Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
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Drug
Enzyme
Compound
Query: EC:2.7.7.6 (
RNA polymerase
)
34,946
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
To explore the domain-scale flexibility of bacterial
RNA polymerase
(RNAP) throughout its functional cycle, block normal-mode analyses (BNM) were performed on several important functional states, including the holoenzyme, the core complex, a model of RNAP bound to primarily duplex DNA, and a model of the ternary elongation complex. The calculations utilized a molecular mechanics (MM) force field with physical interactions; this is made possible by the use of BNM and the implementation of a sparse-matrix diagonalization routine. The use of homology models necessitated the MM force field rather than the simpler elastic network model (ENM). From the MM/BNM, we have systematically and semiquantitatively calculated the atomic fluctuations in the four functional states without bias due to crystal packing or other artifactual forces. We have observed that both alpha subunits and the omega subunit are rigid, in line with their roles as structural motifs that are not mechanistically involved in RNAP's functional cycle. It has been observed that the beta subunit has two highly mobile domains; these are commonly known as the beta1 and beta2 domains. Our calculations suggest that the flexibility of these domains is modulated throughout the functional cycle and that they move entirely independently of each other unless DNA is bound. From an energetic perspective, we have shown the beta2 domain can flex into and out of the cleft, forming interactions with DNA in the
TEC
as has been previously proposed. Our calculations also confirm that the beta' subunit's likely flexibility into and out of the DNA binding cleft is energetically allowed. These two observations validate that both of the RNAP crab claw's pincers are mobile, as both beta and beta' have substantial flexibility.
...
PMID:Normal-mode analysis suggests protein flexibility modulation throughout RNA polymerase's functional cycle. 1547 2
Transcription elongation in vitro is affected by the interactions between
RNA polymerase
(RNAP) subunits and the nucleic acid scaffold of the ternary elongation complex (
TEC
, RNAP-DNA-RNA). We have investigated the role of the RNAP subunits F/E (homologous to eukaryotic RPB4/7) during transcription elongation and termination using a wholly recombinant archaeal RNAP and synthetic nucleic acid scaffolds. The F/E complex greatly stimulates the processivity of RNAP, it enhances the formation of full length products, reduces pausing, and increases transcription termination facilitated by weak termination signals. Mutant variants of F/E that are defective in RNA binding show that these activities correlate with the nucleic acid binding properties of F/E. However, a second RNA-binding independent component also contributes to the stimulatory activities of F/E. In summary, our results suggest that interactions between RNAP subunits F/E and the RNA transcript are pivotal to the molecular mechanisms of RNAP during transcription elongation and termination.
...
PMID:Molecular mechanisms of RNA polymerase--the F/E (RPB4/7) complex is required for high processivity in vitro. 1990 31
