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 Escherichia coli MukB, MukE, and MukF proteins form a bacterial condensin (MukBEF) that contributes to chromosome management by compacting DNA. MukB is an ATPase and DNA-binding protein of the SMC superfamily; however, the structure and function of non-SMC components, such as MukF, have been less forthcoming. Here, we report the crystal structure of the N-terminal 287 amino acids of MukF at 2.9 A resolution. This region folds into a winged-helix domain and an extended coiled-coil domain that self-associate to form a stable, doubly domain-swapped dimer. Protein dissection and affinity purification data demonstrate that the region of MukF C-terminal to this fragment binds to MukE and MukB. Our findings, together with sequence analyses, indicate that MukF is a kleisin subunit for E. coli condensin and suggest a means by which it may organize the MukBEF assembly.
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PMID:The MukF subunit of Escherichia coli condensin: architecture and functional relationship to kleisins. 1590 72

Chromodomain from heterochromatin protein 1 and polycomb protein is known to be a lysine-methylated histone H3 tail-binding module. Chromo-helicase/ATPase DNA-binding protein 1 (CHD1) is an ATP-dependent chromatin remodeling factor, containing two tandem chromodomains. In human CHD1, both chromodomains are essential for specific binding to a K4 methylated histone H3 (H3 MeK4) peptide and are found to bind cooperatively in the crystal structure. For the budding yeast homologue, Chd1, the second but not the first chromodomain was once reported to bind to an H3 MeK4 peptide. Here, we reveal that neither the second chromodomain nor a region containing tandem chromodomains from yeast Chd1 bind to any lysine-methylated or arginine-methylated histone peptides that we examined. In addition, we examined the structures of the chromodomains from Chd1 by NMR. Although the tertiary structure of the region containing tandem chromodomains could not be obtained, the secondary structure deduced from NMR is well conserved in the tertiary structures of the corresponding first and second chromodomains determined individually by NMR. Both chromodomains of Chd1 demonstrate a structure similar to that of the corresponding part of CHD1, consisting of a three-stranded beta-sheet followed by a C-terminal alpha-helix. However, an additional helix between the first and second beta-strands, which is found in both of the first chromodomains of Chd1 and CHD1, is positioned in an entirely different manner in Chd1 and CHD1. In human CHD1 this helix forms the peptide-binding site. The amino acid sequences of the chromodomains could be well aligned on the basis of these structures. The alignment showed that yeast Chd1 lacks several key functional residues, which are responsible for specific binding to a methylated lysine residue in other chromodomains. Chd1 is likely to have no binding affinity for any H3 MeK peptide, as found in other chromodomain proteins.
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PMID:Structural polymorphism of chromodomains in Chd1. 1709 52

RecG is a member of the superfamily 2 helicase family. Its possible role in vivo is ATP hydrolysis driven regression of stalled replication forks. To gain mechanistic insight into how this is achieved, a coupled spectrophotometric assay was utilized to characterize the ATPase activity of RecG in vitro. The results demonstrate an overwhelming preference for negatively supercoiled DNA ((-)scDNA) as a cofactor for the hydrolysis of ATP. In the presence of (-)scDNA the catalytic efficiency of RecG and the processivity (as revealed through heparin trapping), were higher than on any other cofactor examined. The activity of RecG on (-)scDNA was not due to the presence of single-stranded regions functioning as loading sites for the enzyme as relaxed circular DNA treated with DNA gyrase, resulted in the highest levels of ATPase activity. Relaxation of (-)scDNA by a topoisomerase resulted in a 12-fold decrease in ATPase activity, comparable to that observed on both linear double-stranded (ds)DNA and (+)scDNA. In addition to the elevated activity in the presence of (-)scDNA, RecG also has high activity on model 4Y-substrates (i.e. chicken foot structures). This is due largely to the high apparent affinity of the enzyme for this DNA substrate, which is 46-fold higher than a 2Y-substrate (i.e. a three-way with two single-stranded (ss)DNA arms). Finally, the enzyme exhibited significant, but lower activity on ssDNA. This activity was enhanced by the Escherichia coli stranded DNA-binding protein (SSB) protein, which occurs through stabilizing of the binding of RecG to ssDNA. Stabilization is not afforded by the bacteriophage gene 32 protein, indicating a species specific, protein-protein interaction is involved. These results combine to provide significant insight into the manner and timing of the interaction of RecG with DNA at stalled replication forks.
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PMID:Characterization of the ATPase activity of the Escherichia coli RecG protein reveals that the preferred cofactor is negatively supercoiled DNA. 1729 98

