QD participated in data acquisition. KLG contributed to the materials. All authors participated in drafting the manuscript, and read and approved the final manuscript.”
“Background Most bacteria have a regulatory system, known as quorum sensing (QS), to modulate gene expression as a function of their cell density (for reviews see [1, 2]). It usually works via
the production of a signaling molecule that reaches a threshold concentration at high cell density allowing its detection by the bacterial population and resulting in the modulation of target gene expression. In gram negative, N-acyl homoserine lactone signaling molecules (AHLs) are thus far the most common signal molecules produced. A typical AHL QS system involves two major components: an AHL synthase gene (belonging to the LuxI protein family) and a modular transcriptional response-regulator (belonging to the LuxR protein family) which detects
and responds to the AHL concentration selleck chemicals [3]. AHL QS thus far is exclusively found in proteobacteria; 68 of 265 sequenced proteobacterial genomes possess at least one luxI/R family pair [4]. Interestingly, 90 genomes contained at https://www.selleckchem.com/products/gsk1120212-jtp-74057.html least one luxR gene having the modular characteristics of the QS-family of regulators; however it was not associated with a cognate luxI-family gene. Of these, 45 genomes harbor at least one complete AHL QS system in addition to one or more luxR gene/s. These unpaired LuxR family proteins were firstly designated orphans [5] and recently they have been proposed to be renamed as LuxR ‘solos’ [6]; a few of these LuxR solos are beginning to be studied. ExpR of Sinorhizobium meliloti, BisR of Rhizobium leguminosarum bv. viciae and QscR of Pseudomonas aeruginosa, are LuxR solo proteins in AHL producing bacteria which have been well characterized and shown to be integrated with
the resident complete AHL QS regulatory networks [7–10]. Only two solo LuxR homologs in non-AHL producing bacteria have thus far been investigated in some detail. One is called SdiA which is present in the Salmonella enterica and Capmatinib Escherichia coli and shown to be able Edoxaban to bind and detect AHLs produced by other bacteria. The other one is from plant pathogenic Xanthomonas spp. and in two Xanthomonas species it is involved in regulating virulence factors upon binding an unknown plant produced low molecular weight compound which is not an AHL [11–13]. This indicates that certain quorum sensing related LuxR family proteins are able to be involved in inter-kingdom signaling by detecting non-AHL compounds produced by eukaryotes. Pseudomonas putida strains are mainly studied either for their ability to establish beneficial association with plants or due to their versatile catabolic potential. Previous studies have indicated that the majority of soil-borne or plant-associated P. putida strains do not produce AHLs; apparently only about one third of strains belonging to these species have a complete AHL QS system [14, 15].