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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 products of the Escherichia coli dnaK, dnaJ, and grpE heat shock genes have been previously shown to be essential for bacteriophage lambda DNA replication at all temperatures and for bacterial survival under certain conditions. DnaK, the bacterial heat shock protein hsp70 analogue and putative chaperonin, possesses a weak ATPase activity. Previous work has shown that ATP hydrolysis allows the release of various polypeptides complexed with DnaK. Here we demonstrate that the ATPase activity of DnaK can be greatly stimulated, up to 50-fold, in the simultaneous presence of the DnaJ and GrpE heat shock proteins. The presence of either DnaJ or GrpE alone results in a slight stimulation of the ATPase activity of DnaK. The action of the DnaJ and GrpE proteins may be sequential, since the presence of DnaJ alone leads to an acceleration in the rate of hydrolysis of the DnaK-bound ATP. The presence of GrpE alone increases the rate of release of bound ATP or ADP without affecting the rate of hydrolysis. The stimulation of the ATPase activity of DnaK may contribute to its more efficient recycling, and it helps explain why mutations in dnaK, dnaJ, or grpE genes often exhibit similar pleiotropic phenotypes.
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PMID:Escherichia coli DnaJ and GrpE heat shock proteins jointly stimulate ATPase activity of DnaK. 182 68

DnaK, DnaJ, and GrpE heat shock proteins of Escherichia coli activate site-specific DNA binding by the RepA replication initiator protein of plasmid P1 in a reaction dependent on ATP and Mg2+. We previously showed that GrpE is essential for in vitro RepA activation specifically at about 1 microM free Mg2+. In this paper, we demonstrate that GrpE lowers the requirement of DnaK ATPase for Mg2+, resulting in a large stimulation of ATP hydrolysis at about 1 microM Mg2+ with and without DnaJ and RepA. In contrast to its effect on the Mg2+ requirement, GrpE increases the ATP requirement for DnaK ATPase and dramatically lowers the affinity of DnaK for ATP in the absence of Mg2+. We propose that GrpE not only lowers the affinity of DnaK for nucleotide but, by increasing affinity of DnaK for Mg2+, also weakens the interactions of Mg2+ with nucleotide prior to its release.
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PMID:GrpE alters the affinity of DnaK for ATP and Mg2+. Implications for the mechanism of nucleotide exchange. 759 37

In Escherichia coli the heat shock response is under the positive control of the sigma 32 transcription factor. Three of the heat shock proteins, DnaK, DnaI, and GrpE, play a central role in the negative autoregulation of this response at the transcriptional level. Recently, we have shown that the DnaK and DnaJ proteins can compete with RNA polymerase for binding to the sigma 32 transcription factor in the presence of ATP, by forming a stable DnaJ-sigma 32-DnaK protein complex. Here, we report that DnaJ protein can catalytically activate DnaK's ATPase activity. In addition, DnaJ can activate DnaK to bind to sigma 32 in an ATP-dependent reaction, forming a stable sigma 32-DnaK complex. Results obtained with two DnaJ mutants, a missense and a truncated version, suggest that the N-terminal portion of DnaJ, which is conserved in all family members, is essential for this activation reaction. The activated form of DnaK binds preferentially to sigma 32 versus the bacteriophage lambda P protein substrate.
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PMID:The DnaJ chaperone catalytically activates the DnaK chaperone to preferentially bind the sigma 32 heat shock transcriptional regulator. 760 76

We have reconstituted an ATP-dependent protein folding machinery using purified yeast cytosolic proteins. The S. cerevisiae Hsp70 Ssa1p and the DnaJ homolog Ydj1p refolded denatured firefly luciferase. In E. coli, efficient refolding of luciferase requires the Hsp70 DnaK and two modulators, DnaJ and GrpE, that synergistically stimulate its ATPase activity. Exchanging DnaJ homologs between the S. cerevisiae and E. coli systems revealed that their ability to stimulate Hsp70 ATPase activity was conserved. In contrast, GrpE further stimulated only DnaK's ATPase activity. Efficient refolding of luciferase by Ssa1p and DnaJ, but not by DnaK and Ydj1p, suggests that a compatible Hsp70/DnaJ homolog pair can act as a protein folding machinery.
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PMID:Conserved ATPase and luciferase refolding activities between bacteria and yeast Hsp70 chaperones and modulators. 763 93