Conjugative systems contain an essential integral membrane protein involved in DNA transport called the Type IV coupling protein (T4CP). The T4CP of conjugative plasmid R388 is TrwB, a DNA-dependent ATPase. Biochemical and structural data suggest that TrwB uses energy released from ATP hydrolysis to pump DNA through its central channel by a mechanism similar to that used by F1-ATPase or ring helicases. For DNA transport, TrwB couples the relaxosome (a DNA-protein complex) to the secretion channel. In this work we show that TrwA, a tetrameric oriT DNA-binding protein and a component of the R388 relaxosome, stimulates TrwBDeltaN70 ATPase activity, revealing a specific interaction between the two proteins. This interaction occurs via the TrwA C-terminal domain. A 68-kDa complex between TrwBDeltaN70 and TrwA C-terminal domain was observed by gel filtration chromatography, consistent with a 1:1 stoichiometry. Additionally, electron microscopy revealed the formation of oligomeric TrwB complexes in the presence, but not in the absence, of TrwA protein. TrwBDeltaN70 ATPase activity in the presence of TrwA was further enhanced by DNA. Interestingly, maximal ATPase rates were achieved with TrwA and different types of dsDNA substrates. This is consistent with a role of TrwA in facilitating the interaction between TrwB and DNA. Our findings provide a new insight into the mechanism by which TrwB recruits the relaxosome for DNA transport. The process resembles the mechanism used by other DNA-dependent molecular motors, such as the RuvA/RuvB system, to be targeted to the DNA followed by hexamer assembly.
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PMID:The ATPase activity of the DNA transporter TrwB is modulated by protein TrwA: implications for a common assembly mechanism of DNA translocating motors. 1759 13

The dynamic, mitosis-like segregation of bacterial chromosomes and plasmids often involves proteins of the ParA (ATPase) and ParB (DNA-binding protein) families. The conversion of multigenomic aerial hyphae of the mycelial organism Streptomyces coelicolor into chains of unigenomic spores requires the synchronous segregation of multiple chromosomes, providing an unusual context for chromosome segregation. Correct spatial organization of the oriC-proximal region prior to septum formation is achieved by the assembly of ParB into segregation complexes (Jakimowicz et al., 2005; J Bacteriol 187: 3572-3580). Here, we focus on the contribution of ParA to sporulation-associated chromosome segregation. Elimination of ParA strongly affects not only chromosome segregation but also septation. In wild type hyphae about to undergo sporulation, immunostained ParA was observed as a stretched double-helical filament, which accompanies the formation of ParB foci. We show that ParA mediates efficient assembly of ParB complexes in vivo and in vitro, and that ATP binding is crucial for ParA dimerization and interaction with ParB but not for ParA localization in vivo. We suggest that S. coelicolor ParA provides scaffolding for proper distribution of ParB complexes and consequently controls synchronized segregation of several dozens of chromosomes, possibly mediating a segregation and septation checkpoint.
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PMID:Alignment of multiple chromosomes along helical ParA scaffolding in sporulating Streptomyces hyphae. 1763 86

Mitochondrial biogenesis and function are essential for proper embryo development; however, these processes have not been further studied during the placentation period, when important oxidative metabolism activation is taking place. Thus, the aim of the present study was to investigate the oxidative phosphorylation system (OXPHOS) enzymatic activities as well as the expression of genes involved in the coordinated regulation of both mitochondrial and nuclear genomes (peroxisome proliferator-activated receptor-gamma coactivator-1alpha, nuclear respiratory factors 1 and 2, mitochondrial single-strand DNA-binding protein, mitochondrial transcription factor A), and mitochondrial function (cytochrome c oxidase subunit IV, cytochrome c oxidase subunit I and beta-ATP phosphohydrolase) in rat embryo throughout the placentation period (gestational days 11, 12 and 13). Our results reflect that embryo mitochondria were enhancing their OXPHOS potential capacities, pointing out that embryo mitochondria become more differentiated during the placentation period. Besides, the current findings show that the mRNAs of the nuclear genes involved in mitochondrial biogenesis were downregulated, whereas their protein content together with the mitochondrial DNA expression were upregulated throughout the period studied. These data indicate that the molecular regulation of the mitochondrial differentiation process during placentation involves a post-transcriptional activation of the nuclear-encoded genes that would lead to an increase in both the nuclear- and mitochondrial-encoded proteins responsible for the mitochondrial biogenic process. As a result, embryo mitochondria would reach a more differentiated stage with a more efficient oxidative metabolism that would facilitate the important embryo growth during the second half of the pregnancy.
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PMID:Mitochondrial differentiation and oxidative phosphorylation system capacity in rat embryo during placentation period. 1764 Oct 96

Accurate DNA partition at cell division is vital to all living organisms. In bacteria, this process can involve partition loci, which are found on both chromosomes and plasmids. The initial step in Escherichia coli plasmid R1 partition involves the formation of a partition complex between the DNA-binding protein ParR and its cognate centromere site parC on the DNA. The partition complex is recognized by a second partition protein, the actin-like ATPase ParM, which forms filaments required for the active bidirectional movement of DNA replicates. Here, we present the 2.8 A crystal structure of ParR from E. coli plasmid pB171. ParR forms a tight dimer resembling a large family of dimeric ribbon-helix-helix (RHH)2 site-specific DNA-binding proteins. Crystallographic and electron microscopic data further indicate that ParR dimers assemble into a helix structure with DNA-binding sites facing outward. Genetic and biochemical experiments support a structural arrangement in which the centromere-like parC DNA is wrapped around a ParR protein scaffold. This structure holds implications for how ParM polymerization drives active DNA transport during plasmid partition.
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PMID:Structural analysis of the ParR/parC plasmid partition complex. 1789 4

