Centrosome duplication proceeds during mimosine-induced G1 cell cycle arrest

Centrosome duplication must remain coordinated with cell cycle progression to ensure the formation of a strictly bipolar mitotic spindle, but the mechanisms that regulate this coordination are poorly understood. Previous work has shown that prolonged S-phase is permissive for centrosome duplication, but prolonging either G2 or M-phase cannot support duplication. To examine whether G1 is permissive for centrosome duplication, we release serum-starved G0 cells into mimosine, which delays the cell cycle in G1. We find that in mimosine, centrosome duplication does occur, albeit slowly compared with cells that progress into S-phase; centrosome duplication in mimosine-treated cells also proceeds in the absence of a rise in Cdk2 kinase activity normally associated with the G1/S transition. CHO cells arrested with mimosine can also assemble more than four centrioles (termed "centrosome amplification"), but the extent of centrosome amplification during prolonged G1 is decreased compared to cells that enter S-phase and activate the Cdk2-cyclin complex. Together, our results suggest a model, which predicts that entry into S-phase and the rise in Cdk2 activity associated with this transition are not absolutely required to initiate centrosome duplication, but rather, serve to entrain the centrosome reproduction cycle with cell cycle progression.     

Centrosome number is controlled by a centrosome-intrinsic block to reduplication

The centrosome duplicates once in S phase. To determine whether there is a block in centrosome reduplication, we used a cell fusion assay to compare the duplication potential of unduplicated G1 centrosomes and recently duplicated G2 centrosomes. By fusing cells in different cell cycle stages, we found that G2 centrosomes were unable to reduplicate in a cellular environment that supports centrosome duplication. Furthermore, G2 cytoplasm did not inhibit centrosome duplication in fused cells, indicating that the block to reduplication is intrinsic to the centrosomes rather than the cytoplasm. To test the underlying mechanism, we created mononucleate G1 cells with two centrosomes by fusing cells with enucleated cytoplasts. Both centrosomes duplicated, indicating that the block is not controlled by centrosome:nucleus ratio. We also found that human primary cells have tight control over centrosome number during prolonged S-phase arrest and that this control is partially abrogated in transformed cells. This suggests a link between the control of centrosome duplication and maintenance of genomic stability.     

Loading and Unloading: Orchestrating Centrosome Duplication and Spindle Assembly by Ran/Crm1

The cell cycle is an intricate process of DNA replication and cell division thatconcludes with the formation of two genetically equivalent daughter cells. In thisprogression, the centrosome is duplicated once and only once during the G1/S transitionto produce the bipolar spindle and ensure proper chromosome segregation. The presenceof multiple centrosomes in cancer cells suggests that this process is mis-regulated duringcarcinogenesis. This suggests that certain factors exist that license the progression ofcentrosome duplication and serve to inhibit further duplications during a single cell cycle.Recent studies suggest that the Ran/Crm1 complex not only regulates nucleocytoplasmictransport but is also independently involved in mitotic spindle assembly. Factors that arecapable of interacting with Ran/Crm1 through their nuclear export sequences, such ascyclins/cdks, p53 and Brca1/2, may potentially function as centrosome checkpoints akinto the G1/S and G2/M checkpoints of the cell cycle. Our recent findings indicate thatnucleophosmin, a protein whose trafficking is mediated by the Ran/Crm1 network, is oneof such checkpoint factors for maintaining proper centrosome duplication. We proposethat Ran/Crm1 may act as a ‘loading dock’ to coordinate various checkpoint factors inregulating the fidelity of centrosome duplication during cell cycle progression, and thedisruption of these processes may lead to genomic instability and an acceleration ofoncogenesis.     

