Conformational changes of Escherichia coli RNA polymerase sigma70 factor induced by binding to the core enzyme

Mutants of RNA polymerase sigma70 subunit from Escherichia coli with unique cysteine residues engineered into conserved region 1 (autoinhibition domain of sigma70), region 2.4 (-10 DNA element binding domain), region 4.2 (-35 DNA element binding domain), and a nonconserved region between regions 1 and 2 were prepared. The chemical reactivity of the cysteine at each position was determined for free sigma70 and sigma70 in complex with the core polymerase and was used as a measure of a conformational response of a particular region of the protein to an interaction with the core polymerase. Both increases and decreases in cysteine reactivity were observed in the presence of core polymerase at several positions in sigma70, providing direct physical evidence for modulation of sigma70 conformation by the core enzyme. Binding of the core polymerase resulted in increased solvent exposure of DNA binding domains of sigma70 and in more complex changes in the autoinhibition domain (region 1). Similar conformational changes in sigma70 were detected using fluorescence probes covalently attached to cysteine residues engineered into sigma70. Thus, the results obtained provided physical evidence supporting a model in which core enzyme allosterically regulates DNA binding activity of sigma70 by "unmasking" its DNA binding domains.     

Architecture of a complex between the sigma70 subunit of Escherichia coli RNA polymerase and the nontemplate strand oligonucleotide. Luminescence resonance energy transfer study

We used luminescence energy transfer measurements to determine the localization of 5'- and 3'-ends of a 12-nucleotide nontemplate strand oligonucleotide bound to sigma70 holoenzyme. Five single reactive cysteine mutants of sigma70 (cysteine residues at positions 1, 59, 366, 442, and 596) were labeled with a europium chelate fluorochrome (donor). The oligonucleotide was modified at the 5'- or at the 3'-end with Cy5 fluorochrome (acceptor). The energy transfer was observed upon complex formation between the donor-labeled sigma70 holoenzyme and the acceptor-labeled nontemplate strand oligonucleotide, whereas no interaction was observed with the template strand oligonucleotide. The oligonucleotide was bound in one preferred orientation. This observation together with the sequence specificity of single-stranded oligonucleotide interaction suggests that two mechanisms of discrimination between the template and nontemplate strand are used by sigma70: sequence specificity and strand polarity specificity. The bound oligonucleotide was found to be close to residue 442, confirming that the single-stranded DNA binding site of sigma70 is located in an alpha-helix containing residue 442. The 5'-end of the oligonucleotide was oriented toward the COOH terminus of the helix.     

Sigma s-dependent promoters in Escherichia coli are located in DNA regions with intrinsic curvature

Expression of a number of genes during stationary phase in Escherichia coli is controlled by the alternative sigma factor sigma s (KatF). Promoters recognized by sigma s do not present a well-defined consensus sequence in their -10 and -35 regions. By polyacrylamide gel electrophoresis of DNA fragments performed at different temperatures, and by computer prediction analyses, we have found that sigma s-regulated promoters are located in regions where DNA shows intrinsic curvatures. This feature does not appear in a stationary-phase-induced promoter which is not controlled by sigma s. We propose that DNA bending may help in recognition and/or binding of sigma s to stationary-phase-induced promoters.