Cell-cycle-dependent polar morphogenesis in Caulobacter crescentus: roles of phospholipid, DNA, and protein syntheses.

During swarmer cell differentiation in Caulobacter crescentus, morphogenesis at the swarmer pole is characterized by the loss of the flagellum, by the loss of phage receptor activity (PRA) (the ability of the cell to adsorb phage phi CbK), and finally by the initiation of stalk outgrowth at the site formerly occupied by the flagellum and the PRA. We show here that each of these events is a cell cycle-dependent event requiring continuous protein synthesis for its execution but occurring normally in the absence of DNA synthesis or phospholipid synthesis. During stalked-cell differentiation, the flagellum and PRA reappear and the stalk elongates considerably. We show here that these events are also cell cycle dependent, requiring not only de novo protein synthesis but also DNA and phospholipid syntheses. When synchronous cells dividing 160 min after collection were used, PRA reappearance occurred at 110 min. This PRA reappearance was dependent on a phospholipid synthesis-requiring event occurring at 70 min, a DNA synthesis-requiring event occurring at 95 min, and a protein synthesis-requiring event occurring at 108 min. In the absence of net phospholipid synthesis, stalk elongation appeared more or less normal, but the stalks eventually became fragile, and by 240 min, most of the stalks had broken off, leaving only stubs attached to the cell body.