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

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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)

We report a "running start, two-bond" protocol to analyze elongation by human RNA polymerase II (RNAP II). In this procedure, the running start allowed us to measure rapid rates of elongation and provided detailed insight into the RNAP II mechanism. Formation of two bonds was tracked to ensure that at least one translocation event was analyzed. By using this method, RNAP II is stalled briefly at a defined template position before restoring the next NTP. Significantly, slow reaction steps are identified both before and after phosphodiester bond synthesis, and both of these steps can be highly dependent on the next templated NTP. The initial and final NTP-driven events, however, are not identical, because the slow step after chemistry, which includes translocation and pyrophosphate release, is regulated differently by elongation factors hepatitis delta antigen and transcription factor IIF. Because recovery from a stall and the processive transition from one bond to the next can be highly NTP-dependent, we conclude that translocation can be driven by the incoming substrate NTP, a model fully consistent with the RNAP II elongation complex structure.
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PMID:NTP-driven translocation by human RNA polymerase II. 1263 20

RNA chain initiation and promoter escape is the latter stage of transcription initiation. This stage is characterized by several well-defined biochemical events: synthesis and release of short RNA products ranging 2 to 15 nucleotides in length, release of the sigma subunit from the enzyme-promoter complex, and initial translocation of the polymerase away from the promoter. In this paper, we report the use of a steady-state transcription assay with [gamma-(32)P]ATP labeling to subject the RNA chain initiation-promoter escape reaction to quantitative analysis. The specific parameters we follow to describe the chain initiation-promoter escape process include the abortive and productive rates, the abortive probability, the abortive:productive ratio, and the maximal size of the abortive product. In this study, we measure these parameters for three bacteriophage promoters transcribed by Escherichia coli RNA polymerase: T7 A1, T5 N25, and T5 N25(antiDSR). Our studies show that all three promoters form substantial amounts of abortive products under all conditions we tested. However, each of the promoters shows distinct differences from the others when the various parameters are compared. At 100 microM NTP, in a 10 min reaction, the abortive and productive yields are 87 and 13%, respectively, for T7 A1; 97 and 3%, respectively, for T5 N25; and 99.4 and 0.6%, respectively, for T5 N25(antiDSR). These values correspond to approximately 7, 32, and 165 abortive transcripts per productive transcript for the three promoters, respectively. The yield of most of the abortive products is not affected by the elevated concentration of the NTP substrate corresponding to the next template-specified nucleotide; hence, abortive products are not normally formed through a simple process of "kinetic competition". Instead, formation of abortive products appears to be determined by intrinsic DNA signals embedded in the promoter recognition region and the initial transcribed sequence region of each promoter.
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PMID:In vitro studies of transcript initiation by Escherichia coli RNA polymerase. 1. RNA chain initiation, abortive initiation, and promoter escape at three bacteriophage promoters. 1266 69

The ability of RNA polymerase (RNAP) to adopt multiple conformations is central to transcriptional regulation. In previous work, we demonstrated that RNAP can exist in an unactivated state that catalyzes synthesis slowly and an activated state that catalyzes synthesis rapidly, with the transition from the unactivated to the activated state being induced by the templated NTP binding to an allosteric site on the RNAP. In this work, we investigate the effects of downstream DNA sequences on the kinetics of single nucleotide incorporation. We demonstrate that changing the identity of the DNA base 1 bp downstream (+2) from the site of incorporation (+1) can regulate the catalytic activity of RNAP. Combining these data with sequence and structural analyses and molecular modeling, we identify the streptolydigin-binding region (Escherichia coli beta residues 543-546), which lies across from the downstream DNA, as the putative allosteric NTP binding site. We present a structural model in which the NTP binds to the streptolydigin loop and upon pairing with the +1 DNA base in the unactivated state or the +2 DNA base in the activated state facilitates translocation via a ratchet motion. This model provides an alternative mechanism for pausing as well as a structural explanation not only for our kinetic data but also for data from elongation studies on yeast RNAP II.
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PMID:Downstream DNA sequence effects on transcription elongation. Allosteric binding of nucleoside triphosphates facilitates translocation via a ratchet motion. 1281 36

