EC:2.7.7.6 - FACTA Search

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Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

DNA methyltransferase was purified 310-fold from a green alga, Chlamydomonas reinhardi vegetative cells. The native enzyme of molecular weight 55 000--58 000 catalyzed the transfer of methyl groups from S-adenosylmethionine to the 5 position of cytosine in DNA. Native DNA accepted methyl groups 10-fold more than did denatured DNA. The sequence specificity analysis of methylated deoxycytidine in vitro revealed that the enzyme introduces methyl groups preferentially into sequences containing 5'd(T-mC-R)3'. Kinetic analysis of the reaction indicated that the enzyme obeys a random sequential mechanism. The extent of saturation with methyl groups depends upon the species from which the DNA was obtained. Kinetic analysis of the reaction catalyzed by RNA polymerase II has indicated that DNA methylation decreases the rate of initiation of RNA synthesis, but does not affect the rate of RNA chain elongation.
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PMID:Deoxyribonucleic acid methyltransferase from the eukaryote, Chlamydomonas reinhardi. 737 44

The effect of 5-aza-CR and 5-aza-2'-deoxycytidine (5-aza-CdR) on cell differentiation and DNA methylation of HL-60 cells was studied. The differentiation index of HL-60 cells was measured after being treated with drugs by using the NBT stain method. DNA methylase activities of HL-60 cells treated with the drugs were assayed by using 3H-methyl-S-adenosylmethionine (3H-SAM) as a methyl donor. The DNA methylation level of HL-60 cells treated with the drugs was measured by HPLC. The results showed that the HL-60 cell differentiation index was increased after being treated with 5-aza-CR or 5-aza-CdR at a certain concentration for 4 days. But, at the same time, DNA methylase activity and the DNA methylation level were decreased. And all these changes were related to the concentration of the drugs. 5-Aza-CdR was more efficient than 5-aza-CR. We also assayed the E. coli RNA polymerase activity in vitro by using different DNA templets different in DNA methylation level. We found that the transcriptional activity of RNA polymerase was increased with the decrease of the DNA methylation level of HL-60 cells.
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PMID:The effect of 5-azacytidine (5-aza-CR) and its analogue on cell differentiation and DNA methylation of HL-60 cells. 769 Oct 71

Escherichia coli ada ogt mutants, which are totally deficient in O6-methylguanine-DNA methyltransferases, have an increased spontaneous mutation rate. This phenotype is particularly evident in starving cells and suggests the generation of an endogenous DNA alkylating agent under this growth condition. We have found that in wild-type cells, the level of the inducible Ada protein is 20-fold higher in stationary-phase and starving cells than in rapidly growing cells, thus enhancing the defense of these cells against DNA damage. The increased level of Ada in stationary cells is dependent on RpoS, a stationary-phase-specific sigma subunit of RNA polymerase. We have also identified a potential source of the mutagenic agent. Nitrosation of amides and related compounds can generate directly acting methylating agents and can be catalyzed by bacteria] enzymes. E. coli moa mutants, which are defective in the synthesis of a molybdopterin cofactor required by several reductases, are deficient in nitrosation activity. It is reported here that a moa mutant shows reduced generation of a mutagenic methylating agent from methylamine (or methylurea) and nitrite added to agar plates. Moreover, a moa mutation eliminates much of the spontaneous mutagenesis in ada ogt mutants. These observations indicate that the major endogenous mutagen is not S-adenosylmethionine but arises by bacterially catalyzed nitrosation.
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PMID:Generation of an endogenous DNA-methylating agent by nitrosation in Escherichia coli. 875 26

