Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Three overlapping RNA fragments containing the pseudoknot, as found in the tRNA-like structure of turnip yellow mosaic virus (TYMV) RNA, have been isolated and purified. Site-directed cleavage of TYMV RNA by RNase H, followed by ammonium sulphate precipitation and ion-exchange HPLC, yielded a pure preparation of a 3'-terminal, 112-nucleotide TYMV RNA fragment. Transcription of TYMV cDNA by T7 RNA polymerase, resulted in the isolation of an 88-nucleotide fragment. Finally, a 44-nucleotide fragment containing the TYMV RNA pseudoknot and strongly resembling the aminoacyl acceptor arm of the viral RNA was also synthesised using T7 RNA polymerase. The three fragments were isolated in milligram amounts and used for biochemical structure mapping, ultraviolet melting studies and NMR spectroscopy. Chemical modification with diethyl pyrocarbonate and sodium bisulphite and enzymatic digestion with RNase T1 confirmed the presence of the pseudoknot in the 44-nucleotide fragment. Also the analogue of the T-stem and T-loop of the tRNA-like structure of TYMV RNA was found. The results of modification at various temperatures in Mg2+-containing buffers were in general agreement with optical melting studies. Ultraviolet melting analysis of the longer fragments revealed their greater complexity and the results appear similar to those obtained for some tRNA species. To obtain direct biophysical evidence for base-pairing and stacking interactions in the pseudoknot, NMR studies were initiated. The first proton-NMR spectra ever obtained for plant viral RNA fragments are presented. NMR spectra were recorded at various buffer conditions and at various temperatures. The spectra for the 112-nucleotide and 88-nucleotide fragment are too complicated to be solved at present. In the case of the 44-nucleotide fragment, however, the imino proton resonances are well separated and this system turns out to be most promising for structural studies.
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PMID:Biochemical and biophysical analysis of pseudoknot-containing RNA fragments. Melting studies and NMR spectroscopy. 277 53

Transcription termination in vitro by vaccinia RNA polymerase is dependent on a trans-acting factor, VTF, that is associated with, if not identical to, the vaccinia mRNA capping enzyme. VTF-induced termination occurs approximately 50 nucleotides downstream of a signal sequence TTTTTNT in the non-transcribed templated strand; thus the cognate sequence UUUUUNU is expressed in the nascent RNA. To address the role of the nascent RNA in chain termination, the effects of nucleotide base analog substitutions were studied. Incorporation of bromo- (Br) UMP or iodo- (I) UMP into RNA abrogated factor-dependent termination without preventing the synthesis of read-through transcripts. Substitution of either ITP or 7'-methylguanosine for GTP did not inhibit factor-dependent termination, nor did the substitution of BrCTP or ICTP for CTP. The early transcripts synthesized in vitro were sensitive to RNase T2 but resistant to RNase H, indicating an absence of extensive hybridization of RNA product to the DNA template. Substitution of BrUTP for UTP did not alter the nuclease sensitivity of the transcripts, suggesting that increased stability of RNA:DNA hybrid structures did not account for the analog effects. These results are consistent with a model in which recognition of the primary sequence UUUUUNU in nascent RNA by the polymerase and/or VTF is required for transcription termination.
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PMID:Factor-dependent transcription termination by vaccinia virus RNA polymerase. Evidence that the cis-acting termination signal is in nascent RNA. 283 68

I have previously reported an activity in HeLa cells which facilitates transcript displacement by purified mammalian RNA polymerase II in vitro. I have shown that this activity copurifies with one of two separable ribonuclease (RNase) H activities in HeLa cells. The RNase H activity in question has characteristics similar to those reported for RNase H2b from calf thymus. RNase H proteins purified from several other sources including Escherichia coli also show renaturase activity. When the renaturase/RNase H protein is present during transcription by purified RNA polymerase II, transcripts are truncated close to the 5' end, and the remainder of the transcript is displaced normally from its template by the polymerase. Since RNA polymerase II dependent transcripts in vivo normally require the presence of the 5'-triphosphate terminus for capping, the in vivo significance of RNase H as a renaturase factor is presently not understood. However, the in vitro action of renaturase/RNase H suggests that the mechanism of this reaction may involve R-loop displacement after formation of a short single-stranded region of DNA on the template strand following hydrolysis of a hybrid transcript oligonucleotide by RNase H.
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PMID:Renaturase and ribonuclease H: a novel mechanism that influences transcript displacement by RNA polymerase II in vitro. 283 25

