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)

On the basis of their recently described T7 RNA polymerase-T7 promoter crystal structure, Cheetham et al. [(1999) Nature 399, 80] propose that discrimination of the hydrogen bonding character of the elongating NTP ribose 2'-substituent involves a hydrogen bond to histidine 784. This would contradict a previous conclusion, based on the characterization of mutant RNAPs, that discrimination of the hydrogen bonding character of the ribose 2'-substituent depends solely on the hydroxyl group of tyrosine 639. To resolve this point, we prepared and characterized histidine 784 point mutants. We find that while these mutations reduce the activity of the polymerase, they do not significantly reduce the level of ribose discrimination. Furthermore, a mutant with alanine at position 784 preferentially utilizes NTPs with 2'-substituents capable of acting as hydrogen bond donors or acceptors (2'-OH and 2'-NH(2)) over NTPs with substituents that lack such properties (2'-F and 2'-H). In contrast, mutation of tyrosine 639 to phenylalanine eliminates discrimination of ribose 2'-group hydrogen bonding character. The effects on ribose discrimination of mutating tyrosine 639 to phenylalanine are independent of the side chain at position 784. These results indicate that histidine 784 is not involved in discrimination of the ribose 2'-group of the elongating NTP. The ability of T7RNAP tyrosine 639, which is conserved in both RNA and DNA polymerases, to select for rNTPs appears to be due to the fact that in RNAPs this tyrosine is available to hydrogen bond to the ribose 2'-OH, while in DNAPs it is hydrogen bonded to a glutamic acid.
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PMID:Roles of histidine 784 and tyrosine 639 in ribose discrimination by T7 RNA polymerase. 1065 35

The interaction of the bacterial regulatory protein H-NS with RNA polymerase and the ribosomal RNA P1 promoter was analyzed to better understand the mechanism of H-NS-dependent transcriptional repression. We could show that initial binding of RNA polymerase to the promoter was not inhibited by the simultaneous interaction of H-NS, although H-NS binding sites extend into the core promoter region. Binding of sigma(70)-saturated RNA polymerase and H-NS to the promoter DNA occurs cooperatively and results in a stable complex of slower gel electrophoretic mobility as compared to complexes formed with the single proteins. The presence of the upstream curved H-NS binding site contributes strongly to the cooperative RNA polymerase-promoter interaction. By KMnO(4) modification of single-stranded template nucleotides we could show that open complex formation at the rrnB P1 promoter was not inhibited by H-NS binding. An increased KMnO(4) reactivity of several positions within the open complex rather supports the view that open complex formation is stimulated in presence of H-NS. Moreover, subtle changes in the modification pattern indicate that the open complex formed in the presence of H-NS are structurally distinct from the H-NS-free complex. In vitro transcriptional analysis of the abortive and productive yields revealed that the formation of transcription products longer than three nucleotides is dramatically reduced in the presence of H-NS, while the amount of shorter abortive products remained unaffected. Together the results demonstrate that H-NS inhibits transcription at the rrnB P1 promoter not by interfering with initial RNA polymerase binding but by blocking chain elongation steps subsequent to the first (two) phosphodiester bond formations. The mechanism of H-NS dependent repression at rRNA promoters can thus be explained as a trap which inhibits substrate NTP incorporation beyond template position +3 into the initial transcribing complex.
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PMID:The bacterial DNA-binding protein H-NS represses ribosomal RNA transcription by trapping RNA polymerase in the initiation complex. 1080 45

Hepatitis C virus (HCV), the major causative agent of chronic and sporadic non-A, non-B hepatitis worldwide, is a distinct member of the Flaviviridae virus family. These viruses have in common a plus-strand RNA genome that is replicated in the cytoplasm of the infected cell via minus-strand RNA intermediates. Owing to the lack of reliable cell culture systems and convenient animal models for HCV, the mechanisms governing RNA replication are not known. As a first step towards the development of appropriate in vitro systems, we expressed the NS5B RNA-dependent RNA polymerase (RdRp) in insect cells, purified the protein to near homogeneity and studied its biochemical properties. It is a primer- and RNA template-dependent RNA polymerase able to copy long heteropolymeric templates without additional viral or cellular cofactors. We determined the optimal reaction parameters, the kinetic constants and the substrate specificity of the enzyme, which turned out to be similar to those described for the 3D polymerase of poliovirus. By analysing a series of nucleosidic and non-nucleosidic compounds for their effect on RdRp activity, we found that ribavirin triphosphates have no inhibitory effect, providing direct experimental proof that the therapeutic effect observed in patients is not related to a direct inhibition of the viral polymerase. Finally, mutation analysis was performed to map the minimal NS5B sequence required for enzymatic activity and to identify the 'classical' polymerase motifs important for template and NTP binding and catalysis.
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PMID:Biochemical and structural analysis of the NS5B RNA-dependent RNA polymerase of the hepatitis C virus. 1084 58

