Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

HslVU in Escherichia coli a new two-component ATP-dependent protease composed of two heat-shock proteins, the HslU ATPase and the HslV peptidase which is related to proteasome beta-type subunits. Here we show that the reconstituted HslVU enzyme degrades not only certain hydrophobic peptides but also various polypeptides, including insulin B-chain, casein, and carboxymethylated lactalbumin. Maximal proteolytic activity was obtained with a 1:2 molar ratio of HslV (a 250-kDa complex) to HslU (a 450-kDa complex). By itself, HslV could slowly hydrolyze these polypeptides, but its activity was stimulated 20-fold by HslU in the presence of ATP. The ATPase activity of HslU was stimulated up to 50% by the protein substrates, but not by nonhydrolyzed proteins, and this stimulation further increased 2-3-fold in the presence of HslV. Concentrations of insulin B-chain that maximally stimulated the ATPase allowed maximal rates of the B-chain hydrolysis. Furthermore, addition of increasing amounts of ADP or N-ethylmaleimide reduced ATP and protein or peptide hydrolysis in parallel. Thus, HslVU is a protein-activated ATPase as well as an ATP-dependent proteinase, and these processes appear linked. Surprisingly, the protein and peptide substrates do not compete with each other for hydrolysis. Lactacystin strongly inhibits protein degradation, but has little effect on peptide hydrolysis, while the peptide aldehydes are potent inhibitors of hydrolysis of small peptides, but have little effect on proteins. Thus, the functional requirements for ATP-dependent hydrolysis of peptides and proteins appear different.
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PMID:The heat-shock protein HslVU from Escherichia coli is a protein-activated ATPase as well as an ATP-dependent proteinase. 928 41

HslVU is an ATP-dependent protease consisting of two multimeric components: the HslU ATPase and the HslV peptidase. To gain an insight into the role of ATP hydrolysis in protein breakdown, we determined the insulin B-chain-degrading activity and assembly of HslVU in the presence of ATP and its nonhydrolyzable analogs. While beta,gamma-methylene-ATP could not support the proteolytic activity, beta,gamma-imido-ATP supported it to an extent less than 10% of that seen with ATP. Surprisingly, however, HslVU degraded insulin B-chain even more rapidly in the presence of ATPgammaS than with ATP. Furthermore, the ability of ATP and its analogs in supporting the proteolytic activity was closely correlated with their ability in supporting the oligomerization of HslU and the formation of the HslVU complex. However, ADP, which is capable of supporting the HslU oligomerization, could not support the HslVU complex formation or the proteolytic activity, suggesting that the conformation of the ADP-bound HslU oligomer is different from that of ATP-bound form. Thus, it appears that ATP-binding, but not its hydrolysis, is essential for assembly and proteolytic activity of HslVU.
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PMID:ATP binding, but not its hydrolysis, is required for assembly and proteolytic activity of the HslVU protease in Escherichia coli. 929 55

We have charterized a Mycobacterium smegmatis gene encoding a homolog of the ATP-dependent protease Lon (La). Our identification of a Lon homolog, in conjunction with our previous work, identifies M. smegmatis as the first known example of a eubacterium containing both Lon and a complete 20S proteasome (containing both alpha- and beta-subunits). Despite the significant primary sequence divergence between M. smegmatis Lon (Ms-Lon) and E. coli Lon (Ec-Lon), expression of Ms-Lon was only moderately toxic to E. coli cells. The ability of E. coli cells to tolerate expression of Ms-Lon reveals that Ms-Lon does not recognize and degrade essential E. coli proteins. We conclude that discrimination against nonsubstrate proteins is broadly conserved between Ec-Lon and Ms-Lon. Additional conservation of substrate recognition was demonstrated by the ability of Ms-Lon to degrade efficiently RcsA, a natural substrate of Ec-Lon. Purified Ms-Lon displays chymotrypsin-like specificity in peptidase assays that are stimulated by unfolded protein and supported by nonhydrolyzed nucleotide analogs. Maximal peptidase activity requires ATP or dATP. Replacement of Ms-Lon's catalytic Ser with Ala (S675A), Thr (S675T), or Cys (S675C) reduced to background levels Ms-Lon's in vitro peptidase activity. However, by employing a sensitive in vivo assay, based on the degradation of RcsA, we demonstrated that the S675C variant retained specific protease activity. Finally, variants of Ms-Lon, with substututions at or near S675, reduce the enzyme's basal ATPase activity, suggesting a structural interaction between the peptidase and ATPase active sites of Ms-Lon.
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PMID:The lon protease from Mycobacterium smegmatis: molecular cloning, sequence analysis, functional expression, and enzymatic characterization. 942 59

