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 vaccinia virus D6R open reading frame encodes the small subunit of the heterodimeric vaccinia virus early transcription factor (VETF) that activates transcription of early genes in vitro. VETF binds early gene promoters and has a DNA-dependent ATPase activity that is essential for activation of transcription. To examine the relationship between the structure and function of VETF, we have localized the mutations in two temperature-sensitive viruses whose lesions previously were mapped to the D6R gene. For both mutants, a single G-to-A nucleotide change that would alter protein coding potential was identified. In mutant E93, the codon for alanine 25 was changed to that of threonine, and in mutant S4 the codon for valine 278 was replaced with that for methionine. The molecular phenotype of each mutant was assessed by expressing mutant transcription factors in HeLa cells by using a vaccinia virus-T7 system and characterizing the proteins' activities in vitro. The A25T mutant activated transcription to a lesser extent than wild-type VETF, and the V278M mutant had no demonstrable transcription factor activity. Both mutant proteins were shown to be defective for promoter binding, accounting for their impairment in transcription activation. The functional defects for both mutants were observed at permissive as well as nonpermissive temperatures. The mutant proteins retained ATPase activity but required higher DNA concentrations to activate the ATPase. These results indicate that the small subunit of VETF is essential for its promoter binding activity and likely contacts the promoter DNA. Immunoblotting experiments showed that the virion particles from the two mutant viruses contained about half the VETF of wild-type virus, suggesting that promoter binding may contribute to packaging of VETF into the virion particle. RNA polymerase, mRNA capping enzyme, and nucleoside triphosphate phosphohydrolase I were found at similarly reduced levels in the virion, indicating that packaging of some virion core enzymes may be interdependent.
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PMID:Temperature-sensitive mutations in the gene encoding the small subunit of the vaccinia virus early transcription factor impair promoter binding, transcription activation, and packaging of multiple virion components. 813 39

An expression system for alpha 1-antitrypsin in Escherichia coli was developed using a T7 RNA polymerase promoter. Addition of rifampicin to inhibit the E. coli RNA polymerase after induction of the T7 RNA polymerase gene resulted in about 30% of newly synthesized protein being alpha 1-antitrypsin. This expression system was then used to examine the effect of mutations in the hinge region of alpha 1-antitrypsin on its activity. The mutations were based on ones in antithrombin III that had previously been shown to have adverse effects on activity. Mutation of Ala347 to threonine in alpha 1-antitrypsin did not affect the kinetic behavior of the protein with trypsin or human leukocyte elastase. In contrast, mutation of Gly349 to proline converted the majority of the protein into a substrate for both proteinases. The small fraction of this mutant that was active, however, had kinetic parameters that were indistinguishable from wild-type alpha 1-antitrypsin. Cleavage within the reactive-site loop of wild-type alpha 1-antitrypsin causes a conformational change in the molecules (the S-to-R transition) and results in a marked increase in heat stability. This increase in heat stability was also seen upon cleavage within the reactive-site loops of both of the alpha 1-antitrypsin mutants. The results are discussed in terms of a kinetic mechanism for serpin-proteinase interactions, in which after the formation of an initial complex the serpin partitions between the formation of a stable complex and a cleavage reaction.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effects of mutations in the hinge region of serpins. 834 75

A cDNA coding for the beta 4 subunit of murine integrin (m beta 4) has been cloned and sequenced using mRNA from a murine lung carcinoma as the template. The 5' sequence contains two AUG codons, the second of which initiates synthesis of the mature protein. The cDNA sequence has an open reading frame coding for 1748 amino acids (aa), including a signal peptide, cysteine-rich region, serine- and threonine-rich region, transmembrane domain, and a cytoplasmic domain of over 1000 aa. Overall, the deduced m beta 4 aa sequence has 88% identity with the human beta 4 subunit (h beta 4) sequence deduced from the sequence of placental mRNA. Reverse transcriptase-polymerase chain reaction using primers flanking splice sites for two variant forms of h beta 4 transcripts provided evidence for alternate splicing of RNA in the murine spleen and to a lesser extent in the skin, uterus, and thymus but was found at only one of the two alternative sites. Five potential glycosylation sites present in the extracellular domain of h beta 4 are conserved in m beta 4. One tyrosine in the terminal region of the cytoplasmic domain (position 1600) is conserved between m beta 4 and h beta 4 and has the consensus sequence for tyrosine phosphorylation. Finally, a genomic restriction map of m beta 4 shows that the gene is about 40 kb in length. No restriction-fragment length polymorphisms were detected between BALB/c liver and BALB/c lung carcinoma DNA.
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PMID:Sequence of a cDNA encoding the beta 4 subunit of murine integrin. 835 87