Transcript elongation by RNA polymerase is discontinuous and interrupted by pauses that play key regulatory roles. We show here that two different classes of pause signals punctuate elongation. Class I pauses, discovered in enteric bacteria, depend on interaction of a nascent RNA structure with RNA polymerase to displace the 3' OH away from the catalytic center. Class II pauses, which may predominate in eukaryotes, cause RNA polymerase to slide backwards along DNA and RNA and to occlude the active site with nascent RNA. These pauses differ in their responses to antisense oligonucleotides, pyrophosphate, GreA, and general elongation factors NusA and NusG. In contrast, substitutions in RNA polymerase that increase or decrease the rate of RNA synthesis affect both pause classes similarly. We propose that both pause classes, as well as arrest and termination, arise from a common intermediate that itself binds NTP substrate weakly.
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PMID:Pausing by bacterial RNA polymerase is mediated by mechanistically distinct classes of signals. 1086 Sep 76

Pyrazofurin (PZF), a cytidine analog and an inhibitor of orotate monophosphate decarboxylase, has been shown to decrease the levels of UTP and CTP in treated cells. When Sindbis virus (SV)-infected Aedes albopictus cells were treated with PZF, the yield of virus was reduced 100- to 1000-fold. By serial passage of our standard SV(STD) in Ae. albopictus cells in the presence of increasing concentrations of PZF, a mutant, SV(PZF), was derived, which was not inhibited by PZF. SV(PZF) is also resistant to adenosine, guanosine, and phosphono-acetyl-N-aspartate, all of which have been shown to decrease levels of UTP and CTP. Analysis of chimeric viruses containing sequences from the SV(PZF) and parental genomes showed that the sequence between nt 5262 and 7999 conferred the PZF-resistant phenotype. Sequencing of this region identified four mutations (nt 5750, 6627, 7543, and 7593), which are predicted to lead to amino acid changes: opal550L in nsP3 and M287L, K592I, and P609T in nsP4. Characterization of viruses containing one or more of these mutations demonstrated that all three mutations in the nsP4 coding region are required to produce full resistance to PZF. Using a molecular model of nsP4 based on the structure of HIV reverse transcriptase, we located amino acid change M287L at the tip of the fingers domain and K592I and P609T at the base of the thumb domain of the viral RNA polymerase. We suggest that these three amino acid changes in nsP4 alter the geometry of the NTP binding pocket so as to increase the affinity of the enzyme for CTP and UTP.
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PMID:A mutant of Sindbis virus that is resistant to pyrazofurin encodes an altered RNA polymerase. 1087 49

2-Etheny1-2,3-dihydrophthalazine-1,4-diones were successfully synthesized and proved to be effective cytotoxic agents against the growth of suspended murine and human leukemias and lymphomas. Selected compounds were also active in human HeLa uterine carcinoma, suspended effusion breast MCF-7 and glioma HS683 screens. These agents suppressed P388 lymphocytic leukemia DNA synthesis after 60 min at 100 microM. Their target appeared to be the de novo synthesis pathway with significant inhibition of the activities of both regulatory enzymes of the pathway, i.e. PRPP-amide transferase and IMP dehydrogenase resulting in a reduction in the d[NTP] pool levels for DNA incorporation. The compounds did not affect de novo pyrimidine synthesis and its regulatory enzymes. Very minor reduction by the agents was noted for the nucleoside kinases and the DNA and RNA polymerase activities within 60 min. DNA was not a target of the agents in that there was no alkylation of the nucleotide bases, intercalation between base pairs or cross-linking of the DNA strands; however, the agents did cause P388 DNA strand scission after 24 h at 100 microM.
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PMID:Cytotoxicity of 2-ethenyl-2,3-dihydrophthalazine-1,4-diones in murine and human tumor cultured cells. 1123 48

