EC:2.7.7.6 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: EC:2.7.7.6 (RNA polymerase)
34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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.
...
PMID:Host factor requirements for processive antitermination of transcription and suppression of pausing by the N protein of bacteriophage lambda. 138 70

We have reconstituted biologically relevant transcriptional antitermination in vitro by the phage lambda N protein. This required the isolation of NusG, a newly identified Escherichia coli transcription elongation factor. NusG is encoded by an E. coli gene, formerly called U and now called nusG, in which a mutation affects antitermination by N in vivo. Efficient antitermination by N in our reconstituted system depends on the bacterial proteins NusG, NusA, NusB, and ribosomal protein S10 (which functions without ribosomes in transcriptional antitermination). In reactions containing E. coli S100 extract, NusG is stoichiometrically bound to lambda N-modified transcription elongation complexes. We used RNA polymerase affinity chromatography to show that NusG binds to the core component of E. coli RNA polymerase. This binding is weak, and the stable association of NusG with lambda elongation complexes additionally requires at least N, NusA, and the boxA component of an N utilization site. In reactions containing bacterial S100 extract, NusG and NusB are also present in elongation complexes transcribing E. coli boxA-containing rDNA.
...
PMID:NusG, a new Escherichia coli elongation factor involved in transcriptional antitermination by the N protein of phage lambda. 153 77

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.
...
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 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.
...
PMID:An elongation control particle containing the N gene transcriptional antitermination protein of bacteriophage lambda. 244 91

Bacteriophage lambda N gene product acts to modify host RNA polymerase allowing the formation of a termination-resistant transcription apparatus. Previous studies have demonstrated that the nusE71 mutation that has altered the ribosomal protein S10 prevents N action in vivo. Using a coupled transcription-translation system, we demonstrate here that purified S10 protein as well as the 30S ribosomal subunit is sufficient to restore N activity in the nusE mutant extract, allowing antitermination of Rho-dependent and Rho-independent terminators. This provides direct biochemical evidence that the S10 protein itself is one of the cellular components necessary for the formation of an antitermination apparatus.
...
PMID:Evidence that ribosomal protein S10 itself is a cellular component necessary for transcription antitermination by phage lambda N protein. 298 61

The stable association of the N gene transcriptional antiterminator protein of bacteriophage lambda with transcribing RNA polymerase requires a nut site (boxA+boxB) in the nascent transcript and the Escherichia coli factors NusA, NusB, NusG, and ribosomal protein S10. We have used electrophoretic mobility shift assays to analyze the assembly of N protein, the E. coli factors, and RNA polymerase onto the nut site RNA in the absence of a DNA template. We show that N binds boxB RNA and that subsequent association of NusA with the N-nut site complex is facilitated by both boxA and boxB. In the presence of N, NusA, and RNA polymerase the nut site assembles ribonucleoprotein complexes containing NusB, NusG, and S10. The effects on assembly of mutations in boxA, boxB, NusA, and RNA polymerase define multiple weak protein-protein and protein-RNA interactions (e.g., NusB with NusG; NusA with boxB; NusA, NusB, and NusG with boxA) that contribute to the overall stability of the complex. Interaction of each component of the complex with two or more other components can explain the many observed cooperative binding associations in the DNA-independent assembly of a stable antitermination complex on RNA polymerase.
...
PMID:A protein-RNA interaction network facilitates the template-independent cooperative assembly on RNA polymerase of a stable antitermination complex containing the lambda N protein. 759 Feb 57

The boxA sequences of the E. coli ribosomal RNA (rrn) operons are sufficient to cause RNA polymerase to read through Rho-dependent transcriptional terminators. We show that a complex of the transcription antitermination factors NusB and ribosomal protein S10 interacts specifically with boxA RNA. Neither NusB nor S10 binds boxA RNA on its own, and neither NusA nor NusG affects the interaction of the NusB-S10 complex with boxA RNA. Mutations in boxA that impair its antitermination activity compromise its interaction with NusB and S10, suggesting that ribosomal protein S10 regulates the synthesis of ribosomal RNA in bacteria. RNA containing the closely related boxA sequence from the bacteriophage lambda nutR site is not stably bound by NusB and S10. This probably explains why antitermination in phage lambda depends on the phage lambda N protein and the boxB component of the nut site, in addition to boxA.
...
PMID:Recognition of boxA antiterminator RNA by the E. coli antitermination factors NusB and ribosomal protein S10. 767 81