Acute hypertension provokes a rapid decrease in proximal tubule sodium reabsorption with a decrease in basolateral membrane sodium-potassium-ATPase activity and an increase in the density of membranes containing apical membrane sodium/hydrogen exchangers (NHE3) [Y. Zhang, A. K. Mircheff, C. B. Hensley, C. E. Magyar, D. G. Warnock, R. Chambrey, K.-P. Yip, D. J. Marsh, N.-H. Holstein-Rathlou, and A. A. McDonough. Am. J. Physiol. 270 (Renal Fluid Electrolyte Physiol. 39): F1004-F1014, 1996]. To determine the reversibility and specificity of these responses, rats were subjected to 1) elevation of blood pressure (BP) of 50 mmHg for 5 min, 2) restoration of normotension after the first protocol, or 3) sham operation. Systolic hypertension increased urine output and endogenous lithium clearance three- to fivefold within 5 min, but these returned to basal levels only 15 min after BP was restored. Renal cortex lysate was fractionated on sorbitol gradients. Basolateral membrane sodium-potassium-ATPase activity (but not subunit immunoreactivity) decreased one-third to one-half after BP was elevated and recovered after BP was normalized. After BP was elevated, 55% of the apical NHE3 immunoreactivity, smaller fractions of sodium-phosphate cotransporter immunoreactivity, and apical alkaline phosphatase and dipeptidyl-peptidase redistributed to membranes of higher density enriched in markers of the intermicrovillar cleft (megalin) and endosomes (Rab 4 and Rab 5), whereas density distributions of the apical cytoskeleton protein villin were unaltered. After 20 min of normalized BP, all the NHE3 and smaller fractions of the other apical membrane proteins returned to their original distributions. These findings suggest that the dynamic regulation of proximal tubule sodium transport by acute changes in BP may be mediated by rapid reversible regulation of sodium pump activity and relocation of apical sodium transporters.
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PMID:Reversible effects of acute hypertension on proximal tubule sodium transporters. 957 7

Lon protease homologues contain a poorly conserved N-terminal region of variable length. To better understand the role of the N-terminal region of Lon in the complicated reaction cycle of ATP-dependent protein degradation, we expressed and characterized mutants of the Lon protease from Mycobacterium smegmatis (Ms-Lon) lacking 90, 225, and 277 N-terminal residues (N-G91, N-E226, and N-I278, respectively). N-I278 displayed neither peptidase nor ATPase activity despite the fact that it was stable and soluble in vivo, had a near-wild-type CD spectrum, and the deleted residues included neither the catalytic nucleophile for peptide bond hydrolysis (S675) nor the ATP binding regions. N-G91 and N-E226 retained peptidase activities against small unstructured peptides that were stimulated, to near-wild-type levels, by the Ms-Lon substrate protein alpha-casein. By contrast, N-G91 and N-E226 retained basal ATPase activities, but these activities were only stimulated weakly by alpha-casein. Ms-Lon, N-E226, and N-G91 all exhibited low-level peptidase activity in assays containing nonhydrolyzed nucleotide analogues. However, these peptidase activities were stimulated strongly by alpha-casein in the case of Ms-Lon but weakly by alpha-casein in the cases of N-G91 and N-E226. Strikingly, despite the near-wild-type peptidase activities of N-G91 and N-E226, both were severely impaired in their degradation of the Ms-Lon protein substrates alpha-casein in vitro and RcsA in vivo. Overall, N-G91 and N-E226 displayed catalytic properties similar to Escherichia coli Lon (Ec-Lon) in the presence of the PinA inhibitor, suggesting that PinA inhibits Ec-Lon protease by inhibiting the function of Ec-Lon's N-terminal region. In vivo protease assays further revealed that, in contrast to the inactive Ms-Lon point mutant S675A, N-G91 and N-E226 did not reduce the cellular activity of RcsA. This same defect was observed previously for Ms-Lons with multiple mutations in their peptidase active sites. We conclude that proteolytically inactive mutants of Ms-Lon retain the ability to reduce the cellular activity of RcsA but that both the N-terminal region and the peptidase active site region of Ms-Lon are required for this activity of wild-type Ms-Lon. The inabilities of N-G91 and N-E226 to degrade larger protein substrates and to reduce the cellular activity of RcsA were not the result of drastic alterations in their quaternary structures. Gel filtration profiles of N-G91 and N-E226 revealed that each was primarily tetrameric, with an increased percentage of dimeric species and a decreased percentage of trimeric species relative to Ms-Lon. The observed shifts in the dimer/trimer ratios of the N-terminal truncation mutants suggest that the Ms-Lon tetramer contains two types of subunit-subunit interactions.
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PMID:Functional role of the N-terminal region of the Lon protease from Mycobacterium smegmatis. 969 72

