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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 gene coding for Bacillus subtilis RNA polymerase major sigma 43, rpoD, was cloned together with its neighboring genes in a 7 kb EcoRI fragment. The complete nucleotide sequence of a 5 kb fragment including the entire rpoD gene revealed the presence of two other genes preceding rpoD in the order P23-dnaE-rpoD. The dnaE codes for DNA primase while the function of P23 remains unknown. The three genes reside in an operon that is similar in organization to the E. coli RNA polymerase major sigma 70 operon, which is composed of genes encoding small ribosome protein S21 (rpsU), DNA primase (dnaG), and RNA polymerase sigma 70 (rpoD). There is a relatively high degree of base and amino acid homology between the DNA primase and sigma genes. The most significant differences between the two operons are observed in the molecular size of the first genes (P23 and rpsU), the complete lack of amino acid homology between P23 and S21, the molecular weights of the two rpoD genes, the size of the intercistronic region between the first two genes, and the regulatory elements of the operon.
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PMID:Nucleotide sequence and organization of Bacillus subtilis RNA polymerase major sigma (sigma 43) operon. 308 39

Sequencing data indicated that the RNA polymerase sigma 43 operon of Bacillus subtilis consisted of three genes, P23 (function unknown), dnaE (DNA primase), and rpoD (sigma 43) (Wang and Doi 1986a). S1 nuclease mapping experiments with RNA from various stages of growth demonstrated the presence of two overlapping sigma 43 promoters that controlled the expression of the operon during growth and a sigma 37 promoter that regulated the expression of the operon during the sporulation phase. This promoter switching mechanism ensured that this important operon would be expressed during different nutritional states of the cell and also illustrated a function for the minor RNA polymerase sigma 37 holoenzyme in the expression of genes which are normally expressed during the logarithmic phase of growth. The location of the transcription termination signal confirmed that the sigma 43 operon consists of three genes.
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PMID:Promoter switching during development and the termination site of the sigma 43 operon of Bacillus subtilis. 329 98

We have previously identified T4 late promoters governing the in vivo expression of T4 late genes 23 and 24 (P23 and P24). T4 late transcription in vivo is known to involve the binding of at least five phage-coded proteins to the bacterial RNA polymerase and normally requires concurrent DNA replication for DNA template activation. We show here that in vitro transcription, primarily of plasmids carrying T4 genes 23 and 24, by RNA polymerase purified from Escherichia coli at late times after T4 infection allows specific initiation at P23 and P24 in the absence of DNA replication. These promoters are not utilized by E. coli RNA polymerase holoenzyme, by RNA polymerase core, or by T4-modified RNA polymerase purified from cells infected with a T4 gene 55 mutant (gene 55 codes for an RNA polymerase binding protein required for late transcription). The utilization of P23 and P24 in vitro is sharply inhibited by NaCl concentrations greater than 100 mM, and this inhibition is partly reversed by the addition of 10% DMSO. Relaxation of plasmid DNA containing P23 (with topoisomerase I) reduces P23 utilization at low salt (50 mM Na+) and nearly abolishes it at high salt (250 mM Na+). P23 utilization is discernible in linear, glucosylated hydroxymethylcytosine-containing T4 virion DNA.
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PMID:Initiation of transcription at phage T4 late promoters with purified RNA polymerase. 687 99

The macromolecular synthesis (MMS) operon consists of three genes: rpsU, which encodes the S21 ribosomal protein in Bacillus subtilis (Bs), rpsU is replaced by orfP23 which encodes a protein of unknown function), dnaG, encoding the DNA primase involved in the initiation of chromosome replication, and rpoD, which encodes the principal sigma subunit of RNA polymerase. The operon was cloned in three segments from Listeria monocytogenes (Lm), initially using a probe designed from a highly conserved region of RpoD. Analysis of the nucleotide sequence revealed three genes: orfP17 (whose product, P17, is homologous to Bs P23), dnaG and rpoD. The Lm DnaG resembles the primase from Escherichia coli through the first two-thirds of the sequence. C-terminal similarity was observed between DnaG from Lm and Bs. Lm RpoD is similar to Bs SigA, shares identical DNA-binding domains with SigA, and is a member of the sigma 43 subgroup of the sigma 70 family.
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PMID:Characterization of the macromolecular synthesis (MMS) operon from Listeria monocytogenes. 782 67

