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)

Previously, we presented evidence that the oral cariogenic species Streptococcus mutans remains viable but physiologically impaired and sensitive to environmental stress when genes encoding the minimal conserved bacterial signal recognition particle (SRP) elements are inactivated. Two-dimensional gel electrophoresis of isolated membrane fractions from strain UA159 and three mutants (Deltaffh, DeltascRNA, and DeltaftsY) grown at pH 7.0 or pH 5.0 allowed us to obtain insight into the adaptation process and the identities of potential SRP substrates. Mutant membrane preparations contained increased amounts of the chaperones DnaK and GroES and ClpP protease but decreased amounts of transcription- and translation-related proteins, the beta subunit of ATPase, HPr, and several metabolic and glycolytic enzymes. Therefore, the acid sensitivity of SRP mutants might be caused in part by diminished ATPase activity, as well as the absence of an efficient mechanism for supplying ATP quickly at the site of proton elimination. Decreased amounts of LuxS were also observed in all mutant membranes. To further define physiological changes that occur upon disruption of the SRP pathway, we studied global gene expression in S. mutans UA159 (parent strain) and AH333 (Deltaffh mutant) using microarray analysis. Transcriptome analysis revealed up-regulation of 81 genes, including genes encoding chaperones, proteases, cell envelope biosynthetic enzymes, and DNA repair and replication enzymes, and down-regulation of 35 genes, including genes concerned with competence, ribosomal proteins, and enzymes involved in amino acid and protein biosynthesis. Quantitative real-time reverse transcription-PCR analysis of eight selected genes confirmed the microarray data. Consistent with a demonstrated defect in competence and the suggested impairment of LuxS-dependent quorum sensing, biofilm formation was significantly decreased in each SRP mutant.
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PMID:Membrane composition changes and physiological adaptation by Streptococcus mutans signal recognition particle pathway mutants. 1708 48

SaeRS is a two-component system that has been characterized as a positive regulatory system for the expression of several virulence factors, including coagulase, alpha-, beta- and gamma-haemolysins, nuclease, and fibronectin-binding proteins in Staphylococcus aureus. Previously, the SaeRS system was found to be induced at the transcriptional level by beta-lactam. Here, we found that subinhibitory concentrations of beta-lactam induce haemolytic activity in the S. aureus N315 strain but not in the saeRS null mutant KSA. Comparison of the transcriptional profile of the N315 and KSA strains by microarray analysis reveals that the SaeRS system modulates the regulation of coagulase (coa), alpha-, beta- and gamma-haemolysins (hla, hlb and hlg), nuclease (SA0746), fibrinogen-binding proteins (emp, efb, SA1000 and SA1004), fibronectin-binding protein B (fnbB), and 13 other genes. Further, the use of cefoxitin as a signal inducer reveals that the SaeRS system appears to modulate 22 additional genes as a secondary regulon, including the staphylococcal accessory regulators SarA and SarT and the Clp protease ATPase subunits ClpB and ClpL. These observations suggest that beta-lactam is able to induce the SaeRS system, which acts as a crucial signal transduction system for S. aureus pathogenicity rather than antimicrobial resistance.
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PMID:Subinhibitory concentrations of beta-lactam induce haemolytic activity in Staphylococcus aureus through the SaeRS two-component system. 1726 51

The ClpAP chaperone-protease complex is active as a cylindrically shaped oligomeric complex built of the proteolytic ClpP double ring as the core of the complex and two ClpA hexamers associating with the ends of the core cylinder. The ClpA chaperone belongs to the larger family of AAA+ ATPases and is responsible for preparing protein substrates for degradation by ClpP. Here, we study in real time using fluorescence and light scattering stopped-flow methods the complete assembly pathway of this bacterial chaperone-protease complex consisting of ATP-induced ClpA hexamer formation and the subsequent association of ClpA hexamers with the ClpP core cylinder. We provide evidence that ClpA assembles into hexamers via a tetrameric intermediate and that hexamerization coincides with the appearance of ATPase activity. While ATP-induced oligomerization of ClpA is a prerequisite for binding of ClpA to ClpP, the kinetics of ClpA hexamer formation are not influenced by the presence of ClpP. Models for ClpA hexamerization and ClpA-ClpP association are presented along with rate parameters obtained from numerical fitting procedures. The hexamerization kinetics show that the tetrameric intermediate transiently accumulates, forming rapidly at early time points and then decaying at a slower rate to generate the hexamer. The association of assembled ClpA hexamers with the ClpP core cylinder displays cooperativity, supporting the coexistence of interchanging ClpP conformations with different affinities for ClpA.
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PMID:Assembly pathway of an AAA+ protein: tracking ClpA and ClpAP complex formation in real time. 1747 47

