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)

A gene encoding thermostable Lon protease from Brevibacillus thermoruber WR-249 was cloned and characterized. The Br. thermoruber Lon gene (Bt-lon) encodes an 88 kDa protein characterized by an N-terminal domain, a central ATPase domain which includes an SSD (sensor- and substrate-discrimination) domain, and a C-terminal protease domain. The Bt-lon is a heat-inducible gene and may be controlled under a putative Bacillus subtilis sigmaA-dependent promoter, but in the absence of CIRCE (controlling inverted repeat of chaperone expression). Bt-lon was expressed in Escherichia coli, and its protein product was purified. The native recombinant Br. thermoruber Lon protease (Bt-Lon) displayed a hexameric structure. The optimal temperature of ATPase activity for Bt-Lon was 70 degrees C, and the optimal temperature of peptidase and DNA-binding activities was 50 degrees C. This implies that the functions of Lon protease in thermophilic bacteria may be switched, depending on temperature, to regulate their physiological needs. The peptidase activity of Bt-Lon increases substantially in the presence of ATP. Furthermore, the substrate specificity of Bt-Lon is different from that of E. coli Lon in using fluorogenic peptides as substrates. Notably, the Bt-Lon protein shows chaperone-like activity by preventing aggregation of denatured insulin B-chain in a dose-dependent and ATP-independent manner. In thermal denaturation experiments, Bt-Lon was found to display an indicator of thermostability value, Tm of 71.5 degrees C. Sequence comparison with mesophilic Lon proteases shows differences in the rigidity, electrostatic interactions, and hydrogen bonding of Bt-Lon relevant to thermostability.
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PMID:Identification of a gene encoding Lon protease from Brevibacillus thermoruber WR-249 and biochemical characterization of its thermostable recombinant enzyme. 1476

ClpAP is a barrel-like complex consisting of hexameric rings of the ClpA ATPase stacked on the double heptameric ring of ClpP peptidase. ClpA has two AAA+ domains (Dl and D2) and a 153-residue N-domain. Substrate proteins bind to the distal surface of ClpA and are unfolded and translocated axially into ClpP. To gain insight into the functional architecture of ClpA in the ATPgammaS state, we have determined its structure at 12A resolution by cryo-electron microscopy. The resulting model has two tiers, corresponding to rings of Dl and D2 domains: oddly, there is no sign of the N-domains in the density map. However, they were detected as faint diffuse density distal to the Dl tier in a difference image between wild-type ClpAP and a mutant lacking the N-domain. This region is also accentuated in a variance map of ClpAP and in a difference imaging experiment with ClpAP complexed with ClpS, a 12kDa protein that binds to the N-domain. These observations demonstrate that the N-domains are highly mobile. From molecular modeling, we identify their median position and estimate that they undergo fluctuations of at least 30A. We discuss the implications of these observations for the role of N-domains in substrate binding: either they effect an initial transient binding, relaying substrate to a second site on the Dl tier where unfolding ensues, or they may serve as an entropic brush to clear the latter site of non-specifically bound ligands or substrates bound in non-productive complexes.
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PMID:The N-terminal substrate-binding domain of ClpA unfoldase is highly mobile and extends axially from the distal surface of ClpAP protease. 1503 49

Proteolysis plays an central role in key metabolic pathways and cellular adaptation to environmental changes. It modulates the activity of regulatory peptides and eliminates misfolded or damaged proteins such as those generated by stress exposure. In eucaryotic cells ATP- dependent proteolysis is carried out by the 26S proteasome whose substrates are identified by ubiquitin tags. Conversely, bacteria possess several tagging systems and different ATP- dependent proteases. Bacterial ATP-dependent proteases carry distinct chaperone-ATPase and peptidase activities, either on the same molecule or on separate subunits. Although unrelated, all ATP-dependent proteases function according to a similar multistep scheme, from the docking of a substrate by the ATPase region to its proteolysis by the peptidase. Major bacterial ATP- dependent proteases include FtsH, Lon, HslUV and the Clp proteases. Clp proteases are multimeric complexes assembled into a structure centered on the proteolytic component ClpP. They are essential for quick adaptation to stress and regulate important developmental processes. Clp-mediated proteolysis is also required for disease progression and virulence of several bacterial pathogens, favoring survival in the host or modulating the activity of genuine virulence factors.
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PMID:[ATP-dependant proteolysis and bacterial pathogenesis]. 1504 85

