Mutational analysis of the promoter recognized by Chlamydia and Escherichia coli sigma(28) RNA polymerase

sigma(28) RNA polymerase is an alternative RNA polymerase that has been postulated to have a role in developmental gene regulation in Chlamydia. Although a consensus bacterial sigma(28) promoter sequence has been proposed, it is based on a relatively small number of defined promoters, and the promoter structure has not been systematically analyzed. To evaluate the sequence of the sigma(28)-dependent promoter, we performed a comprehensive mutational analysis of the Chlamydia trachomatis hctB promoter, testing the effect of point substitutions on promoter activity. We defined a -35 element recognized by chlamydial sigma(28) RNA polymerase that resembles the consensus -35 sequence. Within the -10 element, however, chlamydial sigma(28) RNA polymerase showed a striking preference for a CGA sequence at positions -12 to -10 rather than the longer consensus -10 sequence. We also observed a strong preference for this CGA sequence by Escherichia coli sigma(28) RNA polymerase, suggesting that this previously unrecognized motif is the critical component of the -10 promoter element recognized by sigma(28) RNA polymerase. Although the consensus spacer length is 11 nucleotides (nt), we found that sigma(28) RNA polymerase from both Chlamydia and E. coli transcribed a promoter with either an 11- or 12-nt spacer equally well. Altogether, we found very similar results for sigma(28) RNA polymerase from C. trachomatis and E. coli, suggesting that promoter recognition by this alternative RNA polymerase is well conserved among bacteria. The preferred sigma(28) promoter that we defined in the context of the hctB promoter is TAAAGwwy-n(11/12)-ryCGAwrn, where w is A or T, r is a purine, y is a pyrimidine, n is any nucleotide, and n(11/12) is a spacer of 11 or 12 nt.     

Mapping of transcripts encoded by the plasmid in Chlamydia trachomatis

Mapping of the plasmid-encoded RNA of the intracellular parasite, Chlamydia trachomatis revealed that the upstream control elements are different from those of other Gram-negative bacteria. A tetranucleotide, AYAA was found near the -10 position, in 5 out of 8 upstream sequences described so far. The plasmid also has a developmentally regulated promoter. The chlamydial upstream elements do not function as promoters in E. coli and vice versa. An E. coli promoter-like sequence has been found to occur fortuitously upstream from the plasmid-encoded dnaB gene. Such sequences may be evolutionary relics.     

A polymerase chain reaction-based approach to cloning sigma factors from eubacteria and its application to the isolation of a sigma-70 homolog from Chlamydia trachomatis.

Taking advantage of the known sequence conservation of portions of bacterial sigma factor proteins, we have designed degenerate oligonucleotides corresponding to these domains and used these synthetic DNA sequences as primers in a polymerase chain reaction (PCR) to amplify DNA sequences from the chlamydial genome. The PCR products were used as a probe to recover the genomic fragments from a library of cloned murine Chlamydia trachomatis DNA. Sequence analysis of one of these clones revealed striking homology to the sigma-70 protein of Escherichia coli and the sigma-43 protein of Bacillus subtilis, strongly implying that this locus (sigA) encodes the major vegetative sigma factor of murine C. trachomatis. This PCR-based approach will be broadly applicable to the cloning of major sigma factors from other eubacteria.