Schizosaccharomyces pombe Cdk9/Pch1 protein kinase is a functional ortholog of the essential Saccharomyces cerevisiae Bur1/Bur2 kinase and a putative ortholog of metazoan P-TEFb (Cdk9/cyclin T). SpCdk9/Pch1 phosphorylates of the carboxyl-terminal domain (CTD) of the S. pombe transcription elongation factor Spt5, which consists of 18 tandem repeats of a nonapeptide of consensus sequence 1TPAWNSGSK9. We document the divalent cation dependence and specificity of SpCdk9/Pch1, its NTP dependence and specificity, the dependence of Spt5-CTD phosphorylation on the number of tandem nonamer repeats, and the specificity for phosphorylation of the Spt5-CTD on threonine at position 1 within the nonamer element. SpCdk9/Pch1 also phosphorylates the CTD heptaptide repeat array of the largest subunit of S. pombe RNA polymerase II (consensus sequence YSPTSPS) and does so exclusively on serine. SpCdk9/Pch1 catalyzes autophosphorylation of the kinase and cyclin subunits of the kinase complex. The distribution of phosphorylation sites on SpCdk9 (86% Ser(P), 11% Thr(P), 3% Tyr(P)) is distinct from that on Pch1 (2% Ser(P), 98% Thr(P)). We conducted a structure-guided mutational analysis of SpCdk9, whereby a total of 29 new mutations of 12 conserved residues were tested for in vivo function by complementation of a yeast bur1Delta mutant. We identified many lethal and conditional mutations of side chains implicated in binding ATP and the divalent cation cofactor, phosphoacceptor substrate recognition, and T-loop dynamics. We surmise that the lethality of the of T212A mutation in the T-loop reflects an essential phosphorylation event, insofar as the conservative T212S change rescued wild-type growth; the phosphomimetic T212E change rescued growth at 30 degrees C; and the effects of mutating the T-loop threonine were phenocopied by mutations in the three conserved arginines predicted to chelate the phosphate on the T-loop threonine.
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PMID:Characterization of the Schizosaccharomyces pombe Cdk9/Pch1 protein kinase: Spt5 phosphorylation, autophosphorylation, and mutational analysis. 1290 90

It is becoming clearer that genetic activity is closely associated with the intracellular energy state. However, the mechanisms of this association are still unclear. In this study, we focused on large-scale changes in the structure of DNA to examine the effect of the NTP concentration on the transcription reaction with T7 RNA polymerase and compared the results with long duplex DNA to those with a short persistent-length(1) fragment. The transcriptional activity dramatically changed only for long duplex DNA within a narrow range of NTP concentrations associated with changes in the large-scale structure of DNA. This result suggests that the energy state may play an essential role in regulating ON/OFF switching on transcriptional activity.
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PMID:NTP concentration switches transcriptional activity by changing the large-scale structure of DNA. 1295 73

Transcription initiation by sigma(54)-RNA polymerase (RNAP) relies explicitly on a transient interaction with a complex molecular machine belonging to the AAA+ (ATPases associated with various cellular activities) superfamily. Members of the AAA+ superfamily convert chemical energy derived from NTP hydrolysis to a mechanical force used to remodel their target substrate. Recently Bordes and colleagues,1 using a protein fragmentation approach, identified a unique sequence within sigma(54)-dependent transcriptional activators that constitutes a sigma(54)-binding interface. This interface is not static, but subject to nucleotide-dependent movement which may represent a common mechanism for controlling output that has been adopted by other AAA+ proteins.
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PMID:Investigating protein-protein interfaces in bacterial transcription complexes: a fragmentation approach. 1463 49

