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 nucleotide sequence of a cloned section of the Escherichia coli chromosome containing the dnaG primase gene [Lupski, J., Smiley, B., Blattner, F. & Godson, G. N. (1982) Mol. Gen, Genet. 185, 120--128] has been determined. The region coding for the dnaG primase has been identified by NH2-terminal and tryptic peptide amino acid analysis of the dnaG protein. The coding region is 1,740 base pairs long (580 amino acids) and is preceded by an unusual ribosome-binding site sequence (G-G-G-G). The dnaG gene is read in the same direction as the adjacent rpoD gene, but no obvious promoter sequences can be found for either gene within several hundred nucleotides upstream. Other unusual features of the dnaG gene that may explain the maintenance of its product at low copy number are the presence of a RNA polymerase terminator 31 nucleotides upstream from the ATG initiator codon and greater use (3--10 times) of certain condons that occur infrequently in other E. coli genes. The nucleotide sequence has also been correlated with data from transposon Tn5 insertional inactivation mapping.
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PMID:Sequences of the Escherichia coli dnaG primase gene and regulation of its expression. 675 Jun 4

The nucleotide sequence of the 5'-proximal portion of the RNA polymerase beta subunit gene (rpoB) has been determined. From the nucleotide sequence it is possible to predict that NH2-terminal 390 amino acid residues of the protein. The codon utilization in this portion of the rpoB gene is similar to the utilization in the adjacent cluster of ribosomal protein genes. The NH2-terminal portion of the protein is rich in both acidic (59/390) and basic (54/390) amino acid residues; more than half of the basic residues are clustered within limited stretches of the polypeptide and may play a role in RNA polymerase-nucleic acid interaction.
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PMID:Nucleotide sequence of the proximal portion of the RNA polymerase beta subunit gene of Escherichia coli. 701

The nucleotide sequence of trpR of Escherichia coli was determined. This gene codes for a polypeptide (Mr 12,356) that is 108 amino acid residues in length. NH2-terminal, COOH-terminal, and total amino acid analyses of purified aporepressor agree with the deduced amino acid sequence and establish the translation start and stop codons of the structural gene. The transcription start site for trpR mRNA synthesis in vitro was shown to be 56 base pairs prior to the translation start site. The nucleotide sequence on either side of the transcription start site is homologous to the trp operon operator. Purified trp aporepressor, when activated by L-tryptophan, protects restriction sites in this region, the presumed trpR operator, from cleavage by the respective restriction endonucleases. Bound RNA polymerase protects the same restriction sites. These findings and the additional observation that trp repressor inhibits transcription initiation in vitro establish that there is a functional overlap of operator and promoter sequences in the regulatory region of the trpR operon. These findings indicate that expression of trpR is autoregulatory.
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PMID:Nucleotide sequence and expression of Escherichia coli trpR, the structural gene for the trp aporepressor. 701 34

The protein sigma 54 associates with Escherichia coli core RNA polymerase to form a holoenzyme that binds promoters but is inactive in the absence of enhancer activation. Here, mutants of sigma 54 enabled polymerases to transcribe without enhancer protein and adenosine triphosphate. The mutations are in leucines within the NH2-terminal glutamine-rich domain of sigma 54. Multiple leucine substitutions mimicked the effect of enhancer protein, which suggests that the enhancer protein functions to disrupt a leucine patch. The results indicate that sigma 54 acts both as an inhibitor of polymerase activity and as a receptor that interacts with enhancer protein to overcome this inhibition, and that these two activities jointly confer enhancer responsiveness.
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PMID:Converting Escherichia coli RNA polymerase into an enhancer-responsive enzyme: role of an NH2-terminal leucine patch in sigma 54. 748 5