A family of ATPases resides within the regulatory particle of the proteasome. These proteins (Rpt1-Rpt6) have been proposed to mediate substrate unfolding, which may be required for translocation of substrates through the channel that leads from the regulatory particle into the proteolytic core particle. To analyze the role of ATP hydrolysis in protein breakdown at the level of the individual ATPase, we have introduced equivalent site-directed mutations into the ATPbinding motif of each RPT gene. Non-conservative substitutions of the active-site lysine were lethal in four of six cases, and conferred a strong growth defect in two cases. Thus, the ATPases are not functionally redundant, despite their multiplicity and sequence similarity. Degradation of a specific substrate can be inhibited by ATP-binding-site substitutions in many of the Rpt proteins, indicating that they co-operate in the degradation of individual substrates. The phenotypic defects of the different rpt mutants were strikingly varied. The most divergent phenotype was that of the rpt1 mutant, which was strongly growth defective despite showing no general defect in protein turnover. In addition, rpt1 was unique among the rpt mutants in displaying a G1 cell-cycle defect. Proteasomes purified from an rpt2 mutant showed a dramatic inhibition of peptidase activity, suggesting a defect in gating of the proteasome channel. In summary, ATP promotes protein breakdown by the proteasome through multiple mechanisms, as reflected by the diverse phenotypes of the rpt mutants.
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PMID:Active site mutants in the six regulatory particle ATPases reveal multiple roles for ATP in the proteasome. 972 28

Proteolytic inactivation of key regulatory proteins is essential in eukaryotic cell-cycle control. We have identified a protease in the eubacterium Caulobacter crescentus that is indispensable for viability and cell-cycle progression, indicating that proteolysis is also involved in controlling the bacterial cell cycle. Mutants of Caulobacter that lack the ATP-dependent serine protease ClpXP are arrested in the cell cycle before the initiation of chromosome replication and are blocked in the cell division process. ClpXP is composed of two types of polypeptides, the ClpX ATPase and the ClpP peptidase. Site-directed mutagenesis of the catalytically active serine residue of ClpP confirmed that the proteolytic activity of ClpXP is essential. Analysis of mutants lacking ClpX or ClpP revealed that both proteins are required in vivo for the cell-cycle-dependent degradation of the regulatory protein CtrA. CtrA is a member of the response regulator family of two-component signal transduction systems and controls multiple cell-cycle processes in Caulobacter. In particular, CtrA negatively controls DNA replication and our findings suggest that specific degradation of the CtrA protein by the ClpXP protease contributes to G1-to-S transition in this organism.
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PMID:An essential protease involved in bacterial cell-cycle control. 975 66

