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)

In the enteric bacterium, Escherichia coli, acyl coenzyme A synthetase (fatty acid:CoA ligase (AMP-forming) EC 6.2.1.3) activates exogenous long-chain fatty acids concomitant with their transport across the inner membrane into metabolically active CoA thioesters. These compounds serve as substrates for acyl-CoA dehydrogenase in the first step in the process of beta-oxidation. The acyl-CoA synthetase structural gene, fadD, has been identified on clone 6D1 of the Kohara E. coli gene library and by a process of subcloning and complementation analyses shown to be contained on a 2.2-kilobase NcoI-ClaI fragment of genomic DNA. The polypeptide encoded within this DNA fragment was identified following T7 RNA polymerase-dependent induction and estimated to be M(r) = 62,000 using SDS-polyacrylamide gel electrophoresis. The N-terminal amino acid sequence of acyl-CoA synthetase was determined by automated sequencing to be Met-Lys-Lys-Val-Trp-Leu-Asn-Arg-Tyr-Pro. Sequence analysis of the 2.2-kilobase NcoI-ClaI fragment revealed a single open reading frame encoding these amino acids as the first 10 residues of a protein with a molecular weight of 62,028. The initiation codon for methionine was TTG. Primer extension of total in vivo mRNA from two fadD-specific oligonucleotides defined the transcriptional start at an adenine residue 60 base pairs upstream from the predicted translational start site. Two FadR operator sites of the fadD gene were identified at positions -13 to -29 (OD1) and positions -99 to -115 (OD2) by DNase I footprinting. Comparisons of the predicted amino acid sequence of the E. coli acyl-CoA synthetase to the deduced amino acid sequences of the rat and yeast acyl-CoA synthetases and the firefly luciferase demonstrated that these enzymes shared a significant degree of similarity. Based on the similar reaction mechanisms of these four enzymes, this similarity may define a region required for the same function.
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PMID:Cloning, sequencing, and expression of the fadD gene of Escherichia coli encoding acyl coenzyme A synthetase. 146 45

The primary structure of a multifunctional protein, the large alpha-subunit of the Escherichia coli fatty acid oxidation complex, was determined by sequencing the fadB region of the fadBA operon. The amino-terminal sequence of this protein had been established by Edman degradation. The transcription start site of the fadBA operon was located 42 nucleotides upstream of the initiator codon of the fadB gene by primer extension analysis. Sequences of -10 and -35 regions of the promoter responsible for interaction with RNA polymerase were found to be CACACT and TTTGCA, respectively. The location of the promoter of the fadBA operon was defined, and the transcription direction of this operon, from fadB to fadA, as previously proposed [Yang, S.-Y., et al. (1990) J. Biol. Chem. 265, 10424-10429], was corroborated. The multifunctional protein is composed of 729 amino acid residues and has a calculated Mr of 79,593. A putative NAD-binding beta alpha beta-fold necessary for L-3-hydroxyacyl-CoA dehydrogenase function was found in the central region of the fadB gene product. Sequence analyses suggest that the functional domains of the multifunctional protein are arranged in the order enoyl-CoA hydratase:L-3-hydroxyacyl-CoA dehydrogenase: delta 3-cis-delta 2-trans-enoyl-CoA isomerase and suggest that the genes of the E. coli multifunctional protein and rat peroxisomal trifunctional beta-oxidation enzyme evolved from a common ancestral gene.
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PMID:Nucleotide sequence of the promoter and fadB gene of the fadBA operon and primary structure of the multifunctional fatty acid oxidation protein from Escherichia coli. 171 30

