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)

In the presence of Zn2+, the Drosophila 26 S proteasome disassembles into RP (regulatory particle) and CP (catalytic particle), this process being accompanied by the dissociation of subunit Rpn10/p54, the ubiquitin receptor subunit of the proteasome. The dissociation of Rpn10/p54 induces extensive rearrangements within the lid subcomplex of the RP, while the structure of the ATPase ring of the base subcomplex seems to be maintained. As a consequence of the dissociation of the RP, the peptidase activity of the 26 S proteasome is lost. The Zn2+-induced structural and functional changes are fully reversible; removal of Zn2+ is followed by reassociation of subunit Rpn10/p54 to the RP, reassembly of the 26 S proteasome and resumption of the peptidase activity. After the Zn2+-induced dissociation, Rpn10/p54 interacts with a set of non-proteasomal proteins. Hsp82 (heat-shock protein 82) has been identified by MS as the main Rpn10/p54-interacting protein, suggesting its role in the reassembly of the 26 S proteasome after Zn2+ removal. The physiological relevance of another Rpn10/p54-interacting protein, the Smt3 SUMO (small ubiquitin-related modifier-1)-activating enzyme, detected by chemical cross-linking, has been confirmed by yeast two-hybrid analysis. Besides the Smt3 SUMO-activating enzyme, the Ubc9 SUMO-conjugating enzyme also exhibited in vivo interaction with the 5'-half of Rpn10/p54 in yeast cells. The mechanism of 26 S proteasome disassembly after ATP depletion is clearly different from that induced by Zn2+. Rpn10/p54 is permanently RP-bound during the ATP-dependent assembly-disassembly cycle, but during the Zn2+ cycle it reversibly shuttles between the RP-bound and free states.
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PMID:Zn2+-induced reversible dissociation of subunit Rpn10/p54 of the Drosophila 26 S proteasome. 1594 24

ARIP4 [AR (androgen receptor)-interacting protein 4] is a member of the SNF2-like family of proteins. Its sequence similarity to known proteins is restricted to the centrally located SNF2 ATPase domain. ARIP4 is an active ATPase, and dsDNA (double-stranded DNA) and ssDNA (single-stranded DNA) enhance its catalytic activity. We show in the present study that ARIP4 interacts with AR and binds to DNA and mononucleosomes. The N-terminal region of ARIP4 mediates interaction with AR. Kinetic parameters of the ARIP4 ATPase are similar to those of BRG-1 and SNF2h, two members of the SNF2-like protein family, but the specific activity of ARIP4 protein purified to >90% homogeneity is approximately ten times lower, being 120 molecules of ATP hydrolysed by an ARIP4 molecule per min in contrast with approx. 1000 ATP molecules hydrolysed per min by ATP-dependent chromatin remodellers. Unlike other members of the SNF2 family, ARIP4 does not appear to form large protein complexes in vivo or remodel mononucleosomes in vitro. ARIP4 is covalently modified by sumoylation, and mutation of six potential SUMO (small ubiquitin-related modifier) attachment sites abolished the ability of ARIP4 to bind DNA, hydrolyse ATP and activate AR function. We conclude that, similar to its closest homologues in the SNF2-like protein family, ATRX (alpha-thalassemia, mental retardation, X-linked) and Rad54, ARIP4 does not seem to be a classical chromatin remodelling protein.
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PMID:Biochemical characterization of androgen receptor-interacting protein 4. 1621 58

MOT1 encodes an essential ATPase that functions as a general transcriptional regulator in vivo by modulating TATA-binding protein (TBP) DNA-binding activity. Although MOT1 was originally identified both biochemically and in several genetic screens as a transcriptional repressor, a combination of subsequent genetic, chromatin immunoprecipitation, and microarray analysis suggested that MOT1 might also have an additional role in vivo as a transcriptional activator. To better understand the role(s) of MOT1 in vivo, we selected for genomic suppressors of a mot1 temperature-sensitive mutation. This selection identified mutations in SPT15 (TBP) and BUR6, both of which are clearly linked with MOT1 at the functional level. The vast majority of the suppressor mutations, however, unexpectedly occurred in six genes that encode known components of the SUMO pathway and in two other genes with unknown functions, SLX5 and SLX8. Additional results presented here, including extensive synthetic lethality observed between slx5delta and slx8delta and SUMO pathway mutations, suggest that SLX5 and SLX8 are new components or regulators of the SUMO pathway and that SUMO modification might have a general role in transcriptional regulation as part of the TBP regulatory network.
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PMID:Genetic analysis connects SLX5 and SLX8 to the SUMO pathway in Saccharomyces cerevisiae. 1638 68