Using the native proteins lambda P, lambda O, delta 32, and RepA, as well as permanently unfolded alpha-carboxymethylated lactalbumin, we show that DnaK and DnaJ molecular chaperones possess differential affinity toward these protein substrates. In this paper we present evidence that the DnaK protein binds not only to short hydrophobic peptides, which are in an extended conformation, but also efficiently recognizes large native proteins (RepA, lambda P). The best substrate for either the DnaK or DnaJ chaperone is the native P1 coded replication RepA protein. The native delta 32 transcription factor binds more efficiently to DnaJ than to DnaK, whereas unfolded alpha-carboxymethylated lactalbumin or native lambda P binds more efficiently to DnaK than to the DnaJ molecular chaperone. The presence of nucleotides does not change the DnaJ affinity to any of the tested protein substrates. In the case of DnaK, the presence of ATP inhibits, while a nonhydrolyzable ATP analogues markedly stimulates the binding of DnaK to all of these various protein substrates. ADP has no effect on these reactions. In contrast to substrate protein binding, DnaK binds to the DnaJ chaperone protein in a radically different manner, namely ATP stimulates whereas a nonhydrolyzable ATP analogue inhibits the DnaK-DnaJ complex formation. Moreover, the DnaKc94 mutant protein lacking 94 amino acids from its C-terminal domain, which still possesses at ATPase activity and forms a transient complex with protein substrates, does not interact with DnaJ protein. We conclude that the DnaK-ADP form, derived from ATP hydrolysis, possesses low affinity to the protein substrates but can efficiently interact with DnaJ molecular chaperone.
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PMID:Divergent effects of ATP on the binding of the DnaK and DnaJ chaperones to each other, or to their various native and denatured protein substrates. 764 5

hsp70 proteins of both eukaryotes and prokaryotes possess both ATPase and peptide binding activities. These two activities are crucial for the chaperone activity of hsp70 proteins. The activity of DnaK, the primary hsp70 of Escherichia coli, is modulated by the GrpE and DnaJ proteins. In the yeast Saccharomyces cerevisiae, the predominant cytosolic hsp70, Ssa1p, interacts with a DnaJ homologue, Ydj1p. In order to better understand the function of the Ssa1p/Ydj1p chaperone, the effects of polypeptide substrates and Ydj1p on Ssa1p ATPase activity were assessed using a combination of steady-state kinetic analysis and single turnover substrate hydrolysis experiments. Polypeptide substrates and Ydj1p both serve to stimulate ATPase activity of Ssa1p. The two types of effector are biochemically distinct, each conferring a characteristic K+ dependence on Ssa1p ATPase activity. However, in single turnover ATP hydrolysis experiments, both polypeptide substrates and Ydj1p destabilized the ATP.Ssa1p complex through a combination of accelerated hydrolysis of bound ATP and accelerated release of ATP from Ssa1p. The acceleration of ATP release by Ydj1p is a previously unidentified function of a DnaJ homologue. In the case of Ydj1p-stimulated Ssa1p, steady-state ATPase activity is increased less than 2-fold at physiological K+ concentrations, despite a 15-fold increase in the hydrolysis of bound ATP. The primary effect of Ydj1p appears to be to disfavor an ATP form of Ssa1p. On the other hand, peptide stimulation of Ssa1p ATPase activity was enhanced at physiological K+ concentrations, supporting the idea that cycles of ATP hydrolysis play an important role in the interaction of hsp70 with polypeptide substrates. The enhanced ATP dissociation caused by both polypeptide substrates and Ydj1p may play a role in the regulation of Ssa1p chaperone activity by altering the relative abundance of ATP-and ADP-bound forms.
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PMID:The dissociation of ATP from hsp70 of Saccharomyces cerevisiae is stimulated by both Ydj1p and peptide substrates. 773 74

Hsp70 chaperons interact with protein substrates in an ATP-dependent manner to prevent aggregation and promote protein folding. For the Escherichia coli homolog DnaK, we have characterized the ATP hydrolysis cycle as well as the effects of the DnaJ and GrpE cofactors on substrate interaction to reach conclusions on the functional cycle. DnaK ATPase was stimulated by substrates (ninefold) and DnaJ (13-fold) through stimulation of the rate limiting step, gamma-phosphate cleavage (approximately tenfold slower than ADP release). Substrates stimulate ATPase after binding with high affinity (KA < 10 microM) to preformed DnaK-ATP complexes. The rapid binding kinetics lead to the conclusion that ATP-bound DnaK is the primary form initiating interaction with substrates for chaperone activity. The resulting DnaK-ATP-substrate complexes, however, are also characterized by rapid dissociation of bound substrate, but can be stabilized by hydrolysis of ATP (stimulated either by the substrate itself or DnaJ through their effects on the rate-limiting step). Stimulation of the gamma-phosphate cleavage reaction by DnaJ is much more efficient (complete conversion of bound ATP to ADP within five seconds) than that by substrates, indicating the special and important role for DnaJ in stabilization of DnaK-substrate interactions.
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PMID:The role of ATP in the functional cycle of the DnaK chaperone system. 777 67