DNA-dependent RNA polymerase (RPase) from Escherichia coli contains 2 mol of intrinsic Zn(II)/mol of core enzyme (alpha 2 beta beta'). In techniques analogous to those employed with the Zn(II) metalloenzyme aspartate transcarbamoylase [Hunt, J. B., Neece, S. H., Schachman, H. K., & Ginsberg, A. (1984) J. Biol. Chem. 259, 14793-14803], we show that titration of core or holoRPase with 10 or 16 equiv, respectively, of the sulfhydryl reagent p-(hydroxymercuri)benzenesulfonate (PMPS) results in the facile release of 1 mol of Zn(II) [B-site Zn(II)] in a reaction totally reversible with the addition of excess thiol provided no metal chelator is present. If ethylenediaminetetraacetic acid (EDTA) is present, reversal of the PMPS-enzyme complex results in formation of a Zn1 RPase [A-site Zn(II)]. This enzyme retains full transcriptional activity relative to Zn2 RPase on both calf thymus (nonspecific) and T7 (sigma-dependent, specific) DNA templates. If the core enzyme-PMPS complex is incubated with a large excess of another metal such as Cd(II) followed by thiol treatment, a hybrid ZnACdB RPase is formed. Direct treatment of the enzyme with excess Cd(II) also gives rise to a hybrid ZnACdB RPase. Transcription by these enzymes is also comparable to that of the starting Zn2 enzyme. Isolation of in vivo synthesized Co2 RPase and Cd2 RPase and treatment of either enzyme with PMPS/EDTA results in formation of a CoA and CdA enzyme, respectively. Co(II)A and Cd(II)A enzymes show 123 and 76%, respectively, of the elongation rates on T7 DNA observed for the Zn(II) enzyme. Visible absorption spectroscopy of the Co2 enzyme exhibits four d-d transition bands positioned at 760 (epsilon = 800), 710 (epsilon = 900), 602 (epsilon = 1500), and 484 (epsilon = 4000) nm. In addition, two charge-transfer bands are found at 350 (epsilon = 9600) and 370 (epsilon = 9500) nm. Only the Co(II) ion bound at site A is associated with this unique set of intense d-d transitions. The positions and intensities of both the visible and charge-transfer bands of Co(II)A RPase approximate those shown by Co(II)-substituted metalloenzyme sites where the ligands are four S rather than mixed S,N or S,O sites.
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PMID:Structural and functional differences between the two intrinsic zinc ions of Escherichia coli RNA polymerase. 309 79

RNA polymerase (RPase) from E. coli contains two tightly incorporated Zn(II) ions, while the monomeric RPase from bacteriophage T7 does not contain zinc and does not require Zn(II) in the assay. One of the two Zn(II) ions can be differentially removed from E. coli RPase with p-hydroxymercuriphenylsulfonate (PMPS) combined with EDTA and thiol. The resultant Znl or ZnA RPase shows no alteration in transcription initiation and elongation rate from sigma-specific promoters. Biosynthesis of a Co2 RPase and formation of CoA RPase by similar treatment shows the tetrahedral-type Co(II) d-d absorption bands to be associated only with the Co(II) at the A site with maxima at 760 (epsilon = 800), 710 (epsilon = 900), 602 (epsilon = 1500), and 484 (epsilon = 4000) nm. Sulfur to Co(II) charge transfer bands are present at 350 (epsilon = 9600) and 370 (epsilon = 9500) nm. The absorption characteristics strongly suggest that the A site is a tetrathiolate site. While DNA polymerases do not in general appear to contain zinc, gene 32 protein (g32P) from bacteriophage T4, an accessory protein essential for DNA replication and recombination and translational control in the T4 life cycle, is a Zn(II) metalloprotein and contains 1 gram atom of tightly incorporated Zn(II). PMPS displaces the zinc by reacting with three SH groups. Apo-g32P shows markedly altered DNA binding properties. Co(II) substitution gives a protein with intense d-d transitions typical of a tetrahedral Co(II) complex with absorption maxima at 680 (epsilon = 480), 645 (epsilon = 660), 605 (epsilon = 430), 355 (epsilon = 2250), and 320 (epsilon = 3175) nm. The data support a 3 Cys, 1 His coordination site located in the middle of the DNA binding domain of g32P. Data thus far suggest that the Zn(II) binding sites in multisubunit RNA polymerases and in accessory proteins involved in polynucleotide biosynthesis are more likely to play structural or allosteric (regulatory) roles rather than directly participating in catalysis.
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PMID:Zinc metalloproteins involved in replication and transcription. 354 19

