EC:3.6.1.3 - FACTA Search

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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The mitochondrial heat shock protein Hsp70 is essential for import of nuclear-encoded proteins, involved in both unfolding and membrane translocation of preproteins. mtHsp70 interacts reversibly with Tim44 of the mitochondrial inner membrane, yet the role of this interaction is unknown. We analysed this role by using two yeast mutants of mtHsp70 that differentially influenced its interaction with Tim44. One mutant mtHsp70 (Ssc1-2p) efficiently bound preproteins, but did not show a detectable complex formation with Tim44; the mitochondria imported loosely folded preproteins with wild-type kinetics, yet were impaired in unfolding of preproteins. The other mutant Hsp70 (Ssc1-3p') bound both Tim44 and preproteins, but the mitochondria did not import folded polypeptides and were impaired in import of unfolded preproteins; Ssc1-3p' was defective in its ATPase domain and did not undergo a nucleotide-dependent conformational change, resulting in permanent binding to Tim44. The following conclusions are suggested. (i) The import of loosely folded polypeptides (translocase function of mtHsp70) does not depend on formation of a detectable Hsp70-Tim44 complex. Two explanations are possible: a trapping mechanism by soluble mtHsp70, or a weak/very transient interaction of Ssc1-2p with Tim44 that leads to a weak force generation sufficient for import of loosely folded, but not folded, polypeptides. (ii) Import of folded preproteins (unfoldase function of mtHsp70) involves a reversible nucleotide-dependent interaction of mtHsp70 with Tim44, including a conformational change in mtHsp70. This is consistent with a model that the dynamic interaction of mtHsp70 with Tim44 generates a pulling force on preproteins which supports unfolding during translocation.
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PMID:Differential requirement for the mitochondrial Hsp70-Tim44 complex in unfolding and translocation of preproteins. 865 64

Chaperonin cpn60 and heat shock protein hsp70 couple their ATPase cycles to the binding and dissociation of non-native proteins. cpn60 is a cylindrical tetradecamer that uses a co-protein (cpn10) and both positive and negative cooperativity to alter the properties of its two voluminous protein-binding chambers in an alternating, asymmetric cycle. In the hsp70 reaction cycle, short segments of polypeptide bind rapidly and weakly to the ATP state, so triggering hydrolysis and consequent stabilization of the complex. Co-proteins of the hsp40 family enhance this partial reaction, whereas nucleotide exchange factors destabilize the product. The individual steps in the two energy transducing mechanisms have only recently been elucidated and provide us with a more detailed picture of the way in which these chaperones can influence the folding, assembly and translocation of protein structures in the cell.
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PMID:Molecular chaperones in protein folding and translocation. 869 72

70-kDa heat shock protein (Hsp70) molecular chaperones are ATPases that participate in protein folding by regulating protein-protein interactions. ATP binds to the highly conserved amino-terminal domain, whereas polypeptides bind to the less conserved carboxyl-terminal domain. These domains are functionally coupled. Polypeptides were previously shown to dissociate from Hsp70s upon ATP binding and to stimulate ATPase activity. We probed the structure of the yeast cytosolic Hsp70 Ssa1p using limited proteolysis to determine whether the conformations of its nucleotide and polypeptide binding domains are also coupled. Ssa1p adopted three distinct conformations, nucleotide-free, ADP-dependent, and ATP-dependent. Complete conformational changes required K+ and Mg2+. Using amino-terminal sequencing, ATP-agarose chromatography, and a carboxyl-terminal-specific antibody, we mapped the locations of the major proteolytic fragments. Nucleotides altered the conformations of both the nucleotide and polypeptide binding domains. Similarly, a polypeptide altered the conformations of both domains. These results indicate that the conformations of the nucleotide and polypeptide binding domains are coupled.
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PMID:Conformations of the nucleotide and polypeptide binding domains of a cytosolic Hsp70 molecular chaperone are coupled. 870 42