RNA polymerase II is a multisubunit enzyme composed of two large subunits of molecular weight in excess of 100,000 and a collection of 8-10 smaller subunits. The largest subunit, designated IIa, contains at its carboxyl terminus a highly repetitive domain consisting of tandem repeats of the consensus sequence Tyr-Ser-Pro-Thr-Ser-Pro-Ser. Extensive phosphorylation within this COOH-terminal domain (CTD) gives rise to subunit IIo which has a markedly reduced mobility in SDS-polyacrylamide gel electrophoresis (PAGE) relative to subunit IIa. Recent evidence suggests that RNA polymerase IIA, containing an unphosphorylated CTD, is involved in preinitiation complex assembly, whereas RNA polymerase IIO is involved in elongation. Consequently, CTD phosphorylation is thought to occur after RNA polymerase II has bound to the promoter by a protein kinase that stably associates with the preinitiation complex. We present here the partial purification and characterization of two distinct CTD kinases from a HeLa cell transcription extract. These CTD kinases, designated CTDK1 and CTDK2, are fractionated by chromatography on Mono Q. CTDK1 catalyzes the incorporation of approximately 33 pmol of phosphate/pmol of calf thymus RNA polymerase subunit IIa, almost exclusively on serine. CTDK2 catalyzes the incorporation of approximately 50 pmol of phosphate/pmol of calf thymus subunit IIa, predominantly on serine; appreciable phosphate transfer onto threonine is also observed. Phosphorylation by CTDK2, but not CTDK1, results in a complete mobility shift in SDS-PAGE of subunit IIa to the position of IIo. CTDK1 can utilize ATP, dATP, or GTP as phosphate donor, whereas CTDK2 can utilize only ATP or dATP. The apparent Km for ATP is 30 microM for CTDK1 and 60 microM for CTDK2. CTDK1 and CTDK2 also differ in their protein substrate specificity. CTDK1 phosphorylates casein whereas CTDK2 does not. Neither kinase phosphorylates phosvitin or histone H1 to an appreciable extent. CTDK1 and CTDK2 do not appear to be related to cdc2 kinases as determined by their inability to phosphorylate H1 and their failure to react with antibodies directed against the cdc2 kinase. These results establish that a partially fractionated HeLa transcription extract contains two distinct CTD kinases that differ in their nucleotide requirements and in their patterns of CTD phosphorylation.
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PMID:Partial purification and characterization of two distinct protein kinases that differentially phosphorylate the carboxyl-terminal domain of RNA polymerase subunit IIa. 841 77

We have investigated the mechanism of transcription termination in vitro by spinach chloroplast RNA polymerase using templates encoding variants of the transcription-termination structure (attenuator) of the regulatory region of the threonine (thr) operon of Escherichia coli. Fourteen sequence variants located within its d(G+C) stem-loop and d(A+T)-rich regions were studied. We found that the helix integrity in the stem-loop structure is necessary for termination but that its stability is not directly correlated with termination efficiency. The sequence of the G+C stem-loop itself also influences termination. Moreover, the dA template stretch at the 3' end of the terminator plays a major role in termination efficiency, but base pairing between the A and U tract of the transcript does not. From the studies using deletion variants and a series of mutants that alter the sequences immediately downstream from the transcription termination site, we found that termination of transcription by spinach chloroplast RNA polymerase was also modulated by downstream DNA sequences in a sequence-specific manner. The second base immediately following the poly(T) tract is crucial for determining the termination efficiency by chloroplast RNA polymerase, but not of the T7 or E.coli enzymes.
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PMID:Transcription termination at the Escherichia coli thra terminator by spinach chloroplast RNA polymerase in vitro is influenced by downstream DNA sequences. 852 62

A newly identified temperature-sensitive mutant whose defect was mapped to the reovirus M1 gene (minor core protein mu2) was studied to better understand the functions of this virion protein. Sequence determination of the Ml gene of this mutant (tsH11.2) revealed a predicted methionine-to-threonine alteration at amino acid 399 and a change from proline to histidine at amino acid 414. The mutant made normal amounts of single-stranded RNA, both in in vitro transcriptase assays and in infected cells, and normal amounts of progeny viral protein at early times in a restrictive infection. However, tsH11.2 produced neither detectable progeny protein nor double-stranded RNA at late times in a restrictive infection. These studies indicate that mu2 plays a role in the conversion of reovirus mRNA to progeny double-stranded RNA.
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PMID:Identification and characterization of a double-stranded RNA- reovirus temperature-sensitive mutant defective in minor core protein mu2. 867 44