A vaccinia virus transient expression system was used to determine which of the Sindbis virus (SIN) proteins and/or polyproteins are necessary for the formation of active replication complexes and, in particular, to analyze the role of nsP4, the putative polymerase, versus P34 in RNA replication. We generated vaccinia virus recombinants in which the cDNA for the entire SIN nonstructural coding region as well as cDNA copies of the individual nonstructural proteins (nsPs) and several intermediate polyproteins were placed downstream of the promoter for T7 RNA polymerase and the encephalomyocarditis virus 5' untranslated region. The proteins expressed by the vaccinia virus recombinants comigrate with authentic proteins synthesized in SIN-infected cells, and the polyproteins appear to be processed to the individual proteins of the correct size. To examine the replication efficiencies of different protein combinations, a vaccinia virus recombinant was designed to express an engineered substrate RNA which could serve as a template for replication and subgenomic mRNA transcription by the SIN nsPs. Expression of the entire SIN nonstructural coding region resulted in the synthesis of high levels of both genomic and subgenomic RNAs derived from the engineered template. No RNA replication could be detected during coexpression of the four individual nsPs, although the proteins were indistinguishable, in terms of electrophoretic mobility, from those synthesized in SIN-infected cells. Coexpression of polyproteins P12, P23, and/or P34 with the individual nsPs also did not result in detectable levels of RNA replication. However, when P123 and P34 were coexpressed, efficient RNA replication and subgenomic mRNA transcription of the substrate RNA was observed. Coexpression of nsP4 with P123 resulted in the synthesis of only minus-strand RNAs. These studies show that expression of both P123 and P34 is necessary for establishment of functional RNA replication and transcription complexes and raise the possibility that the polyproteins themselves may be functional components of these complexes. In addition, these data indicate that an nsP4 moiety expressed independently with an additional N-terminal methionine is capable of functioning in minus-strand but not plus-strand RNA synthesis.
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PMID:Assembly of functional Sindbis virus RNA replication complexes: requirement for coexpression of P123 and P34. 844 16

We identified mutations in the gene for nsP2, a nonstructural protein of the alphavirus Sindbis virus, that appear to block the conversion of the initial, short-lived minus-strand replicase complex (RCinitial) into mature, stable forms that are replicase and transcriptase complexes (RCstable), producing 49S genome or 26S mRNA. Base changes at nucleotide (nt) 2166 (G-->A, predicting a change of Glu-163-->Lys), at nt 2502 (G-->A, predicting a change of Val-275-->Ile), and at nt 2926 (C-->U, predicting a change of Leu-416-->Ser) in the nsP2 N domain were responsible for the phenotypes of ts14, ts16, and ts19 members of subgroup 11 (D.L. Sawicki and S.G. Sawicki, Virology 44:20-34, 1985) of the A complementation group of Sindbis virus RNA-negative mutants. Unlike subgroup I mutants, the RCstable formed at 30 degrees C transcribed 26S mRNA normally and did not synthesize minus strands in the absence of protein synthesis after temperature shift. The N-domain substitutions did not inactivate the thiol protease in the C domain of nsP2 and did not stop the proteolytic processing of the polyprotein containing the nonstructural proteins. The distinct phenotypes of subgroup I and 11 A complementation group mutants are evidence that the two domains of nsP2 are essential and functionally distinct. A detailed analysis of ts14 found that its nsPs were synthesized, processed, transported, and assembled at 40 degrees C into complexes with the properties of RCinitial and synthesized minus strands for a short time after shift to 40 degrees C. The block in the pathway to the formation of RCstable occurred after cleavage of the minus-strand replicase P123 or P23 polyprotein into mature nsP1, nsP2, nsP3, and nsP4, indicating that structures resembling RCstable, were formed at 40 degrees C. However, these RCstable or pre-RCstable structures were not capable of recovering activity at 30 degrees C. Therefore, failure to increase the rate of plus-strand synthesis after shift to 40 degrees C appears to result from failure to convert RCinitial to RCstable. We conclude that RCstable is derived from RCinitial by a conversion process and that ts14 is a conversion mutant. From their similar phenotypes, we predict that other nsP2 N-domain mutants are blocked also in the conversion of RCinitial to RCstable. Thus, the N domain of nsP2 plays an essential role in a folding pathway of the nsPs responsible for formation of the initial minus-strand replicase and for its conversion into stable plus-strand RNA-synthesizing enzymes.
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PMID:Sindbis virus RNA-negative mutants that fail to convert from minus-strand to plus-strand synthesis: role of the nsP2 protein. 862 44

