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)

The activity of purified RNA polymerase II from Novikoff ascites tumor cells is stimulated 5-7-fold by a purified protein factor. This protein factor, designated HLF2, has extensive protein kinase activity and catalyzed the incorporation of gamma-32G from ATP into protein under normal RNA polymerase assay conditions. Protein phosphorylation is totally dependent on the presence of HLF2 and is stimulated 2-3-fold by the presence of highly purified RNA polymerase II. The purification procedure developed for the isolation of the polymerase stimulatory factor resulted in a 4000-fold purification of a protein kinase. Chromatography on carboxymethylcellulose, phosphocellulose, and Sephadex G-100 did not resolve polymerase stimulatory activity from protein kinase activity. Adenylimidodiphosphate (AMP-PNP), an inhibitor of protein kinases, inhibited the stimulatory activity of purified factor by 80%. The heat denaturation profile of protein kinase was paralleled by the loss of polymerase stimulatory activity. Concentrations of (NH4)2SO4 which are known to inhibit polymerase stimulation (Lee and Dahmus, 1973) also inhibit protein kinase activity. The protein kinase activity associated with stimulatory factor catalyzes the phosphorylation of basic proteins such as protamine or histone. The protein kinase is not stimulated by cyclic 3', 5'-AMP or -GMP over a concentration range of 10(-6)-10(-4)M. Furthermore, protein kinase activity is not inhibited by either the regulatory subunit of rabbit muscle protein kinase or by the heat-stable inhibitor of cyclic 3', 5'-AMP-dependent protein kinases. Protein kinase activity is stimulated by KCl or NH4Cl and is inhibited by MnCl2. The apparent Km values, determined in the presence of 4 mM Mg2+, are 0.02 mM for ATP, and 4.1 mM for GTP.
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PMID:Stimulation of ascites tumor RNA polymerase II by protein kinase. 17 56

The interaction of Mn2+, substrates and initiators with RNA polymerase have been studied by kinetic and magnetic resonance methods. As determined by electron paramagnetic resonance, Mn2+ binds to RNA polymerase at one tight binding site with a dissociation constant less than 10 muM and at 6 +/- 1 weak binding sites with dissociation constants 100-fold greater. The binding of Mn2+ to RNA polymerase at both types of sites causes an order of magnitude enhancement of the paramagnetic effect of Mn2+ on the longitudinal relaxation rate of water protons, indicating the presence of residual water ligands on the enzyme-bound Mn2+. A kinetic analysis of the Mn2+-activated enzyme with poly(dT) as template indicates the substrate to be MnATP under steady-state conditions in the presence or absence of the initiator ApA. ATP and UTP interact with the tightly bound Mn2+ to form ternary complexes with approximately 50% greater enhancement factors. The dissociation constant of MnATP from the tight Mn2+ site as determined by longitudinal proton relaxation rate (PRR) titration (4.7 muM) is similar to the KM of MnATP in the ApA-initiated RNA polymerase reaction (10 +/- 3 muM) but not in the ATP-initiated reaction (160 +/- 30 muM). Similarly, the dissociation constant of the substrate MnUTP from the tight Mn2+ site (90 muM) is in agreement with the KM of MnUTP (101 +/- 13 muM) when poly[d(A-T)]-poly[d(A-T)] is used as template, indicating the tight Mn2+ site to be the catalytic site for RNA chain elongation. Manganese adenylyl imidodiphosphate (MnAMP-PNP) has been found to be a substrate for RNA polymerase. It has the same affinity as MnATP for the tight site but, unlike the results obtained with MnATP, the enhancement is decreased by 43% in the enzyme Mn-AMP-PNP complex. These results suggest that the enzyme-bound Mn2+ interacts with the leaving pyrophosphate group. The initiators ApA and ApU and the inhibitor rifamycin interact with the enzyme-Mn2+ complex producing small (15-20%) decreases in the enhancement. The dissociation constant of ApA estimated from PRR data (less than or equal to 1.5 muM) agrees with that determined kinetically (1.0 +/- 0.5 muM) as the concentration of ApA required to produce half-maximal change in the KM of MnATP. In the presence of the initiation specific reagents ApA, ApU, or rifamycin, the affinity of the enzyme-Mn complex for ATP or UTP shows little change. However, ATP and UTP no longer increase the enhancement factor of the tightly bound Mn2+ but decrease it by 30-55%, indicating a change in the environment of the Mn2+-substrate complex on the enzyme when the initiation site is either occupied or blocked. Although the role of the six weak Mn2+ binding sites is not clear, the presence of a single tightly bound Mn2+ at the catalytic site for chain elongation which interacts with the substrate reinforces the number of active sites as one per molecule of holoenzyme and provides a paramagnetic reference point for further structural studies.
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PMID:Magnetic resonance and kinetic studies of the role of the divalent cation activator of RNA polymerase from Escherichia coli. 18 95