The association of the transcriptional antitermination protein N of bacteriophage lambda with Escherichia coli RNA polymerase depends on nut site RNA (boxA + boxB) in the nascent transcript and the host protein, NusA. This ribonucleoprotein complex can transcribe through Rho-dependent and intrinsic termination sites located up to several hundred base pairs downstream of nut. For antitermination to occur farther downstream, this core antitermination complex must be stabilized by the host proteins NusB, NusG, and ribosomal protein S10. Here, we show that the assembly of NusB, NusG, and S10 onto the core complex involves nucleotides 2-7 of lambda boxA (CGCUCUUACACA) and is a fully cooperative process that depends on the presence of all three proteins. This assembly of NusB, NusG, and S10 also requires the carboxyl-terminal region (amino acids 73-107) of N, which interacts directly with RNA polymerase. NusB and S10 assemble in the absence of NusG when lambda boxA is altered at nucleotides 8 and 9 to create a consensus version of boxA (CGCUCUUUAACA). These experiments suggest that multiple protein-protein and protein-RNA interactions are required to convert a core antitermination complex into a complete complex.
...
PMID:Involvement of boxA nucleotides in the formation of a stable ribonucleoprotein complex containing the bacteriophage lambda N protein. 946 9

The association of the essential Escherichia coli protein NusA with RNA polymerase increases pausing and the efficiency of termination at intrinsic terminators. NusA is also part of the phage lambda N protein-modified antitermination complex that functions to prevent transcriptional termination. We have investigated the structure of NusA using various deletion fragments of NusA in a variety of in vitro assays. Sequence and structural alignments have suggested that NusA has both S1 and KH homology regions that are thought to bind RNA. We show here that the portion of NusA containing the S1 and KH homology regions is important for NusA to enhance both termination and antitermination. There are two RNA polymerase-binding regions in NusA, one in the amino-terminal 137 amino acids and the other in the carboxy-terminal 264 amino acids; only the amino-terminal RNA polymerase-binding region provides a functional contact that enhances termination at an intrinsic terminator or antitermination by N. The carboxy-terminal region of NusA is also required for interaction with N and is important for the formation of an N-NusA-nut site or N-NusA-RNA polymerase-nut site complex; the instability of complexes lacking this carboxy-terminal region of NusA that binds N and RNA polymerase can be compensated for by the presence of the additional E. coli elongation factors, NusB, NusG and ribosomal protein S10.
...
PMID:Functional importance of regions in Escherichia coli elongation factor NusA that interact with RNA polymerase, the bacteriophage lambda N protein and RNA. 1056 94

Gene expression in lambdoid phages in part is controlled by transcription antitermination. For most lambdoid phages, maximal expression of delayed early genes requires an RNA polymerase modified by the phage N and host Nus proteins at RNA NUT sites. The NUT sites (NUTL and NUTR) are made up of three elements: BOXA, BOXB and an intervening spacer sequence. We report on N antitermination in H-19B, a lambdoid phage carrying shiga toxin 1 genes. H-19B N requires NusA, but not two other host factors required by lambda N, NusB and ribosomal protein S10. The H-19B NUT site BOXA is not required, whereas the BOXB is required for N action. H-19B nut sites have dyad symmetries in the spacer regions that are not in other nut sites. Changes in one arm of the dyad symmetry inactivate the NUT RNA. Compensating changes increasing the number of mutant nucleotides but restoring dyad symmetry restore activity. Deletion of the sequences encoding the dyad symmetry has little effect. Thus, the specific nucleotides composing the dyad symmetry seem relatively unimportant. We propose that the RNA stem-loop structure, called the 'reducer', by sequestering nucleotides from the linear RNA brings into proximity sites on either side of the dyad symmetry that contribute to forming an active NUT site.
...
PMID:N-mediated transcription antitermination in lambdoid phage H-19B is characterized by alternative NUT RNA structures and a reduced requirement for host factors. 1112 80

1 2 Next >>