Although the third component of complement, C3, has been isolated and its primary structure determined from most living classes of vertebrate, limited information is available on its structure and function for aves, which represent a significant stage in complement evolution. In this study, we present the complete cDNA sequence of chicken C3, the cDNA sequences of the thioester region for two chicken alpha 2-macroglobulin (alpha 2M)-related proteins, a simplified method for purifying chicken C3, and an analysis of the C3 convertase and factor I-mediated cleavages in chicken C3. Using the reverse-transcriptase PCR, with degenerate oligonucleotide primers derived from two conserved C3 sequences (GCGEQN/TM, TWLTAY/FV) and liver mRNA as template, we isolated three distinct 220-bp PCR products, one with a high degree of sequence similarity to C3 and two to alpha 2M and pregnancy zone protein from other species. The complete cDNA sequence of chicken C3 was obtained by screening a chicken liver lambda gt10 library with the C3 PCR product and probes from the 5' end of the partial-length C3 clones. The obtained sequence is in complete agreement with the protein sequence of several tryptic peptides of purified chicken C3. Chicken pro-C3 consists of an 18-residue putative signal peptide, a 640-residue beta-chain (70 kDa), a 989-residue alpha-chain (111 kDa), and an RKRR linker region. It contains an internal thioester and three potential N-glycosylation sites, all in the alpha-chain. The convertase cleavage site, predicted to be Arg-Ser, was confirmed by sequencing the zymosan-bound C3 fragments generated upon complement activation. NH2-terminal sequencing of the purified C3 chains showed that 1) pro-C3 is indeed cleaved at the RKRR linker sequence to generate the mature two-chain molecule, and 2) the beta-chain of chicken C3 is blocked. The deduced amino acid sequence shows 54, 54, 54, 53, 52, 57, and 55% amino acid identities to human, mouse, rat, guinea pig, rabbit, cobra, and Xenopus C3, respectively, and an identity of 44, 31, and 33% to trout, hagfish, and lamprey C3, respectively. The identities to human C4, C5, and alpha 2M are 31, 29 and 23%, respectively. A phylogenetic tree for C3, C4, C5, and alpha 2M-related proteins was constructed based on the sequence data and is discussed.
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PMID:Isolation, primary structure, and evolution of the third component of chicken complement and evidence for a new member of the alpha 2-macroglobulin family. 753 62

The gene on chromosome 10 at band p12 (AF10), involved in the t(10;11) translocation in acute myeloid leukemia, has been identified and shown to contain conserved zinc finger and leucine zipper domains. These regions are highly homologous to the equivalent regions on AF17, the gene involved in the t(11;17) translocations. A series of adult, childhood, and infant leukemias with either simple or complex versions of the t(10;11) has been examined by Southern analysis and shown to involve rearrangement to the HRX locus. Reverse transcriptase-polymerase chain reaction from either bone marrow or peripheral blood cells showed that HRX sequence was fused to AF10 sequence in all 8 cases and subsequent sequence analysis showed an in-frame fusion between the HRX and AF10 sequence. A consistent feature of these fusions was the juxtaposition of the leucine dimerization motif of AF10 onto the NH2-terminal region of HRX. The published data suggest that a similar conclusion can be drawn about the t(11;17) translocation, implying a critical role for this motif in the chimaeric HRX protein.
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PMID:The t(10;11) translocation in acute myeloid leukemia (M5) consistently fuses the leucine zipper motif of AF10 onto the HRX gene. 766 54

Double-stranded DNA oligomers were constructed to evaluate the effect of bifunctional and monofunctional platinum(II) complexes at the level of DNA transcription. They contained a single lesion, which is either a cis-[Pt(NH3)2(d(GpTpG))] intrastrand cross-link, a trans-[Pt(NH3)2(d(GpTpG))] intrastrand cross-link, a cis-[Pt(NH3)2(d(GpC/GpC))] interstrand cross-link, or a (diethylenetriamine)-platinum(II)-dG adduct. The synthetic duplexes were multimerized and then used as templates in dinucleotide-primed reactions catalyzed by prokaryotic or eukaryotic RNA polymerases. Reactions were conducted in the presence of a single triphosphate substrate (single-step addition reaction) or of a combination of triphosphate substrates, permitting elongation of the trinucleotide products to longer RNA chains (productive elongation reaction), respectively. In transcription of the platinated strands, none of the DNA adducts provided an absolute block to formation of a single phosphodiester bond by either Escherichia coli RNA polymerase or wheat germ RNA polymerase II. However, the single-step addition reactions were much more impeded from transcription of bifunctional adduct-containing templates as compared to those containing monofunctional lesions. Productive elongation was irreversibly blocked in transcription of the platinated strand of templates containing a cis-d(G*pTpG*) intrastrand cross-link or a cis-d(G*pC/G*pC) interstrand cross-link. In both cases transcription stopped at the level of the lesion. Termination occurred also several nucleotides before the elongation complexes reached the interstrand cross-link. A substantial amount of the RNA polymerase molecules was able of bypassing the trans-d(G*pTpG*) cross-links. In all the cases single-step addition reactions were enhanced on the template strand complementary to that containing the intrastrand cross-links.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Spectrum of DNA--platinum adduct recognition by prokaryotic and eukaryotic DNA-dependent RNA polymerases. 768 35

