Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

We present DNA sequence data from a 35,364 bp region on the left arm of chromosome VII of Saccharomyces cerevisiae. This region contains 19 open reading frames (ORFs). ORF G1821 corresponds to the RAD54 gene involved in repair and recombination (Emery et al., 1991). G1810 is identical to the ACE1 gene sequenced by Szczypka and Thiele (1989), required for copper-inducible transcription of the CUP1 gene. The first 693 bp on the minus strand represent part of the 3' non-coding region from the P-type ATPase gene PMR1, previously sequenced by Rudolph et al. (1989), which is identical to the SSC1 gene (Smith et al., 1988). G1845 corresponds to the RCK1 protein kinase gene from S. cerevisiae (Dahlkvist and Sunnerhagen, 1994). G1861 is almost identical to the alpha-mannosidase gene AMS1 reported by Yoshihisa and Anraku (1989) and G1864 has 100% identity with the yeast CAL1 gene (Ohya et al., 1989)/CDC43 gene (Johnson et al., 1990) which is involved in control of cell polarity. This region also contains a gene specifying a Leu-tRNA precursor and a remnant of a tau element. ORF G1880 shows some similarity to the S. cerevisiae SNF2, STH1 and NPS1 genes and to the human ERCC1 gene. A 93 bp region shows similarity to yeast EST sequenced by Burns et al. (1994). None of the remaining ORFs has similarity to any sequence within the databases screened.
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PMID:DNA sequence analysis of a 35 kb segment from Saccharomyces cerevisiae chromosome VII reveals 19 open reading frames including RAD54, ACE1/CUP2, PMR1, RCK1, AMS1 and CAL1/CDC43. 858 24

Many proteins of the SNF2 family, which share a similar DNA-dependent ATPase/putative helicase domain, are involved in global transcriptional control and processing of DNA damage. We report here the partial cloning and characterization of 89B helicase, a gene encoding a new Drosophila melanogaster member of the SNF2 family. 89B Helicase protein shows a high degree of homology in its ATPase/helicase domain to the global transcriptional activators SNF2 and Brahma and to the DNA repair proteins ERCC6 and RAD54. It is, however, most strikingly similar to the Saccharomyces cerevisiae protein Mot1, a transcriptional repressor with many target genes for which no homologue has yet been described. 89B helicase is expressed throughout fly development and its large transcript encodes a >200 kDa protein. Staining with anti-89B Helicase antibodies reveals that the protein is present uniformly in early embryos and then becomes localized to the ventral nerve cord and brain. On the polytene chromosomes, 89B Helicase is bound to several hundred specific sites that are randomly distributed. The homology of 89B Helicase to Mot1, its widespread developmental expression and its large number of targets on the polytene chromosomes of larval salivary gland cells suggest that 89B Helicase may play a role in chromosomal metabolism, particularly global transcriptional regulation.
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PMID:Expanding the Mot1 subfamily: 89B helicase encodes a new Drosophila melanogaster SNF2-related protein which binds to multiple sites on polytene chromosomes. 877 90

The yeast SWI2/SNF2 polypeptide is a subunit of the SWI/SNF protein complex that is required for many transcriptional activators to function in a chromatin context. SWI2 is believed to be the founding member of a new subfamily of DNA-stimulated ATPases/DNA helicases that includes proteins that function in DNA repair (RAD5, RAD16, ERCC6), recombination (RAD54), transcription (MOT1, ISWI, brm, BRG1, hBRM) and cell cycle control (STH1). We have created a set of 16 mutations within the SWI2 ATPase domain and have analyzed the functional consequences of these mutations in vivo. We have identified residues within each of the seven ATPase motifs that are required for SWI2 function. We have also identified crucial residues that are interspersed between the known ATPase motifs. In contrast, we identify other highly conserved residues that appear to be dispensable for SWI2 function. We also find that single amino acid changes in ATPase motifs IV and VI lead to a dominant negative phenotype. None of the 12 SWI2 mutations that disrupt SWI2 activity in vivo alter the assembly of the SWI/SNF complex. These studies provide an invaluable framework for biochemical analysis of the SWI2 ATPase and for functional analysis of other SWI2 family members.
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PMID:Functional analysis of the DNA-stimulated ATPase domain of yeast SWI2/SNF2. 887 45

