Open complex formation in vitro by sigma38 (rpoS) RNA polymerase: roles for region 2 amino acids

Non-functional mutants of sigma(38)(sigma(S)) were studied in vitro to identify the nature of their defects. Mutations in four amino acids led to severe defects in DNA binding and enzyme isomerization with promoter fork junction probes containing single-stranded non-template DNA. The same properties were previously seen with DNA mutations at the fork junction, implying that sigma:DNA interactions at the fork junction are used both for DNA binding and enzyme isomerization. An overlapping set of four mutants had defects that appear to be associated with DNA melting to create the fork junction. When mapped onto the sigma(70) structure, these groups of mutants suggest motifs used by sigma factors to melt DNA and isomerize RNA polymerase to form functional open promoter complexes.     

DNA strand specificity in promoter recognition by RNA polymerase.

DNA strand and enzyme subunit specificities involved in the interaction between E. coli RNA polymerase and T7 DNA were studied by photo-crosslinking techniques. In non-specific enzyme-DNA complexes, subunits, sigma, beta, and beta' were crosslinked to both strands of the DNA. Under conditions leading to specific enzyme-promoter complexes, however, only sigma and beta subunits were crosslinked. The sigma subunit was crosslinked preferentially to the non-sense strand at promoter sites. No such strand specificity was observed for the beta subunit. These results provide insight into the molecular mechanism of promoter recognition and indicate that the interaction between RNA polymerase and DNA template is different at promoters and at non-specific sites.     

Identification of close contacts between the sigma N (sigma 54) protein and promoter DNA in closed promoter complexes.

The complexes forming between the alternative sigma factor protein sigma N (sigma 54), its holoenzyme and promoter DNA were analysed using the hydroxyl radical probe and by photochemical footprinting of bromouridine-substituted DNA. Close contacts between the promoter, sigma N and its holoenzyme appear to be restricted predominantly to one face of the DNA helix, extending from -31 to -5. They all appear attributable to sigma N and no extra close contacts from the core RNA polymerase subunits in the holoenzyme-promoter DNA complex were detected. We suggest that the apparent absence of close core RNA polymerase contacts in the region of the promoter DNA to be melted during open complex formation is important for maintaining the closed complex. Results of the hydroxyl radical footprinting imply that sigma N makes multiple DNA backbone contacts across and beyond the -12, -24 consensus promoter elements, and the photochemical footprints indicate that consensus thymidine residues contribute important major groove contacts to sigma N. Formation of the open complex is shown to involve a major structural transition in the DNA contacted by sigma N, establishing a direct role for sigma N in formation of the activated promoter complex.     

Active recruitment of sigma54-RNA polymerase to the Pu promoter of Pseudomonas putida: role of IHF and alphaCTD.

The sequence elements determining the binding of the sigma54-containing RNA polymerase (sigma54-RNAP) to the Pu promoter of Pseudomonas putida have been examined. Contrary to previous results in related systems, we show that the integration host factor (IHF) binding stimulates the recruitment of the enzyme to the -12/-24 sequence motifs. Such a recruitment, which is fully independent of the activator of the system, XylR, requires the interaction of the C-terminal domain of the alpha subunit of RNAP with specific DNA sequences upstream of the IHF site which are reminiscent of the UP elements in sigma70 promoters. Our data show that this interaction is mainly brought about by the distinct geometry of the promoter region caused by IHF binding and the ensuing DNA bending. These results support the view that binding of sigma54-RNAP to a promoter is a step that can be subjected to regulation by factors (e.g. IHF) other than the sole intrinsic affinity of sigma54-RNAP for the -12/-24 site.     

Polypeptides containing highly conserved regions of transcription initiation factor sigma 70 exhibit specificity of binding to promoter DNA.

The sigma 70 subunit of E. coli RNA polymerase is required for sequence-specific recognition of promoter DNA. Genetic studies and sequence analysis have indicated that sigma 70 contains two specific DNA-binding domains that recognize the two conserved portions of the prokaryotic promoter. However, intact sigma 70 does not bind to DNA. Using C-terminal and internal polypeptides of sigma 70, carrying one or both putative DNA-binding domains, we demonstrate that sigma 70 does contain two DNA-binding domains, but that N-terminal sequences inhibit the ability of intact sigma 70 to bind to DNA. Thus, we propose that sigma 70 is a sequence-specific DNA-binding protein that normally functions through an allosteric interaction with the core subunits of RNA polymerase.