heat sensitizer) compared to cells heated without procaine. These data suggest that lamin B may play an important role in the heat shock response, and that modulation of lamin B content by heat sensitizers or protectors may play a role in regulation of heat sensitivity.     

A heat shock protein is encoded within mitochondria of higher plants

A temperature shift from 25 to 41 degrees C initiates the synthesis of a specific set of proteins in maize, including a peptide of 60 kilodaltons. Using an in vitro mitochondrial protein synthesizing system, we provide evidence that this 60-kDa heat shock protein is encoded within the organelle. Further support for this heat-induced protein being encoded within mitochondria is that its synthesis is inhibited in whole seedlings by chloramphenicol. This 60-kDa heat shock protein is induced in all lines of maize we examined. Additionally, a heat-induced peptide of similar size (62 kDa) can be detected in isolated mitochondria of a dicot plant, Brassica campestris. The function of the heat shock protein encoded within the mitochondria remains unknown.     

Induction of thermotolerance in T cells protects nuclear DNA topoisomerase I from heat stress.

In this study, we have demonstrated that topoisomerase I DNA relaxing activity is protected against a severe heat shock in T cells made thermotolerant by a prior modest heat treatment. However, following a severe heat-shock challenge and incubation at 37 degrees C, topoisomerase activity in the control population eventually returned to levels similar to those detected in thermotolerant cells. This recovery of topoisomerase activity appears to result from the renaturation of heat-inactivated enzyme rather than from synthesis of new protein because the rate of recovery of catalytic activity was not inhibited by the presence of the protein synthesis inhibitor, cycloheximide.     

Characterization of the thermotolerant cell. II. Effects on the intracellular distribution of heat-shock protein 70, intermediate filaments, and small nuclear ribonucleoprotein complexes

Here we further characterize a number of properties inherent to the thermotolerant cell. In the preceding paper, we showed that the acquisition of the thermotolerant state (by a prior induction of the heat-shock proteins) renders cells translationally tolerant to a subsequent severe heat-shock treatment and thereby results in faster kinetics of both the synthesis and subsequent repression of the stress proteins. Because of the apparent integral role of the 70-kD stress proteins in the acquisition of tolerance, we compared the intracellular distribution of these proteins in both tolerant and nontolerant cells before and after a severe 45 degrees C/30-min shock. In both HeLa and rat embryo fibroblasts, the synthesis and migration of the major stress-induced 72-kD protein into the nucleolus and its subsequent exit was markedly faster in the tolerant cells as compared with the nontolerant cells. Migration of preexisting 72-kD into the nucleolus was shown to be dependent upon heat-shock treatment and independent of active heat-shock protein synthesis. Using both microinjection and immunological techniques, we observed that the constitutive and abundant 73-kD stress protein similarly showed a redistribution from the cytoplasm and nucleus into the nucleolus as a function of heat-shock treatment. We show also that other lesions that occur in cells after heat shock can be prevented or at least minimized if the cells are first made tolerant. Specifically, the heat-induced collapse of the intermediate filament cytoskeleton did not occur in cells rendered thermotolerant. Similarly, the disruption of intranuclear staining patterns of the small nuclear ribonucleoprotein complexes after heat-shock treatment was less apparent in tolerant cells exposed to a subsequent heat-shock treatment.     

c-myc and c-myb protein degradation: effect of metabolic inhibitors and heat shock.

The proteins encoded by both viral and cellular forms of the c-myc oncogene have been previously demonstrated to have exceptionally short in vivo half-lives. In this paper we report a comparative study on the parameters affecting turnover of nuclear oncoproteins c-myc, c-myb, and the rapidly metabolized cytoplasmic enzyme ornithine decarboxylase. The degradation of all three proteins required metabolic energy, did not result in production of cleavage intermediates, and did not involve lysosomes or ubiquitin. A five- to eightfold increase in the half-life of c-myc proteins, and a twofold increase in the half-life of c-myb proteins was detected after heat-shock treatment at 46 degrees C. In contrast, heat shock had no effect on the turnover of ornithine decarboxylase. Heat shock also had the effect of increasing the rate of c-myc protein synthesis twofold, whereas c-myb protein synthesis was decreased nearly fourfold. The increased stability and synthesis of c-myc proteins led to an overall increase in the total level of c-myc proteins in response to heat-shock treatment. Furthermore, treatments which reduced c-myc and c-myb protein turnover, such as heat shock and exposure to inhibitors of metabolic energy production, resulted in reduced detergent solubility of both proteins. The recovery from heat shock, as measured by increased turnover and solubility, was energy dependent and considerably more rapid in thermotolerant cells.     

Differences in thermotolerance induced by heat or sodium arsenite: cell killing and inhibition of protein synthesis

Chinese hamster ovary (CHO) cells became thermotolerant after treatment with either heat for 10 min at 45.5 degrees C or incubation in 100 microM sodium arsenite for 1 h at 37 degrees C. Thermotolerance was tested using heat treatment at 45 degrees C or 43 degrees C administered 6-12 h after the inducing agent. At 45 degrees C thermotolerance ratios at 10(-2) isosurvival levels were 4.2 and 3.8 for heat and sodium arsenite, respectively. Recovery from heat damage as measured by resumption of protein synthesis was more rapid in heat-induced thermotolerant cells than in either sodium arsenite-induced thermotolerant cells or nonthermotolerant cells. Differences in inhibition of protein synthesis between heat-induced thermotolerant cells and sodium arsenite-induced thermotolerant cells were also evident after test heating at 43 degrees C for 5 h. At this temperature heat-induced thermotolerant cells were protected immediately from inhibition of protein synthesis, whereas sodium arsenite-induced thermotolerant cells, while initially suppressed, gradually recovered within 24 h. Furthermore, adding cycloheximide during the thermotolerance development period greatly inhibited sodium arsenite-induced thermotolerance (SF less than 10(-6] but not heat-induced thermotolerance (SF = 1.7 X 10(-1] when tested with 43 degrees C for 5 h. Our results suggest that both the development of thermotolerance and the thermotolerant state for the two agents, while similar in terms of survival, differed significantly for several parameters associated with protein synthesis.     

Analysis by Confocal Microscopy of the Behavior of Heat Shock Protein 70 within the Nucleus and of a Nuclear Matrix Polypeptide during Prolonged Heat Shock Response in HeLa Cells

By means of confocal laser scanning microscopy and indirect fluorescence experiments we have examined the behavior of heat-shock protein 70 (HSP70) within the nucleus as well as of a nuclear matrix protein (M_r = 125 kDa) during a prolonged heat-shock response (up to 24 h at 42°C) in HeLa cells. In control cells HSP70 was mainly located in the cytoplasm. The protein translocated within the nucleus upon cell exposure to hyperthermia. The fluorescent pattern revealed by monoclonal antibody to HSP70 exhibited several changes during the 24-h-long incubation. The nuclear matrix protein showed changes in its location that were evident as early as 1 h after initiation of heat shock. After 7 h of treatment, the protein regained its original distribution. However, in the late stages of the hyperthermic treatment (17-24 h) the fluorescent pattern due to 125-kDa protein changed again and its original distribution was never observed again. These results show that HSP70 changes its localization within the nucleus conceivably because it is involved in solubilizing aggregated polypeptides present in different nuclear regions. Our data also strengthen the contention that proteins of the insoluble nucleoskeleton are involved in nuclear structure changes that occur during heat-shock response.     

Ligand-induced association of surface immunoglobulin with the detergent insoluble cytoskeleton may involve alpha-actinin

B cell surface immunoglobulin (SIg) plays an important role in antigen recognition and cellular activation. Cross-linking of SIg by bivalent antibody converts it into a detergent insoluble state. The resultant SIg may be partially solubilized by incubating the detergent insoluble cytoskeleton in buffers that convert F actin to G actin. Immunoprecipitation of SIg from the detergent soluble fraction of [35S]methionine-labeled B cells results in the co-isolation of 112 kDa, 42 kDa, (actin), and three additional proteins in the 70- to 73-kDa molecular mass range, isoelectric point 4.8 to 5.6. Analysis of anti-Ig immunoprecipitates made after preclearing with anti-alpha-actinin showed complete depletion of the 112-kDa protein, suggesting that the 112-kDa protein is immunologically related to alpha-actinin. These immunoprecipitates also showed partial depletion of 70- to 73-kDa proteins and mu and delta heavy chains. After treatment of a rat B cells with anti-Ig, much of the Ig-associated 112-kDa protein and 70- to 73-kDa proteins became detergent insoluble, concomitant with most of the SIg. The migration of the SIg-associated 112-kDa and 70- to 73-kDa proteins from the detergent soluble fraction to the detergent insoluble fraction after ligand treatment, suggests that these proteins might be involved in linking SIg to the underlying cytoskeleton and could be involved in the transmission of mitogenic signals.     

Glucocorticoid receptor phosphorylation in mouse L-cells

This paper summarizes our observations on the phosphorylation state of untransformed and transformed glucocorticoid receptors isolated from 32P-labeled L-cells. The 300-350-kDa 9S untransformed murine glucocorticoid receptor complex is composed of a 100-kDa steroid-binding phosphoprotein and one or possibly two units of the 90-kDa heat shock protein (hsp90), which is also a phosphoprotein. Transformation of this complex to the 4S DNA-binding state is accompanied by dissociation of hsp90. When receptors in cytosol are transformed by heating at 25 degrees C, there is no gross change in the degree of phosphorylation of the steroid-binding protein. Both receptors that are bound to DNA after transformation under cell-free conditions and receptors that are located in the nucleus of cells incubated at 37 degrees C in the presence of glucocorticoid are labeled with 32P. The results of experiments in which the 32P-labeled receptor was submitted to limited proteolysis suggest that the 16-kDa DNA-binding domain is phosphorylated and that the 28-kDa steroid-binding domain is not.     

Heat shock mediated modulation of protein kinase CK2 in the nuclear matrix

Nuclear matrix, a key structure in the nuclear framework, appears to be a particularly responsive target during heat shock treatment of cells. We have previously shown that nuclear matrix is a preferential target for protein kinase CK2 signaling in the nucleus. The levels of CK2 in the nuclear matrix undergo dynamic changes in response to altered growth status in the cell. Here, we have demonstrated that CK2 targeting to the nuclear matrix is profoundly influenced by treatment of the cells to temperatures higher than 37 degrees C. Rapid increase in the nuclear matrix association of CK2 is observed when cells are placed at temperatures of 41 and 45 degrees C. This effect at 45 degrees C was higher than at 41 degrees C, and was time-dependent. Also, different cell lines behaved in a qualitatively similar manner though the quantitative responses differed. The modulations in the nuclear matrix associated CK2 in response to heat shock appear to be due to trafficking of the enzyme between cytosolic and nuclear compartments. In addition, it was noted that isolated nuclei subjected to heat shock also responded by a shuttling of the intrinsic CK2 to the nuclear matrix compartment. These results suggest that modulations in CK2 in the nuclear compartment in response to the heat stress occur not only by a translocation of the enzyme from the cytoplasmic compartment to the nuclear compartment, but also that there is a redistribution of the kinase within the nuclear compartment resulting in a preferential association with the nuclear matrix. The results support the notion that CK2 association with the nuclear matrix in response to heat shock may serve a protective role in the cell response to stress.     

Heat-induced aggregation of XRCC5 (Ku80) in nontolerant and thermotolerant cells.

XRCC5 (also known as Ku80) is a component of the DNA-dependent protein kinase (DNA-PK), existing as a heterodimer with G22P1 (also known as Ku70). DNA-PK is involved in the nonhomologous end-joining (NHEJ) pathway of DNA double-strand break (DSB) repair, and kinase activity is dependent upon interaction of the Ku subunits with the resultant DNA ends. Nuclear XRCC5 is normally extractable with non-ionic detergent; it is found in the soluble cytoplasmic fraction after nuclear isolation with Triton X-100. In this study, we found that heating at 45.5 degrees C causes a decreased extractability of XRCC5 from the nuclei of human U-1 melanoma or HeLa cells. Such decreases in extractability are indicative of protein aggregation within nuclei. Recovery of extractability of XRCC5 to that of unheated control cells was observed after incubation at 37 degrees C after heat shock. The decrease in extractability and the kinetics of recovery were dependent on dose, although the decrease in extractability reached a plateau after heating for 15 min or more. Thermotolerant U-1 cells also showed decreased extractability of XRCC5, but to a lesser degree compared to nontolerant cells. When a comparable initial reduction of extractability of XRCC5 was induced in both thermotolerant and nontolerant cells, the kinetics of recovery was nearly identical. The kinetics of recovery of the extractability of XRCC5 was different from that of total nuclear protein in nontolerant cells; recovery of extractability of XRCC5 occurred faster initially and returned to the level in unheated cells faster than total nuclear protein. Similar results were obtained for thermotolerant cells, with differences between the initial recovery of the extractability of XRCC5 and total protein being particularly evident after longer heating times. Heat has been shown to inactivate XRCC5. We speculate that inactivation of XRCC5 after heat shock results from protein aggregation, and that changes in XRCC5 may, in part, lead to inhibition of DSB repair through inactivation of the NHEJ pathway.