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)

During carbon-starvation-induced entry into stationary phase, Escherichia coli cells exhibit a variety of physiological and morphological changes that ensure survival during periods of prolonged starvation. Induction of 30-50 proteins of mostly unknown function has been shown under these conditions. In an attempt to identify C-starvation-regulated genes we isolated and characterized chromosomal C-starvation-induced csi::lacZ fusions using the lambda placMu system. One operon fusion (csi2::lacZ) has been studied in detail. csi2::lacZ was induced during transition from exponential to stationary phase and was negatively regulated by cAMP. It was mapped at 59 min on the E. coli chromosome and conferred a pleiotropic phenotype. As demonstrated by two-dimensional gel electrophoresis, cells carrying csi2::lacZ did not synthesize at least 16 proteins present in an isogenic csi2+ strain. Cells containing csi2::lacZ or csi2::Tn10 did not produce glycogen, did not develop thermotolerance and H2O2 resistance, and did not induce a stationary-phase-specific acidic phosphatase (AppA) as well as another csi fusion (csi5::lacZ). Moreover, they died off much more rapidly than wild-type cells during prolonged starvation. We conclude that csi2::lacZ defines a regulatory gene of central importanc e for stationary phase E. coli cells. These results and the cloning of the wild-type gene corresponding to csi2 demonstrated that the csi2 locus is allelic with the previously identified regulatory genes katF and appR. The katF sequence indicated that its gene product is a novel sigma factor supposed to regulate expression of catalase HPII and exonuclease III (Mulvey and Loewen, 1989). We suggest that this novel sigma subunit of RNA polymerase defined by csi2/katF/appR is a central early regulator of a large starvation/stationary phase regulon in E. coli and propose 'rpoS' ('sigma S') as appropriate designations.
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PMID:Identification of a central regulator of stationary-phase gene expression in Escherichia coli. 184 9

We previously described the purification and characterization of E1BF, a rat rRNA gene core promoter-binding factor that consists of two polypeptides of 89 and 79 kDa. When this factor was incubated in the absence of any exogenous protein kinase under conditions optimal for protein phosphorylation, the 79-kDa polypeptide of E1BF was selectively phosphorylated. The labeled phosphate could be removed from the E1BF polypeptide by treatment with calf intestinal alkaline phosphatase or potato acid phosphatase. Elution of the protein from the E1BF-promoter complex formed in an electrophoretic mobility-shift assay followed by incubation of the concentrated eluent with [gamma-32P] ATP resulted in the selective labeling of the 79-kDa band. The E1BF-associated protein kinase did not phosphorylate casein or histone H1. Fraction DE-B, a preparation containing RNA polymerase I and all polymerase I transcription factors (including E1BF), lost polymerase I transcriptional activity when treated with phosphatase. The phosphatase-induced inactivation of polymerase I activity associated with fraction DE-B could be reversed by the addition of purified E1BF. Treatment of purified E1BF with heat, SDS, or an ATP affinity analog eliminated its capacity to reactivate dephosphorylated fraction DE-B. These data demonstrate that (i) polymerase I promoter-binding factor E1BF contains an intrinsic substrate-specific protein kinase and (ii) E1BF is an essential polymerase I transcription factor that can modulate rRNA gene transcription by protein phosphorylation. Further, these studies have provided a direct means to identify a protein kinase or any other enzyme that can interact with a specific DNA sequence.
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PMID:E1BF is an essential RNA polymerase I transcription factor with an intrinsic protein kinase activity that can modulate rRNA gene transcription. 192 88

Nuclei from sea urchin blastula embryos synthesize a variety of small RNAs, one of which has identical mobility with sea urchin U1 RNA. This RNA is synthesized by RNA polymerase II and, in a hybridization-selection experiment, was selected by the cloned sea urchin U1 gene. The U1 RNA was initiated with ATP, but not GTP, in isolated nuclei with beta-S- and gamma-S-ribonucleotide triphosphates as substrates. The U1 RNA containing thiophosphate at the 5' end was not capped but accumulated as an uncapped transcript from which the thiophosphate could be removed with calf intestinal phosphatase.
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PMID:Synthesis of U1 RNA in isolated nuclei from sea urchin embryos: U1 RNA is initiated at the first nucleotide of the RNA. 258 39

