Both cyclin A and cyclin E have S-phase promoting (SPF) activity in Xenopus egg extracts.

Extracts of activated Xenopus eggs in which protein synthesis has been inhibited support a single round of chromosomal DNA replication. Affinity-depletion of cyclin dependent kinases (Cdks) from these extracts blocks the initiation of DNA replication. We define 'S-phase promoting factor' (SPF) as the Cdk activity required for DNA replication in these Cdk-depleted extracts. Recombinant cyclins A and E, but not cyclin B, showed significant SPF activity. High concentrations of cyclin A promoted entry into mitosis, which inhibited DNA replication. In contrast, high concentrations of cyclin E1 promoted neither nuclear envelope disassembly nor full chromosome condensation. In the early embryo cyclin E1 complexes exclusively with Cdk2 and cyclin A is complexed predominantly with Cdc2; only later in development does cyclin A associate with Cdk2. We show that baculovirus-produced complexes of cyclin A-Cd2, cyclin A-Cdk2 and cyclin E-Cdk2 could each provide SPF activity. These results suggest that although in the early Xenopus embryo cyclin E1-Cdk2 is sufficient to support entry into S-phase, cyclin A-Cdc2 provides a significant additional quantity of SPF as its levels rise during S phase.

Cip1 inhibits DNA replication but not PCNA-dependent nucleotide excision-repair.

BACKGROUND: DNA that is damaged by ultraviolet (UV) light is repaired predominantly by nucleotide excision-repair, a process requiring the DNA polymerase auxiliary factor PCNA. UV-irradiation also induces the production of Cip1 protein via activation of p53. Cip1 is an inhibitor of the cyclin-dependent kinases, which are required for the cell cycle to proceed through the G1/S-phase transition and initiate DNA replication. Inhibition by Cip1 probably causes the block to initiation of DNA replication that is seen in irradiated cells. Cip1 also directly inhibits the function of PCNA during DNA synthesis. As nucleotide excision-repair requires PCNA, the physiological relevance of PCNA inhibition by Cip1 is currently unclear. RESULTS: We show that nucleotide excision-repair of UV-damaged DNA occurs in extracts of Xenopus eggs, and that this reaction is PCNA-dependent. The repair reaction is not inhibited by Cip1, even when the level of PCNA is reduced 100-fold so that it becomes limiting for DNA repair. By contrast, Cip1 strongly suppresses the function of PCNA in replicative DNA synthesis under these conditions. CONCLUSIONS: Cip1 can potentially inhibit DNA replication in Xenopus egg extracts by inhibiting the cyclin-dependent kinase function required for the initiation of replication forks, and also by inhibiting PCNA function. The inhibition of PCNA is selective for its function in DNA replication, however, as Cip1 does not affect PCNA function in nucleotide excision-repair. The induction of Cip1 in response to DNA damage, therefore, allows repair to continue in the genome under conditions in which replication is severely inhibited.

Cip1 blocks the initiation of DNA replication in Xenopus extracts by inhibition of cyclin-dependent kinases.

BACKGROUND: Cip1 is a 21 kD protein that interacts with and inhibits cyclin-dependent kinases (cdks). Expression of Cip1 is induced by the tumour suppressor p53, and tumour cells have greatly reduced levels of Cip1. As cdks are required for normal progression through the cell cycle, their inhibition by Cip1 may mediate the ability of p53 to block cell proliferation. Cip1 has also been shown to inhibit the DNA polymerase delta auxiliary factor PCNA (proliferating cell nuclear antigen), which is required for replication-fork elongation, and this could be an alternative mechanism by which p53-induced Cip1 blocks cell proliferation. RESULTS: We have investigated the effect of Cip1 protein on chromosomal DNA replication, using cell-free extracts of Xenopus eggs that initiate and complete chromosome replication under normal cell-cycle control. Cip1 protein strongly inhibited an early stage of DNA replication in this system, and this inhibition was not complemented by extracts that had been affinity-depleted of cdks. In contrast, Cip1 did not inhibit the elongation of replication forks that had accumulated in the presence of aphidicolin. Cip1 inhibition of DNA replication was fully rescued by addition of cyclins A or E, but not cyclin B, cdk2 or PCNA. CONCLUSIONS: Our results suggest that Cip1 specifically blocks the initiation of DNA replication by inhibition of a cyclin-dependent kinase (cdk2), but has no major effect on the elongation of preassembled replication forks. The ability of cyclin A or cyclin E to rescue the Cip1 inhibition suggests that these cyclins may play a direct role in the initiation of replication in the Xenopus system.