The AAA domain, a conserved Walker-type ATPase module, is a feature of members of the AAA family of proteins, which are involved in many cellular processes, including vesicular transport, organelle biogenesis, microtubule rearrangement and protein degradation. The function of the AAA domain, however, has not been explained. Membrane-anchored AAA proteases of prokaryotic and eukaryotic cells comprise a subfamily of AAA proteins that have metal-dependent peptidase activity and mediate the degradation of non-assembled membrane proteins. Inactivation of an orthologue of this protease family in humans causes neurodegeneration in hereditary spastic paraplegia. Here we investigate the AAA domain of the yeast protein Yme1, a subunit of the iota-AAA protease located in the inner membrane of mitochondria. We show that Yme1 senses the folding state of solvent-exposed domains and specifically degrades unfolded membrane proteins. Substrate recognition and binding are mediated by the amino-terminal region of the AAA domain. The purified AAA domain of Yme1 binds unfolded polypeptides and suppresses their aggregation. Our results indicate that the AAA domain of Ymel has a chaperone-like activity and suggest that the AAA domains of other AAA proteins may have a similar function.
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PMID:Chaperone-like activity of the AAA domain of the yeast Yme1 AAA protease. 1019 37

The region of the Caulobacter crescentus chromosome harboring the genes for the ClpXP protease was isolated and characterized. Comparison of the deduced amino acid sequences of the C. crescentus ClpP and ClpX proteins with those of their homologues from several gram-positive and gram-negative bacteria revealed stronger conservation for the ATPase regulatory subunit (ClpX) than for the peptidase subunit (ClpP). The C. crescentus clpX gene was shown by complementation analysis to be functional in Escherichia coli. However, clpX from E. coli was not able to substitute for the essential nature of the clpX gene in C. crescentus. The clpP and clpX genes are separated on the C. crescentus chromosome by an open reading frame pointing in the opposite direction from the clp genes, and transcription of clpP and clpX was found to be uncoupled. clpP is transcribed as a monocistronic unit with a promoter (PP1) located immediately upstream of the 5' end of the gene and a terminator structure following its 3' end. PP1 is under heat shock control and is induced upon entry of the cells into the stationary phase. At least three promoters for clpX (PX1, PX2, and PX3) were mapped in the clpP-clpX intergenic region. In contrast to PP1, the clpX promoters were found to be downregulated after heat shock but were also subject to growth phase control. In addition, the clpP and clpX promoters showed different activity patterns during the cell cycle. Together, these results demonstrate that the genes coding for the peptidase and the regulatory subunits of the ClpXP protease are under independent transcriptional control in C. crescentus. Determination of the numbers of ClpP and ClpX molecules per cell suggested that ClpX is the limiting component compared with ClpP.
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PMID:Identification and transcriptional control of the genes encoding the Caulobacter crescentus ClpXP protease. 1032 4

The development of pharmacological approaches for preventing the loss of muscle proteins would be extremely valuable for cachectic patients. For example, severe wasting in cancer patients correlates with a reduced efficacy of chemotherapy and radiotherapy. Pentoxifylline (PTX) is a very inexpensive xanthine derivative, which is widely used in humans as a haemorheological agent, and inhibits tumor necrosis factor transcription. We have shown here that a daily administration of PTX prevents muscle atrophy and suppresses increased protein breakdown in Yoshida sarcoma-bearing rats by inhibiting the activation of a nonlysosomal, Ca(2+)-independent proteolytic pathway. PTX blocked the ubiquitin pathway, apparently by suppressing the enhanced expression of ubiquitin, the 14-kDa ubiquitin conjugating enzyme E2, and the C2 20S proteasome subunit in muscle from cancer rats. The 19S complex and 11S regulator associate with the 20S proteasome and regulate its peptidase activities. The mRNA levels for the ATPase subunit MSS1 of the 19S complex increased in cancer cachexia, in contrast with mRNAs of other regulatory subunits. This adaptation was suppressed by PTX, suggesting that the drug inhibited the activation of the 26S proteasome. This is the first demonstration of a pharmacological manipulation of the ubiquitin-proteasome pathway in cachexia with a drug which is well tolerated in humans. Overall, the data suggest that PTX can prevent muscle wasting in situations where tumor necrosis factor production rises, including cancer, sepsis, AIDS and trauma.
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PMID:Manipulation of the ubiquitin-proteasome pathway in cachexia: pentoxifylline suppresses the activation of 20S and 26S proteasomes in muscles from tumor-bearing rats. 1036 54


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