It was shown recently that mutations of the ATRX gene give rise to a severe, X-linked form of syndromal mental retardation associated with alpha thalassaemia (ATR-X syndrome). In this study, we have characterised the full-length cDNA and predicted structure of the ATRX protein. Comparative analysis shows that it is an entirely new member of the SNF2 subgroup of a superfamily of proteins with similar ATPase and helicase domains. ATRX probably acts as a regulator of gene expression. Definition of its genomic structure enabled us to identify four novel splicing defects by screening 52 affected individuals. Correlation between these and previously identified mutations with variations in the ATR-X phenotype provides insights into the pathophysiology of this disease and the normal role of the ATRX protein in vivo.
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PMID:ATRX encodes a novel member of the SNF2 family of proteins: mutations point to a common mechanism underlying the ATR-X syndrome. 896 41

The SNF2/Brahma proteins are a class of DNA-dependent ATPases which activate gene expression by disrupting chromatin repression. They also cooperate with nuclear hormone receptors to activate transcription. Two cDNAs encoding chicken homologues of the SNF2/Brahma proteins have been isolated from chicken haematopoietic libraries. The encoded proteins closely resemble the human homologues, hBRM and BRG1, and the chicken homologues have therefore been termed cBRH and cBRG1. Homology is conserved in five characteristic domains: an N-terminal domain that binds the SNF11 protein, a conserved domain A of unknown function, a central ATPase domain, a domain that binds the retinoblastoma tumor suppressor protein Rb, and a C-terminal bromodomain of unknown function.
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PMID:Isolation of cDNAs encoding chicken homologues of the yeast SNF2 and Drosophila Brahma proteins. 901 49

The human SNF2alpha (or hbrm) and SNF2beta (or BRG1) proteins have previously been shown to enhance transcriptional activation by nuclear receptors (NRs) in cultured human cells, and to be present in SWI/SNF complexes which are thought to be involved in control of transcription by facilitating remodelling of chromatin templates. Using the yeast two-hybrid system, we now demonstrate that the N-terminal regions of hSNF2alpha and hSNF2beta, preceding the DNA-dependent ATPase domain, specifically interact with the region of the estrogen receptor (ER) which includes the ligand binding domain and the ligand-dependent activation function AF-2. These interactions are increased by estrogen, but not by the ER AF-2 antagonist hydroxytamoxifen. Furthermore, mutants of ER that lack AF-2 activity are unable to interact with hSNF2alpha and -beta. These results suggest that the human homologues of the yeast SWI2/SNF2 protein may participate in the enhancement of transcription by the ER in vivo through interactions with the AF-2 activating domain, thus leading to ligand-dependent remodelling of chromatin templates.
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PMID:Ligand-dependent interaction between the estrogen receptor and the human homologues of SWI2/SNF2. 909 65

The SWI2/SNF2 gene family has been implicated in a wide variety of processes, involving regulation of DNA structure and chromatin configuration, mitotic chromosome segregation, and DNA repair. Here we report the characterization of the Zbu1 gene, also known as HIP116, located on human chromosome band 3q25, which encodes a DNA-binding member of this superfamily. Zbu1 was isolated in this study by its affinity for a site in the myosin light chain 1/3 enhancer. The protein has single-stranded DNA-dependent ATPase activity, includes seven helicase motifs, and a RING finger motif that is shared exclusively by the RAD5, spRAD8, and RAD16 family members. During mouse embryogenesis, Zbu1 transcripts are detected relatively late in fetal development and increase in neonatal stages, whereas the protein accumulates asynchronously in heart, skeletal muscle, and brain. In adult human tissues, alternatively spliced Zbu1 transcripts are ubiquitous with highest expression in these tissues. Gene expression is also dramatically induced in human tumor lines and in Li-Fraumeni fibroblast cultures, suggesting that it is aberrantly regulated in malignant cells. The developmental profile of Zbu1 gene expression and the association of the protein with a tissue-specific transcriptional regulatory element distinguish it from other members of the SWI2/SNF2 family and suggest novel roles for the Zbu1 gene product.
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PMID:Developmental regulation of Zbu1, a DNA-binding member of the SWI2/SNF2 family. 912 92