A BHK cell line persistently expressing a Kunjin (KUN) virus replicon RNA (repBHK, similar to our recently described ME/76Neo BHK cell line [A. A. Khromykh and E. G. Westaway, J. Virol. 71:1497-1505, 1997]) was used for rescue and propagation of KUN viruses defective in the RNA polymerase gene (NS5). A new infectious full-length KUN virus cDNA clone, FLSDX, prepared from our previously described cDNA clone pAKUN (A. A. Khromykh and E. G. Westaway, J. Virol. 68:4580-4588, 1994) and possessing approximately 10(5)-fold higher specific infectivity than that of pAKUN, was used for preparation of defective mutants. Deletions of the predicted RNA polymerase motif GDD (producing FLdGDD) and of one of the predicted methyltransferase motifs (S-adenosylmethionine [SAM] binding site, producing FLdSAM) were introduced separately into FLSDX. Transcription and transfection of FLdGDD and FLdSAM RNAs into repBHK cells but not into normal BHK cells resulted in their replication and the recovery of defective viruses able to replicate only in repBHK cells. Reverse transcription-PCR and sequencing analyses showed retention of the introduced deletions in the genomes of the recovered viruses. Retention of these deletions, as well as our inability to recover viruses able to replicate in normal BHK cells after prolonged incubation (for 7 days) of FLdGDD- or FLdSAM-transfected repBHK cells, excluded the possibility that recombination had occurred between the deleted defective NS5 genes present in transfected RNAs and the functional NS5 gene present in the repBHK cells. An RNA with a point mutation in the GDD motif (FLGVD) was also complemented in transfected repBHK cells, and defective virus was recovered by day 3 after transfection. However, in contrast to the results with FLdGDD and FLdSAM RNAs, prolonged (4 days or more) incubation of FLGVD RNA in normal BHK cells allowed recovery of a virus in which the GVD mutation had reverted via a single base change to the wild-type GDD sequence. Overall, these results represent the first demonstration of trans-complementation of defective flavivirus RNAs with deleterious deletions in the flavivirus RNA polymerase gene NS5. The complementation system described here may prove to be useful for the in vivo complementation of deletions and mutations affecting functional domains or the essential secondary structure in any of the other flavivirus nonstructural proteins.
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PMID:trans-Complementation of flavivirus RNA polymerase gene NS5 by using Kunjin virus replicon-expressing BHK cells. 969 22

Guanine N-7 methylation is an essential step in the formation of the m7GpppN cap structure that is characteristic of eukaryotic mRNA 5' ends. The terminal 7-methylguanosine is recognized by cap-binding proteins that facilitate key events in gene expression including mRNA processing, transport, and translation. Here we describe the cloning, primary structure, and properties of human RNA (guanine-7-)methyltransferase. Sequence alignment of the 476-amino acid human protein with the corresponding yeast ABD1 enzyme demonstrated the presence of several conserved motifs known to be required for methyltransferase activity. We also identified a Drosophila open reading frame that encodes a putative RNA (guanine-7-)methyltransferase and contains these motifs. Recombinant human methyltransferase transferred a methyl group from S-adenosylmethionine to GpppG 5'ends, which are formed on RNA polymerase II transcripts by the sequential action of RNA 5'-triphosphatase and guanylyltransferase activities in the bifunctional mammalian capping enzyme. Binding studies demonstrated that the human cap methyltransferase associated with recombinant capping enzyme. Consistent with selective capping of RNA polymerase II transcripts, methyltransferase also formed ternary complexes with capping enzyme and the elongating form of RNA polymerase II.
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PMID:Recombinant human mRNA cap methyltransferase binds capping enzyme/RNA polymerase IIo complexes. 970 70