The heat-shock 70 protein (Hsp70) chaperone family is very conserved and its prokaryotic homologue, the DnaK protein, is assumed to form one of the cellular systems for the prevention and restoration of heat-induced protein denaturation. By using anti-DnaK antibodies we purified the DnaK homologue heat-shock cognate protein (Hsc70) from calf thymus to apparent homogeneity. This protein was classified as an eukaryotic Hsc70, since (i) monoclonal antibodies against eukaryotic Hsc70 recognized it, (ii) its amino-terminal sequence showed strong homology to Hsp70s from eukaryotes and, (iii) it had an intrinsic weak ATPase activity that was stimulated by various peptide substrates. We show that this calf thymus Hsc70 protein protected calf thymus DNA polymerases alpha and epsilon as well as Escherichia coli DNA polymerase III and RNA polymerase from heat inactivation and could reactivate these heat-inactivated enzymes in an ATP-hydrolysis dependent manner, likely leading to the dissociation of aggregates formed during heat inactivation. In contrast to this, DnaK protein was exclusively able to protect and to reactivate the enzymes from E.coli but not from eukaryotic cells. Finally, the addition of calf thymus DnaJ co-chaperone homologue reduced the amount of Hsc70 required for reactivation at least 10-fold.
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PMID:Calf thymus Hsc70 protein protects and reactivates prokaryotic and eukaryotic enzymes. 779 40

The universally conserved DnaK and DnaJ molecular chaperone proteins bind in a coordinate manner to protein substrates to prevent aggregation, to disaggregate proteins, or to regulate proper protein function. To further examine their synergistic mechanism of action, we constructed and characterized two DnaJ deletion proteins. One has an 11-amino-acid internal deletion that spans amino acid residues 77-87 (DnaJ delta 77-87) and the other amino acids 77-107 (DnaJ delta 77-107). The DnaJ delta 77-87 mutant protein, was normal in all respects analyzed. The DnaJ delta 77-107 mutant protein has its entire G/F (Gly/Phe) motif deleted. This motif is found in most, but not all DnaJ family members. In vivo, DnaJ delta 77-107 supported bacteriophage lambda growth, albeit at reduced levels, demonstrating that at least some protein function was retained. However, DnaJ delta 77-107 did not exhibit other wild type properties, such as proper down-regulation of the heat-shock response, and had an overall poisoning effect of cell growth. The purified DnaJ delta 77-107 protein was shown to physically interact and stimulate DnaK's ATPase activity at wild type levels, unlike the previously characterized DnaJ259 point mutant (DnaJH33Q). Moreover, both DnaJ delta 77-107 and DnaJ259 bound to substrate proteins, such as sigma 32, at similar affinities as DnaJ+. However, DnaJ delta 77-107 was found to be largely defective in activating the ATP-dependent substrate binding mode of DnaK. In vivo, the ability of the mutant DnaJ proteins to down-regulate the heat-shock response was correlated only with their in vitro ability to activate DnaK to bind sigma 32, in an ATP-dependent manner, and not with their ability to bind sigma 32. We conclude, that although the G/F motif of DnaJ does not directly participate in the stimulation of DnaK's ATPase activity, nevertheless, it is involved in an important manner in modulating DnaK's substrate binding activity.
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PMID:The conserved G/F motif of the DnaJ chaperone is necessary for the activation of the substrate binding properties of the DnaK chaperone. 783 43

The DnaK (Hsp70), DnaJ, and GrpE heat shock proteins of Escherichia coli constitute a cellular chaperone system for protein folding. Substrate interactions are controlled by the ATPase activity of DnaK which itself is regulated by the nucleotide exchange factor GrpE. To understand the structure-function relationship of this chaperone system, the quaternary structures of DnaK, GrpE, and DnaK-GrpE complexes were analyzed by gel filtration chromatography, dynamic light scattering, analytical ultracentrifugation, and native gel electrophoresis. GrpE formed dimers in solution. DnaK formed monomers, dimers, and higher mole mass oligomers, the equilibrium between these forms being dependent on the DnaK concentration. The behavior of DnaK and GrpE in gel filtration and dynamic light scattering suggested elongated shapes of both molecules. In the absence of added nucleotides, DnaK and GrpE formed stable complexes containing one molecule of DnaK and two molecules of GrpE. A 44-kDa N-terminal ATPase fragment of DnaK also formed complexes with GrpE with the same 1:2 stoichiometry. DnaK-GrpE complex formation was unaffected by elimination of DnaK-bound nucleotides or addition of saturating concentrations of a DnaK peptide substrate. These findings allow the correlation of DnaK-GrpE interactions with a role for GrpE in the functional cycle of the DnaK chaperone system.
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PMID:The DnaK chaperone system of Escherichia coli: quaternary structures and interactions of the DnaK and GrpE components. 783 48


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