Cationic antimicrobial peptides elicit a complex stress response in Bacillus subtilis that involves ECF-type sigma factors and two-component signal transduction systems.

Stress responses of Bacillus subtilis to membrane-active cationic antimicrobial peptides were studied. Global analysis of gene expression by DNA macroarray showed that peptides at a subinhibitory concentration activated numerous genes. A prominent pattern was the activation of two extracytoplasmic function sigma factor regulons, SigW and SigM. Two natural antimicrobial peptides, LL-37 and PG-1, were weak activators of SigW regulon genes, whereas their synthetic analogue poly-L-lysine was clearly a stronger activator of SigW. It was demonstrated for the first time that LL-37 is a strong and specific activator of the YxdJK two-component systems, one of the three highly homologous two-component systems sensing antimicrobial compounds. YxdJK regulates the expression of the YxdLM ABC transporter. The LiaRS (YvqCE) TCS was also strongly activated by LL-37, but its activation is not LL-37 specific, as was demonstrated by its activation with PG-1 and Triton X-100. Other strongly LL-37-induced genes included yrhH and yhcGHI. Taken together, the responses to cationic antimicrobial peptides revealed highly complex regulatory patterns and induction of several signal transduction pathways. The results suggest significant overlap between different stress regulons and interdependence of signal transduction pathways mediating stress responses.

ClpXP protease regulates the signal peptide cleavage of secretory preproteins in Bacillus subtilis with a mechanism distinct from that of the Ecs ABC transporter.

Identification and characterization of a suppressor mutation, sup-15, which partially restored secretion in the protein secretion-deficient Bacillus subtilis ecsA26 mutant, led us to discover a novel function of Clp protease. Inactivation of ClpP improved the processing of the precursor of AmyQ alpha-amylase exposed on the outer surface of the cytoplasmic membrane. A similar improvement of AmyQ secretion was conferred by inactivation of the ClpX substrate-binding component of the ClpXP complex. In the absence of ClpXP, the transcription of the sipS, sipT, sipV, and lsp signal peptidase genes was elevated two- to fivefold, a likely cause of the improvement of the processing and secretion of AmyQ and complementation of ecs mutations. Specific overproduction of SipT enhanced the secretion. These findings extend the regulatory roles of ClpXP to protein secretion. ClpXP also influenced the processing of the lipoprotein PrsA. A concerted regulation of signal peptidase genes by a ClpXP-dependent activator is suggested. In contrast, Ecs did not affect transcription of the sip genes, pointing to a different mechanism of secretion regulation.

Molecular analysis of an operon in Bacillus subtilis encoding a novel ABC transporter with a role in exoprotein production, sporulation and competence.

The levels of exoamylase and other exoenzymes of Bacillus subtilis are pleiotropically decreased by the ecs-26 (prs-26) and ecs-13 (prs-13) mutations. These mutations also cause a competence- and sporulation-deficient phenotype. In the present work, the ecs locus, which has been defined by the ecs-26 and ecs-13 mutations, was cloned and sequenced. Sequence analysis revealed a putative operon of three ORFs (ecsA, ecsB and ecsC). ecsA can encode a putative polypeptide of 248 amino acid residues containing an ATP-binding site. The polypeptide shows about 30% sequence similarity with the ATP-binding components of numerous membrane transporters of the ABC-type (ATP-binding cassette transporters or traffic ATPases). The ecs-26 mutation was found to result from a transition of one base pair chaning the glycine164 of EcsA to a glutamic acid residue in the vicinity of the putative ATP-binding pocket. ecsB was predicted to encode a hydrophobic protein with six membrane-spanning helices in a pattern found in other hydrophobic components of ABC transporters. The properties deduced for the ecsA and ecsB gene products are consistent with the interpretation that ecs encodes a novel ABC-type membrane transporter of B. subtilis. The third ORF, ecsC, can encode a putative polypeptide of 237 amino acid residues. The polypeptide does not resemble components of ABC transporters.