Cell cycle dysregulation of globally important SAR11 bacteria resulting from environmental perturbation

Genome streamlining is hypothesized to occur in bacteria as an adaptation to resource-limited environments but can result in ostensibly deleterious gene losses affecting core aspects of cellular physiology. The most abundant marine microorganisms, SAR11 (order Pelagibacterales), exhibit canonical genome streamlining, but the consequences of this genotype on core cellular processes like cell division remain unexplored. Analysis of 470 SAR11 genomes revealed widespread absence of key cell cycle control genes, and growth experiments demonstrated that, although SAR11 bacteria maintain a normal cell cycle under oligotrophic conditions, they exhibit growth inhibition and aneuploidy when exposed to nutrient enrichment, carbon source shifts, or temperature stress. Detailed temporal sampling demonstrated that these phenotypes occur as a result of cell division disruption with continuing DNA replication, leading to heterogeneous subpopulations of normal and polyploid cells. This vulnerability reflects an evolutionary trade-off where adaptation to stable nutrient-limited conditions results in reduced physiological resilience.