Intermediates in the formation of the open complex by RNA polymerase holoenzyme containing the sigma factor sigma 32 at the groE promoter

The interaction of E sigma 32 with the groE promoter at temperatures between 0 degrees C and 37 degrees C was studied using DNase I footprinting and dimethyl sulfate methylation. Three distinct complexes were observed. At 0 degrees C E sigma 32 fully protected sequences between -60 and -5 from DNase I digestion on the top (non-template) strand of the promoter. At 16 degrees C the majority of the E sigma 32 promoter complexes had a DNase I footprint almost identical with that seen at 37 degrees C, protecting the DNA from about -60 to +20; however, little DNA strand separation had occurred, and the changes in sensitivity of guanine residues to dimethyl sulfate methylation caused by E sigma 32 differed from those seen at 37 degrees C. DNA strand separation, and changes in the pattern of protections from and enhancements of methylation by dimethyl sulfate to those characteristic of the open complex, occurred at temperatures between 16 degrees C and 27 degrees C. It is plausible to assume that these temperature-dependent isomerizations are analogous to the time-dependent sequence of intermediates on the pathway to open complex formation at 37 degrees C. Therefore we propose that the formation of an open complex by E sigma 32 at the groE promoter involves three classes of steps: E sigma 32 initially binds to the promoter in a closed complex (RPC1) in which the enzyme interacts with a smaller region of the DNA than in the open complex. E sigma 32 then isomerizes to form a second closed complex (RPC2) in which the enzyme interacts with the same region of the DNA as in the open complex. Finally, a process of local DNA denaturation (strand opening) leads to formation of the open complex (RPO).     

Sigma38 (rpoS) RNA polymerase promoter engagement via -10 region nucleotides

Band shift assays using DNA probes that mimic closed and open complexes were used to explore the determinants of promoter recognition by sigma38 (rpoS) RNA polymerase. Duplex recognition was found to be much weaker than that observed in sigma70 promoter usage. However, binding to fork junction probes, which attempt to mimic melted DNA, was very strong. This binding occurs via the non-template strand with the identity of the two conserved junction nucleotides (-12T and -11A) being of paramount importance. A modified promoter consensus sequence identified these two nucleotides as among only four (underlined) that are highly conserved, and all four were in the -10 region (CTAcacT from -13 to -7). The remaining two nucleotides were shown to have different roles, -13C in preventing recognition by the heterologous sigma70 polymerase and -7T in directing enzyme isomerization. These -10 region nucleotides appear to have their primary function prior to full melting because probes that had a melted start site were relatively insensitive to substitution at these positions. These results suggest the sigma38 mechanism differs from the sigma70 mechanism, and this difference likely contributes to selective use of sigma38 under conditions that exist during stationery phase.     

Effect of DNA bases and backbone on sigma70 holoenzyme binding and isomerization using fork junction probes

Abasic substitutions in the non-template strand and promoter sequence changes were made to assess the roles of various promoter features in σ70 holoenzyme interactions with fork junction probes. Removal of –10 element non-template single strand bases, leaving the phosphodiester backbone intact, did not interfere with binding. In contrast these abasic probes were deficient in promoting holoenzyme isomerization to the heparin resistant conformation. Thus, it appears that the melted –10 region interaction has two components, an initial enzyme binding primarily to the phosphodiester backbone and a base dependent isomerization of the bound enzyme. In contrast various upstream elements cooperate primarily to stimulate binding. Features and positions most important for these effects are identified.     

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.     

Inhibitory effect of phosphate on in vitro development of 2-cell rat embryos is overcome by a factor(s) in oviductal extracts

The promoter recognition site on the sigma70 initiation factor is shielded from interaction with DNA unless sigma70 is bound to the core component of RNA polymerase (RNAP). It is shown that interaction of sigma70 with the isolated beta' subunit of Escherichia coli RNAP is sufficient to induce unshielding of the DNA binding site. Using UV-induced DNA-protein cross-linking we demonstrate that free beta' stimulates specific cross-links between region 2 of the sigma70 polypeptide and a fragment of the non-template promoter strand containing the TATAAT sequence. Thus the sigmabeta' subassembly of RNAP can assume a functionally competent conformation independently of the bulk of the RNAP core.     

sigma factor mutations affecting the sequence-selective interaction of RNA polymerase with -10 region single-stranded DNA.

Thesigmasubunit of RNA polymerase determines promoter recognition and catalyzes DNA strand separation. The -35 promoter region is recognized by a helix-turn-helix motif in region 4, while the -10 region is specified, at least in part, by an amphipathic helix in region 2. We have proposed that conserved aromatic residues insigmaregion 2.3 interact with the non-template strand of the -10 element to drive open complex formation. We now report that Bacillus subtilis sigmaA holoenzyme, but neither core nor sigmaA alone, binds with high selectivity to single-stranded (ss) DNA containing the non-template -10 consensus sequence. UV irradiation of holoenzyme-ssDNA complexes efficiently crosslinks sigmaA to DNA and protease mapping supports a primary contact site in or near region 2. Several mutations in sigmaA region 2.3, shown previously to impair promoter melting, affect ssDNA binding: Y184A decreases binding selectivity, while Y189A and W193A decrease the efficiency of photocrosslinking. These results support a model in which these aromatic amino acids are juxtaposed to ssDNA, consistent with their demonstrated role in stabilizing the open complex.     

Mutational analysis of an extracytoplasmic-function sigma factor to investigate its interactions with RNA polymerase and DNA

The extracytoplasmic-function (ECF) family of sigma factors comprises a large group of proteins required for synthesis of a wide variety of extracytoplasmic products by bacteria. Residues important for core RNA polymerase (RNAP) binding, DNA melting, and promoter recognition have been identified in conserved regions 2 and 4.2 of primary sigma factors. Seventeen residues in region 2 and eight residues in region 4.2 of an ECF sigma factor, PvdS from Pseudomonas aeruginosa, were selected for alanine-scanning mutagenesis on the basis of sequence alignments with other sigma factors. Fourteen of the mutations in region 2 had a significant effect on protein function in an in vivo assay. Four proteins with alterations in regions 2.1 and 2.2 were purified as His-tagged fusions, and all showed a reduced affinity for core RNAP in vitro, consistent with a role in core binding. Region 2.3 and 2.4 mutant proteins retained the ability to bind core RNAP, but four mutants had reduced or no ability to cause core RNA polymerase to bind promoter DNA in a band-shift assay, identifying residues important for DNA binding. All mutations in region 4.2 reduced the activity of PvdS in vivo. Two of the region 4.2 mutant proteins were purified, and each showed a reduced ability to cause core RNA polymerase to bind to promoter DNA. The results show that some residues in PvdS have functions equivalent to those of corresponding residues in primary sigma factors; however, they also show that several residues not shared with primary sigma factors contribute to protein function.