RNA polymerase from Escherichia coli was inhibited by long chain fatty acyl CoAs, such as myristoyl CoA (Ki = 17.2 microM), palmitoyl CoA (Ki = 8.9 microM), oleoyl CoA (Ki = 5.5 microM), and stearoyl CoA (Ki = 0.94 microM). The inhibition by these CoA thioesters was non-competitive against nucleoside triphosphates. Short chain fatty acyl CoAs, such as acetyl CoA, propionyl CoA, acetoacetyl CoA, butyryl CoA, and decanoyl CoA, failed to inhibit RNA polymerase. CoA, Na-myristate, Na-palmitate, Na-oleate, Na-stearate, palmitoyl carnitine, and carnitine did not inhibit the enzyme. The inhibition of RNA polymerase by long chain fatty acyl CoAs was competitive against template DNA.
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PMID:Inhibitory effect of long chain fatty acyl CoAs on RNA polymerase from Escherichia coli. 635 76

cDNA encoding the mature form of human hydroxy-methylglutaryl-CoA (HMG-CoA) lyase, a mitochondrial matrix protein, has been used to prepare expression plasmids appropriate for production of this protein in Escherichia coli. Using a T7 RNA polymerase-based pET system, HMG-CoA lyase was overexpressed but largely recovered in an insoluble, catalytically inactive form. In contrast, an expression plasmid (pTrcHL-1), derived from pTrc99a, supported production of soluble, active enzyme. A synthetic oligonucleotide cassette was employed to produce an enzyme variant in which cysteine was replaced by serine at position 323. Both wild-type and C323S HMG-CoA lyases were isolated in homogeneous form and characterized. The function of Cys-323 in influencing catalytic activity in vitro has been investigated by comparing the response of wild-type and C323S lyases to oxidation and reduction. Additionally, the consequences of treatment of these enzymes with the sulfhydryl-directed bifunctional reagent, o-phenylenedimaleimide have been determined. The results support the hypothesis that a thiol/disulfide exchange mechanism affects enzyme activity in vitro and indicate that Cys-323 residues on adjacent subunits of the homodimeric native enzyme are suitably positioned to form an intersubunit cross-link upon oxidative inactivation and disulfide formation.
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PMID:3-Hydroxy-3-methylglutaryl-CoA lyase: expression and isolation of the recombinant human enzyme and investigation of a mechanism for regulation of enzyme activity. 802 38

Myristoyl CoA:protein N-myristoyltransferase catalyzes the addition of myristate to the amino-terminal glycine residue of a number of eukaryotic proteins. The gene encoding human N-myristoyltransferase (hNMT) was cloned into the overexpression vector pT7-7 which utilizes the T7 RNA polymerase gene expression system. The hNMT enzyme was purified to near homogeneity with more than 95% recovery using a single-step purification method involving SP-Sepharose fast flow column chromatography. The specific activity of the purified NMT was 220 nmol/min/mg of protein in the presence of oncoprotein-derived peptide substrate pp60src. The hNMT exhibited an apparent molecular weight of 49 kDa on SDS-polyacrylamide gel electrophoresis. Antibodies to Escherichia coli-expressed hNMT specifically recognize hNMT from crude bacterial lysates. The over-expressed hNMT was homogeneous and showed enzyme activity.
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PMID:Overexpression of human N-myristoyltransferase utilizing a T7 polymerase gene expression system. 877 63