The immunosuppressants cyclosporin A (CyA), FK-506, and rapamycin (RAP) have multiple actions on target cells that appear to be mediated by interaction of drug-binding protein complexes. Both FK-506 and CyA, but not RAP, inhibit the Ca2(+)-dependent phosphatase, calcineurin, and in so doing have been found to inhibit Na(+)-K(+)-ATPase activity in various nephron segments. Of interest, FK-506 and RAP, but not CyA, are bound by the steroid receptor-associated FK-506-binding heat shock protein of 56 kDa, HSP56. To determine the physiological effect of this interaction on a steroid-mediated phenomenon, the effect of these agents on steroid-mediated Na+ transport in A6 cells was investigated. Aldosterone stimulation of Na+ transport and Na(+)-K(+)-ATPase activity are significantly inhibited by prolonged incubation with FK-506 and RAP. Although CyA inhibits basal Na(+)-K(+)-ATPase activity, it has no effect on aldosterone-induced Na+ transport or the aldosterone-induced increase in Na(+)-K(+)-ATPase activity. FK-506 inhibits the aldosterone-induced synthesis of G alpha i-3 protein but has no effect on glucocorticoid receptor number as quantified by Western blotting. The results suggest that FK-506 and RAP inhibit steroid-mediated Na+ transport at some pretranslational site. The common interaction of these agents with the steroid receptor-associated HSP56 might account for these findings.
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PMID:FK-506 and rapamycin but not cyclosporin inhibit aldosterone-stimulated sodium transport in A6 cells. 876 46

Cardiomyoplasty has the potential to become an alternative therapy for congestive heart failure patients and is presently in Phase III clinical trials. In experimental studies, it is necessary to use an animal with muscle characteristics that resemble those of humans. Therefore, the purpose of this study was to compare morphological and biochemical characteristics of the latissimus dorsi muscle (LDM) of three common large mammals with those of human. Of the three mammals studied, the goat had the most overall similarities to the human when comparing mitochondrial capacity, percent fiber types, fiber areas, myofibrillar (MF)-AT-Pase activity, and 72-kDa heat shock protein (HSP) content. The pig was dissimilar to the human in its fiber-type arrangement, glycolytic capacity, percent fiber type, MF-ATPase activity, and HSP-72 content. The dog differed from the human in that it had high-mitochondrial enzyme activity, a fiber-type profile consisting of all high-aerobic fibers, and fiber cross-sectional areas that were nearly half those of humans. These findings show that the LDM of the goat most resembles that of the human.
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PMID:Cardiomyoplasty: comparison of latissimus dorsi muscles of three large mammals with that of human. 877 32

The uncoating of clathrin-coated vesicles can be mediated in vitro by the 'uncoating ATPase' that has been identified as the constitutive 70 kDa heat shock protein (hsp70), hsc70. It is now established that the activity of hsp70 proteins can be regulated by another family of molecular chaperones, the DnaJ family. In this study, we have investigated the effects of DnaJ-like proteins (the human neuron-specific proteins HSJ1a and HSJ1b) on clathrin uncoating. In order to measure the kinetics of clathrin release from coated vesicles, we have developed a quantitative, two-site ELISA for clathrin triskelions and demonstrated that stoichiometric amounts of HSJ1 proteins inhibit the initial burst of hsc70-mediated clathrin uncoating by over 40%. This inhibition is not a consequence of ADP binding by hsc70 or the aggregation of hsc70, but correlates with an increase in the hsc70 associated with the coated vesicle fraction, suggesting that the inhibition is a consequence of a non-productive stabilization of hsc70 with a component of the coated vesicle fraction. These results strongly suggest that HSJ1 proteins interfere with an endogenous DnaJ-like protein that is involved in uncoating. Recent evidence suggests that the brain-specific vesicle-associated protein auxilin could play such a role. Although we find no evidence for auxilin in our coated vesicle preparation, our results predict that an auxilin-like protein will be a general factor in clathrin uncoating.
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PMID:Inhibition of hsc70-catalysed clathrin uncoating by HSJ1 proteins. 887 Jun 55

A secondary structure has been predicted for the heat shock protein HSP90 family from an aligned set of homologous protein sequences by using a transparent method in both manual and automated implementation that extracts conformational information from patterns of variation and conservation within the family. No statistically significant sequence similarity relates this family to any protein with known crystal structure. However, the secondary structure prediction, together with the assignment of active site positions and possible biochemical properties, suggest that the fold is similar to that seen in N-terminal domain of DNA gyrase B (the ATPase fragment).
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PMID:A predicted consensus structure for the N-terminal fragment of the heat shock protein HSP90 family. 909 46