The factor(s) responsible for the adenovirus E1A-stimulated transcription of RNA polymerase III genes was localized previously in a chromatographic fraction containing transcription factor IIIC (TFIIIC). In further studies, two distinct forms of TFIIIC, which were chromatographically separable, generated VA gene-protein complexes that were distinguished by gel shift assays. The form of TFIIIC that generated the more slowly migrating promoter complex had greater transcriptional activity in vitro, associated more rapidly with the promoter, and formed a more salt-resistant complex. Greater amounts of this more active form of TFIIIC resulted from either E1A expression during infection or growth of the cells in a higher concentration of serum, whereas template commitment assays indicated that overall TFIIIC concentrations remained unchanged during viral infection. The in vitro interconversion of the two forms of TFIIIC by phosphatase treatment suggests that transcriptional activation of RNA polymerase III genes can be mediated by phosphorylation of TFIIIC.
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PMID:Activation of transcription factor IIIC by the adenovirus E1A protein. 296 57

Antisera were raised in rabbits against fusion proteins consisting of beta-galactosidase and partial amino acid sequences of Semliki Forest virus (SFV)-specific non-structural proteins nsP1, nsP2, nsP3 and nsP4. The antisera were specific since each of them precipitated only one labelled protein of a size expected for nsP1, nsP2, nsP3 or nsP4 from lysates of [35S]methionine-labelled SFV-infected BHK-21 cells. The specific antisera also precipitated p220 (with sequences of nsP1, nsP2 and nsP3), p155 (nsP1 and nsP2) and p135 (nsP3 and nsP4) which have been previously shown to be cleavage products of the polyprotein precursor of the non-structural proteins. nsP1, nsP4 and most of nsP3, together with the virus-specific RNA polymerase activity, were in the mitochondrial pellet (P15) fraction of infected BHK-21 cells whereas nsP2 was evenly distributed between P15 and the supernatant fraction (S15). Only antisera directed against nsP3 sequences precipitated a labelled protein from cells incubated with [32P]orthophosphate during SFV infection. Treatment of the immunoprecipitate with calf alkaline intestinal phosphatase reduced the amount of labelled nsP3 considerably. Immunoprecipitated 32P-labelled nsP3, isolated by SDS-PAGE, was subjected to acid hydrolysis. Both phosphoserine and phosphothreonine but not phosphotyrosine could be identified in the hydrolysate. Approximately twice as much [32P]serine as [32P]threonine was detected in nsP3. P15 and S15 fractions were prepared from [35S]methionine- and 32P-labelled SFV-infected cells and the 35S/32P ratio of nsP3 was determined after immunoprecipitation and SDS-PAGE. The nsP3 in S15 was less heavily phosphorylated (about 50%) than P15-associated nsP3. Anti-nsP3 serum revealed large cytoplasmic vesicles in SFV-infected cells in indirect immunofluorescence microscopy.
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PMID:Semliki Forest virus-specific non-structural protein nsP3 is a phosphoprotein. 297 May 23

Treatment of insect polyribosomes with 1 M KCl released a messenger ribonucleoprotein with a pronounced 16S peak. Phenol extraction resulted in a defined peak of 10S RNA, which was judged as mRNA by the following criteria: it showed specificity for binding to ribosomes, and the formation of initiation complex was dependent on protein initiation factors, GTP, mRNA, and aminoacyl-tRNA. The complex directed protein synthesis upon the addition of elongation factors. mRNA was treated with phosphatase and phosphorylated at the 5'-end with [(32)P]cyanoethylphosphate. [(32)P]mRNA was digested by T1 ribonuclease to completion and chromatographed on DEAE-cellulose. The only fragment with (32)P was 15 nucleotides long; it was treated with pancreatic ribonuclease and fingerprinted. Fractions of AC, AAC, and AAAC were found. Initiation signal AUG or GUG in these mRNAs does not begin immediately at the 5'-end and may be at a distance greater than 15 nucleotides. Alkaline hydrolysis of mRNAs labeled in vivo with [(14)C]adenosine revealed Ap and pppAp. Alkaline hydrolysis of mRNA labeled with (32)P at the 5'-terminus resulted in pAp. Hence, these results suggest that in a heterogeneous population of mRNAs from insects, all start with A and have sequence homology at the 5'-termini. This sequence may reflect the signal for RNA polymerase on the gene or may promote the binding of mRNA to ribosomes.
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PMID:Sequence homology at the 5'-termini of insect messenger RNAs. 435 Nov 73