In the ClpXP compartmental protease, ring hexamers of the AAA(+) ClpX ATPase bind, denature and then translocate protein substrates into the degradation chamber of the double-ring ClpP(14) peptidase. A key question is the extent to which functional communication between ClpX and ClpP occurs and is regulated during substrate processing. Here, we show that ClpX-ClpP affinity varies with the protein-processing task of ClpX and with the catalytic engagement of the active sites of ClpP. Functional communication between symmetry-mismatched ClpXP rings depends on the ATPase activity of ClpX and seems to be transmitted through structural changes in its IGF loops, which contact ClpP. A conserved arginine in the sensor II helix of ClpX links the nucleotide state of ClpX to the binding of ClpP and protein substrates. A simple model explains the observed relationships between ATP binding, ATP hydrolysis and functional interactions between ClpX, protein substrates and ClpP.
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PMID:Communication between ClpX and ClpP during substrate processing and degradation. 1506 53

Escherichia coli Lon, also known as protease La, is a serine protease that is activated by ATP and other purine or pyrimidine triphosphates. In this study, we examined the catalytic efficiency of peptide cleavage as well as intrinsic and peptide-stimulated nucleotide hydrolysis in the presence of hydrolyzable nucleoside triphosphates ATP, CTP, UTP, and GTP. We observed that the k(cat) of peptide cleavage decreases with the reduction in the nucleotide binding affinity of Lon in the following order: ATP > CTP > GTP approximately UTP. Compared to those of the other hydrolyzable nucleotide triphosphates, the ATPase activity of Lon is also the most sensitive to peptide stimulation. Collectively, our kinetic as well as tryptic digestion data suggest that both nucleotide binding and hydrolysis contribute to the peptidase turnover of Lon. The kinetic data that were obtained were further put into the context of the structural organization of Lon protease by probing the conformational change in Lon bound to the different nucleotides. Both adenine-containing nucleotides and CTP protect a 67 kDa fragment of Lon from tryptic digestion. Since this 67 kDa fragment contains the ATP binding pocket (also known as the alpha/beta domain), the substrate sensor and discriminatory (SSD) domain (also known as the alpha-helical domain), and the protease domain of Lon, we propose that the binding of ATP induces a conformational change in Lon that facilitates the coupling of nucleotide hydrolysis with peptide substrate delivery to the peptidase active site.
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PMID:Correlation of an adenine-specific conformational change with the ATP-dependent peptidase activity of Escherichia coli Lon. 1518 86

Conditions of limited proteolysis of the protease Lon from Escherichia coli that provided the formation of fragments approximately corresponding to the enzyme domains were found for studying the domain functioning. A method of isolation of the domains was developed, and their functional characteristics were compared. The isolated proteolytic domain (LonP fragment) of the enzyme was shown to exhibit both peptidase and proteolytic activities; however, it cleaved large protein substrates at a significantly lower rate than the full-size protease Lon. On the other hand, the LonAP fragment, containing both the ATPase and the proteolytic domains, retained almost all of the enzymatic properties of the full-size protein. Both LonP and LonAP predominantly form dimers unlike the native protease Lon functioning as a tetramer. These results suggest that the N-terminal domain of protease Lon plays a considerable role in the process of the enzyme oligomerization.
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PMID:[Isolation and characterization of fragments of ATP-dependent protease Lon from Escherichia coli obtained by limited proteolysis]. 1546 6

Escherichia coli Lon, also known as protease La, is an oligomeric ATP-dependent protease, which functions to degrade damaged and certain short-lived regulatory proteins in the cell. To investigate the kinetic mechanism of E. coli Lon protease, we performed the first pre-steady-state kinetic characterization of the ATPase and peptidase activities of this enzyme. Using rapid quench-flow and fluorescence stopped-flow spectroscopy techniques, we demonstrated that ATP hydrolysis occurs before peptide cleavage, with the former reaction displaying a burst and the latter displaying a lag in product production. The detection of burst kinetics in ATP hydrolysis is indicative of a step after nucleotide hydrolysis being rate-limiting in ATPase turnover. At saturating substrate concentrations, the lag rate constant for peptide cleavage is comparable to the kcat of ATPase, indicating that two hydrolytic processes are coordinated during the first enzyme turnover. The involvement of subunit interaction during enzyme catalysis was detected as positive cooperativity in the binding and hydrolysis of substrates, as well as apparent asymmetry in the ATPase activity in Lon. When our data are taken together, they are consistent with a reaction model in which ATP hydrolysis is used to generate an active enzyme form that hydrolyzes peptide.
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PMID:Monitoring the timing of ATP hydrolysis with activation of peptide cleavage in Escherichia coli Lon by transient kinetics. 1568 51

