Faculty Bibliography

Activation of the cdc2 kinase in the cell cycle occurs upon binding to a regulatory subunit called cyclin. Cyclin A associates with both Cdc2 and its homologue Cdk2. The two complexes appear in S phase but cyclin A/Cdk2 is activated earlier than cyclin A/Cdc2. Several regions in Cdc2 are involved in binding cyclins A and B. Phosphorylation of cyclin/Cdk complexes ensures that the kinase activity peaks at a specific time in the cell cycle. Phosphorylation of Thr161 in Cdc2 is required for strong cyclin binding and kinase activity in vitro; its dephosphorylation is necessary for cells to exit mitosis. We have identified a novel 'Activating factor' that stimulates binding between cyclin and Cdc2 by inducing phosphorylation of Cdc2 on Thr161. We propose that Thr161 is targeted by an additional cell cycle regulatory pathway.

One of the most fundamental questions in biology is how a cell is able to regulate its division cycle. Initially it was thought that in mammalian cells control over entry into the cell cycle is exerted at a restriction point in G1; once past this point the cell would be free to undergo all the steps needed until the following division. Hence, for many years research on tumorigenesis focused on the mitogenic activation of quiescent cells by growth factors, peptide hormones and oncogene products (for reviews see [1, 2]). These studies investigated the initial steps required to induce a quiescent, nondividing cell to proliferate, and led to the identification of many growth factor receptors, of both the tyrosine kinase family and the G-protein coupled family. Receptors bearing protein tyrosine phosphatase or serine kinase catalytic domains were also identified via this route (for reviews see [3, 4, 5]). However more recent studies on the cooperation between different growth factors for mitogenesis have shown that multiple requirements exist for a cell to proceed through the entire division cycle. Indeed studies in several different organisms, pioneered by investigators working with Ascomycetes [6, 7, 8], have now clearly shown that the eukaryotic cell cycle proceeds through multiple check-points. Furthermore, it now appears that many of the regulatory elements and even pathways have been conserved throughout evolution. In this review we discuss the possible involvement of one of the transducing molecules, cyclin A, in abnormal cell proliferation.