The complete sequence of a 36 196 bp DNA segment located on the right arm of chromosome XV of Saccharomyces cerevisiae has been determined and analysed. The sequence includes the 5' coding region of the SNF2 gene, the CPA1 leader peptide sequence and 17 open reading frames (ORFs) of at least 100 amino acids. Two of these correspond to previously known genes (CPA1, SLY41), whereas 15 correspond to new genes. The putative translation products of three ORFs show significant similarity with known proteins: one is a putative transport ATPase, another appears to be a ribosomal protein, and the third is an Snf2p homologue.
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PMID:Sequence and analysis of a 36.2 kb fragment from the right arm of yeast chromosome XV reveals 19 open reading frames including SNF2 (5' end), CPA1, SLY41, a putative transport ATPase, a putative ribosomal protein and an SNF2 homologue. 915 58

MOT1 is an essential Saccharomyces cerevisiae protein and a member of the SNF2/SWI2 family of ATPases. MOT1 functions by removing TATA-binding protein (TBP) from DNA, and as a consequence, MOT1 can regulate transcription both in vitro and in vivo. Here we describe the in vivo and in vitro activities of MOT1 deletion and substitution mutants. The results indicate that MOT1 is targeted to TBP both in vitro and in vivo via amino acids in its nonconserved N terminus. The conserved C-terminal ATPase of MOT1 appears to contribute to TBP-DNA complex recognition in the absence of ATP, but it appears to function primarily during the actual ATP-dependent dissociation reaction. Chimeric proteins in which homologous portions of SNF2/SWI2 have been substituted for the MOT1 ATPase can bind to TBP-DNA complexes but fail to dissociate these complexes in the presence of ATP, suggesting that the specificity of action of MOT1 is also conferred by the C-terminal ATPase. ATPase assays demonstrate that the MOT1 ATPase is activated by TBP. Thus, MOT1 undergoes at least two conformational changes: (i) an allosteric effect of TBP that mediates the activation of the MOT1 ATPase and (ii) an ATP-driven "power stroke" that causes TBP-DNA complex dissociation. These results provide a general framework for understanding how members of the SNF2/SWI2 protein family use ATP to modulate protein-DNA interactions to regulate many diverse processes in cells.
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PMID:Molecular analysis of the SNF2/SWI2 protein family member MOT1, an ATP-driven enzyme that dissociates TATA-binding protein from DNA. 923 40

The murine gene CHD1 (MmCHD1) was previously isolated in a search for proteins that bound a DNA promoter element. The presence of chromo (chromatin organization modifier) domains and an SNF2-related helicase/ATPase domain led to speculation that this gene regulated chromatin structure or gene transcription. This study describes the cloning and characterization of three novel human genes related to MmCHD1. Examination of sequence databases produced several more related genes, most of which were not known to be similar to MmCHD1, yielding a total of 12 highly conserved CHD genes from organisms as diverse as yeast and mammals. The major region of sequence variation is in the C-terminal part of the protein, a region with DNA-binding activity in MmCHD1. Targeted deletion of ScCHD1, the sole Saccharomyces cerevesiae CHD gene, was performed with deletion strains being less sensitive than wild type to the cytotoxic effect of 6-azauracil. This finding suggested that enhanced transcriptional arrest at RNA polymerase II pause sites due to 6-azauracil-induced nucleotide pool depletion was reduced in the deletion strain and that ScCHD1 inhibited transcription. This observation, along with the known roles of other proteins with chromo or SNF2-related helicase/ATPase domains, suggests that alteration of gene expression by CHD genes might occur by modifications of chromatin structure, with altered access of the transcriptional apparatus to its chromosomal DNA template.
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PMID:Characterization of the CHD family of proteins. 932 34


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