The rates of transcription of several protein coding genes during Acanthamoeba differentiation have been examined by nuclear run-on and RNase protection assays. During early encystment, transcription by RNA polymerase II increases approximately 4-fold, whereas transcription by RNA polymerases I and III is decreased, as previously described. The rates of transcription from a wide variety of individual genes are only slightly affected during the first 16 h of encystment, although profilin gene expression is markedly increased. The levels of mRNAs encoding TPBF, TATA binding protein, cyclin-dependent kinase, protein disulfide isomerase, profilin, myosin II heavy chain, ubiquitin and extendin are stable during mature cyst formation, whereas mRNAs encoding actin, S-adenosyl methionine synthase and tubulin are substantially decreased in abundance within 16 h of starvation-induced encystment. We conclude that in contrast to the negative regulation of large rRNA and 5S rRNA synthesis during differentiation, the RNA polymerase II transcription apparatus is not negatively regulated. Control of Acanthamoeba differentiation is likely to be mediated by positive regulation of genes necessary for cyst maturation.
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PMID:Transcription by RNA polymerase II during Acanthamoeba differentiation. 987 98

Gcd10p and Gcd14p were first identified genetically as repressors of GCN4 mRNA translation in Saccharomyces cerevisiae. Recent findings indicate that Gcd10p and Gcd14p reside in a nuclear complex required for the presence of 1-methyladenosine in tRNAs. Here we show that Gcd14p is an essential protein with predicted binding motifs for S-adenosylmethionine, consistent with a direct function in tRNA methylation. Two different gcd14 mutants exhibit defects in cell growth and accumulate high levels of initiator methionyl-tRNA (tRNAiMet) precursors containing 5' and 3' extensions, suggesting a defect in processing of the primary transcript. Dosage suppressors of gcd10 mutations, encoding tRNAiMet (hcIMT1 to hcIMT4; hc indicates that the gene is carried on a high-copy-number plasmid) or a homologue of human La protein implicated in tRNA 3'-end formation (hcLHP1), also suppressed gcd14 mutations. In fact, the lethality of a GCD14 deletion was suppressed by hcIMT4, indicating that the essential function of Gcd14p is required for biogenesis of tRNAiMet. A mutation in GCD10 or deletion of LHP1 exacerbated the defects in cell growth and expression of mature tRNAiMet in gcd14 mutants, consistent with functional interactions between Gcd14p, Gcd10p, and Lhp1p in vivo. Surprisingly, the amounts of NME1 and RPR1, the RNA components of RNases P and MRP, were substantially lower in gcd14 lhp1::LEU2 double mutants than in the corresponding single mutants, whereas 5S rRNA was present at wild-type levels. Our findings suggest that Gcd14p and Lhp1p cooperate in the maturation of a subset of RNA polymerase III transcripts.
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PMID:GCD14p, a repressor of GCN4 translation, cooperates with Gcd10p and Lhp1p in the maturation of initiator methionyl-tRNA in Saccharomyces cerevisiae. 1033 Jan 57

The oocyte nuclear antigen of the monoclonal antibody 32-5B6 of Xenopus laevis is subject to regulated nuclear translocation during embryogenesis. It is distributed in the cytoplasm during oocyte maturation, where it remains during cleavage and blastula stages, before it gradually reaccumulates in the nuclei during gastrulation. We have now identified this antigen to be the enzyme S-adenosylhomocysteine hydrolase (SAHH). SAHH is the only enzyme that cleaves S-adenosylhomocysteine, a reaction product and an inhibitor of all S-adenosylmethionine-dependent methylation reactions. We have compared the spatial and temporal patterns of nuclear localization of SAHH and of nuclear methyltransferase activities during embryogenesis and in tissue culture cells. Nuclear localization of Xenopus SAHH did not temporally correlate with DNA methylation. However, we found that SAHH nuclear localization coincides with high rates of mRNA synthesis, a subpopulation colocalizes with RNA polymerase II, and inhibitors of SAHH reduce both methylation and synthesis of poly(A)(+) RNA. We therefore propose that accumulation of SAHH in the nucleus may be required for efficient cap methylation in transcriptionally active cells. Mutation analysis revealed that the C terminus and the N terminus are both required for efficient nuclear translocation in tissue culture cells, indicating that more than one interacting domain contributes to nuclear accumulation of Xenopus SAHH.
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PMID:Nuclear accumulation of S-adenosylhomocysteine hydrolase in transcriptionally active cells during development of Xenopus laevis. 1058 58

