A two-plasmid system for identification of promoters recognized by RNA polymerase containing extracytoplasmic stress response sigma(E) in Escherichia coli

We have previously established a two-plasmid system in Escherichia coli for identification of promoters recognized by RNA polymerase containing a heterologous sigma factor. Attempts to optimize this system for identification of promoters recognized by RNA polymerase containing E. coli extracytoplasmic stress response sigma(E) failed owing to high toxicity of the expressed rpoE. A new system for identification of sigma(E)-cognate promoters was established, and verified using the two known sigma(E)-dependent promoters, rpoEp2 and degPp. Expression of the sigma(E)-encoding rpoE gene was under the control of the AraC-dependent P(BAD) promoter. A low level of arabinose induced a non-toxic, however, sufficient level of sigma(E) to interact with the core enzyme of RNA polymerase. Such an RNA polymerase holoenzyme recognized both known sigma(E)-dependent promoters, rpoEp2 and degPp, which were cloned in the compatible promoter probe plasmid, upstream of a promoterless lacZ alpha reporter gene. This new system has proved to be useful for identification of E. coli sigma(E)-cognate promoters. Moreover, the system could be used for identification of ECF sigma-cognate promoters from other bacteria.     

Substitution of RNA-polymerase sigma-subunits and transcription regulation

Recent data on regulation of gene activity in bacteria by substitution of RNA polymerase sigma subunits are reviewed. The htpR gene which controls the switch-on of the Escherichia coli heat-shock protein synthesis codes for sigma 32 subunit. sigma 32-containing RNA polymerase transcribes the heat-shock genes in vitro from specific promoters of no use for RNA polymerase containing the major sigma 70 subunit. Several minor sigma subunits have been found in Bacillus subtilis vegetative cells, in addition to the major sigma 55 subunit, differing in the specificity of promoter recognition. Many B. subtilis genes are controlled by tandemly located promoters recognized by RNA polymerases carrying different sigma subunits. sigma 29 subunit is encoded by spoIIG gene and is probably involved in the regulation of sporulation. Specific sigma subunits for transcribing "middle" or "late" genes are encoded by a number of phages.     

Interactions of Bacillus subtilis RNA polymerase with subunits determining the specificity of initiation. Sigma and delta peptides can bind simultaneously to core

The Bacillus subtilis RNA polymerase sigma 43 subunit and the phage SP82 encoded 28-kDa peptide are responsible for the binding of RNA polymerase to early and middle SP82 promoters, respectively. The delta peptide enhances the specificity of the interaction of B. subtilis RNA polymerase with these promoters. We have used sedimentation experiments to determine the effect of each of the three specificity factors, delta, sigma, and the 28-kDa peptide, on the binding of the other two factors to RNA polymerase core and the effect of NaCl on these binding equilibria. We show that sigma 43 and the 28-kDa peptide can each bind to RNA polymerase core at the same time as delta. Sigma 43 and the 28-kDa peptide have similar affinities to core at 0.1 M NaCl, but the 28-kDa peptide binds to core-delta more strongly than sigma 43. The implications of these findings with respect to the replacement of sigma 43 by the 28-kDa peptide and the mechanism of promoter search by B. subtilis RNA polymerase are discussed.