We have examined the interaction of human immunodeficiency virus reverse transcriptase (HIV RT) and T7 RNA polymerase (T7 RNAP) with modified nucleoside triphosphates and inorganic pyrophosphate (PPi) analogs containing nonhydrolyzable bisphosphonate groups. We have synthesized a number of derivatives of bisphosphonic acid having different aromatic and nonaromatic side substituents, as well as the NTP derivatives whose incorporation into the growing nucleotide chain during the polymerization reaction results in formation of bisphosphonates as leaving groups. The competitive character of inhibition of both enzymes has been revealed for all the compounds under study, and the inhibition constants have been estimated. One of PPi analogs containing a bulky aromatic substituent is characterized by similar inhibition constants for both T7 RNAP and RT. The universal character of this inhibitor can serve as evidence for a similar structure of the NPT-binding sites in the two polymerases. It has been shown that nonsubstituted methylenebisphosphate is a better leaving group than that containing additional methyl and hydroxyl groups. The NTP analogs are very weak inhibitors of T7 RNAP, whereas HIV-1 RT is more sensitive to this type of compounds. On the basis of the X-ray crystallographic data on the T7 RNAP complex with a template and NTP, we have modeled the binding of some derivatives of bisphosphonic acid in the active center of the enzyme. The peculiarities observed in the model correlate well with the experimental data on inhibition.
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PMID:[Interaction of HIV-1 reverse transcriptase and bacteriophage T7 RNA polymerase with NTP phosphonate analogs and inorganic pyrophosphate]. 1160 38

Transcription initiation as catalyzed by T7 RNA polymerase consists primarily of promoter binding, strand separation, nucleotide binding, and synthesis of the first phosphodiester bond. The promoter strand separation process occurs at a very fast rate, but promoter opening is incomplete in the absence of the initiating NTPs. In this paper, we investigate how initiating NTPs affect the kinetics and thermodynamics of open complex formation. Transient state kinetic studies show that the open complex, ED(o), is formed via an intermediate ED(c), and the conversion of ED(c) to ED(o) occurs with an unfavorable equilibrium constant. In the presence of the initiating NTP that base-pairs with the template at position +2, the process of open complex formation is nearly complete. Our studies reveal that the nucleotide that drives open complex formation needs to be a triphosphate and to be correctly base-paired with the template. These results indicate that the melted template DNA in the open complex is positioned to bind the +2 NTP. The addition of +1 NTP alone does not stabilize the open complex; nor is it required for +2 NTP binding. However, there appears to be cooperativity in initiating NTP binding in that the binding of +2 NTP facilitates +1 NTP binding. The dissection of the initiation pathway provides insights into how open complex formation steps that are sensitive to the promoter sequence upstream from the initiation start site modulate the affinity of initiating NTPs and allow transcription initiation to be regulated by initiating NTP concentration.
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PMID:The +2 NTP binding drives open complex formation in T7 RNA polymerase. 1215 83

We have determined the complete nucleotide sequence (Accession No. AF484251) of the Pepino mosaic virus (PepMV) RNA genome. PepMV is the etiological agent of a new disease which affects tomato crops in Europe and North America. The PepMV genome consists of one single stranded positive sense RNA 6410 nt long that contains five open reading frames (ORFs). ORF 1 is the putative RNA dependent RNA polymerase (RdRp), as it has the characteristic methyltransferase, NTP-binding and polymerase motifs. ORF 2 to 4 form the PepMV triple gene block. ORF 5 codes for the capsid protein. Two short untranslated regions flank the coding regions and there is a poly(A) tail at the 3'end of the genomic RNA. Thus, the genome organization of PepMV is that of a typical member of the genus Potexvirus. The nucleotide sequence obtained shares an overall 99% identity with the genomic RNA of a PepMV isolate from UK which has been partially sequenced. Protein coded by ORF4 is the least conserved between both isolates (95% amino acid identity), whereas proteins coded by ORF3 and ORF5 are identical.
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PMID:Complete sequence of the Pepino mosaic virus RNA genome. 1237 61

Transcription of stable RNA genes is known to be dramatically reduced in the presence of guanosine tetraphosphate (ppGpp), the mediator of the stringent response. Using in vitro transcription systems with ribosomal RNA P1 promoters, we have analyzed which step of the initiation cycle is inhibited by the effector ppGpp. We show that formation of the ternary transcription initiation complex consisting of RNA polymerase holoenzyme, the promoter DNA, and the first initiating nucleotide triphosphate is the major step at which ppGpp exerts its regulation. Neither primary binding of RNA polymerase to the promoter nor isomerization to the open binary complexes or the subsequent promoter clearance steps contributes notably to the observed inhibition. The effect of ppGpp-dependent inhibition in the formation of the ternary transcription initiation complex could be mimicked by nucleotide derivatives known to bind to the RNA polymerase active center. Using these model compounds, almost identical inhibition characteristics were observed as seen with ppGpp. The results support the previously published model, which suggests that ppGpp-dependent inhibition is based on competition between the inhibitor molecules and NTP substrates for access to the active center of RNA polymerase.
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PMID:Essential steps in the ppGpp-dependent regulation of bacterial ribosomal RNA promoters can be explained by substrate competition. 1262 Oct 53

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