Saccharomyces cerevisiae has a single integral plasma membrane heat shock protein (Hsp). This Hsp30 is induced by several stresses, including heat shock, ethanol exposure, severe osmostress, weak organic acid exposure and glucose limitation. Plasma membrane H(+)-ATPase activities of heat shocked and weak acid-adapted, hsp30 mutant and wild-type cells, revealed that Hsp30 induction leads to a downregulation of the stress-stimulation of this H(+)-ATPase. Plasma membrane H(+)-ATPase activity consumes a substantial fraction of the ATP generated by the cell, a usage that will be increased by the H(+)-ATPase stimulation occurring with several Hsp30-inducing stresses. Hsp30 might therefore provide an energy conservation role, limiting excessive ATP consumption by plasma membrane H(+)-ATPase during prolonged stress exposure or glucose limitation. Consistent with the role of Hsp30 being energy conservation, Hsp30 null cultures give lower final biomass yields. They also have lower ATP levels, consistent with higher H(+)-ATPase activity, at the glucose exhaustion stage of batch fermentations (diauxic lag), when Hsp30 is normally induced. Loss of Hsp30 does not affect several stress tolerances but it extends the time needed for cells to adapt to growth under several stressful conditions where the maintenance of homeostasis will demand an unusually high usage of energy, hsp30 is the first yeast gene identified as both weak organic acid-inducible and assisting the adaptation to growth in the presence of these acids.
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PMID:Hsp30, the integral plasma membrane heat shock protein of Saccharomyces cerevisiae, is a stress-inducible regulator of plasma membrane H(+)-ATPase. 925 Mar 91

Proteins associated with the cell wall peptidoglycan (CW-Pr) of Mycobacterium tuberculosis H37Ra were isolated to evaluate their immunoreactivity and immunoprophylactic properties against experimental tuberculosis. Chemical treatment of the cell wall with trifluoromethanesulfonic acid: anisole (2:1) resulted in the release of three proteins of 71, 60 and 45 kDa as resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A comparative study of immune responses elicited to individual proteins in mice immunized with CW-Pr emulsified in incomplete Freund's adjuvant showed the 71-kDa protein to be the most immunoreactive antigen. This 71-kDa protein was found to cross-react with the 70-kDa heat shock protein from M. leprae and possessed ATPase activity. Mice immunized with the 71-kDa protein exhibited significantly higher immune responses, on the basis of T and B cell reactivity, as compared to a M. bovis Bacillus Calmette Guerin (BCG)-vaccinated group. The culture supernatants collected from 71-kDa stimulated lymphocytes stimulated exhibited increased interferon-gamma and interleukin-2 production. The protective efficacy of the 71-kDa protein in comparison to BCG was determined by challenging the mice with a virulent strain M. tuberculosis H37Rv. The 71-kDa protein was found to be more protective in animals challenged at 8 and 16 weeks post immunization, shown by increased survival rates and decreased viable bacilli counts in the target organs as compared to BCG-vaccinated animals.
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PMID:Immunoprophylactic properties of 71-kDa cell wall-associated protein antigen of Mycobacterium tuberculosis H37Ra. 925 66

A number of protein reactive compounds, including the thiol reagents diamide and arsenite, are known inducers of heat shock protein (HSP) synthesis and thermotolerance. These compounds are thought to damage cellular protein, which has been proposed to serve as the signal for induction. The specific mechanism of protein damage and its relation to thermal denaturation are unknown. The Ca2+-ATPase of sarcoplasmic reticulum, a membrane protein that contains 24 cys residues, was used to determine the effect of diamide, arsenite, N-ethylmaleimide (NEM), and the cys-specific probes Br-DMC and IAEDANS, which label one or two specific cys residues, respectively, on protein conformation and stability. The Ca2+-ATPase was chosen because diamide has been shown to affect the thermal properties of a class of membrane proteins of CHO cells (Freeman et al., 1995). The labeling of one or two thiols has no effect on activity or conformation, while more extensive reaction (but with less than approximately five to eight groups titrated) results in destabilization of the Ca2+-ATPase such that it denatures thermally at 37 degrees C. Higher levels of titration result in greater destabilization such that the protein is no longer stable at room temperature, with the production of a state similar to the thermally denatured state as assayed by activity, differential scanning calorimetry, ANS binding, and light scattering. The fractional denaturation induced by these thiol reagents, determined by the decrease in the heat absorbed during thermal denaturation, is directly proportional to inactivation of ATPase activity. Thus, inactivation of the Ca2+-ATPase by thiol reagents occurs because of denaturation not through oxidation of essential thiols. These results indicate that these thiol-specific heat shock inducers function by two mechanisms: (1) destabilization of proteins such that they thermally denature at 37 degrees C and (2) direct denaturation, apparently driven by thermal processes at room temperature, following more extensive reaction which results in extreme destabilization. We suggest that these are general mechanisms by which heat shock inducers damage proteins.
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PMID:Destabilization of the Ca2+-ATPase of sarcoplasmic reticulum by thiol-specific, heat shock inducers results in thermal denaturation at 37 degrees C. 928 92

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