Characterized proteins in this subgroup are involved in the maturation of ComX, part of a major quorum-sensing system that regulates the development of genetic competence, by geranylation or farnesylation of a conserved tryptophan in ComX
Tortosa P, Logsdon L, Kraigher B, Itoh Y, Mandic-Mulec I, Dubnau D
Specificity and genetic polymorphism of the Bacillus competence quorum-sensing system
▸ Abstract
A quorum-sensing mechanism involving the pheromone ComX and the ComP-ComA two-component system controls natural competence in Bacillus subtilis. ComX is expressed as a cytoplasmic inactive precursor that is released into the extracellular medium as a cleaved, modified decapeptide. This process requires the product of comQ. In the presence of ComX, the membrane-localized ComP histidine kinase activates the response regulator ComA. We compared the sequences of the quorum-sensing genes from four closely related bacilli, and we report extensive genetic polymorphism extending through comQ, comX, and the 5' two-thirds of comP. This part of ComP encodes the membrane-localized and linker domains of the sensor protein. We also determined the sequences of the comX genes of four additional wild-type bacilli and tested the in vivo activities of all eight pheromones on isogenic strains containing four different ComP receptor proteins. A striking pattern of specificity was discovered, providing strong evidence that the pheromone contacts ComP directly. Furthermore, we show that coexpression of comQ and comX in Escherichia coli leads to the production of active pheromone in the medium, demonstrating that comQ is the only dedicated protein required for the processing, modification, and release of active competence pheromone. Some of the implications of these findings for the evolution and the mechanism of the quorum-sensing system are discussed.
Characterization of comQ and comX, two genes required for production of ComX pheromone in Bacillus subtilis
▸ Abstract
Many microbes use secreted peptide-signaling molecules to stimulate changes in gene expression in response to high population density, a process called quorum sensing. ComX pheromone is a modified 10-amino-acid peptide used by Bacillus subtilis to modulate changes in gene expression in response to crowding. comQ and comX are required for production of ComX pheromone. We found that accumulation of ComX pheromone in culture supernatant paralleled cell growth, indicating that there was no autoinduction of production of ComX pheromone. We overexpressed comQ and comX separately and together and found that overexpression of comX alone was sufficient to cause an increase in production of ComX pheromone and early induction of a quorum-responsive promoter. These results indicate that the extracellular concentration of ComX pheromone plays a major role in determining the timing of the quorum response and that expression of comX is limiting for production of ComX pheromone. We made alanine substitutions in the residues that comprise the peptide backbone of ComX pheromone. Analysis of these mutants highlighted the importance of the modification for ComX pheromone function and identified three residues (T50, G54, and D55) that are unlikely to interact with proteins involved in production of or response to ComX pheromone. We have also identified and mutated a putative isoprenoid binding domain of ComQ. Mutations in this domain eliminated production of ComX pheromone, consistent with the hypothesis that ComQ is involved in modifying ComX pheromone and that the modification is likely to be an isoprenoid.
Tsuji F, Ishihara A, Kurata K, Nakagawa A, Okada M, Kitamura S, Kanamaru K, Masuda Y, Murakami K, Irie K, Sakagami Y
Geranyl modification on the tryptophan residue of ComXRO-E-2 pheromone by a cell-free system
▸ Abstract
ComX pheromone is an isoprenoidal oligopeptide containing a modified tryptophan residue, which stimulates natural genetic competence in the gram-positive bacterium Bacillus. Since posttranslational prenylation on the tryptophan residue has not been reported except in ComX pheromone, the universality of this modification has not yet been elucidated. In this paper, we established a cell-free system, whereby the tryptophan residue in peptides is modified with a geranyl group by modifying enzyme ComQ. In addition, we investigated enzymatic reaction conditions using an in vitro enzyme reaction system. This is the first report of in vitro geranylation on the tryptophan residue. This system is potentially a useful tool for elucidating the universality of prenylation on the tryptophan residue.
FEBS Lett
2012;586(2):174-179
| PubMed ID:
22197102
