Coupling of cell growth modulation to asymmetric division and cell cycle regulation in Caulobacter crescentus

In proliferating bacteria, growth rate is often assumed to be similar between daughter cells. However, most of our knowledge of cell growth derives from studies on symmetrically dividing bacteria. In many α-proteobacteria, asymmetric division is a normal part of the life cycle, with each division producing daughter cells with different sizes and fates. Here, we demonstrate that the functionally distinct swarmer and stalked daughter cells produced by the model α-proteobacterium Caulobacter crescentus have different average growth rates despite sharing an identical genome and environment. The discrepancy in growth rate is due to a growth slowdown during the cell cycle stage preceding DNA replication (the G1 phase), which is predominantly associated with swarmer cell functionality. We also provide evidence that the second messenger (p)ppGpp extends the timing of the G1/swarmer cell stage by slowing growth specifically during the beginning of the cell cycle. Our data further show that cells factor the amount and rate of their growth to control the G1/S transition, allowing them to adjust the time they spend with ecologically important G1-specific traits.