S-Adenosyl-L-methionine decarboxylase (AdoMetDC; EC 4.1.1.50) is one of the key regulatory enzymes in the biosynthesis of polyamines. Isolation of genomic and cDNA sequences from rice and Arabidopsis had indicated that this enzyme is encoded by a small multigene family in monocot and dicot plants. Analysis of rice, maize and Arabidopsis AdoMetDC cDNA species revealed that the monocot enzyme possesses an extended C-terminus relative to dicot and human enzymes. Interestingly, we discovered that all expressed plant AdoMetDC mRNA 5' leader sequences contain a highly conserved pair of overlapping upstream open reading frames (uORFs) that overlap by one base. The 5' tiny uORF consists of two or three codons and the 3' small uORF encodes 50-54 residues. Sequences of the small uORFs are highly conserved between monocot, dicot and gymnosperm AdoMetDC mRNA species and the C-terminus of the plant small uORFs is conserved with the C-terminus of nematode AdoMetDC uORFs; such a conserved arrangement is strongly suggestive of a translational regulatory mechanism. No introns were found in the main AdoMetDC proenzyme ORF from any of the plant genes encoding AdoMetDC, whereas introns were found in conserved positions flanking the overlapping uORFs. The absence of the furthest 3' intron from the Arabidopsis gene encoding AdoMetDC2 suggests that this intron was lost recently. Reverse-transcriptase-mediated PCR analysis of the two Arabidopsis genes for AdoMetDC indicated that AdoMetDC1 is abundant and ubiquitous, whereas the gene for AdoMetDC2 is expressed preferentially in leaves and inflorescences. Investigation of recently released Arabidopsis genome sequences has revealed that in addition to the two genes encoding AdoMetDC isolated as part of the present work, four additional genes are present in Arabidopsis but they are probably not expressed.
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PMID:Characterization of monocot and dicot plant S-adenosyl-l-methionine decarboxylase gene families including identification in the mRNA of a highly conserved pair of upstream overlapping open reading frames. 1113 6

S-adenosylhomocysteine hydrolase (SAHH) is the only enzyme known to cleave S-adenosylhomocysteine (SAH), a product and an inhibitor of all S-adenosylmethionine-dependent transmethylation reactions. Xenopus SAHH is a nuclear enzyme in transcriptionally active cells and inhibition of xSAHH prevents cap methylation of hnRNA [Mol. Biol. Cell 10 (1999) 4283]. Here, we demonstrate that inhibition of xSAHH in Xenopus XTC cells results in a cytoplasmic accumulation of the shuttling hnRNPs, while xSAHH itself remains in the nucleus. The functional link between xSAHH and mRNA cap methylation is further supported by a physical association between xSAHH and mRNA(guanine-7-)methyltransferase (CMT). We show by co-immunoprecipitation of tagged proteins that both enzymes interact in vivo. Direct interaction in vitro is shown by pull-down experiments that further demonstrate that the N-terminal 55 amino acids of xSAHH are sufficient for binding to CMT. Since CMT is known to bind to the hyperphoshorylated C-terminal domain (CTD) of its large subunit of RNA polymerase II, we have studied the co-localisation of RNA polymerase II and xSAHH in oocyte nuclei. Immunolocalisation on spreads of lampbrush chromosomes shows xSAHH on the loops of the transcriptionally active lampbrush chromosomes, in Cajal bodies and in B-snurposomes, the nuclear compartments that are most likely engaged in storage and recycling of RNA polymerase II and its cofactors. We therefore suggest that a subfraction of the nuclear xSAHH remains associated with the RNA polymerase holoenzyme complexes, also while these are not actively engaged in transcription.
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PMID:Interaction of S-adenosylhomocysteine hydrolase of Xenopus laevis with mRNA(guanine-7-)methyltransferase: implication on its nuclear compartmentalisation and on cap methylation of hnRNA. 1206 72

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