The replication of plasmid pBR322 DNA has been reconstituted with purified proteins from Escherichia coli. Initiation of the leading-strand requires RNA polymerase holoenzyme, DNA polymerase I, RNase H, and DNA gyrase. Initiation of the lagging-strand requires the primosomal proteins (the dnaB, dnaC, and dnaG proteins, replication factor Y (protein n') and proteins i, n, and n") and the single-stranded DNA binding protein. DNA polymerase III holoenzyme is required for extensive elongation of the nascent DNA chains. The products of this replication reaction are primarily nonsegregated daughter molecules. However, the addition of small amounts of soluble extract from E. coli results in the completion and segregation of these molecules to give mature form I DNA, suggesting that additional factors are required for this process. Topoisomerase I is necessary to make the replication system specific for pBR322 DNA as a template, indicating that the linking number of the DNA, determined by an equilibrium between the opposing activities of topoisomerase I and DNA gyrase, plays a crucial role in determining the reactivity of the DNA molecule toward initiating DNA replication. The function of the proteins involved in the replication of this closed-circular, double-stranded, superhelical DNA is discussed.
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PMID:Replication of pBR322 DNA in vitro with purified proteins. Requirement for topoisomerase I in the maintenance of template specificity. 299 Dec 40

Promoter properties were analyzed for the convergently-overlapped E. coli genes coding for the DNA polymerase III epsilon subunit (dnaQ) and the ribonuclease H (rnh). The rates of open complex formation for a single promoter of the rnh gene and two tandem promoters of the dnaQ gene were constant whether they are located on a single DNA fragment or separated into individual fragments. The relative expression levels of these three promoters, as measured using an in vitro mixed transcription system, varied differentially depending on the concentration of RNA polymerase. At low enzyme concentrations, the downstream promoter (P2) of the dnaQ gene was utilized preferentially, but the upstream promoter (P1) was utilized as well when the enzyme concentration was increased. This indicates different physiological roles between the two dnaQ promoters. The level of rnh transcription was as low as that of dnaQ-1 RNA synthesis but the rnh promoter was utilized as well as the dnaQ P2 promoter when it was separated from the dnaQ promoters. This implies a promoter interference between the convergently transcribed genes.
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PMID:Promoter selectivity of E. coli RNA polymerase: analysis of the promoter system of convergently-transcribed dnaQ-rnh genes. 299 1

More than ten proteins are known to participate in replication of plasmids bearing the unique origin of the Escherichia coli chromosome (oriC). Initiation of replication of oriC plasmids has been resolved into five separable stages. An initial complex formation (Stage I) requires an oriC plasmid, dnaA protein and HU protein. In the presence of ATP at a temperature of greater than 28 degrees C, a dnaB-C protein complex interacts to form a prepriming complex (Stage II). This is followed by extensive unwinding of the template that depends on the further addition of gyrase and single-strand binding protein (SSB) (Stage III). Hydrolysis of an rNTP by dnaB protein (a helicase action) and of ATP by gyrase (a swivelling action) drives the extreme unwinding of the template. This unwound template-protein complex is the substrate for priming by primase (Stage IV) and elongation by DNA polymerase III holoenzyme (Stage V). Priming of all DNA chains is done by primase; RNA polymerase functions in template activation rather than priming. DNA polymerase III holoenzyme, composed of at least seven subunits, synthesizes the DNA chains. The alpha subunit is the polymerase, the epsilon subunit is the 3'----5' exonuclease; alpha + epsilon is the proofreading activity. Following the synthesis of new DNA chains, DNA polymerase I and ribonuclease H remove the RNA primers, polymerase I fills the gaps, and ligase seals the daughter strands (Stage VI). Replication produces plasmids identical in structure and sequence to the initial template.
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PMID:Enzyme systems initiating replication at the origin of the Escherichia coli chromosome. 333 50

To analyze the specificity of RNA processing reactions, we constructed hybrid genes containing RNA polymerase III promoters fused to sequences that are normally transcribed by polymerase II and assessed their transcripts following transfection into human 293 cells. Transcripts derived from these chimeric constructs were analyzed by using a combined RNase H and S1 nuclease assay to test whether RNAs containing consensus 5' and 3' splicing signals could be efficiently spliced in intact cells, even though they were transcribed by RNA polymerase III. We found that polymerase III-derived RNAs are not substrates for splicing. Similarly, we were not able to detect poly(A)+ RNAs derived from genes that contained a polymerase III promoter linked to sequences that were necessary and sufficient to direct 3'-end cleavage and polyadenylation when transcribed by RNA polymerase II. Our findings are consistent with the view that in vivo splicing and polyadenylation pathways are obligatorily coupled to transcription by RNA polymerase II.
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PMID:Specificity of RNA maturation pathways: RNAs transcribed by RNA polymerase III are not substrates for splicing or polyadenylation. 368 96