A cDNA encoding the catalytic core of a novel brain 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase isoenzyme was isolated from a lambda gt10 bovine brain library. This brain cDNA begins and ends in an open reading frame encoding a peptide of 476 amino acids. This peptide contains both the catalytic kinase and bisphosphatase domains and has an overall 65% and 67% indentity with the bovine heart and liver isozymes, respectively, whereas the NH2 and COOH-termini are divergent. An active catalytic core brain bifunctional enzyme was expressed in E. coli using a T7 RNA polymerase-based expression system. These results support the presence of a distinct gene coding for the protein in bovine brain.
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PMID:Cloning and expression of a catalytic core bovine brain 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase. 773 68

Chicken liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase was expressed in E. coli by using a pET3a T7 RNA polymerase-based expression system and was purified to homogeneity. The kinase and bisphosphatase of the expressed bifunctional enzyme had kinetic properties identical to those of the native chicken liver enzyme. However, the kinase activity of the chicken liver enzyme was 7-fold higher, while the bisphosphatase activity was 50 percent lower than those of the rat liver enzyme. Cys-256 of the rat liver bisphosphatase domain is not conserved in the chicken liver enzyme. A site-directed mutation was engineered at Cys-256 of the rat liver enzyme and the results indicate that the variation of this residue is not responsible for the difference in fructose-2,6-bisphosphatase activity between the rat and chicken liver enzymes. It is postulated that the difference in the kinase/bisphosphatase activity ratios of these two enzymes results from differences in their NH2-terminal regions.
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PMID:Expression of chicken liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase in Escherichia coli. 773 80

We demonstrate here that stilbene estrogen (diethylstilbestrol) is converted to nuclear protein binding metabolite(s) both in vitro and in vivo. In vitro reaction of DES with nuclei from hamster liver or kidney in the presence of cumene hydroperoxide or NADPH revealed binding of [3H]DES in nuclear proteins (histones; nonhistones precipitable by 2% TCA, NH2; nonhistones soluble in 2% TCA, NH30). The binding was significantly inhibited by cytochromes P450 inhibitors. In an in vitro system [3H]DES quinone, one of the metabolites of DES, was able to bind to pure nonhistone proteins RNA polymerase and DNA polymerase. The binding of [3H]DES quinone to nonhistones RNA polymerase and DNA polymerase was inhibited by low molecular weight thiols, i.e. glutathione and cysteine, or thiol modifiers, such as n-ethylmaleimide, dithionitrobenzoic acid and hydroxymercuric benzoate. DES and DES metabolites inhibited transcriptional activity. In vivo [3H]DES was able to bind to nuclear proteins of hamster liver, kidneys and testes. The level of in vivo [3H]DES binding to all three types of nuclear proteins (histones, NH2, NH30) in the kidney (target organ) was two or more fold higher than that observed in the liver or testis (nontarget organs). Four nuclear NH30 proteins (mol wts.: 56, 37, 33 and 28 kDa) were irreversibly bound to [3H]DES in vivo. The in vivo binding of [3H]DES to transcriptionally active chromatin NH30 proteins also was observed. The data reported here establish that DES was able to bind to liver or kidney nuclear proteins in vitro, which was catalyzed by nuclear enzymes when fortified with an appropriate cofactor. DES quinone may be one of the protein binding metabolites. DES and DES metabolites inhibited transcriptional activity. The level of in vivo binding of [3H] DES to nuclear proteins of kidney (target organ) was double in comparison with that observed in liver or testis (nontarget organs). In vivo modifications in the chromatin proteins may be a factor in the development of DES-induced renal carcinogenesis is not clear.
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PMID:In vivo binding of diethylstilbestrol to nuclear proteins of kidneys of Syrian hamsters. 773 58

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