Coordinated cell and chloroplast growth and its perturbation by chloroplast DNA replication inhibition in green algae

Coordination among cell growth, chloroplast expansion, and organelle genome dynamics is fundamental to algal physiology, yet its regulation remains unclear. We used time-resolved single-cell analyses to examine scaling relationships among cell size, chloroplast volume, nuclear dynamics, and nucleoid organization in Desmodesmus communis and Chlamydomonas reinhardtii under normal conditions and after inhibition of chloroplast DNA replication with nalidixic acid (NAL). Under control conditions, both species showed coordinated scaling among cell, chloroplast, and nuclear size, while nucleoid dynamics were driven mainly by changes in number. NAL disrupted these relationships in a species- and time-dependent manner. In C. reinhardtii, prolonged treatment uncoupled chloroplast and nuclear growth from cell expansion and led to fewer, enlarged nucleoids, consistent with impaired replication. In contrast, D. communis largely maintained coordinated scaling, with effects mainly limited to reduced nucleoid proliferation and delayed division. Temporal analyses indicated that NAL primarily affected nucleoid replication and segregation, with secondary consequences for chloroplast growth and cell-cycle progression. These findings identify chloroplast genome dynamics as a regulatory link between organelle growth and cell division.