6S RNA regulates E. coli RNA polymerase activity

The E. coli 6S RNA was discovered more than three decades ago, yet its function has remained elusive. Here, we demonstrate that 6S RNA associates with RNA polymerase in a highly specific and efficient manner. UV crosslinking experiments revealed that 6S RNA directly contacts the sigma70 and beta/beta' subunits of RNA polymerase. 6S RNA accumulates as cells reach the stationary phase of growth and mediates growth phase-specific changes in RNA polymerase. Stable association between sigma70 and core RNA polymerase in extracts is only observed in the presence of 6S RNA. We show 6S RNA represses expression from a sigma70-dependent promoter during stationary phase. Our results suggest that the interaction of 6S RNA with RNA polymerase modulates sigma70-holoenzyme activity.     

The kinetics of E. coli RNA polymerase.

Using an assay specific for chain elongation of E. coli RNA polymerase the kinetics of this propagation reaction have been studied. The kinetic behaviour is consistent woth the mathematical model formulated for this multisubstrate enzyme. The effect of increasing salt concentration on the kinetics of the reaction indicated that DNA unwinding is probably a necessary step in the propagation step, although this may not be the rate limiting step under all conditions.     

Conformational changes in E. coli RNA polymerase during promoter recognition.

We analysed complexes formed during recognition of the lacUV5 promoter by E. coli RNA polymerase using formaldehyde as a DNA-protein and protein-protein cross-linking reagent. Most of the cross-linked complexes specific for the open complex (RPO) contain the beta' subunit of RNA polymerase cross-linked with promoter DNA in the regions: -50 to -49; -5 to -10; + 5 to +8 and +18 to +21. The protein-protein cross-linking pattern of contacting subunits is the same for the RNA polymerase in solution and in RPO: there are strong sigma-beta' and beta-beta' interactions. In contrast, only beta-beta' cross-links were detected in the closed (RPC) and intermediate (RPI) complexes. In presence of lac repressor before or after formation of the RPO cross-linking pattern is similar with that of RPI (RPC) complex.     

Interaction between RNA polymerase and a ribosomal RNA promoter of E. coli.

The interaction between RNA polymerase and the E. coli ribosomal (r) RNA promoter(s) of the rrnE operon has been studied by the filter-binding method. The extent of complex formation between RNA polymerase and rrnE promoter(s) is salt-dependent; ppGpp specifically inhibits interaction of RNA polymerase with the rrnE promoter(s). A tentative model is proposed for the molecular events in the early steps of rRNA initiation: a transition of the primarily formed, labile RNA polymerase-rRNA promoter complex to a more stable form is the determining step. This step is salt-sensitive; ppGpp acts on this "isomerization".     

Subunit assembly and metabolic stability of E. coli RNA polymerase

Immunological cross-reaction was employed for identification of proteolytic fragments of E. coli RNA polymerase generated both in vitro and in vivo. Several species of partially denatured but assembled RNA polymerase were isolated, which were composed of fragments of the two large subunits, beta and beta', and the two small and intact subunits, alpha and sigma. Comparison of the rate and pathway of proteolytic cleavage in vitro of unassembled subunits, subassemblies, and intact enzymes indicated that the susceptibility of RNA polymerase subunits to proteolytic degradation was dependent on the assembly state. Using this method, degradation in vivo was found for some, but not all, of the amber fragments of beta subunit in merodiploid cells carrying both wild-type and mutant rpoB genes. Although the RNA polymerase is a metabolically stable component in exponentially growing cells of E. coli, degradation of the full-sized subunits was found in two cases, i.e., several temperature-sensitive E. coli mutants with a defect in the assembly of RNA polymerase and the stationary-phase cells of a wild-type E. coli. The in vivo degradation of RNA polymerase was indicated to be initiated by alteration of the enzyme structure.     

E. coli RNA polymerase interacts homologously with two different promoters

We present and review experiments that identify points of close approach of the RNA polymerase to two promoters, lac UV5 and T7 A3. We identify the contacts to the phosphates along the DNA backbone, to the N7s of guanines in the major groove and the N3s of adenines in the minor groove, and to the methyl groups of thymines. These contacts to the two promoters are strikingly homologous in space, as shown on three-dimensional models, and identify major regions of interactions lying on one side of the DNA molecule (at -35 and -16), as well as further areas extending through the Pribnow box. Both promoters are unwound similarly by the polymerase, across a region of about twelve bases extending from the middle of the Pribnow box to just beyond the RNA start site. We discuss the areas of interaction in the context of promoter homologies and promoter mutations. The disposition of the contacts in space suggests a model for the pathway along which the RNA polymerase binds to promoters.