Core control principles of the eukaryotic cell cycle

Cyclin-dependent kinases (CDKs) lie at the heart of eukaryotic cell cycle control, with different cyclin–CDK complexes initiating DNA replication (S-CDKs) and mitosis (M-CDKs) 1 , 2 . However, the principles on which cyclin–CDK complexes organize the temporal order of cell cycle events are contentious 3 . One model proposes that S-CDKs and M-CDKs are functionally specialized, with substantially different substrate specificities to execute different cell cycle events 4 – 6 . A second model proposes that S-CDKs and M-CDKs are redundant with each other, with both acting as sources of overall CDK activity 7 , 8 . In this model, increasing CDK activity, rather than CDK substrate specificity, orders cell cycle events 9 , 10 . Here we reconcile these two views of core cell cycle control. Using phosphoproteomic assays of in vivo CDK activity in fission yeast, we find that S-CDK and M-CDK substrate specificities are remarkably similar, showing that S-CDKs and M-CDKs are not completely specialized for S phase and mitosis alone. Normally, S-CDK cannot drive mitosis but can do so when protein phosphatase 1 is removed from the centrosome. Thus, increasing S-CDK activity in vivo is sufficient to overcome substrate specificity differences between S-CDK and M-CDK, and allows S-CDK to carry out M-CDK function. Therefore, we unite the two opposing views of cell cycle control, showing that the core cell cycle engine is largely based on a quantitative increase in CDK activity through the cell cycle, combined with minor and surmountable qualitative differences in catalytic specialization of S-CDKs and M-CDKs. The core cell cycle is largely driven by increasing total CDK activity together with minor differences in the substrate specificity of the CDKs initiating DNA replication and mitosis.