The results showed that the paddy soil profile harbored diverse bacterial communities and experienced depth-related changes in community structure and carbon source utilization. The bacterial communities and functions might be shaped by the soil edaphic characteristics along the soil profile. “
“HAS University of Applied Sciences, Venlo, The Netherlands Pseudomonas fluorescens SS101 produces the cyclic lipopeptide massetolide with diverse functions in antimicrobial activity, motility, and biofilm formation. To understand how massetolide biosynthesis is genetically regulated in SS101, c. 8000 random plasposon mutants were
screened for reduced or loss of massetolide production. Of a total of 58 putative mutants, 45 had a mutation
in one Androgen Receptor Antagonist cell line PLX4032 mouse of the three massetolide biosynthesis genes massA, massB, or massC. For five mutants, the insertions were located in the known regulatory genes gacS, gacA, and clpP. For the remaining eight mutants, insertions were located in clpA, encoding the ClpP chaperone, in phgdh, encoding D-3-phosphoglycerate dehydrogenase, in the heat shock protein-encoding dnaK, or in the transmembrane regulatory gene prtR. Genetic, chemical, and phenotypic analyses showed that phgdh, dnaK, and prtR are indeed involved in the regulation of massetolide biosynthesis, most likely by transcriptional repression of the LuxR-type regulator genes massAR and massBCR. In addition to their role in massetolide biosynthesis, dnaK and prtR were found to affect siderophore and extracellular protease(s) production, respectively. The identification of new regulatory genes substantially extended insights into the signal transduction pathways of lipopeptide biosynthesis
in P. fluorescens and into regulation of other traits that may contribute to its life-style in the rhizosphere. “
“The two-component system (TCS), consisting of a response regulator (RR) and a cognate histidine kinase (HK), responds to extra-/intercellular cues and triggers adaptive changes. The RR, RavR, has been reported to act as a positive virulence regulator and a c-di-GMP hydrolase in Xanthomonas campestris Methocarbamol pv. campestris (Xcc). Here, we identified the cognate HK, RavA, that regulate RavR phosphorylation levels and bacterial pathogenesis. Deletion of ravA, a putative HK gene flanking ravR, dramatically attenuated Xcc virulence. Phenotypes of the double mutant ΔravR/ΔravA were similar to those of ΔravR, suggesting that RavR is a downstream component of RavA signaling. RavA interacts with RavR and positively influences the phosphorylated RavR levels. In vitro analysis suggests that RavR is a bifunctional enzyme involved in c-di-GMP synthesis and degradation.