Characterization of sigma factors ECF subfamily in Caulobacter crescentus

Alternative sigma factors permit the rapid adaptation to environmental changes in bacteria. Among them, members of the ECF subfamily (extrac</i<ytoplasmic function) are characterized by their involvement in responses to changes in the extracytoplasmic compartment of the cell. Analysis of the complete genome sequence of Caulobacter crescentus has led to the identification of 13 ORFs encoding putative sigma factors of the ECF subclass. The present work describes the characterization of mutant strains in five genes encoding ECF sigma factors from C. crescentus, named sigL, sigM, sigN, sigU and sigF. The expression of these genes in response to distinct stress conditions was also investigated, using transcriptional fusions of their promoter regions to the lacZ reporter gene. The five mutants strains obtained were viable and did not show increased sensitivity, when compared to the parental strain, to a series of environmental stress conditions, indicating that these genes are not essential. However, the sigL and sigM mutant strains were shown to be more sensitive to extreme heat shock (48°C). Furthermore, the characterization of the sigF mutant strain demonstrated that this gene is essential for oxidative stress survival during stationary phase. Analysis of sigF expression indicated a post-transcriptional control, with an increase in the levels of SigF protein during this growth phase, without changes in the transcription rate of the gene. Eight genes regulated by &#963;F during stationary phase were identified in microarray experiments, including the oxidative stress response genes sodA and msrA. Analysis of sigU promoter activity in response to distinct stress conditions showed induction upon entry into stationary phase and during saline and osmotic stress. Nevertheless, the sigU null mutant did not show increased sensitivity to these stresses. The results described here identified the importance of some of the C. crescentus ECF sigma factors in the response to stresses in this bacterium. (AU)