The interaction of the hepatitis C virus (HCV) RNA-dependent RNA polymerase with RNA substrate is incompletely defined. We have characterized the activities of the HCV NS5B polymerase, modified by different deletions and affinity tags, with a routinely used homopolymeric substrate, and established apparent affinities of the various NS5B constructs both for the NTP and the template/primer substrates. We identified a uniquely tagged HCV NS5B RNA polymerase construct with a lower affinity (higher K(m)) than mature HCV NS5B for template/ primer substrate and highlighted the use of such a polymerase for the identification of inhibitors of NS5B activity, particularly inhibitors of productive RNA binding. The characterization of specific benzimidazole-5-carboxamide-based inhibitors, identified in a screening campaign, revealed that this class of compounds was non-competitive with regard to NTP incorporation and had no effect on processive elongation, but inhibited an initiation phase of the HCV polymerase activity. The potency of these compounds versus a panel of different NS5B polymerase constructs was inversely proportional to the enzymes' affinities for template/primer substrate. The benzimidazole-5-carboxamide compounds also inhibited the full-length, untagged NS5B de novo initiation reaction using HCV 3'-UTR substrate RNA and expand the diversifying pool of potential HCV replication inhibitors.
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PMID:Specific inhibitors of HCV polymerase identified using an NS5B with lower affinity for template/primer substrate. 1473 34

Current models for transcription elongation infer that RNA polymerase (RNAP) moves along the template by a passive sliding mechanism that takes advantage of random lateral oscillations in which single basepair sliding movements interconvert the elongation complex between pre- and post-translocated states. Such passive translocational equilibrium was tested in vivo by a systematic change in the templated NTP that is to be incorporated by RNAP, which is temporarily roadblocked by the lac repressor. Our results show that, under these conditions that hinder the forward movement of the polymerase, the elongation complex is able to extend its RNA chain one nucleotide further when the incoming NTP is a kinetically favoured substrate (i.e. low K(m)). The addition of an extra nucleotide destabilizes the repressor-operator roadblock leading to an increase in transcriptional readthrough. Similar results are obtained when the incoming NTPs are less kinetically favoured substrates (i.e. high K(m)s) by specifically increasing their intracellular concentrations. Altogether, these in vivo data are consistent with a passive sliding model in which RNAP forward translocation is favoured by NTP binding. They also suggest that fluctuations in the intracellular NTP pools may play a key role in gene regulation at the transcript elongation level.
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PMID:Translocation of Escherichia coli RNA polymerase against a protein roadblock in vivo highlights a passive sliding mechanism for transcript elongation. 1498 39

The rolling circle (RC) mechanism of DNA replication generating single-stranded DNA (ssDNA) intermediates is common in various high-copy circular plasmids in Streptomyces, and the ssDNA released after leading strand synthesis is converted to its double-stranded form (dsDNA) by the host proteins. The in vivo and in vitro lagging strand syntheses from ssDNA replicative intermediates of RC plasmid pSN22 in Streptomyces lividans was characterized. The presence or absence of the single-strand origin (sso), the replication initiation site of lagging strand synthesis, did not significantly affect the copy numbers of pSN22 derivatives. In vivo lagging strand synthesis was not affected by the rifampicin inhibition of S. lividans RNA polymerase. Likewise, in vitro lagging strand synthesis using cell-free extracts revealed sso-independent, rifampicin-resistant lagging strand synthesis in S. lividans. Although all four dNTPs are usually required for the initiation of such synthesis, the presence of only one NTP was sufficient to carry outlagging strand synthesis in vitro. Interestingly, the cell-free extract of exponential-phase cells required less ATP than that of stationary-phase cells. These results reveal a predominant RNA polymerase-independent priming system in S. lividans that may be a result of the stabilization of RC plasmids lacking sso in S. lividans.
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PMID:Lagging strand replication of rolling-circle plasmids in Streptomyces lividans: an RNA polymerase-independent primer synthesis. 1500 43

RNA polymerase functions like a molecular motor that can convert chemical energy into the work of strand separation and translocation along the DNA during transcription. The structures of phage T7 RNA polymerase in an elongation phase substrate complex that includes the incoming nucleoside triphosphate and a pretranslocation product complex that includes the product pyrophosphate (PPi) are described here. These structures and the previously determined posttranslocation elongation complex demonstrate that two enzyme conformations exist during a cycle of single nucleotide addition. One orientation of a five-helix subdomain is stabilized by the phosphates of either the incoming NTP or by the product PPi. A second orientation of this subdomain is stable in their absence and is associated with translocation of the heteroduplex product as well as strand separation of the downstream DNA. We propose that the dissociation of the product PPi after nucleotide addition produces the protein conformational change resulting in translocation and strand separation.
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PMID:The structural mechanism of translocation and helicase activity in T7 RNA polymerase. 1501 67


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