DNA repair is regulated on many levels by ubiquitination. In order to identify novel connections between DNA repair pathways and ubiquitin signaling, we used mass spectrometry to identify proteins that interact with lysine 6-linked polyubiquitin chains. From this proteomic screen, we identified the DNA repair protein WRNIP1 (Werner helicase-interacting protein 1), along with nucleosome assembly protein 1, as novel ubiquitin-interacting proteins. We found that a small zinc finger domain at the N terminus of WRNIP1 is sufficient and necessary for noncovalent ubiquitin binding. This ubiquitin-binding zinc finger (UBZ) domain binds polyubiquitin but not monoubiquitin and appears to show no specificity for polyubiquitin chain linkage. A homologous zinc finger domain in RAD18 also binds polyubiquitin, suggesting a wider role for the UBZ domain in DNA repair. The WRNIP1 ubiquitin-binding function, along with its previously established ATPase activity, suggests that WRNIP1 plays a role in the metabolism of ubiquitinated proteins. Supporting this model, deletion of MGS1, the yeast homolog of WRNIP1, slows the rate of ubiquitin turnover, rendering yeast resistant to cycloheximide. We also find that WRNIP1 is heavily modified with ubiquitin and SUMO, revealing complex layers in the involvement of ubiquitin pathway proteins in the regulation of DNA repair. The novel ubiquitin-binding ability of WRNIP1 sheds light on the role of UBZ domain-containing proteins in postreplication DNA repair.
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PMID:Werner helicase-interacting protein 1 binds polyubiquitin via its zinc finger domain. 1755 Aug 99

The protein Rad52 is a key player in various types of homologous recombination and is essential to maintenance of genomic integrity. Although evidence indicates that Rad52 is modified by SUMO, the physiological relevance of this sumoylation remains unclear. Here, we identify the conditions under which Rad52 sumoylation is induced, and clarify the role of this modification in homologous recombination. Oligomerization of Rad52 was a prerequisite for sumoylation, and the modification occurred in the cell proceeding S phase being exposed to the DNA-damaging agent methyl methanesulfonate (MMS). Following exposure to MMS, sumoylated Rad52 accumulated in rad51 cells, but not in the recombination-related gene mutants, rad54, rad55, rad59, sgs1, or srs2. The accumulation of sumoylated Rad52 was suppressed in rad51 cells expressing Rad51-K191R, an ATPase-defective protein presumed to be recruited to ssDNA. Although the sumoylation defective mutant rad52-3KR (K10R/K11R/K220R) showed no defect in mating-type switching, which did not lead to Rad52 sumoylation in wild-type cells, the mutant did demonstrate a partial defect in MMS-induced interchromosomal homologous recombination.
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PMID:Rad52 sumoylation and its involvement in the efficient induction of homologous recombination. 1839 68

Distinct chromatin remodeling complexes can share a common ATPase subunit. The functional characteristics of each remodeling complex are determined by the respective ATPase-associated subunits. The Mi-2 nucleosome remodeling ATPase has so far only been shown to reside within Nucleosome Remodeling and Deacetylase (NuRD) complexes. Here we will review the recent discovery of two Mi-2 related remodelers that function independently of NuRD and that act as SUMO (small ubiquitin-related modifier)-dependent corepressors: First, Mi-2 exists in a novel chromatin remodeling complex, dMec, that does not rely on histone deacetylation to effect transcriptional repression of proneural genes. Second, the Mi-2 related factor dCHD3 acts as a monomer and does not associate with additional subunits in vivo. These recent results have uncovered an unanticipated complexity in the composition and function of CHD (Chromodomain-Helicase-DNA-binding) complexes.
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PMID:Novel Mi-2 related ATP-dependent chromatin remodelers. 1953 3

