Early mitotic degradation of Nek2A depends on Cdc20-independent interaction with the APC/C.

The temporal control of mitotic protein degradation remains incompletely understood. In particular, it is unclear why the mitotic checkpoint prevents the anaphase-promoting complex/cyclosome (APC/C)-mediated degradation of cyclin B and securin in early mitosis, but not cyclin A. Here, we show that another APC/C substrate, NIMA-related kinase 2A (Nek2A), is also destroyed in pro-metaphase in a checkpoint-independent manner and that this depends on an exposed carboxy-terminal methionine-arginine (MR) dipeptide tail. Truncation of the Nek2A C terminus delays its degradation until late mitosis, whereas Nek2A C-terminal peptides interfere with APC/C activity in an MR-dependent manner. Most importantly, we show that Nek2A binds directly to the APC/C, also in an MR-dependent manner, even in the absence of the adaptor protein Cdc20. As similar C-terminal dipeptide tails promote direct association of Cdc20, Cdh1 and Apc10-Doc1 with core APC/C subunits, we propose that this sequence also allows a substrate, Nek2A, to directly bind the APC/C. Thus, although Cdc20 is required for the degradation of Nek2A, it is not required for its recruitment and this renders its degradation insensitive to the mitotic checkpoint.

Dynamic recruitment of Nek2 kinase to the centrosome involves microtubules, PCM-1, and localized proteasomal degradation.

Centrosomes undergo dramatic changes in composition and activity during cell cycle progression. Yet mechanisms involved in recruiting centrosomal proteins are poorly understood. Nek2 is a cell cycle-regulated protein kinase required for regulation of centrosome structure at the G2/M transition. Here, we have addressed the processes involved in trafficking of Nek2 to the centrosome of human adult cells. We find that Nek2 exists in small, highly dynamic cytoplasmic particles that move to and from the centrosome. Many of these particles align along microtubules and a motif was identified in the Nek2 C-terminal noncatalytic domain that allows both microtubule binding and centrosome localization. FRAP experiments reveal that 70% of centrosomal Nek2 is rapidly turned over (t(1/2) approximately 3 s). Microtubules facilitate Nek2 trafficking to the centrosome but only over long distances. Cytoplasmic Nek2 particles colocalize in part with PCM-1 containing centriolar satellites and depletion of PCM-1 interferes with centrosomal recruitment of Nek2 and its substrate C-Nap1. Finally, we show that proteasomal degradation is necessary to allow rapid recruitment of new Nek2 molecules to the centrosome. Together, these data highlight multiple processes involved in regulating the abundance of Nek2 kinase at the centrosome including microtubule binding, the centriolar satellite component PCM-1, and localized protein degradation.

p16(INK4A)-independence of Epstein-Barr virus-induced cell proliferation and virus latency.

Epstein-Barr virus (EBV) has the ability to promote cell cycle progression following the initial infection of primary resting B-lymphocytes and to cause cell cycle arrest at the onset of the viral replicative cycle. Various mechanisms have been proposed for the proliferative effects, including the up-regulation of cyclin D2 by the viral EBNA-2 and EBNA-LP proteins, direct binding of EBNA3C to the retinoblastoma protein (pRb), and down-regulation of the p16(INK4A) tumour suppressor by the viral LMP1 product. To try to gain insight into the relative importance of these mechanisms, the ability of EBV to immortalize lymphocytes from an individual who is genetically deficient for p16(INK4A) was examined. From detailed analyses of the resultant lymphoblastoid cell lines it is concluded that p16(INK4A) status has little bearing on EBV's ability to manipulate the cell cycle machinery and a model to accommodate the previously proposed routes taken by EBV to bypass the restriction point is presented.