Recent insights into the early events in Sindbis virus RNA replication suggest a requirement for either the P123 or P23 polyprotein, as well as mature nsP4, the RNA-dependent RNA polymerase, for initiation of minus-strand RNA synthesis. Based on this observation, we have succeeded in reconstituting an in vitro system for template-dependent initiation of SIN RNA replication. Extracts were isolated from cells infected with vaccinia virus recombinants expressing various SIN proteins and assayed by the addition of exogenous template RNAs. Extracts from cells expressing P123C>S, a protease-defective P123 polyprotein, and nsP4 synthesized a genome-length minus-sense RNA product. Replicase activity was dependent upon addition of exogenous RNA and was specific for alphavirus plus-strand RNA templates. RNA synthesis was also obtained by coexpression of nsP1, P23C>S, and nsP4. However, extracts from cells expressing nsP4 and P123, a cleavage-competent P123 polyprotein, had much less replicase activity. In addition, a P123 polyprotein containing a mutation in the nsP2 protease which increased the efficiency of processing exhibited very little, if any, replicase activity. These results provide further evidence that processing of the polyprotein inactivates the minus-strand initiation complex. Finally, RNA synthesis was detected when soluble nsP4 was added to a membrane fraction containing P123C>S, thus providing a functional assay for purification of the nsP4 RNA polymerase.
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PMID:Template-dependent initiation of Sindbis virus RNA replication in vitro. 965 98

There are two types of infection caused by pathogenic microorganisms, intracellular infection and intercellular infection. Infection of pathogenic leptospira is an intercellular infection. The immunological reaction of host to intercellular infection is unique. The potential immunogen of an expressed protein should meet three criteria: it can be degraded (by antigen-present cells in the host); it should have antigenic epitope which can be recognized by specific antibodies and have at least one epitope that can be recognized by an MHC II protein and T cell receptor. In this study we report the cloning of an L. interrogans protein in plasmid rpDJt and the immunogencity of the expressed protein derivative. A genomic library of L. interrogans serovar lai strain 017 was constructed with the plasmid vector pUC18. Recombinant plasmids, designated pDJH2 and pDJ8 were screened from the bank. EcoRI-inserted fragment of 1. 9 kb recombinant DNA of pDJH2 was ligated into T7 RNA polymerase/promoter vectors (pT7-7). Then they were transformed into E. coli JM109 (De3), one of subclones, designated rpDJt was achieved. SDS-PAGE showed that the molecular weights of expression proteins were 68 kd and 23 kd respectively, designated p68 and p23. Purifying and isolating p68 and p23, we separated them from SDS-Polyacrylamide gels by using Side-Strip method. After fragmenting and electroeluting, p68 and p23 were injected into guinea pigs and rabbits. An extremely strong immune response to p68 was obtained since an anti-p68 antibody response could be detected to a dilution 1:524,288 (guinea pigs) and 1:262,144 (rabbits) by ELISA while anti-P23 antibody being 1:1024 (the same to guinea pigs and rabbits). The results of improved MTT and conA 3HTdR transformation methods showed the activities and proliferation of Th-cells were increased in guinea pigs after p68 immunization (IL-6, 83.25 IU/ml, IL-2, 28.75 IU/ml; RPI, 2.04, SI, 65.62%) Thlymphocyte existed in two subclasses, the Th1- and Th2-cells. A major role of Th2-cells is to "help" B-cells differentiate, replicate, and secrete antibody. The properties of these interactions explain why p68 makes good antigen and p23 does not. The antigens responsible for eliciting the production of protective antibodies are not known; however, several outer membrane proteins on L. interrogans are candidates for vaccine. Our results suggest that expresion protein p68 from recombinants (rpDJt) may be a candidate for gene engineered subunit vaccine for Leptospirosis.
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PMID:[Immunogenecity of expressed protein p68 from recombinant plasmid rpDJt in L. interrogans serovar lai]. 1068 17