ATP-dependent protein degradation is controlled principally by substrate recognition. The AAA+ HslU ATPase is thought to bind protein substrates, denature them, and translocate the unfolded polypeptide into the HslV peptidase. The lack of well-behaved high-affinity substrates for HslUV (ClpYQ) has hampered understanding of the rules and mechanism of substrate engagement. We show that HslUV efficiently degrades Arc repressor, especially at heat-shock temperatures. Degradation depends on sequences near the N terminus of Arc. Fusion protein and peptide-binding experiments demonstrate that this sequence is a degradation tag that binds directly to HslU. Strong binding of this tag to the enzyme requires ATP and Mg(2+). Furthermore, fusion of this sequence to a protein with marked mechanical stability leads to complete degradation. Thus, these experiments demonstrate that HslUV is a powerful protein unfoldase and that initial substrate engagement by the HslU ATPase must occur after ATP binding.
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PMID:Nucleotide-dependent substrate recognition by the AAA+ HslUV protease. 1569 75

Enterococcus faecalis BM4405-1, a susceptible derivative of the VanE-type vancomycin-resistant E. faecalis strain BM4405, was obtained after growth in the presence of novobiocin, an inhibitor of the GyrB subunit of DNA gyrase. In contrast to findings for BM4405, UDP-MurNAc-L-Ala-gamma-D-Glu-L-Lys-D-Ala-D-Ala (pentapeptide[D-Ala]) was the only peptidoglycan precursor found in BM4405-1, and no VanXY(E) D,D-peptidase or VanT serine racemase activities were detected in that strain, even after induction by subinhibitory concentrations of vancomycin. Sequencing of the vanE operon of BM4405-1 revealed two mutations leading to substitutions in VanE (D200N) and in the C-terminal amino acid of VanR(E) (Y225F). Cloning of the vanE, vanXY(E), and vanT(E) genes of BM4405-1 into the susceptible E. faecalis strain JH2-2 conferred resistance to vancomycin, indicating that the mutation in vanE was not responsible for susceptibility. Transcriptional analysis of the vanE operon in BM4405 by quantitative reverse transcription-PCR indicated that novobiocin did not affect the expression level of the vanE operon. Sequencing of the gyrB gene of BM4405-1 revealed a mutation responsible for substitution of a residue (K337Y) required for ATPase activity and thus implicated in DNA supercoiling. Cloning of the gyrB gene of BM4405 restored vancomycin resistance to BM4405-1. Taken together, these data suggest that alteration of DNA supercoiling following a mutation in GyrB was responsible for lack of expression of the vanE operon and thus for vancomycin susceptibility in BM4405-1.
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PMID:Silencing of glycopeptide resistance in Enterococcus faecalis BM4405 by novobiocin. 1579 21

HslVU is an ATP-dependent protease consisting of HslU ATPase and HslV peptidase. In an HslVU complex, the central pores of HslU hexamer and HslV dodecamer are aligned and the proteolytic active sites are sequestered in the inner chamber of HslV. Thus, the degradation of natively folded proteins requires unfolding and translocation processes for their access into the proteolytic chamber of HslV. A highly conserved GYVG(93) sequence constitutes the central pore of HslU ATPase. To determine the role of the pore motif on protein unfolding and translocation, we generated various mutations in the motif and examined their effects on the ability of HslU in supporting the proteolytic activity of HslV against three different substrates: SulA as a natively folded protein, casein as an unfolded polypeptide, and a small peptide. Flexibility provided by Gly residues and aromatic ring structures of the 91st amino acid were essential for degradation of SulA. The same structural features of the GYVG motif were highly preferred, although not essential, for degradation of casein. In contrast, none of the features were required for peptide hydrolysis. Mutations in the GYVG motif of HslU also showed marked influence on its ATPase activity, affinity to ADP, and interaction with HslV. These results suggest that the GYVG motif of HslU plays important roles in unfolding of natively folded proteins as well as in translocation of unfolded proteins for degradation by HslV. These results also implicate a role of the pore motif in ATP cleavage and in the assembly of HslVU complex.
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PMID:Role of the GYVG pore motif of HslU ATPase in protein unfolding and translocation for degradation by HslV peptidase. 1584

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