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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)

Ribosomal protein L4 of Escherichia coli autogenously regulates both transcription and translation of the 11-gene S10 operon. Transcription regulation occurs by L4-stimulated premature termination at an attenuator hairpin in the S10 leader. This effect can be reproduced in vitro but depends on the addition of transcription factor NusA. We show that NusA is required to promote RNA polymerase pausing at the termination site; such paused transcription complexes are then stabilized further by r-protein L4. The L4 effect is observed even if the protein is added after the NusA-modified RNA polymerase has already reached the pause site. Genetically separable regions of the S10 leader are required for NusA and L4 action: The attenuator hairpin is sufficient for NusA-dependent pausing, but upstream elements are necessary for L4 to prolong the pause.
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PMID:Ribosomal protein L4 and transcription factor NusA have separable roles in mediating terminating of transcription within the leader of the S10 operon of Escherichia coli. 128 27

The genes for the beta (rpoB) and beta' (rpoC) subunits of Escherichia coli RNA polymerase are the distal members of a complex transcriptional unit that contains four upstream ribosomal protein genes. The RNA polymerase subunit genes are transcribed at a lower frequency than the ribosomal protein genes as a result of termination at an attenuator preceding rpoB. A purified in vitro transcription system was developed using linear DNA templates that carry the attenuator. The ability of known termination and antitermination proteins to modulate termination at the attenuator was tested. Both NusA and NusG increase the frequency of transcriptional readthrough at the attenuator whereas NusB, S10, and Rho had no significant effect in this system.
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PMID:The NusA and NusG proteins of Escherichia coli increase the in vitro readthrough frequency of a transcriptional attenuator preceding the gene for the beta subunit of RNA polymerase. 137 Apr 74

The N protein of phage lambda prevents termination of transcription by Escherichia coli RNA polymerase at Rho-dependent and -independent terminators in the lambda early operons. The modification of RNA polymerase by N requires an N-utilization (nut) site, present in each lambda early operon, and involves the E. coli factors NusA, NusB, NusG, and ribosomal protein S10. We show that, in the presence of NusA, N inhibits pausing by RNA polymerase and Rho-dependent termination in vitro at three sites in the lambda terminator tR1 which are located less than 100 base pairs downstream from nutR. NusA is also sufficient for partial antitermination at sites located farther downstream from nutL and nutR if there is a high concentration of N in the reaction. At low concentrations of N, the additional factors NusB, S10, and NusG are essential for antitermination at distal sites. In these conditions, the presence of NusA, NusB, S10, and NusG in the reaction enables N-modified RNA polymerase to elongate efficiently and processively through Rho-dependent and -independent terminators over distances as great as 7 kilobases downstream from the lambda nut sites. This substantial processivity of antitermination in vitro also occurs in vivo and probably reflects the stable association of N, NusA, NusB, S10, and NusG with RNA polymerase and nut site RNA in elongation complexes transcribing the lambda chromosome.
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PMID:Host factor requirements for processive antitermination of transcription and suppression of pausing by the N protein of bacteriophage lambda. 138 70

Ribosomal protein L4 of Escherichia coli functions not only as a component of the ribosome but also as a regulatory factor inhibiting both transcription and translation of its own operon, the 11 gene S10 operon. L4-mediated transcription control results in premature termination of transcription within the 172 base S10 operon leader. This attenuation control can be reproduced in a purified transcription system containing RNA polymerase, but depends on the addition of transcription factor NusA. The NusA stimulation saturates at about 2-4 copies per RNA polymerase. The L4 effect plateaus at about 4 copies per RNA polymerase. The specific recognition sites on 23S rRNA and in the S10 leader for L4 binding are not yet known. However, we can demonstrate that a fragment of 23S rRNA containing the proximal 840 bases can eliminate in vitro L4-stimulated attenuation, and hence, contains the information sufficient for L4 binding to 23S rRNA.
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PMID:Ribosomal protein L4 of Escherichia coli: in vitro analysis of L4-mediated attenuation control. 176 18

The transcription antitermination protein, N, of bacteriophage lambda; the Escherichia coli elongation factors NusA, NusB, ribosomal protein S10, and NusG; and a DNA template containing a lambda nut (N-ututilization) site are necessary and sufficient for the highly cooperative formation in vitro of stable transcription complexes containing all five elongation factors. Mutations in the nut site, NusA, or the beta-subunit of RNA polymerase (RNAP) that impair antitermination in vivo also abolish the assembly of a stable complex containing the antitermination factors in vitro. The effects of RNAP mutations on assembly imply that the antitermination factors assemble on the surface of RNAP. We have shown previously that NusA binds directly to transcribing RNAP (Ka approximately 10(7) M-1); Ka = association constant and we show here that S10 also binds directly and specifically to RNAP with an apparent Ka of 10(6) M-1. These observations led to a model for the ordered assembly of the N-modified transcription complex.
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PMID:Assembly of transcription elongation complexes containing the N protein of phage lambda and the Escherichia coli elongation factors NusA, NusB, NusG, and S10. 183 Nov 76