Previously, a clpX gene encoding a predicted 67 kDa membrane-associated ATPase subunit of the Clp protease (ClpX) was identified in a porcine strain (95/1,000) of the intestinal spirochaete Brachyspira pilosicoli. In the current study, the distribution of this large clpX gene was investigated in a collection of strains representing all seven Brachyspira spp. Using PCR with internal primers, an 878 bp portion of the gene was detected in 29 of 35 strains (83 %) of B. pilosicoli, 6 of 24 strains (25 %) of Brachyspira hyodysenteriae, 14 of 16 strains (88 %) of Brachyspira intermedia, 6 of 17 strains (35 %) of Brachyspira innocens, 1 of 6 strains (17 %) of Brachyspira murdochii, 1 of 2 strains (50 %) of Brachyspira aalborgi and not in the single strain of Brachyspira alvinipulli. The whole gene was sequenced from 20 Brachyspira spp. strains and compared with the clpX gene from B. pilosicoli 95/1,000 (GenBank accession no. AY466377). The genes had 99.3-99.7 % nucleotide sequence similarity and the predicted products had 99.7-100 % amino acid sequence similarity. The clpX gene from WesB, a human strain of B. pilosicoli, was cloned and expressed as a histidine-tagged fusion protein in Escherichia coli BL21. The purified protein was used to vaccinate mice and their sera were found to recognize the expected approximately 67 kDa protein in whole-cell preparations of WesB. Sera from mice vaccinated with formalin-treated whole-cell proteins of WesB reacted with the recombinant protein. These results indicate that ClpX is both conserved and immunogenic and hence might be useful as a subunit vaccine component for Brachyspira spp. infections. Sera from humans with no known exposure to B. pilosicoli reacted with the recombinant ClpX protein, indicating that it is unlikely to be useful as a reagent for serological detection of Brachyspira spp. infections.
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PMID:Distribution of the clpX gene in Brachyspira species and reactivity of recombinant Brachyspira pilosicoli ClpX with sera from mice and humans. 1757 58

In prokaryotic cells the ATP-dependent proteases Lon and ClpP (Clp proteolytic subunit) are involved in the turnover of misfolded proteins and the degradation of regulatory proteins, and depending on the organism, these proteases contribute variably to stress tolerance. We constructed mutants in the lon and clpP genes of the food-borne human pathogen Campylobacter jejuni and found that the growth of both mutants was impaired at high temperature, a condition known to increase the level of misfolded protein. Moreover, the amounts of misfolded protein aggregates were increased when both proteases were absent, and we propose that both ClpP and Lon are involved in eliminating misfolded proteins in C. jejuni. In order to bind misfolded protein, ClpP has to associate with one of several Clp ATPases. Following inactivation of the ATPase genes clpA and clpX, only the clpX mutant displayed the same heat sensitivity as the clpP mutant, indicating that the ClpXP proteolytic complex is responsible for the degradation of heat-damaged proteins in C. jejuni. Notably, ClpP and ClpX are required for growth at 42 degrees C, which is the temperature of the intestinal tract of poultry, one of the primary carriers of C. jejuni. Thus, ClpP and ClpX may be suitable targets of new intervention strategies aimed at reducing C. jejuni in poultry production. Further characterization of the clpP and lon mutants revealed other altered phenotypes, such as reduced motility, less autoagglutination, and lower levels of invasion of INT407 epithelial cells, suggesting that the proteases may contribute to the virulence of C. jejuni.
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PMID:Contribution of conserved ATP-dependent proteases of Campylobacter jejuni to stress tolerance and virulence. 1793 20

Protein degradation in the cytosol of Escherichia coli is carried out by a variety of different proteolytic machines, including ClpAP. The ClpA component is a hexameric AAA+ (ATPase associated with various cellular activities) chaperone that utilizes the energy of ATP to control substrate recognition and unfolding. The precise role of the N-domains of ClpA in this process, however, remains elusive. Here, we have analysed the role of five highly conserved basic residues in the N-domain of ClpA by monitoring the binding, unfolding and degradation of several different substrates, including short unstructured peptides, tagged and untagged proteins. Interestingly, mutation of three of these basic residues within the N-domain of ClpA (H94, R86 and R100) did not alter substrate degradation. In contrast mutation of two conserved arginine residues (R90 and R131), flanking a putative peptide-binding groove within the N-domain of ClpA, specifically compromised the ability of ClpA to unfold and degrade selected substrates but did not prevent substrate recognition, ClpS-mediated substrate delivery or ClpP binding. In contrast, a highly conserved tyrosine residue lining the central pore of the ClpA hexamer was essential for the degradation of all substrate types analysed, including both folded and unstructured proteins. Taken together, these data suggest that ClpA utilizes two structural elements, one in the N-domain and the other in the pore of the hexamer, both of which are required for efficient unfolding of some protein substrates.
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PMID:Conserved residues in the N-domain of the AAA+ chaperone ClpA regulate substrate recognition and unfolding. 1827 86