The virus-specific components (nsP1-nsP4) of Semliki Forest virus RNA polymerase are synthesized as a large polyprotein (P1234), which is cleaved by a virus-encoded protease. Based on mutagenesis studies, nsP2 has been implicated as the protease moiety of P1234. Here, we show that purified nsP2 (799 amino acids) and its C-terminal domain Pro39 (amino acids 459-799) specifically process P1234 and its cleavage intermediates. Analysis of cleavage products of in vitro synthesized P12, P23, and P34 revealed cleavages at sites 1/2, 2/3, and 3/4. The cleavage regions of P1/2, P2/3, and P3/4 were expressed as thioredoxin fusion proteins (Trx12, Trx23, and Trx34), containing approximately 20 amino acids on each side of the cleavage sites. After exposure of these purified fusion proteins to nsP2 or Pro39, the reaction products were analyzed by SDS-polyacrylamide gel electrophoresis, mass spectrometry, and amino-terminal sequencing. The expected amino termini of nsP2, nsP3, and nsP4 were detected. The cleavage at 3/4 site was most efficient, whereas cleavage at 1/2 site required 5000-fold more of Pro39, and 2/3 site was almost resistant to cleavage. The activity of Pro39 was inhibited by N-ethylmaleimide, Zn(2+), and Cu(2+), but not by EDTA, phenylmethylsulfonyl fluoride, or pepstatin, in accordance with the thiol proteinase nature of nsP2.
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PMID:Site-specific protease activity of the carboxyl-terminal domain of Semliki Forest virus replicase protein nsP2. 1141 May 98

Alphavirus nonstructural proteins are translated as a polyprotein that is ultimately cleaved into four mature proteins called nsP1, nsP2, nsP3, and nsP4 from their order in the polyprotein. The role of this nonstructural polyprotein, of cleavage intermediates, and of mature proteins in synthesis of Semliki Forest virus (SFV) RNA has been studied using mutants unable to cleave one or more of the sites in the nonstructural polyprotein or that had the arginine sense codon between nsP3 and nsP4 changed to an opal termination codon. The results were compared with those obtained for Sindbis virus (SINV), which has a naturally occurring opal codon between nsP2 and nsP3. We found that (1) an active nonstructural protease in nsP2 is required for RNA synthesis. This protease is responsible for all three cleavages in the nonstructural polyprotein. (2) Cleavage between nsP3 and nsP4 (the viral RNA polymerase) is required for RNA synthesis by SFV. (3) SFV mutants that are able to produce only polyprotein P123 and nsP4 synthesize minus-strand RNA early after infection as efficiently as SF wild type but are defective in the synthesis of plus-strand RNA. The presence of sense or opal following nsP3 did not affect this result. At 30 degrees C, they give rise to low yields of virus after a delay, but at 39 degrees C, they are nonviable. (4) SFV mutants that produce nsP1, P23, nsP4, as well as the precursor P123 are viable but produce an order of magnitude less virus than wild type at 30 degrees C and two orders of magnitude less virus at 39 degrees C. The ratio of subgenomic mRNA to genomic RNA is much reduced in these mutants relative to the parental viruses. (5) At 30 degrees C, the variants containing an opal codon grow as well as or slightly better than the corresponding virus with a sense codon. At 39 degrees C, however, the opal variants produce significantly more virus. These results support the conclusion that SFV and SINV, and by extension all alphaviruses, regulate their RNA synthesis in the same fashion after infection. P123 and nsP4 form a minus-strand replicase that synthesizes plus-strand RNA only inefficiently, especially at the higher temperatures found in mammals and birds. A replicase containing nsP1, P23, and nsP4 can make both plus and minus strands, but prefers the promoter for genomic plus sense RNA to that for subgenomic mRNA. The fully cleaved replicase can make only plus-strand RNA, and prefers the promoter for subgenomic mRNA to that for genomic RNA. Alphaviruses alternate between infection of hematophagous arthropods and higher vertebrates. Although the infection of higher vertebrates is acute and often accompanied by disease, continuing transmission of the virus in nature requires that infection of arthropods be persistent and relatively asymptomatic. We propose that this mechanism for control of RNA synthesis evolved to moderate the pathogenicity of the viruses in their arthropod hosts.
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PMID:Regulation of Semliki Forest virus RNA replication: a model for the control of alphavirus pathogenesis in invertebrate hosts. 1516 27

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