21Sophisticated signaling mechanisms allow bacterial cells to cope with environmental 22 and intracellular challenges. Activation of specific pathways facilitates the cells to 23 overcome cellular damage and thereby warrant integrity. Here we demonstrate the 24 pliability of the CckA-CtrA two component signaling system in the freshwater bacterium, 25 Caulobacter crescentus. Our forward genetic screen to analyse suppressor mutations 26 that can negate the chromosome segregation block induced by the topoisomerase IV 27 inhibitor, NstA, yielded various point mutations in the cell cycle histidine kinase, CckA.
28Notably, we identified a point mutation in the PAS-B domain of CckA, which resulted in 29 increased levels of phosphorylated CtrA (CtrA~P), the master cell cycle regulator.30 Surprisingly, this increase in CtrA~P levels did not translate into a genome-wide 31 increase in the DNA occupancy of CtrA, but specifically enriched its affinity to the 32 chromosomal origin of replication, C ori , and a very small sub-set of CtrA regulated 33 promoters. We show that through this enhanced binding of CtrA to the C ori , cells are 34 able to overcome the toxic defects rendered by stable NstA through a possible slow 35 down in the chromosome cycle. Taken together, our work opens up an unexplored and 36 intriguing aspect of the CckA-CtrA signal transduction pathway. The distinctive DNA 37 binding nature of CtrA and its regulation by CckA might also be crucial for pathogenesis 38 because of the highly conserved nature of CckA-CtrA pathway in alphaproteobacteria.39 40 41 42 2 48 crescentus (henceforth Caulobacter), has emerged as a powerful model organism for 49 studying the complex signaling mechanisms that control cell cycle and development in 50 response to environmental cues. During its cell cycle, Caulobacter undergoes 51 asymmetric division to produce progenies with distinct developmental fates. One of the 52 daughter cells, the swarmer cell, acquires a dispersal fate wherein its motility is assisted 53 by the polar flagellum and a tuft of pili (1,2). In contrast, the stalked daughter cell 54 acquires a sedentary fate and is in an S-phase-like state capable of replicating its 55 chromosome and proliferating by cytokinesis ( Figure 1A) (3,4). The G1-like swarmer cell 56 has to terminally differentiate into a stalked cell to enter into the proliferative phase. This 57 G1 to S-like transition is marked by the shedding of the flagellum, retraction of the pili, 58 and production of a stalk at the same cell pole ( Figure 1A).
59In the swarmer cells, the master transcriptional regulator, CtrA, inhibits the DNA 60 replication. The Caulobacter origin of replication, C ori , is bound by CtrA, which prevents 61 replisome formation in the swarmer cells (5). Concurrent with the swarmer to stalked 62 cell transition, CtrA is degraded by proteolysis and thus facilitating the binding of DnaA, 63 the replication initiator, to the C ori triggering chromosome replication.(6). Apart from 64 blocking DNA replication initiation, CtrA also...