Cyclin E in centrosome duplication and reduplication in sea urchin zygotes

When protein synthesis is completely blocked from before fertilization, the sea urchin zygote arrests in first S phase and the paternal centrosome reduplicates multiple times. However, when protein synthesis is blocked starting in prophase of first mitosis, the zygote divides and the blastomeres arrest in a G1-like state. The centrosome inherited from this mitosis duplicates only once in each blastomere for reasons that are not understood. The late G1 rise in cyclin E/cdk2 kinase activity initiates centrosome duplication in mammalian cells and its activity is needed for centrosome duplication in Xenopus egg extracts. Since the half-time for cyclin E turnover is normally approximately 1 h in sea urchin zygotes, the different behaviors of centrosomes during G1 and S phase arrests could be due to differential losses of cyclin E and its associated kinase activities at these two arrest points. To better understand the mechanisms that limit centrosome duplication, we characterize the levels of cyclin E and its associated kinase activity at the S phase and G1 arrest points. We first demonstrate that cyclin E/cdk2 kinase activity is required for centrosome duplication and reduplication in sea urchin zygotes. Next we find that cyclin E levels and cyclin E/cdk2 kinase activities are both constitutively and equivalently elevated during both the S phase and G1 arrests. This indicates that centrosome duplication during the G1 arrest is limited by a block to reduplication under conditions permissive for duplication. The cytoplasmic conditions of S phase, however, abrogate this block to reduplication.     

Cyclin-dependent kinase 2 (Cdk2) is required for centrosome duplication in mammalian cells

Centrosome duplication is indispensable for the formation of the bipolar mitotic spindle. Surprisingly, even if DNA replication or mitosis is inhibited, centrosome duplication can still occur [1] [2] [3] [4] [5]. Thus, it remains unknown how centrosome duplication is coordinated with the cell cycle. Here, we show that centrosome duplication requires cyclin-dependent kinase 2 (Cdk2) in mammalian cells. We have found that in Chinese hamster ovary (CHO) cells, whereas centrosome duplication is not inhibited by hydroxyurea (HU) treatment, which arrests the cells in S phase, it is inhibited by mimosine treatment, which arrests the cells in late G1 phase. Cdk2 activity was higher in HU-treated cells than in mimosine-treated cells. Remarkably, inhibition of the Cdk2 activity in HU-treated cells with butyrolactone I or roscovitine [6], or by expression of the Cdk inhibitor p21(Waf1/Cip1), blocked the continued centrosome duplication. Moreover, overexpression of Cdk2 reversed the inhibition of centrosome duplication by mimosine treatment. These results indicate a requirement of Cdk2 activity for centrosome duplication and therefore suggest an underlying mechanism for the coordination of centrosome duplication with the cell cycle.     

Polo-like kinase-2 is required for centriole duplication in mammalian cells

Centriole duplication initiates at the G1-to-S transition in mammalian cells and is completed during the S and G2 phases. The localization of a number of protein kinases to the centrosome has revealed the importance of protein phosphorylation in controlling the centriole duplication cycle. Here we show that the human Polo-like kinase 2 (Plk2) is activated near the G1-to-S transition of the cell cycle. Endogenous and overexpressed HA-Plk2 localize with centrosomes, and this interaction is independent of Plk2 kinase activity. In contrast, the kinase activity of Plk2 is required for centriole duplication. Overexpression of a kinase-deficient mutant under S-phase arrest blocks centriole duplication. Downregulation of endogenous Plk2 with small hairpin RNAs interferes with the ability to reduplicate centrioles. Furthermore, centrioles failed to duplicate during the cell cycle of human fibroblasts and U2OS cells after overexpression of a Plk2 dominant-negative mutant. These results show that Plk2 is a physiological centrosomal protein and that its kinase activity is likely to be required for centriole duplication near the G1-to-S phase transition.     

Involvement of a centrosomal protein kendrin in the maintenance of centrosome cohesion by modulating Nek2A kinase activity

Centrosome cycle is strictly coordinated with chromosome duplication cycle to ensure the faithful segregation of chromosomes. Centrosome duplication occurs from the beginning of S phase, and the duplicated centrosomes are held together by centrosome cohesion to function as a single microtubule organizing center during interphase. At late G2 phase centrosome cohesion is disassembled by Nek2A kinase-mediated phosphorylation and, as a consequence, centrosomes are split and constitute spindle poles in mitosis. It has been reported that depletion of a centrosomal protein kendrin (also named pericentrin) induces premature centrosome splitting in interphase, however, it remains unknown how kendrin contributes to the maintenance of centrosome cohesion. Here we show that kendrin associates with Nek2A kinase, which exhibits considerably low activity. Nek2A kinase activity is inhibited in vitro by addition of the Nek2A-binding region of kendrin in a dose-dependent manner. Furthermore, ectopic expression of the same region decreases the number of the cells with split centrosomes at late G2 phase. Taken together, these results suggest that kendrin anchors Nek2A and suppresses its kinase activity at the centrosomes, and thus, is involved in the mechanism to prevent premature centrosome splitting during interphase.     