Mycobacterial UvrD2 is a DNA-dependent ATPase with 3' to 5' helicase activity. UvrD2 is an atypical helicase, insofar as its N-terminal ATPase domain resembles the superfamily I helicases UvrD/PcrA, yet it has a C-terminal HRDC domain, which is a feature of RecQ-type superfamily II helicases. The ATPase and HRDC domains are connected by a CxxC-(14)-CxxC tetracysteine module that defines a new clade of UvrD2-like bacterial helicases found only in Actinomycetales. By characterizing truncated versions of Mycobacterium smegmatis UvrD2, we show that whereas the HRDC domain is not required for ATPase or helicase activities in vitro, deletion of the tetracysteine module abolishes duplex unwinding while preserving ATP hydrolysis. Replacing each of the CxxC motifs with a double-alanine variant AxxA had no effect on duplex unwinding, signifying that the domain module, not the cysteines, is crucial for function. The helicase activity of a truncated UvrD2 lacking the tetracysteine and HRDC domains was restored by the DNA-binding protein Ku, a component of the mycobacterial NHEJ system and a cofactor for DNA unwinding by the paralogous mycobacterial helicase UvrD1. Our findings indicate that coupling of ATP hydrolysis to duplex unwinding can be achieved by protein domains acting in cis or trans. Attempts to disrupt the M. smegmatis uvrD2 gene were unsuccessful unless a second copy of uvrD2 was present elsewhere in the chromosome, indicating that UvrD2 is essential for growth of M. smegmatis.
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PMID:Domain requirements for DNA unwinding by mycobacterial UvrD2, an essential DNA helicase. 1870 26

Collaboration between MuA transposase and its activator protein, MuB, is essential for properly regulated transposition. MuB activates MuA catalytic activity, selects target DNA, and stimulates transposition into the selected target site. Selection of appropriate target DNA requires ATP hydrolysis by the MuB ATPase. By fusing MuB to a site-specific DNA-binding protein, the Arc repressor, we generated a MuB variant that could select target DNA independently of ATP. This Arc-MuB fusion protein allowed us to test whether ATP binding and hydrolysis by MuB are necessary for stimulation of transposition into selected DNA, a process termed target delivery. We find that with the fusion proteins, MuB-dependent target delivery occurs efficiently under conditions where ATP hydrolysis is prevented by mutation or use of ADP. In contrast, no delivery was detected in the absence of nucleotide. These data indicate that the ATP- and MuA-regulated DNA-binding activity of MuB is not essential for target delivery but that activation of MuA by MuB strictly requires nucleotide-bound MuB. Furthermore, we find that the fusion protein directs transposition to regions of the DNA within 40-750 bp of its own binding site. Taken together, these results suggest that target delivery by MuB occurs as a consequence of the ability of MuB to stimulate MuA while simultaneously tethering MuA to a selected target DNA. This tethered-activator model provides an attractive explanation for other examples of protein-stimulated control of target site selection.
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PMID:Dissecting the roles of MuB in Mu transposition: ATP regulation of DNA binding is not essential for target delivery. 1871 26

CHD4 (chromodomain helicase DNA-binding protein 4) ATPase is a major subunit of the repressive NuRD (nucleosome remodelling and deacetylase) complex, which is involved in transcriptional regulation and development. CHD4 contains two PHD (plant homeodomain) fingers of unknown function. Here we show that the second PHD finger (PHD2) of CHD4 recognizes the N-terminus of histone H3 and that this interaction is facilitated by acetylation or methylation of Lys9 (H3K9ac and H3K9me respectively) but is inhibited by methylation of Lys4 (H3K4me) or acetylation of Ala1 (H3A1ac). An 18 microM binding affinity toward unmodified H3 rises to 0.6 microM for H3K9ac and to 0.9 microM for H3K9me3, whereas it drops to 2.0 mM for H3K4me3, as measured by tryptophan fluorescence and NMR. A peptide library screen further shows that phosphorylation of Thr3, Thr6 or Ser10 abolishes this interaction. A model of the PHD2-H3 complex, generated using a combination of NMR, data-driven docking and mutagenesis data, reveals an elongated site on the PHD2 surface where the H3 peptide is bound. Together our findings suggest that the PHD2 finger plays a role in targeting of the CHD4/NuRD complex to chromatin.
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PMID:Binding of the CHD4 PHD2 finger to histone H3 is modulated by covalent modifications. 1962 89

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