Cyclin E2, the cycle continues

The eukaryotic cell cycle is regulated by a family of serine/threonine protein kinases known as cyclin-dependent kinases (CDKs). The activation of a CDK is dependent on its association with a cyclin regulatory subunit. The formation of distinct cyclin-CDK complexes controls the progression through the first gap phase (G(1)) and initiation of DNA synthesis (S phase). These complexes are in turn regulated by protein phosphorylation and cyclin-dependent kinase inhibitors (CKIs). Cyclin E2 has emerged as the second member of the E-type cyclin family. Cyclin E2-associated kinase activity is regulated in a cell cycle dependent manner with peak activity at the G(1) to S transition. Ectopic expression of cyclin E2 in human cells accelerates G(1), suggesting that cyclin E2 is rate limiting for G(1) progression. Although the pattern and level of cyclin E2 expression in some primary tumor and normal tissue RNAs are distinct from cyclin E1, both E-type cyclins appear to have inherent functional redundancies. This functional redundancy has facilitated the rapid characterization of cyclin E2 and uncovered unique features associated with each E-type cyclin.     

Cyclin A-CDK activity during G1 phase impairs MCM chromatin loading and inhibits DNA synthesis in mammalian cells

Progression through the mammalian cell division cycle is regulated by the sequential activation of cyclin-dependent kinases, CDKs, at specific phases of the cell cycle. Cyclin A-CDK2 and cyclin A-CDK1 phosphorylate nuclear substrates during S and G2 phases, respectfully. However, the DNA helicase complex, MCM2-7, is loaded onto the origin of replications in G1, prior to the normally scheduled induction of cyclin A. It has previously been shown that cyclin A-CDKs phosphorylate MCM2 and MCM4 in vitro, thereby diminishing helicase activity. Thus, in this study we hypothesize that, in vivo, cyclin A-CDK activity during G1 would result in an inhibition of progression into the S phase. To test this, we establish an in vivo method of inducing cyclin A-CDK activity in G1 phase and observe that activation of cyclin A-CDK, but not cyclin E-CDK complexes, inhibit DNA synthesis without affecting other G1 events such as cyclin D synthesis, E2F activation and cdc6 loading onto chromatin. We further report that the mechanism of this S phase inhibition occurs, at least in part, through impaired loading of MCM onto chromatin, presumably due to decreased levels of cdt1 and premature phosphorylation of MCM by cyclin A-CDK. In addition to providing in vivo confirmation of in vitro predictions regarding cyclin A-CDK phosphorylation of the MCM complex, our results provide insight into the cellular effects of unscheduled cyclin A-CDK activity in mammalian cells.     

The protein SET regulates the inhibitory effect of p21(Cip1) on cyclin E-cyclin-dependent kinase 2 activity.

The cyclin-dependent kinase (CDK) inhibitor p21(Cip1) has a dual role in the regulation of the cell cycle; it is an activator of cyclin D1-CDK4 complexes and an inhibitor of cyclins E/A-CDK2 activity. By affinity chromatography with p21(Cip1)-Sepharose 4B columns, we purified a 39-kDa protein, which was identified by microsequence analysis as the oncoprotein SET. Complexes containing SET and p21(Cip1) were detected in vivo by immunoprecipitation of Namalwa cell extracts using specific anti-p21(Cip1) antibodies. We found that SET bound directly to p21(Cip1) in vitro by the carboxyl-terminal region of p21(Cip1). SET had no direct effect on cyclin E/A-CDK2 activity, although it reversed the inhibition of cyclin E-CDK2, but not of cyclin A-CDK2, induced by p21(Cip1). This result is specific for p21(Cip1), since SET neither bound to p27(Kip1) nor reversed its inhibitory effect on cyclin E-CDK2 or cyclin A-CDK2. Thus, SET appears to be a modulator of p21(Cip1) inhibitory function. These results suggest that SET can regulate G(1)/S transition by modulating the activity of cyclin E-CDK2.