Cdk1 and Cdk2 activity levels determine the efficiency of replication origin firing in Xenopus.

In this paper, we describe how, in a model embryonic system, cyclin-dependent kinase (Cdk) activity controls the efficiency of DNA replication by determining the frequency of origin activation. Using independent approaches of protein depletion and selective chemical inhibition of a single Cdk, we find that both Cdk1 and Cdk2 are necessary for efficient DNA replication in Xenopus egg extracts. Eliminating Cdk1, Cdk2 or their associated cyclins changes replication origin spacing, mainly by decreasing frequency of activation of origin clusters. Although there is no absolute requirement for a specific Cdk or cyclin, Cdk2 and cyclin E contribute more to origin cluster efficiency than Cdk1 and cyclin A. Relative Cdk activity required for DNA replication is very low, and even when both Cdk1 and Cdk2 are strongly inhibited, some origins are activated. However, at low levels, Cdk activity is limiting for the pre-replication complex to pre-initiation complex transition, origin activation and replication efficiency. As such, unlike mitosis, initiation of DNA replication responds progressively to changes in Cdk activity at low activity levels.

An integrated chemical biology approach provides insight into Cdk2 functional redundancy and inhibitor sensitivity.

Cdk2 promotes DNA replication and is a promising cancer therapeutic target, but its functions appear redundant with Cdk1, an essential Cdk affected by most Cdk2 inhibitors. Here, we present an integrated multidisciplinary approach to address Cdk redundancy. Mathematical modeling of enzymology data predicted conditions allowing selective chemical Cdk2 inhibition. Together with experiments in Xenopus egg extracts, this supports a rate-limiting role for Cdk2 in DNA replication. To confirm this we designed inhibitor-resistant (ir)-Cdk2 mutants using a novel bioinformatics approach. Bypassing inhibition with ir-Cdk2 or with Cdk1 shows that Cdk2 is rate-limiting for replication in this system because Cdk1 is insufficiently active. Additionally, crystal structures and kinetics reveal alternative binding modes of Cdk1-selective and Cdk2-selective inhibitors and mechanisms of Cdk2 inhibitor resistance. Our approach thus provides insight into structure, functions, and biochemistry of a cyclin-dependent kinase.

Selective chemical inhibition as a tool to study Cdk1 and Cdk2 functions in the cell cycle.

Cyclin-dependent kinases are highly conserved among all eukaryotes, and have essential roles in the cell cycle. However, these roles are still only poorly understood at a molecular level, partly due to the functional redundancy of different Cdk complexes. Indeed, mice knockouts have even thrown into some doubt the assumed essential roles for Cdk2-cyclin E in triggering S-phase, but this is almost certainly due to compensation by Cdk1 complexes. By combining both knockout approaches and chemical Cdk inhibition in Xenopus egg extracts, we have shown that one reason for functional redundancy of Cdk control of S-phase is that Cdk activity required to trigger S-phase is very low. Cdk1 contributes to this activity even in the presence of Cdk2, and Cdk activity at this stage does not show "switch-like" regulation, as at the onset of mitosis. It is important to try to confirm and extend these findings to other cell-types, and to explain why different cells might have evolved different requirements for Cdk activity. In this paper, we present data that suggest that selective chemical Cdk inhibition will be a useful tool towards achieving this goal.