The small ubiquitin-like modifier SUMO conjugates transcription factors and suppresses their respective activation of target genes. Although various SUMO-modified transcription factors have been isolated, mechanisms whereby sumoylated-substrates modulate transcription remain unknown. Here, we purified ARIP4 (AR interacting protein 4, a Rad54 family member and a SNF2 chromatin remodeling factor), which interacts with sumoylated Ad4BP/SF-1 through two SUMO-interacting motifs and one Ad4BP/SF-1-binding region. Remarkably, ARIP4 also interacts selectively with other sumoylated nuclear receptors including LRH-1, AR, and GR. Interestingly, the ATPase activity of ARIP4 was stimulated in the presence of sumoylated Ad4BP/SF-1 and the Ad4BP/SF-1-binding site containing double-stranded DNA. ChIP assays and siRNA studies strongly suggested that ARIP4 temporally suppresses Ad4BP/SF-1-mediated transcription through its transient recruitment to target genes. These findings suggest that ARIP4 may be a cofactor that modulates SUMO-mediated fine-tuning of transcriptional suppression.
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PMID:Transcriptional Suppression by Transient Recruitment of ARIP4 to Sumoylated nuclear receptor Ad4BP/SF-1. 1969 72

The Smc5/6 complex is an evolutionarily conserved chromosomal ATPase required for cell growth and DNA repair. Its Mms21 subunit supports both functions by docking to the arm region of Smc5 and providing SUMO ligase activity. Here, we report the crystal structure of Mms21 in complex with the Smc5 arm. Our structure revealed two distinct structural and functional domains of the Smc5-bound Mms21: its N-terminal half is dedicated to Smc5 binding by forming a helix bundle with a coiled-coil structure of Smc5; its C-terminal half includes the SUMO ligase domain, which adopts a new type of RING E3 structure. Mutagenesis and structural analyses showed that the Mms21-Smc5 interface is required for cell growth and resistance to DNA damage, while the unique Mms21 RING domain confers specificity to the SUMO E2-E3 interaction. Through structure-based dissection of Mms21 functions, our studies establish a framework for understanding its roles in the Smc5/6 complex.
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PMID:Structural and functional insights into the roles of the Mms21 subunit of the Smc5/6 complex. 1974 59

Post-translational modification of many transcription factors and cofactors by the small ubiquitin-related modifier SUMO has been correlated with transcriptional repression. Recent investigations of the molecular mechanisms underlying SUMO-dependent repression have identified diverse chromatin modifying enzymes and chromatin associated proteins as effectors of SUMO-dependent changes in chromatin structure and gene expression. A surprising diversity of proteins has been identified to be recruited to promoters in a SUMO-dependent manner, including the histone deacetylase HDAC2, the histone demethylase LSD1, the histone methyltransferase SETDB1, the nucleosome remodeling ATPase Mi-2, and chromatin-associated proteins HP1 and L3MBTL1 and L3MBTL2. These findings suggest that SUMOylation plays a central role in coordinating histone modifications and chromatin structure important for regulation of gene expression.
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PMID:SUMO engages multiple corepressors to regulate chromatin structure and transcription. 1982 68

The E1 helicase from BPV and HPV16 interacts with Ubc9 to facilitate viral genome replication. We report that HPV11 E1 also interacts with Ubc9 in vitro and in the yeast two-hybrid system. Residues in E1 involved in oligomerization (353-435) were sufficient for binding to Ubc9 in vitro, but the origin-binding and ATPase domains were additionally required in yeast. Nuclear accumulation of BPV E1 was shown previously to depend on its interaction with Ubc9 and sumoylation on lysine 514. In contrast, HPV11 and HPV16 E1 mutants defective for Ubc9 binding remained nuclear even when the SUMO pathway was inhibited. Furthermore, we found that K514 in BPV E1 and the analogous K559 in HPV11 E1 are not essential for nuclear accumulation of E1. These results suggest that the interaction of E1 with Ubc9 is not essential for its nuclear accumulation but, rather, depends on its oligomerization and binding to DNA and ATP.
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PMID:Characterization of papillomavirus E1 helicase mutants defective for interaction with the SUMO-conjugating enzyme Ubc9. 1983 47

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