The boxA and boxB components of the lambda nut site are important for transcriptional antitermination by the phage N protein. We show here that boxA and boxB RNA in N-modified transcription complexes are inaccessible to ribonucleases and have altered sensitivity to dimethylsulfate. N and NusA suffice to weakly protect boxB, independently of boxA and other factors. However, efficient protection of the entire nut site from ribonucleases requires boxA and boxB, N, NusA, NusB, S10, and NusG. Mutations in RNA polymerase, which inhibit antitermination by N in vivo, disallow protection of the nut site during transcription in vitro; therefore, the surface of RNA polymerase must coordinate the formation of complexes containing the antitermination factors and nut site RNA.
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PMID:The nut site of bacteriophage lambda is made of RNA and is bound by transcription antitermination factors on the surface of RNA polymerase. 183 23

We used two different approaches to study the requirement for Escherichia coli Nus factors for the activity of bacteriophage lambda late antiterminator Q. Using an in vitro coupled transcription-translation assay, based on Q-dependent synthesis of galactokinase from a pR'-tR'-galK template, we showed that mutations in the host nusB and nusE genes do not affect Q activity. A mutation in nusA (nusA1) only partially affects Q action at all temperatures tested. Defective Q function in the nusA1 mutant extract could be restored by the addition of pure NusA but not by excess Q. In a pure transcription system, measurement of the run-off transcript produced by Q-mediated suppression of tR' revealed that NusA is greatly stimulatory to Q activity, whereas NusB and S10, in the presence or absence of NusA, have no effect. Unidentified E. coli factor(s) present in an S30 extract efficiently suppress the natural pausing by RNA polymerase at +15, +16 of pR' without affecting Q activity. These results show that NusA is the only host protein that directly participates in Q function.
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PMID:An analysis of the role of host factors in transcription antitermination in vitro by the Q protein of coliphage lambda. 214 85

The 11-gene S10 ribosomal protein operon of Escherichia coli is under the autogenous control of L4, the product of the third gene of the operon. Ribosomal protein L4 inhibits both transcription and translation of the operon. Our in vivo studies indicated that L4 regulates transcription by causing premature termination within the untranslated S10 operon leader. We have now used an in vitro transcription system to study the effect of purified L4 on expression of the S10 operon. We find that the cell-free system reproduces the in vivo observations. Namely, in the absence of L4, most of the RNA polymerases read through the termination site in the S10 attenuator; the addition of L4 results in increased termination at this site. However, RNA polymerase does not terminate at the S10 attenuator, with or without L4, unless an additional factor, protein NusA, is added to the transcription reaction. These results suggest that the attenuator in the S10 operon is a NusA-dependent terminator whose efficiency is regulated by ribosomal protein L4.
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PMID:Ribosomal protein L4 stimulates in vitro termination of transcription at a NusA-dependent terminator in the S10 operon leader. 215 8

The N gene transcriptional antitermination protein of bacteriophage lambda is incorporated in vitro into transcriptional elongation complexes containing the E. coli proteins NusA and NusB. The binding of NusA to elongating RNA polymerase is sequence-independent and follows the release of sigma 70. Incorporation of N into the elongation complex requires an N utilization site (nut site) on the DNA template. Incorporation of NusB into the complex requires NusA, ribosomal protein S10, and the boxA component of the nut site. T1 RNAase releases N, but not NusB, from the elongation complex. We therefore propose that an N-modified termination-resistant elongation complex includes an elongation control particle (ECP) containing at least NusA, NusB, S10, N, and an RNA transcript of the nut site.
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PMID:An elongation control particle containing the N gene transcriptional antitermination protein of bacteriophage lambda. 244 91

By a chromosome walking strategy the DNA region from Methanococcus vannielii flanking the genes for protein synthesis elongation factor (EF) 1 alpha and EF-2 was cloned and sequenced. A gene organization of 5' - beta' - open reading frame (ORF) 1 - ORF2 - S12 - S7 - EF-2 - EF-1 alpha - S10 - ORF3 - ORF4 - 3' was found where beta', S12, S7, S10, EF-2, and EF-1 alpha represent gene products with sequences similar to the beta' subunit of RNA polymerase, ribosomal proteins S12, S7, and S10, and EF-G and EF-Tu from Escherichia coli, respectively. ORF1-4 represent gene products with no known eubacterial counterparts. Northern blot analysis of transcripts and nuclease S1 mapping showed that transcription initiates between beta' and ORF1 and terminates at the 3' side of the S10 gene and that the genes from ORF1 to S10 are cotranscribed. Apart from the presence of two additional ORFs, ORF1 and ORF2, and of the gene for S10, this organization is identical to that of the eubacterial "streptomycin operon." ORF1 displays sequence similarity to rat liver ribosomal protein L30 and may represent one of the "additional" ribosomal proteins of Methanococcus. The sequenced part of the beta' gene and the EF-2 and EF-1 alpha gene products from Methanococcus are more similar to their eukaryotic than to their eubacterial counterparts. It appears, therefore, that the genetic organization of the translational components resembles the situation in eubacteria, whereas their primary structures are more eukaryotic in nature.
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PMID:Organization and nucleotide sequence of a transcriptional unit of Methanococcus vannielii comprising genes for protein synthesis elongation factors and ribosomal proteins. 247 40

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