Adenosine (beta,gamma-imido)triphosphate (AMP-PNP) and guanosine (beta,gamma-imido)triphosphate (GMP-PNP) are analogs of ATP and GTP with non-hydrolyzable gamma-phosphates. Although both AMP-PNP and GMP-PNP were used in place of ATP and GTP by Escherichia coli RNA polymerase to transcribe vaccinia virus DNA, only GMP-PNP was used by the transcriptase present within vaccinia virus cores. AMP-PNP specifically prevented initiation of transcription, since RNA initiated in the presence of ATP, GTP, and CTP was subsequently elongated by incubating the washed cores in the presence of AMP-PNP, GTP, CTP, and UTP. The RNA formed in this manner, however, was (i) several times longer than normal transcripts, indicating a defect in chain termination and/or cleavage of nascent RNA, (ii) was not polyadenylylated (although free polyadenylic acid formed), and (iii) was not extruded from the virus cores. Nearest neighbor analysis demonstrated that AMP-PNP was incorporated adjacent to all four nucleotides, and hybridization to restriction endonuclease fragments of vaccinia virus DNA indicated that the high-molecular-weight RNA was transcribed from representative fractions of the entire genome. The possibility of a block in processing rather than or in addition to a block in chain termination was suggested by the cleavage of the high-molecular-weight RNA within the core after replacement of AMP-PNP with ATP. Cleavage of purified high-molecular-weight RNA by a soluble endoribonuclease extracted from vaccinia virus cores, however, was not dependent upon ATP, nor was it inhibited by AMP-PNP. The latter results suggest that AMP-PNP blocks a step preceding cleavage.
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PMID:Multiple roles for ATP in the synthesis and processing of mRNA by vaccinia virus: specific inhibitory effects of adenosine (beta,gamma-imido) triphosphate. 69 Nov 15

Cytoplasmic extracts made from HeLa cells that have been harvested late after infection with vaccinia virus are capable of specifically transcribing templates containing vaccinia virus late-gene promoters. We applied such an extract to a phosphocellulose column and eluted the proteins with a series of buffers containing successively higher concentrations of NaCl. None of three column fractions alone was capable of specific transcription of a late-gene template. However, specific transcriptase activity could be reconstituted by mixing column fractions, with maximal activity seen when all three fractions were present. The activities present in all fractions were heat labile, resistant to micrococcal nuclease, and present only in extracts from vaccinia virus-infected cells. A quantitative complementation assay was used to further purify one factor, named VLTF-1, over subsequent columns of DEAE-cellulose and hydroxylapatite. VLTF-1 was separated from endogenous RNA polymerase, was a late-promoter-specific transcription factor, and had a sedimentation rate consistent with an apparent Mr of 45,000. The RNA polymerase-containing fraction was not only necessary for transcription with a late-promoter template but alone was capable of specifically transcribing a vaccinia virus early-gene promoter. A further difference between early and late gene transcription in this system was in the ability of the ATP analog beta-8-imidoadenosine-5'-triphosphate (AMP-PNP) to substitute for ATP in supporting specific transcription of only the late-promoter template. The system reconstituted from the various fractions retained the ability to produce the novel poly(A) sequence found on the 5' end of vaccinia virus late messages.
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PMID:Identification of factors specific for transcription of the late class of vaccinia virus genes. 247 68

In vitro transcription by RNA polymerase II requires hydrolysis of the beta-gamma bond of ATP after the transcription complex forms, prior to RNA synthesis. It was observed that the presence of ATP during transcription complex formation inhibits subsequent transcription when the remaining 3 rNTPs are added. We now report that ATP or GTP inhibits transcription if either is present during transcription complex formation to added to preformed complexes. This inhibition is not due to purine rNTP degradation and occurs if as little as 2 mM ATP or 50 mM GTP is added to forming or preformed complexes. Deoxy derivatives of ATP inhibit similarly. AMP-PNP, a beta-gamma imido derivative, neither satisfies the energy requirement nor inhibits transcription if added to incubations of forming or of preformed transcription complexes.
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PMID:RNA polymerase II transcription complexes are destabilized by ATP or GTP. 276 22

In a continuation of previous efforts to study the modified ATP requirements for RNA synthesis by poIR mutants of vesicular stomatitis virus (VSV), we have used a novel reconstitution assay to show that it is the template moiety of the mutants, not the polymerase proteins, which governs both the increased utilization of the ATP analog, beta, gamma-imido ATP (AMP-PMP), and the loss of a positive cooperativity-like response to varying ATP concentrations. Assays utilized uv-irradiated virus as a source of polymerase proteins and purified N-RNA as templates. Homologous and heterologous transcriptase reactions were carried out with wild-type (wt) virus and each of the two independently isolated poIR mutants. We show that in the presence of wt N-RNA template, substitution of AMP-PNP for ATP resulted in only approximately 5% of control RNA synthesis regardless of which source of polymerase was used. Furthermore, all reactions containing wt N-RNA template responded to varying ATP concentrations with a concave, upward-shaped Lineweaver-Burke plot generally indicative of positive cooperativity effects. In contrast, all reactions which utilized N-RNA templates from the poIR mutants showed an increased utilization of AMP-PNP (greater than 20%) and a more characteristic Michaelis-Menten response to changing ATP concentrations. These findings strongly support the notion that the template-associated nucleocapsid protein modulates the utilization of an ATP site which is directly or indirectly involved in VSV RNA synthesis.
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PMID:Altered ATP utilization by the poIR mutants of vesicular stomatitis virus maps to the N-RNA template. 284 22

