Roles of the histidine protein kinase pleC in Caulobacter crescentus motility and chemotaxis.

The Caulobacter crescentus histidine kinase genes pleC and divJ have been implicated in the regulation of polar morphogenesis and cell division, respectively. Mutations in pleC also potentiate the cell division phenotype of divJ mutations. To investigate the involvement of the PleC kinase in motility and cell cycle regulation, we carried out a pseudoreversion analysis of the divJ332 allele, which confers a temperature-sensitive motility (Mot-) phenotype. All cold-sensitive pseudorevertants with a Mot+ phenotype at 37 degrees C and a cold-sensitive swarm phenotype in soft agar at 24 degrees C contained extragenic suppressors that were null mutations mapping to pleC. Instead of a cell division defect at the nonpermissive temperature, however, revertants displayed a cold-sensitive defect in chemotaxis (Che-). In addition, the mutant cells were also supermotile, a phenotype previously associated only with mutations in the response regulator gene pleD that block the loss of motility. We also found that the Mot- defect of pleC mutants is suppressed by a pleD301/pleD+ merodiploid and results in a similar, supermotile, cold-sensitive Che- phenotype. These results implicate signal transduction pathways mediated by PleC-DivK and DivJ-PleD in the regulation of chemotaxis as well as motility. We discuss these findings and the observation that although the PleC kinase does not play an indispensable role in cell division, a temperature-sensitive allele of pleC (pleC319) has severely reduced viability under stringent growth conditions.

Identification of a novel response regulator required for the swarmer-to-stalked-cell transition in Caulobacter crescentus.

The onset of motility late in the Caulobacter crescentus cell cycle depends on a signal transduction pathway mediated by the histidine kinase PleC and response regulator DivK. We now show that pleD, whose function is required for the subsequent loss of motility and stalk formation by the motile swarmer cell, encodes a 454-residue protein with tandem N-terminal response regulator domains D1 and D2 and a novel C-terminal GGDEF domain. The identification of pleD301, a semidominant suppressor of the pleC Mot phenotype, as a mutation predicted to result in a D-53-->G change in the D1 domain supports a role for phosphorylation in the PleD regulator. Disruptions constructed in the pleD open reading frame demonstrated that the gene is not essential and that the pleC phenotype can also be suppressed by a recessive, loss-of-function mutation. These results suggest that PleD is part of a signal transduction pathway controlling stalked-cell differentiation early in the C. crescentus cell cycle.

An essential single domain response regulator required for normal cell division and differentiation in Caulobacter crescentus.

Signal transduction pathways mediated by sensor histidine kinases and cognate response regulators control a variety of physiological processes in response to environmental conditions. Here we show that in Caulobacter crescentus these systems also play essential roles in the regulation of polar morphogenesis and cell division. Previous studies have implicated histidine kinase genes pleC and divJ in the regulation of these developmental events. We now report that divK encodes an essential, cell cycle-regulated homolog of the CheY/Spo0F subfamily and present evidence that this protein is a cognate response regulator of the histidine kinase PleC. The purified kinase domain of PleC, like that of DivJ, can serve as an efficient phosphodonor to DivK and as a phospho-DivK phosphatase. Based on these and earlier genetic results we propose that PleC and DivK are members of a signal transduction pathway that couples motility and stalk formation to completion of a late cell division cycle event. Gene disruption experiments and the filamentous phenotype of the conditional divK341 mutant reveal that DivK also functions in an essential signal transduction pathway required for cell division, apparently in response to another histidine kinase. We suggest that phosphotransfer mediated by these two-component signal transduction systems may represent a general mechanism regulating cell differentiation and cell division in response to successive cell cycle checkpoints.