Ten ribonucleic acid (RNA) tumor viruses grown in five different host cell species and three non-oncogenic viruses from three different virus groups have been examined for ribonuclease H content. Three different substrates were used to assay ribonuclease H: calf thymus [(3)H]RNA-deoxyribonucleic acid (DNA) hybrid prepared with denatured calf thymus DNA and Escherichia coli DNA-directed RNA polymerase, (3)H-polydenylic acid [(3)H-poly(A)] complexed to polydeoxythymidylic acid [poly(dT)], and (3)H-polyuridylic acid [(3)H-poly(U)] complexed to polydeoxyadenylic acid [poly(dA)]. All ten RNA tumor viruses contained ribonuclease H activity which degraded the RNA of both the calf thymus hybrid and poly(A)-poly(dT), whereas only the ribonuclease H in the Moloney strain of murine sarcoma-leukemia virus and in RD-feline leukemia virus hydrolyzed the RNA strand of poly(U)-poly(dA). No appreciable ribonuclease H activity was detected in influenza, Sendai, or vesicular stomatitis virus. The ribonuclease H and RNA-directed DNA polymerase activities in Moloney murine sarcoma-leukemia virus were inseparable by phosphocellulose chromatography or glycerol gradient centrifugation, but appeared to be partially separated by diethylaminoethyl-cellulose chromatography.
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PMID:Ribonuclease H: a ubiquitous activity in virions of ribonucleic acid tumor viruses. 411 67

Progress of the replication forks of the Escherichia coli chromosome depends on a multisubunit DNA polymerase (for chain elongation) and a primosome (for chain initiations), together comprising about 30 polypeptides with a mass in excess of 10(6) daltons. Integration of their actions with those of helicases and DNA binding proteins suggest a more complex and integrated replisome assembly with novel possibilities for concurrent replication of both parental strands. Initiation of a new cycle of chromosome replication at its unique 245-bp (oriC) is being studied in a soluble enzyme system with plasmids, autonomous replication of which depends on the oriC sequence. Required proteins include RNA polymerase, DNA gyrase, dnaA protein (with 4 strong binding sites in oriC), HU protein, and additional proteins (e.g., topoisomerase I and ribonuclease H) that confer oriC specificity by suppressing initiation of replication elsewhere on the duplex DNA. Clarification of the biochemical mechanisms of replication is fundamental for understanding cell growth and development. Knowledge of the biochemistry of initiating a cycle of chromosome replication opens the way toward exploring the regulation of the cell cycle. I remain faithful to the conviction that anything a cell can do, a biochemist should be able to do. He should do it even better, being freed from the constraints of substrate and enzyme concentrations, pH, ionic strength, and temperature, and by having the license to introduce novel reagents to drive or restrain a reaction. Put another way, one can be creative more easily with a reconstituted system. One can grapple directly with the molecules instead of trying by remote means to manipulate their structures or levels in the intact cell. Enzyme purification carries many dangers beyond the well-known exposure of the fragile enzyme to the hostilities of an unfamiliar environment, high dilution, glass containers and a denaturable investigator. But the rewards of enzyme purification have justified the effort. The polymerases, nucleases, ligases purified out of curiosity about the mechanisms of replication, repair and recombination have supplied the cast of actors responsible for the current drama of genetic engineering. Beyond the uses of these enzymes as reagents, understanding the mechanisms of DNA metabolism will have practical value in manipulating the replication of plasmids and viruses and the expression of their genes and, beyond that, in obtaining a more secure grasp of chromosome structure and function.
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PMID:Enzyme studies of replication of the Escherichia coli chromosome. 609 56

Reverse transcriptase isolated from avian myeloblastosis virus (AMV) and Rauscher murine leukemia virus (RLV) were examined for their ability to catalyze polymerization, ribonuclease H, pyrophosphate exchange, and pyrophosphorolysis reactions. A detailed characterization and a study of requirements for the expression of pyrophosphate exchange and pyrophosphorolysis reactions indicated that a variety of RNA and DNA template-primers supported these catalytic reactions. Furthermore, hydrogen bonding of template to primer was essential, although RNA:RNA template-primers, e.g. poly(rA) . (rU)9 or 70 S RNA . tRNA complex, were not utilized for these reactions. AMV enzyme required Mg2+, and RLV enzyme Mn2+, as the preferred divalent metal ion for the expression of these activities. Response of various catalytic reactions to site-specific inhibitors revealed that polymerization and pyrophosphate exchange reactions were susceptible to reagents that affected either the substrate or the template binding site, intrinsic zinc, or sulfhydryl groups. RNase H and pyrophosphorolysis activities, on the other hand, exhibited susceptibility only to the template site-specific reagent. We, therefore, conclude that RNase H and pyrophosphorolysis reactions are catalyzed through the template binding site while polymerization and pyrophosphate exchange reactions require additional participation of the substrate binding site, as well as that of intrinsic zinc and the presence of reactive sulfhydryl groups.
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PMID:Enzymatic activities associated with avian and murine retroviral DNA polymerases. Catalysis of and active site involvement in pyrophosphate exchange and pyrophosphorolysis reactions. 615 89


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