ClpP and its ATPase compartment, ClpX or ClpA, remove misfolded proteins in cells and are of utmost importance in protein quality control. The ring hexamers of ClpA or ClpX recognize, unfold, and translocate target substrates into the degradation chamber of the double-ring tetradecamer of ClpP. The overall reaction scheme catalyzed by ClpXP or ClpAP has been proposed; however, the molecular mechanisms associated with substrate recognition and degradation have not yet been clarified in detail. To investigate these mechanisms, we determined the crystal structures of ClpP from Helicobacter pylori in complex with product peptides bound to the active site as well as in the apo state. In the complex structure, the peptides are zipped with two antiparallel strands of ClpP and point to the adjacent active site, thus providing structural explanations for the broad substrate specificity, the product inhibition and the processive degradation of substrates in the chamber. The structures also suggest that substrate binding causes local conformational changes around the active site that ultimately induce the active conformation of ClpP.
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PMID:The structural basis for the activation and peptide recognition of bacterial ClpP. 1846 23

Among other functions, ATP-dependent proteases degrade misfolded proteins and remove several key regulatory proteins necessary to activate stress responses. In Bacillus subtilis, ClpX, ClpE, and ClpC form homohexameric ATPases that couple to the ClpP peptidase. To understand where these peptidases and ATPases localize in living cells, each protein was fused to a fluorescent moiety. We found that ClpX-GFP (green fluorescent protein) and ClpP-GFP localized as focal assemblies in areas that were not occupied by the nucleoid. We found that the percentage of cells with ClpP-GFP foci increased following heat shock independently of protein synthesis. We determined that ClpE-YFP (yellow fluorescent protein) and ClpC-YFP formed foci coincident with nucleoid edges, usually near cell poles. Furthermore, we found that ClpQ-YFP (HslV) localized as small foci, usually positioned near the cell membrane. We found that ClpQ-YFP foci were dependent on the presence of the cognate hexameric ATPase ClpY (HslU). Moreover, we found that LonA-GFP is coincident with the nucleoid during normal growth and that LonA-GFP also localized to the forespore during development. We also investigated LonB-GFP and found that this protein localized to the forespore membrane early in development, followed by localization throughout the forespore later in development. Our comprehensive study has shown that in B. subtilis several ATP-fueled proteases occupy distinct subcellular locations. With these data, we suggest that substrate specificity could be determined, in part, by the spatial and temporal organization of proteases in vivo.
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PMID:Clp and Lon proteases occupy distinct subcellular positions in Bacillus subtilis. 1868 73

Spatial control of proteolysis is emerging as a common feature of regulatory networks in bacteria. In the spore-forming bacterium Bacillus subtilis, the peptidase ClpP can associate with any of three ATPases: ClpC, ClpE, and ClpX. Here, we report that ClpCP, ClpEP, and ClpXP localize in foci often near the poles of growing cells and that ClpP and the ATPase are each capable of polar localization independently of the other component. A region of ClpC containing an AAA domain was necessary and sufficient for polar localization. We also report that ClpCP and ClpXP proteases differentially localize to the forespore and mother cell compartments of the sporangium during spore formation. Moreover, model substrates for each protease created by appending recognition sequences for ClpCP or ClpXP to the green fluorescent protein were preferentially eliminated from the forespore or the mother cell, respectively. Biased accumulation of ClpCP in the forespore may contribute to the cell-specific activation of the transcription factor sigma(F) by preferential ClpCP-dependent degradation of the anti-sigma(F) factor SpoIIAB.
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PMID:Polar localization and compartmentalization of ClpP proteases during growth and sporulation in Bacillus subtilis. 1868 76

Energy-dependent protein degradation machines, such as the Escherichia coli protease ClpAP, require regulated interactions between the ATPase component (ClpA) and the protease component (ClpP) for function. Recent studies indicate that the ClpP N-terminus is essential in these interactions, yet the dynamics of this region remain unclear. Here, we use synchrotron hydroxyl radical footprinting and kinetic studies to characterize functionally important conformational changes of the ClpP N-terminus. Footprinting experiments show that the ClpP N-terminus becomes more solvent-exposed upon interaction with ClpA. In the absence of ClpA, deletion of the ClpP N-terminus increases the initial degradation rate of large peptide substrates 5-15-fold. Unlike ClpAP, ClpPDeltaN exhibits a distinct slow phase of product formation that is eliminated by the addition of hydroxylamine, suggesting that truncation of the N-terminus leads to stabilization of the acyl-enzyme intermediate. These results indicate that (1) the ClpP N-terminus acts as a "gate" controlling substrate access to the active sites, (2) binding of ClpA opens this "gate", allowing substrate entry and formation of the acyl-enzyme intermediate, and (3) closing of the N-terminal "gate" stimulates acyl-enzyme hydrolysis.
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PMID:The ClpP N-terminus coordinates substrate access with protease active site reactivity. 1881 64

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