Asymmetric localization of the CDC25B phosphatase to the mother centrosome during interphase

The Cyclin-Dependent Kinase (CDK)-activating phosphatase CDC25B, localises to the centrosomes where its activity is both positively and negatively regulated by several kinases including Aurora A and CHK1. Our recent data also demonstrate a role for CDC25B in the centrosome duplication cycle and microtubule nucleation in interphase that appears to involve the recruitment of γ-tubulin to the centrosomes. In the present study, we report that CDC25B, along with CHK1, CDK1 and WEE1, localise asymmetrically around the mother centrosome from S to G2-phases, and gradually become evenly distributed to the two centrosomes by late G2 phase, concomitant with centrosome maturation. We further demonstrate that siRNA inhibition of CDC25B results in an accumulation of cells in G2 phase with two separated centrosomes, each containing only a single centriole, suggesting a requirement for CDC25B in centriole duplication. We propose that the localisation of key cell cycle regulators to the mother centrosome ensures synchrony between the centrosome duplication and cell division cycles.     

Distinct cell cycle-dependent roles for dynactin and dynein at centrosomes

Centrosomal dynactin is required for normal microtubule anchoring and/or focusing independently of dynein. Dynactin is present at centrosomes throughout interphase, but dynein accumulates only during S and G2 phases. Blocking dynein-based motility prevents recruitment of dynactin and dynein to centrosomes and destabilizes both centrosomes and the microtubule array, interfering with cell cycle progression during mitosis. Destabilization of the centrosomal pool of dynactin does not inhibit dynein-based motility or dynein recruitment to centrosomes, but instead causes abnormal G1 centriole separation and delayed entry into S phase. The correct balance of centrosome-associated dynactin subunits is apparently important for satisfaction of the cell cycle mechanism that monitors centrosome integrity before centrosome duplication and ultimately governs the G1 to S transition. Our results suggest that, in addition to functioning as a microtubule anchor, dynactin contributes to the recruitment of important cell cycle regulators to centrosomes.     

Centrobin: a novel daughter centriole-associated protein that is required for centriole duplication

In mammalian cells, the centrosome consists of a pair of centrioles and amorphous pericentriolar material. The pair of centrioles, which are the core components of the centrosome, duplicate once per cell cycle. Centrosomes play a pivotal role in orchestrating the formation of the bipolar spindle during mitosis. Recent studies have linked centrosomal activity on centrioles or centriole-associated structures to cytokinesis and cell cycle progression through G1 into the S phase. In this study, we have identified centrobin as a centriole-associated protein that asymmetrically localizes to the daughter centriole. The silencing of centrobin expression by small interfering RNA inhibited centriole duplication and resulted in centrosomes with one or no centriole, demonstrating that centrobin is required for centriole duplication. Furthermore, inhibition of centriole duplication by centrobin depletion led to impaired cytokinesis.     

PLK2 phosphorylation is critical for CPAP function in procentriole formation during the centrosome cycle

Control of centrosome duplication is tightly linked with the progression of the cell cycle. Recent studies suggest that the fundamental process of centriole duplication is evolutionally conserved. Here, we identified c entrosomal P 4.1‐a ssociated p rotein (CPAP), a human homologue of SAS‐4, as a substrate of PLK2 whose activity oscillates during the cell cycle. PLK2 phosphorylates the S589 and S595 residues of CPAP in vitro and in vivo. This phosphorylation is critical for procentriole formation during the centrosome cycle. PLK4 also phosphorylates S595 of CPAP, but PLK4 phosphorylation is not a critical step in the PLK4 function in procentriole assembly. CPAP is phosphorylated in a cell cycle stage‐specific manner, so that its phosphorylation increases at the G1/S transition phase and decreases during the exit of mitosis. Phosphorylated CPAP is preferentially located at the procentriole. