The balance between Hsp70 and its cochaperones Hdj1 and Bag1 determines its substrate-binding activity

Heat shock protein Hsp70 presents one of the most effective cell protective systems. Its protective activity is mostly due to the fact that Hsp70 is able to restore native conformation of newly synthesized or damaged proteins. Two other proteins. Hdj and Bag 1, are involved in the process, allowing Hsp70 to perform binding-release cyclec of target proteins. The aim of this study was to investigate interactions between cochaperones Hdj 1 and Bag 1, and the major cell chaperone Hsp in vitro. The accumulation of Hsp70 and Hdj 1 in human erythroleukemia K562 cells was stimulated by heat stress (43 degrees C, 60 min). Cells were collected at certain time periods after heat stress, and amounts of cell chaperones were measured using Western blotting and ELISA assay. The level of Hsp70 chaperone activity in cell extracts was estimated using original technique. The effects of exogenous cochaperones and of their parts on this activity were also investigated. The results of the study indicate that Hsp70 chaperone activity is regulated by the level of its cochaperones, especially Hdj 1. At the same time the amount of ATP appears to be critical for functional activity of Hsp70. Hdj 1 and Bag 1 peptides, which bind to Hsp70 with high affinity, are able to significally reduce its chaperone activity. This finding confirms the possibility of using peptide approach for regulation of Hsp70 function at the cellular and organismal levels.     

Dynamics of chaperone complex Hdj1-Hsp70-Bag1 as a response of erythroleukemia K562 cells to heat stress

Heat shock protein Hsp70 is known to play an important role in cell protection against a variety of harmful factors. This property, at least in part, is due to Hsp70 ability to restore the native conformation of newly synthetized or damaged proteins. In this activity Hsp70 is accompanied by two proteins, Hdj1 and Bag1, that enable Hsp70 to peform cycles of binding-release of target proteins. The aim of this study was to investigate interactions of Hdj1 and Bag1 co-chaperones with Hsp70 in vivo. The accumulation of Hsp70 was stimulated by heat stress, and later, at certain periods following the stress, cell probes were collected for biochemical and microscopic analysis. The data of Western blotting showed that within 24 h after heat shock amounts of Hsp70 and Hdj1 raised to remain at the elevated level for nearly 48 h. Several time points within this period were chosen for analysis of the complexes between Hsp70 and co-chaperones. The data of reciprocal immunoprecipitation/immunoblotting and confocal microscopy showed that Hsp70-Hdj1 complexes were detected primarily at early stage after heat shock, then Hsp70 was preferably bound to Bag1. The dynamics of chaperone complex formation and changes in their intracellular localization are discussed in terms of cell reaction to stress.     

High levels of the molecular chaperone Mdg1/ERdj4 reflect the activation state of endothelial cells

Mdg1/ERdj4, a mammalian chaperone that belongs to the HSP40 protein family, has been reported to be located in the endoplasmic reticulum (ER), is induced by ER stress, and protects ER stressed cells from apoptosis. Here we show that under normal physiological conditions, Mdg1/ERdj4 is expressed at various levels in the vasculature due to different activation states of the endothelium. To elucidate the stimuli that induce ER stress and thus upregulate Mdg1/ERdj4, we investigated the effect of several endothelium specific stressors on its expression. Mdg1/ERdj4 mRNA is induced by activated macrophages, by nitric oxide (NO) and heat shock, and during terminal cell differentiation, whereas shear stress does not affect Mdg1/ERdj4 expression levels. While the mRNA stability of BiP/GRP78 is unaffected in ER stressed cells, the stability of Mdg1/ERdj4 mRNA is prolonged during ER stress resulting in rapid increases and high levels of Mdg1/ERdj4 mRNA. Mdg1/ERdj4 protein is localized in the ER under control conditions. While heat shock induces a rapid translocation of Mdg1/ERdj4 to the nucleoli, no translocation could be observed during ER stress. This indicates that Mdg1/ERdj4 protein has diverse mechanisms to protect stressed cells from apoptosis.     

J-domain Proteins form Binary Complexes with Hsp90 and Ternary Complexes with Hsp90 and Hsp70

Hsp90 and Hsp70 are highly conserved molecular chaperones that help maintain proteostasis by participating in protein folding, unfolding, remodeling and activation of proteins. Both chaperones are also important for cellular recovery following environmental stresses. Hsp90 and Hsp70 function collaboratively for the remodeling and activation of some client proteins. Previous studies using E. coli and S. cerevisiae showed that residues in the Hsp90 middle domain directly interact with a region in the Hsp70 nucleotide binding domain, in the same region known to bind J-domain proteins. Importantly, J-domain proteins facilitate and stabilize the interaction between Hsp90 and Hsp70 both in E. coli and S. cerevisiae. To further explore the role of J-domain proteins in protein reactivation, we tested the hypothesis that J-domain proteins participate in the collaboration between Hsp90 and Hsp70 by simultaneously interacting with Hsp90 and Hsp70. Using E. coli Hsp90, Hsp70 (DnaK), and a J-domain protein (CbpA), we detected a ternary complex containing all three proteins. The interaction involved the J-domain of CbpA, the DnaK binding region of E. coli Hsp90, and the J-domain protein binding region of DnaK where Hsp90 also binds. Additionally, results show that E. coli Hsp90 interacts with E. coli J-domain proteins, DnaJ and CbpA, and that yeast Hsp90, Hsp82, interacts with a yeast J-domain protein, Ydj1. Together these results suggest that the complexes may be transient intermediates in the pathway of collaborative protein remodeling by Hsp90 and Hsp70.     

Scanning mutagenesis identifies amino acid residues essential for the in vivo activity of the Escherichia coli DnaJ (Hsp40) J-domain

The DnaJ (Hsp40) cochaperone regulates the DnaK (Hsp70) chaperone by accelerating ATP hydrolysis in a cycle closely linked to substrate binding and release. The J-domain, the signature motif of the Hsp40 family, orchestrates interaction with the DnaK ATPase domain. We studied the J-domain by creating 42 mutant E. coli DnaJ variants and examining their phenotypes in various separate in vivo assays, namely, bacterial growth at low and high temperatures, motility, and propagation of bacteriophage lambda. Most mutants studied behaved like wild type in all assays. In addition to the (33)HisProAsp(35) (HPD) tripeptide found in all known functional J-domains, our study uncovered three new single substitution mutations (Y25A, K26A, and F47A) that totally abolish J-domain function. Furthermore, two glycine substitution mutants in an exposed flexible loop (R36G, N37G) showed partial loss of J-domain function alone and complete loss of function as a triple (RNQ-GGG) mutant coupled with the phenotypically silent Q38G. Interestingly, all the essential residues map to a small region on the same solvent-exposed face of the J-domain. Engineered mutations in the corresponding residues of the human Hdj1 J-domain grafted in E. coli DnaJ also resulted in loss of function, suggesting an evolutionarily conserved interaction surface. We propose that these clustered residues impart critical sequence determinants necessary for J-domain catalytic activity and reversible contact interface with the DnaK ATPase domain.     

Specificity of class II Hsp40 Sis1 in maintenance of yeast prion [RNQ+

Sis1 and Ydj1, functionally distinct heat shock protein (Hsp)40 molecular chaperones of the yeast cytosol, are homologs of Hdj1 and Hdj2 of mammalian cells, respectively. Sis1 is necessary for propagation of the Saccharomyces cerevisiae prion [RNQ(+)]; Ydj1 is not. The ability to function in [RNQ(+)] maintenance has been conserved, because Hdj1 can function to maintain Rnq1 in an aggregated form in place of Sis1, but Hdj2 cannot. An extended glycine-rich region of Sis1, composed of a region rich in phenylalanine residues (G/F) and another rich in methionine residues (G/M), is critical for prion maintenance. Single amino acid alterations in a short stretch of amino acids of the G/F region of Sis1 that are absent in the otherwise highly conserved G/F region of Ydj1 cause defects in prion maintenance. However, there is some functional redundancy within the glycine-rich regions of Sis1, because a deletion of the adjacent glycine/methionine (G/M) region was somewhat defective in propagation of [RNQ(+)] as well. These results are consistent with a model in which the glycine-rich regions of Hsp40s contain specific determinants of function manifested through interaction with Hsp70s.     

The dual-specificity phosphatase hYVH1 interacts with Hsp70 and prevents heat-shock-induced cell death

hYVH1 [human orthologue of YVH1 (yeast VH1-related phosphatase)] is an atypical dual-specificity phosphatase that is widely conserved throughout evolution. Deletion studies in yeast have suggested a role for this phosphatase in regulating cell growth. However, the role of the human orthologue is unknown. The present study used MS to identify Hsp70 (heat-shock protein 70) as a novel hYVH1-binding partner. The interaction was confirmed using endogenous co-immunoprecipitation experiments and direct binding of purified proteins. Endogenous Hsp70 and hYVH1 proteins were also found to co-localize specifically to the perinuclear region in response to heat stress. Domain deletion studies revealed that the ATPase effector domain of Hsp70 and the zinc-binding domain of hYVH1 are required for the interaction, indicating that this association is not simply a chaperone-substrate complex. Thermal phosphatase assays revealed hYVH1 activity to be unaffected by heat and only marginally affected by non-reducing conditions, in contrast with the archetypical dual-specificity phosphatase VHR (VH1-related protein). In addition, Hsp70 is capable of increasing the phosphatase activity of hYVH1 towards an exogenous substrate under non-reducing conditions. Furthermore, the expression of hYVH1 repressed cell death induced by heat shock, H2O2 and Fas receptor activation but not cisplatin. Co-expression of hYVH1 with Hsp70 further enhanced cell survival. Meanwhile, expression of a catalytically inactive hYVH1 or a hYVH1 variant that is unable to interact with Hsp70 failed to protect cells from the various stress conditions. The results suggest that hYVH1 is a novel cell survival phosphatase that co-operates with Hsp70 to positively affect cell viability in response to cellular insults.     

Localization and function in endoplasmic reticulum stress tolerance of ERdj3, a new member of Hsp40 family protein

Heat shock protein 40 (Hsp40) family proteins are known to bind to Hsp70 through their J-domain and regulate the function of Hsp70 by stimulating its adenosine triphosphatase activity. In the endoplasmic reticulum (ER), there are 5 Hsp40 family proteins known so far, 3 of which were recently identified. In this report, one of the novel Hsp40 cochaperones, ERdj3, was characterized in terms of its subcellular localization, stress response, and stress tolerance of cells. By using ERdj3-specific polyclonal antibody, endogenous ERdj3 protein was shown to reside in the ER as gene transfer–mediated exogenous ERdj3. Analysis of the expression level of endogenous ERdj3 protein revealed its moderate induction in response to various ER stressors, indicating its possible action as a stress protein in the ER. Subsequently, we analyzed whether this molecule was involved in ER stress tolerance of cells, as was the case with the ER-resident Hsp70 family protein BiP. Although overexpression of ERdj3 by gene transfection could not strengthen ER stress tolerance of neuroblastoma cells, reduction of ERdj3 expression by small interfering ribonucleic acid decreased the tolerance of cells, indicating that ERdj3 might have just a marginal role in the ER stress resistance of neuroblastoma cells. In contrast, overexpression of ERdj3 notably suppressed vero toxin–induced cell death. These data suggest that ERdj3 might have diverse roles in the ER, including that of the molecular cochaperone of BiP and an as yet unknown protective action against vero toxin.     

Heat shock protein (Hsp) 40 mutants inhibit Hsp70 in mammalian cells

Heat shock protein (Hsp) 70 and Hsp40 expressed in mammalian cells had been previously shown to cooperate in accelerating the reactivation of heat-denatured firefly luciferase (Michels, A. A., Kanon, B., Konings, A. W. T., Ohtsuka, K., Bensaude, O., and Kampinga, H. H. (1997) J. Biol. Chem. 272, 33283-33289). We now provide further evidence for a functional interaction between Hsp70 and the J-domain of Hsp40 with denatured luciferase resulting in reactivation of heat-denatured luciferase within living mammalian cells. The stimulating effect of Hsp40 on the Hsp70-mediated refolding is lost when the proteins cannot interact as accomplished by their expression in different intracellular compartments. Likewise, the cooperation between Hsp40 and Hsp70 is lost by introduction of a point mutation in the conserved HPD motif of the Hsp40 J-domain or by deletion of the four C-terminal amino acids of Hsp70 (EEVD motif). Most strikingly, co-expression of a truncated protein restricted to the J-domain of Hsp40 had a dominant negative effect on Hsp70-facilitated luciferase reactivation. Taken together, these experiments indicate for the first time that the Hsp70/Hsp40 chaperones functionally interact with a heat-denatured protein within mammalian cells. The dominant negative effect of the Hsp40 J-domain on the activity of Hsp70 demonstrates the importance of J-domain-containing proteins in Hsp70-dependent processes.     

Saccharomyces cerevisiae Hsp104 enhances the chaperone capacity of human cells and inhibits heat stress-induced proapoptotic signaling

Hsp104, the most potent thermotolerance factor in Saccharomyces cerevisiae, is an unusual molecular chaperone that is associated with the dispersal of aggregated, non-native proteins in vivo and in vitro. The close cooperation between Hsp100 oligomeric disaggregases and specific Hsp70 chaperone/cochaperone systems to refold and reactivate heat-damaged proteins has been dubbed a "bichaperone network". Interestingly, animal genomes do not encode a Hsp104 ortholog. To investigate the biochemical and biological consequences of introducing into human cells a stress tolerance factor that has protein refolding capabilities distinct from those already present, Hsp104 was expressed as a transgene in a human leukemic T-cell line (PEER). Hsp104 inhibited heat-shock-induced loss of viability in PEER cells, and this action correlated with reduced procaspase-3 cleavage but not with reduced c-Jun N-terminal kinase phosphorylation. Hsp104 cooperated with endogenous human Hsp70 and Hsc70 molecular chaperones and their J-domain-containing cochaperones Hdj1 and Hdj2 to produce a functional hybrid bichaperone network capable of refolding aggregated luciferase. We also established that Hsp104 shuttles across the nuclear envelope and enhances the chaperoning capacity of both the cytoplasm and nucleoplasm of intact cells. Our results establish the fundamental properties of protein disaggregase function in human cells with implications for the use of Hsp104 or related proteins as therapeutic agents in diseases associated with protein aggregation.     

<Superscript>1</Superscript>H, <Superscript>15</Superscript>N and <Superscript>13</Superscript>C resonance assignments of the J-domain of co-chaperone Sis1 from <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Protein folding in the cell is usually aided by molecular chaperones, from which the Hsp70 (Hsp?=?heat shock protein) family has many important roles, such as aiding nascent folding and participating in translocation. Hsp70 has ATPase activity which is stimulated by binding to the J-domain present in co-chaperones from the Hsp40 family. Hsp40s have many functions, as for instance the binding to partially folded proteins to be delivered to Hsp70. However, the presence of the J-domain characterizes Hsp40s or, by this reason, as J-proteins. The J-domain alone can stimulate Hsp70 ATPase activity. Apparently, it also maintains the same conformation as in the whole protein although structural information on full J-proteins is still missing. This work reports the ¹H, ¹⁵N and ¹³C resonance assignments of the J-domain of a Hsp40 from Saccharomyces cerevisiae, named Sis1. Secondary structure and order parameter prediction from chemical shifts are also reported. Altogether, the data show that Sis1 J-domain is highly structured and predominantly formed by α-helices, results that are in very good agreement with those previously reported for the crystallographic structure.     

Hsp25 and Hsp70 in rodent tumors treated with doxorubicin and lovastatin

Heat shock protein 27 (Hsp27) and Hsp70 have been involved in resistance to anticancer drugs in human breast cancer cells growing in vitro and in vivo. In this study, we examined the expression of Hsp25 (the rodent homologue to human Hsp27) and Hsp70 in 3 different rodent tumors (a mouse breast carcinoma, a rat sarcoma, and a rat lymphoma maintained by subcutaneous passages) treated in vivo with doxorubicin (DOX) and lovastatin (LOV). All tumors showed massive cell death under control untreated conditions, and this massive death increased after cytotoxic drug administration. In this study, we show that this death was due to classic apoptosis. The tumors also showed isolated apoptotic cells between viable tumor cells, and this occurred more significantly in the lymphoma. The tumor type that was more resistant to cell death was the sarcoma, and this was found in sarcomas growing both under control conditions and after cytotoxic drug administration. Moreover, sarcomas showed the highest expression levels of Hsp25 in the viable tumor cells growing under untreated conditions, and these levels increased after DOX and LOV administration. After drug treatment, only sarcoma tumor cells showed a significant increase in Hsp70. In other words, sarcomas were the tumors with lower cell death, displayed a competent Hsp70 and Hsp25 response with nuclear translocation, and had the highest levels of Hsp25. In sarcomas, Hsp25 and Hsp70 were found in viable tumor cells located around the blood vessels, and these areas showed the most resistant tumor cell phenotype after chemotherapy. In addition, Hsp25 expression was found in endothelial cells as unique feature revealed only in lymphomas. In conclusion, our study shows that each tumor type has unique features regarding the expression of Hsp25 and Hsp70 and that these proteins seem to be implicated in drug resistance mainly in sarcomas, making these model systems important to perform more mechanistic studies on the role of Hsps in resistance to certain cytotoxic drugs.     

Kinetics of chaperone activity of proteins Hsp70 and Hdj1 in human leukemia U-937 cells after preconditioning with thermal shock or compound U-133

Kinetics of the chaperone activity of proteins Hsp70 and Hdj1 were analyzed in human U-937 promonocytes during their response to heat shock or to treatment with the echinochrome triacetyl glucoside derivative U-133. To measure the chaperone activity of both proteins, a special test was developed for their recognition and binding of a denatured protein. Using this test, the chaperone activity could be concurrently estimated in large numbers of cellular or tissue extracts. We also estimated the contents of both chaperones in cells by immunoblotting. The values for contents of Hsp70 and Hdj1 obtained by two independent test systems coincided, and this suggested that the substrate-binding activity could change proportionally to the chaperone content in the protein mixture. Therefore, the test developed by us can be employed for high throughput screening of drugs activating cellular chaperones. The analysis of quantity and activity of two cellular chaperones during the cell response to heat stress or to the drug-like substance U-133 showed that both factors caused the accumulation of chaperones with similar kinetics. We conclude that the efficiency of drug preconditioning could be close to the efficiency of hyperthermia and that the high activity of chaperones could be retained in human cells for no less than 1.5 days.     

Endothelial cells downregulate expression of the 70 kDa heat shock protein during hypoxia

Hsp70 is induced by hypoxia in most mammalian cell types and contributes to their ability to survive hypoxic episodes. However, little is known about Hsp70 expression in the hypoxia-tolerant endothelial cells (ECs). We investigated the effect of hypoxia on Hsp70 in human microvascular endothelial HMEC-1 cells. Reduction of pO(2) to 2.5% of normal for 20 h stimulated lactate production and the activity of glycolytic enzymes. This metabolic adaptation to hypoxia was accompanied by a remarkable reduction of Hsp70 on the protein level and on the mRNA level. Approximately 12 h after the hypoxic period Hsp70 expression reached pre-hypoxia levels again. Since ECs are adapted to the low oxygen tension of the vasculature they are confronted with a supraphysiological oxygen level during in vitro culture. We suppose that the high Hsp70 under these conditions reflects a stress response which disappears at the more physiological reduced oxygen tension during hypoxia.     

Cloning and characterization of a new soluble murine J-domain protein that stimulates BiP, Hsc70 and DnaK ATPase activity with different efficiencies

Hsp70s perform many functions in the cell through their ATPase activity that is stimulated by a genuine partner that contains a highly conserved so called J-domain. Here we report the cloning and characterization of a new J-domain protein named MmDjC7. The complete cDNA encodes a putative soluble 22 kDa protein that contains a conserved J-domain, but lacks the G/F- and C-rich regions found in the bacterial Escherichia coli DnaJ. Northern analysis revealed that mmDjC7 mRNA (0.9 kb) is most abundant in the heart and liver tissues. Recombinant hexahistidine tagged MmDjC7 (25 kDa) was efficiently expressed in E. coli and purified to homogeneity. MmDjC7 stimulates the ATPase activity of murine BiP, Hsc70 and E. coli DnaK, albeit with very different molar ratios that vary from 1:2 (for BiP/MmDjC7) to 1:10 (for DnaK/MmDjC7). MmDjC7 thus appears to be a new J-domain protein that can possibly interact with more than one Hsp70.     

Structure of the functional fragment of auxilin required for catalytic uncoating of clathrin-coated vesicles

The three-dimensional structure of the C-terminal 20 kDa portion of auxilin, which consists of the clathrin binding region and the C-terminal J-domain, has been determined by NMR. Auxilin is an Hsp40 family protein that catalytically supports the uncoating of clathrin-coated vesicles through recruitment of Hsc70 in an ATP hydrolysis-driven process. This 20 kDa auxilin construct contains the minimal sequential region required to uncoat clathrin-coated vesicles catalytically. The tertiary structure consists of six helices, where the first three are unique to auxilin and believed to be important in the catalytic uncoating of clathrin. The last three helices correspond to the canonical J-domain of Hsp40 proteins. The first helix, helix 1, which contains a conserved FEDLL motif believed to be necessary for clathrin binding, is transient and not packed against the rest of the structure. Helix 1 is joined to helix 2 by a flexible linker. Helix 2 packs loosely against the J-domain surface, whereas helix 3 packs tightly and makes critical contributions to the J-domain core. A long insert loop, also unique to the auxilin J-domain, is seen between helix 4 and helix 5. Comparison with a previously reported structure of auxilin containing only helices 3-6 shows a significant difference in the invariant HPD segment of the J-domain. The region where helix 1 is located corresponds to the expected region of the unstructured G/F-rich domain seen in DnaJ, i.e., the canonical N-terminal J-domain protein. In contrast, the location of helix 1 differs from the substrate binding regions of two other Hsp40 proteins, Escherichia coli Hsc20 and viral large T antigen. The variety of biological functions performed by Hsp40 proteins such as auxilin, as well as the observed differences in the structure and function of their substrate binding regions, supports the notion that Hsp40 proteins act as target-specific adaptors that recruit their more general Hsp70 partners to specific biological roles.     

The chaperone network connected to human ribosome-associated complex

Mammalian ribosome-associated complex (mRAC), consisting of the J-domain protein MPP11 and the atypical Hsp70 homolog (70-homolog) Hsp70L1, can partly complement the function of RAC, which is the homologous complex from Saccharomyces cerevisiae. RAC is the J-domain partner exclusively of the 70-homolog Ssb, which directly and independently of RAC binds to the ribosome. We here show that growth defects due to mRAC depletion in HeLa cells resemble those of yeast strains lacking RAC. Functional conservation, however, did not extend to the 70-homolog partner of mRAC. None of the major human 70-homologs was able to complement the growth defects of yeast strains lacking Ssb or was bound to ribosomes in an Ssb-like manner. Instead, our data suggest that mRAC was a specific partner of human Hsp70 but not of its close homolog Hsc70. On a mechanistic level, ATP binding, but not ATP hydrolysis, by Hsp70L1 affected mRAC's function as a J-domain partner of Hsp70. The combined data indicate that, while functionally conserved, yeast and mammalian cells have evolved distinct solutions to ensure that Hsp70-type chaperones can efficiently assist the biogenesis of newly synthesized polypeptide chains.     

Heat shock protein 40/DjB1 is required for thermotolerance in early phase

DjB1 (Hsp40/DnajB1/Hdj1) is a member of the Hsp40/DnaJ family that functions as a co-chaperone of mammalian Hsp70s. DjB1 recognizes substrate proteins and facilitates the ATPase activity of Hsp70. We generated DjB1 deficient mice. The DjB1(-/-) mice were viable and fertile with no obvious abnormalities, thus indicating that DjB1 is dispensable for development and viability. No difference was found between the DjB1(-/-) and wild-type peritoneal macrophages regarding resistance against various types of apoptosis-inducing reagents. However, DjB1(-/-) cells showed decreased thermotolerance in the early phase after mild heat treatment, but not in the late phase. After the heat treatment, Hsp70 was induced similarly in wild-type and DjB1(-/-) cells. Immunofluorescence staining of wild-type cells revealed the accumulation of DjB1 and Hsc70 in the nucleus after heat treatment. DjB1 also accumulated in the centrosome. The accumulation of Hsc70 in the nucleus was also observed in DjB1(-/-) cells. These results suggest that the impaired thermotolerance of DjB1(-/-) cells is not due to a mislocation of the Hsp70 family.     

Induction of apoptosis in murine myeloma cells NS0/1, transfected with the gene for the basic heat shock protein HSP70i

Murine myelomas are rare cell variants deficient in inducible isoform of Hsp70 that protects cells from injury. In these cells Hsp70 is absent and is not induced under stress conditions. In this study myeloma cells NS0/1 were transfected with hsp70, and their susceptibility to apoptosis was challenged by serum deprivation or hydrogen peroxide. Expression of Hsp70 in NS0/1 cells made them more resistant to apoptosis in serum-free medium but did not affect their response to hydrogen peroxide. Hsp70 involvement in the protection of myeloma cells from apoptosis caused by different agents is discussed.     

Toc12, a novel subunit of the intermembrane space preprotein translocon of chloroplasts

Translocation of proteins across membranes is essential for the biogenesis of each cell and is achieved by proteinaceous complexes. We analyzed the translocation complex of the intermembrane space from chloroplasts and identified a 12-kDa protein associated with the Toc machinery. Toc12 is an outer envelope protein exposing a soluble domain into the intermembrane space. Toc12 contains a J-domain and stimulates the ATPase activity of DnaK. The conformational stability and the ability to stimulate Hsp70 are dependent on a disulfide bridge within the loop region of the J-domain, suggesting a redox-regulated activation of the chaperone. Toc12 is associated with Toc64 and Tic22. Its J-domain recruits the Hsp70 of outer envelope membrane to the intermembrane space translocon and facilitates its interaction to the preprotein.