The ATP analog 5'-adenylyl imidodiphosphate (AMP-PNP) inhibits transcription of specific genes by the RNA polymerase II contained in whole cell extracts, not only with promoters that contain A as the first nucleotide of the transcript, but also with those that initiate transcripts with G or U. The analog AMP-PNP (a competitive inhibitor of ATP) probably acts at the level of initiation of transcription, but it can be used for elongation by RNA polymerase II in isolated nuclei or in the whole cell extract. AMP-PNP and the other imidotriphosphates have little effect on purified HeLa cell RNA polymerase II initiation and elongation of transcription. Since RNA polymerase III in the crude system both initiates and elongates transcripts with AMP-PNP, we conclude that the availability of the beta-gamma bond of ATP is an indispensable requirement for faithful and specific in vitro initiation only by RNA polymerase II in the whole cell extract. Uncapped U- or G-initiated transcripts were obtained in the presence of UMP-PNP or GMP-PNP, the respective imidodiphosphate analogs. The presence of the 5'-terminal imidotriphosphate at the same oligonucleotide as the cap for U-initiated precursors established that transcription initiation and capping occur at the same site. Capping is not required for transcription by RNA polymerase II in the in vitro system. Methylation of the 2' ribose of the initiating nucleotide does not occur on the imidonucleotide containing 5' ends of adenovirus EIV or murine leukemia virus long terminal repeat.
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PMID:Mechanism of RNA polymerase II--specific initiation of transcription in vitro: ATP requirement and uncapped runoff transcripts. 715 Nov 73

A basal repressor of class II gene transcription was identified, purified, and found to be identical to nonhistone chromosomal protein HMG2. HMG2 was shown to inhibit basal transcription under conditions in which transcription templates form soluble complexes with HMG2. Order-of-addition experiments clearly revealed that HMG2 acted after assembly of a TBP-TFIIA-promoter complex and before formation of the fourth phosphodiester bond by RNA polymerase II. Subsequently, an activity that efficiently counteracted repression of transcription by HMG2 in both TBP- and TFIID-containing transcription systems was isolated. Several lines of evidence suggested that antirepression was mediated by a TFIIH-associated factor. The antirepressor first coeluted with TFIIH, was depleted from this fraction by antibodies directed against the TFIIH subunit p62, was dependent on either ATP or dATP, and then was inhibited by the ATP analogs AMP-PNP and ATP gamma S. Relief of HMG2-mediated repression as well as basal promoter function of TFIIH may involve a helicase that coelutes with TFIIH and displays similar nucleotide specificities. Taken together, these data suggest novel consequences of chromatin-associated HMG proteins and they provide direct evidence for a role of TFIIH-associated enzymes in ATP-dependent antirepression of nonhistone chromosomal proteins.
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PMID:Repression of basal transcription by HMG2 is counteracted by TFIIH-associated factors in an ATP-dependent process. 800 73

Unlike most eukaryotic and prokaryotic RNA polymerases, promoter-specific transcription by RNA polymerase II requires hydrolysis of the ATP beta-gamma phosphoanhydride bond. Here we show that a template containing a 10-base pair DNA mismatch encompassing the start site circumvents this requirement such that the non-hydrolyzable ATP analogues, ATP gamma S (adenosine 5'-O-(thiotriphosphate)) and AMP-PNP (adenyl-5'-yl imidodiphosphate), support both basal and GAL4-VP16-activated transcription in a reconstituted HeLa cell in vitro transcription system. The results imply that ATP regulates either opening of the template at the start site or a closely associated step.
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PMID:A heteroduplex template circumvents the energetic requirement for ATP during activated transcription by RNA polymerase II. 802 Dec 41

When transcription by RNA polymerase II from the major-late (ML) promoter was studied with purified basal transcription factors, it was observed that transcription from negatively-supercoiled ML templates did not require transcription factor IIH (TFIIH). Addition of the basal factor TFIIE was highly stimulatory, but not absolutely required for this reaction. In contrast, transcription from relaxed or linear ML templates required both TFIIE and TFIIH. Adenylylimidodiphosphate (AMP-PNP), an ATP analog with a non-hydrolyzable beta-gamma phosphoanhydride bond, could support RNA synthesis from supercoiled templates, but not from linear templates. Since AMP-PNP cannot act as a cofactor for the DNA helicase activity of TFIIH, this finding independently supported the conclusion that TFIIH is not required for transcription of negatively-supercoiled templates. Taken together, these data indicate that the ATP-dependent step in transcription initiation by RNA polymerase II is caused by a requirement for the ATP-dependent helicase activity of the basal factor TFIIH. The experiments also show that transcription initiation by RNA polymerase II does not require hydrolysis of the beta-gamma phosphoanhydride bond of ATP per se.
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PMID:Transcription initiation by RNA polymerase II does not require hydrolysis of the beta-gamma phosphoanhydride bond of ATP. 831 84

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