The biosynthesis of the hemes, chlorophylls, corrins and other tetrapyrroles begins with the synthesis of 5-aminolevulinic acid (ALA). The pathway is highly conserved except for the synthesis of ALA which is derived from glycine and succinyl CoA (C4) in most eukaryotes and from glutamate (C5) in most bacteria and in green plants. In C5, glutamyl-tRNA synthetase (GTS) converts glutamate to glutamyl-tRNA (glu-tRNA), which is reduced by glutamyl-tRNA reductase (GTR) to glutamyl-1-semialdehyde (GSA), which is converted by aminotransferase (GSA-AT) to ALA. Since GTS is also involved in protein synthesis and GSA can be converted to ALA non-enzymatically, it is highly probable that control of ALA synthesis and thus of the whole pathway resides in the GTR step. In Escherichia coli, GTR is the gene product of hemA. BL21(DE3), a protease-deficient strain which contains the T7 RNA polymerase gene in front of a lac promoter, was transformed with a pET14b-based vector, pWC01, harboring hemA in front of a T7 promoter and ORF1 which is transcribed in the opposite direction. The transformed strain, WC1201, secreted ALA and porphyrins into the medium. Induction of expression of hemA by WC1201 was optimized for concentration of inducer (IPTG, 5 mM), temperature (37 degrees C), presence of betaine and sorbitol (no change) and time of induction (2h). GTR was observable as a 46 kDa band by Brilliant blue G staining of SDS-PAGE gels. Sonicates of the induction mixture exhibited strong ALA synthesis activity which was enhanced by tRNAglu. Most of the activity was in the supernatant of the sonicate indicating that GTR is a soluble enzyme. The induced strain had more GTS activity than the uninduced strain which had more GTS activity than its parent wild-type strain. Autoradiography on native gradient PAGE showed that GTR expressed in vivo by induction of WC1201 had a molecular weight of approx. 117 kDa. Gel filtration of the induced sonicate showed a peak of enzymatic activity at about 126 kDa. When pET14b- or pUC19-based plasmids harboring hemA and ORF1, or importantly, a pUC19-based plasmid harboring only hemA and not ORF1, were expressed in an in vitro transcription-translation system, native gradient PAGE showed a product with a molecular weight of approximately 175 kDA. This expression was higher in the presence of tRNAglu. When the 117 kDa and 175 kDa proteins were excised from their native gels respectively, and run on SDS PAGE, autoradiography showed bands at 46 kDa. We conclude that GTR is present in both high molecular weight species. Since overexpression of hemA from pET14b-based plasmids is associated with increased glutamyl-tRNA synthetase activity, the 175 kDa species may represent different complexes of GTR, GTS and glutamyl-tRNA as observed in Chlamydomonas and the 117-126 kDa species may be an dimer of GTR associated with glu-tRNA or a complex of GTR, GTS and glu-tRNA. These possibilities are being investigated.
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PMID:Expression of glutamyl-tRNA reductase in Escherichia coli. 895 Jan 86

A gene encoding a novel enoyl-SCoA hydratase/lyase enzyme for the hydration and nonoxidative cleavage of feruloyl-SCoA to vanillin and acetyl-SCoA was isolated and characterized from a strain of Pseudomonas fluorescens. Feruloyl-SCoA is the CoASH thioester of ferulic acid (4-hydroxy-3-methoxy-trans-cinnamic acid), an abundant constituent of plant cell walls and a degradation product of lignin. The gene was isolated by a combination of mutant complementation and biochemical approaches, and its function was demonstrated by heterologous expression in Escherichia coli under the control of a T7 RNA polymerase promoter. The gene product is a member of the enoyl-SCoA hydratase/isomerase superfamily.
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PMID:Metabolism of ferulic acid to vanillin. A bacterial gene of the enoyl-SCoA hydratase/isomerase superfamily encodes an enzyme for the hydration and cleavage of a hydroxycinnamic acid SCoA thioester. 946 12

Protein acetylation has emerged as a means of controlling levels of mRNA synthesis in eukaryotic cells. Here we report that acetyl coenzyme A (acetyl-CoA) stimulates RNA polymerase II transcription in vitro in the absence of histones. The effect of acetyl-CoA on basal and activated transcription was studied in a human RNA polymerase II transcription system reconstituted from recombinant and highly purified transcription factors. Both basal and activated transcription were stimulated by the addition of acetyl-CoA to transcription reaction mixtures. By varying the concentrations of general transcription factors in the reaction mixtures, we found that acetyl-CoA decreased the concentration of TFIID required to observe transcription. Electrophoretic mobility shift assays and DNase I footprinting revealed that acetyl-CoA increased the affinity of the general transcription factor TFIID for promoter DNA in a TBP-associated factor (TAF)-dependent manner. Interestingly, acetyl-CoA also caused a conformational change in the TFIID-TFIIA-promoter complex as assessed by DNase I footprinting. These results show that acetyl-CoA alters the DNA binding activity of TFIID and indicate that this biologically important cofactor functions at multiple levels to control gene expression.
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PMID:Acetyl coenzyme A stimulates RNA polymerase II transcription and promoter binding by transcription factor IID in the absence of histones. 1068 40

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