HeLa cell nuclei were permeabilized and reconstituted with nuclear extract to identify soluble nuclear factors which play a role in the organization of pre-mRNA splicing factors in the mammalian cell nucleus. Permeabilized nuclei reconstituted with nuclear extract were active in transcription and DNA replication and nuclear speckles containing pre-mRNA splicing factors were maintained over several hours independent of soluble nuclear components. The characteristic rounding up of nuclear speckles in response to inhibition of RNA polymerase II seen in vivo was reproduced in permeabilized cells and was strictly dependent on a catalytic activity present in the nuclear extract. By inhibitor titration experiments and sensitivity to inhibitor 2, this activity was identified as a member of the serine/threonine protein phosphatase 1 family (PP1). Interference with PP1 activity affected the distribution of pre-mRNA splicing factors in transcriptionally active, permeabilized cells, and excess PP1 activity caused increased dephosphorylation of SR proteins in nuclear speckles. These data show that the dynamic reorganization of the mammalian cell nucleus can be studied in permeabilized cells and that PP1 is involved in the rounding up of speckles as well as the overall organization of pre-mRNA splicing factors in the mammalian cell nucleus.
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PMID:Serine/threonine phosphatase 1 modulates the subnuclear distribution of pre-mRNA splicing factors. 889 62

Human membrane cofactor protein (MCP) is a widely distributed cell-associated complement-regulatory protein, and recent findings suggest that MCP may be involved in sperm-egg interaction. We have isolated four cDNA clones and one reverse transcriptase-PCR product homologous to human MCP from guinea pig testis. These clones defined five isoform classes generated from a single copy gene by alternative splicing. Reverse transcriptase-PCR revealed that two classes for the clones termed GMP1 and GM2 were predominant. GMP1 consisted of four short consensus repeats (SCRs), regions corresponding to the human serine/threonine/proline-rich C (STP(C)) domain and a human region of unknown significance, a hydrophobic region presumed to be a transmembrane domain, and a cytoplasmic region. Identity with human MCP in the SCR region was 56% at the amino acid level and 71% at the nucleotide level. GM2 had the same structure as GMP1, except that it lacked the fourth SCR, which is presumed to be essential for C3b binding of human MCP. Northern blotting analysis of various tissues revealed a significant level of MCP transcripts in testis. Guinea pig MCP is likely to have only one STP domain that is homologous to human STP(C) and is similar in this respect to human spermatozoa MCP. Gene analysis revealed a single base deletion and a lack of consensus sequences for splicing in the guinea pig regions corresponding to human STP(A) and STP(B), respectively. These results suggest that guinea pig MCP plays a more restricted role in reproduction than does human MCP.
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PMID:Molecular cloning of guinea pig membrane cofactor protein: preferential expression in testis. 894

An in vitro system was established to study the transcription and processing of threonine tRNA using spinach chloroplast enzyme extract. Experiments using a series of 5' deletion mutants demonstrated that the transcription of trnT gene required no 5' upstream promoter elements. Four plasmid DNA templates containing trnT were constructed for tRNA processing assay. The processing reaction was carried out either with exogenously added precursor-tRNAs made by T7 RNA polymerase or with RNAs synthesized by the transcription activity in the same processing enzyme extract. Both assays demonstrated that the 5' and 3' ends of mature tRNA were processed endonucleolytically and the processing of the 5' end preceded the maturation of the 3' end. The activity of nucleotidyl transferase that adds CCA nucleotides to the 3' end of tRNA was also observed. The use of a coupled transcription and processing system provides us with a better insight to the tRNA processing mechanism of the chloroplast.
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PMID:Transcription and processing of the gene for spinach chloroplast threonine tRNA in a homologous in vitro system. 914 43

The largest subunit of RNA polymerase II contains a C-terminal repeated domain (CTD) that is the site of phosphorylation by serine (threonine) and tyrosine kinases. Phosphorylation of the CTD is correlated with transcription elongation. A number of different kinases have previously been shown to phosphorylate the CTD; among them is a nuclear tyrosine kinase encoded by the c-abl proto-oncogene. The processive and high stoichiometric phosphorylation of RNA polymerase II by c-Abl requires the tyrosine kinase, the SH2 domain, and a CTD-interacting domain (CTD-ID) in the Abl protein. The physiological tyrosine phosphorylation of RNA polymerase II by c-Abl in DNA damage response has previously been demonstrated. Basal tyrosine phosphorylation of RNA polymerase II, however, is observed in cells derived from abl-deficient mice, indicating the existence of other CTD tyrosine kinases. In this report, we show that the tyrosine kinase encoded by an Abl-related gene (Arg) also phosphorylates the CTD in vitro and in transfected cells. The SH2 and kinase domain of Arg are 95% identical to that of c-Abl. However, these two proteins share only 29% identity in the large C-terminal region. Interestingly, a CTD-ID is also found in the C-terminal region of Arg. Mapping studies and sequence analysis have led to the identification of the CTD-ID that is highly conserved among the divergent C-terminal regions of Abl and Arg. These results indicate that tyrosine phosphorylation of RNA polymerase II CTD could be catalyzed by either c-Abl or Arg kinase.
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PMID:Tyrosine phosphorylation of RNA polymerase II carboxyl-terminal domain by the Abl-related gene product. 922 69

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