The administration of a single dose of aflatoxin B(1) to the rat (7mg./kg. body wt.) results in the slow development of a periportal necrosis. Hepatic enzymes are released into the serum in the second 24hr. of the poisoning, closely preceding the onset of the necrosis, which is followed by a rise in serum alkaline-phosphatase activity and bilirubin concentration. Aflatoxin B(1) has been detected in the nucleus of the poisoned liver cell and in vitro it has been shown to interact with DNA. The toxin inhibits the production of nuclear RNA, probably by preventing the transcription of DNA by the RNA polymerase. It is proposed that the interaction of the toxin with DNA gives rise to its inhibitory action on mitosis and its necrogenic action.
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PMID:The action of aflatoxin B1 on the rat liver. 603 Mar 2

A protein factor which stimulates DNA polymerase alpha activity on heat-denatured DNA has been purified from mouse FM3A cells. The final preparation had a specific activity of 43,000 units/mg protein and lacked detectable DNA polymerase, RNA polymerase, DNA-dependent- and independent ATPase, exo- and endodeoxyribonuclease and phosphatase activities. The stimulating factor sedimented at 2.9S in a glycerol gradient. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of the glycerol gradient fraction revealed the presence of a major band of 36,000 daltons, the amount of which corresponded well with the level of stimulating activity. The stimulation by the factor was specific for heat-denatured DNA, and a little or no stimulation was observed with native DNA, ribo- and deoxyribohomopolymers and single stranded circular DNA. Alkaline sucrose gradient sedimentation analysis of the reaction products revealed that newly synthesized DNA was covalently linked to the termini of heat-denatured DNA. The average chain length of the elongated span determined by the digestion with micrococcal nuclease and phosphodiesterase II, did not differ between in the presence and absence of the stimulating factor, suggesting that the stimulation by the factor was due to the increase in the initiation frequency of DNA synthesis from the 3'-hydroxyl terminus of heat-denatured DNA.
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PMID:Purification and characterization of a factor stimulating DNA polymerase alpha activity from mouse FM3A cells. 632 2

Purified RNA polymerase I was phosphorylated by the endogenous protein kinase or dephosphorylated by alkaline phosphatase and used as antigen in a radioimmunoassay with sera from systemic lupus erythematosus patients or serum from an immunized rabbit. Enzyme incubated in the absence of ATP or phosphatase served as control. Three to seven times more of the autoantibodies in the patients' sera reacted with phosphorylated RNA polymerase I than with control enzyme. The reactivity of the dephosphorylated enzyme with lupus autoantibodies was only 50-60% of that observed with control enzyme. Neither phosphorylation nor dephosphorylation of the enzyme had an effect on its reaction with the rabbit antibodies. The effect of phosphorylation on the reaction of each RNA polymerase I subunit (S1-S8; Mr = 190,000-17,000) with the patients' antibodies was determined by an immunoblot procedure following resolution of the subunits on polyacrylamide gels. Prior phosphorylation of the enzyme resulted in a dramatic increase in binding of each patient's antibodies to all polymerase subunits with the exception of S4. Anti-S4 antibody was not detected with either phosphorylated or control enzyme. Strikingly, antibodies in each patients' sera reacted with S6 only after its phosphorylation. Similarly, anti-S5 antibodies in the serum of one patient were only detected with phosphorylated RNA polymerase I. The present data suggest that at least a significant fraction of the anti-RNA polymerase I autoantibodies in the sera of systemic lupus erythematosus patients might be directed against phosphorylated sites on the enzyme and that phosphorylation may have a role in the production of this and other autoimmunogenic nuclear components which are hallmarks of this disease.
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PMID:Phosphorylation of RNA polymerase I augments its interaction with autoantibodies of systemic lupus erythematosus patients. 650 Dec 73

AlgU is homologous to the extreme heat shock sigma factor sigma E from enteric bacteria. In this work, AlgU was overproduced and purified and its function investigated at the biochemical level. AlgU was shown to associate with RNA polymerase and direct transcription of a target promoter. AlgU also exhibited multiple isoforms detected by 2D gel analysis. Treatment with a Ser/Thr phosphatase shifted the distribution of isoforms towards the basic side on 2D gels, suggesting that posttranslational modifications of AlgU may involve phosphorylation. The underphosphorylated forms of AlgU copurified with RNA polymerase. It is possible that phosphorylation affects AlgU activity or its stability.
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PMID:Biochemical characterization and posttranslational modification of AlgU, a regulator of stress response in Pseudomonas aeruginosa. 748 7

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