Balanced Production of Ribosome Components Is Required for Proper G1/S Transition in Saccharomyces cerevisiae

Cell cycle regulation is a very accurate process that ensures cell viability and the genomic integrity of daughter cells. A fundamental part of this regulation consists in the arrest of the cycle at particular points to ensure the completion of a previous event, to repair cellular damage, or to avoid progression in potentially risky situations. In this work, we demonstrate that a reduction in nucleotide levels or the depletion of RNA polymerase I or III subunits generates a cell cycle delay at the G₁/S transition in Saccharomyces cerevisiae. This delay is concomitant with an imbalance between ribosomal RNAs and proteins which, among others, provokes an accumulation of free ribosomal protein L5. Consistently with a direct impact of free L5 on the G₁/S transition, rrs1 mutants, which weaken the assembly of L5 and L11 on pre-60S ribosomal particles, enhance both the G₁/S delay and the accumulation of free ribosomal protein L5. We propose the existence of a surveillance mechanism that couples the balanced production of yeast ribosomal components and cell cycle progression through the accumulation of free ribosomal proteins. This regulatory pathway resembles the p53-dependent nucleolar-stress checkpoint response described in human cells, which indicates that this is a general control strategy extended throughout eukaryotes.     

Human papillomavirus (HPV) E7 induces prolonged G2 following S phase reentry in differentiated human keratinocytes

The productive program of human papillomaviruses occurs in differentiated squamous keratinocytes. We have previously shown that HPV-18 DNA amplification initiates in spinous cells in organotypic cultures of primary human keratinocytes during prolonged G(2) phase, as signified by abundant cytoplasmic cyclin B1 (Wang, H. K., Duffy, A. A., Broker, T. R., and Chow, L. T. (2009) Genes Dev. 23, 181-194). In this study, we demonstrated that the E7 protein, which induces S phase reentry in suprabasal cells by destabilizing the p130 pocket protein (Genovese, N. J., Banerjee, N. S., Broker, T. R., and Chow, L. T. (2008) J. Virol. 82, 4862-4873), also elicited extensive G(2) responses. Western blots and indirect immunofluorescence assays were used to probe for host proteins known to control G(2)/M progression. E7 expression induced cytoplasmic accumulation of cyclin B1 and cdc2 in the suprabasal cells. The elevated cdc2 had inactivating phosphorylation on Thr(14) or Tyr(15), and possibly both, due to an increase in the responsible Wee1 and Myt1 kinases. In cells that harbored cytoplasmic cyclin B1 or cdc2, there was also an accumulation of the phosphatase-inactive cdc25C phosphorylated on Ser(216), unable to activate cdc2. Moreover, E7 expression induced elevated expression of phosphorylated ATM (Ser(1981)) and the downstream phosphorylated Chk1, Chk2, and JNKs, kinases known to inactivate cdc25C. Similar results were observed in primary human keratinocyte raft cultures in which the productive program of HPV-18 took place. Collectively, this study has revealed the mechanisms by which E7 induces prolonged G(2) phase in the differentiated cells following S phase induction.     

Human cyclin-dependent kinase 2-associated protein 1 (CDK2AP1) is dimeric in its disulfide-reduced state, with natively disordered N-terminal region

CDK2AP1 (cyclin-dependent kinase 2-associated protein 1), corresponding to the gene doc-1 (deleted in oral cancer 1), is a tumor suppressor protein. The doc-1 gene is absent or down-regulated in hamster oral cancer cells and in many other cancer cell types. The ubiquitously expressed CDK2AP1 protein is the only known specific inhibitor of CDK2, making it an important component of cell cycle regulation during G(1)-to-S phase transition. Here, we report the solution structure of CDK2AP1 by combined methods of solution state NMR and amide hydrogen/deuterium exchange measurements with mass spectrometry. The homodimeric structure of CDK2AP1 includes an intrinsically disordered 60-residue N-terminal region and a four-helix bundle dimeric structure with reduced Cys-105 in the C-terminal region. The Cys-105 residues are, however, poised for disulfide bond formation. CDK2AP1 is phosphorylated at a conserved Ser-46 site in the N-terminal "intrinsically disordered" region by IκB kinase ε.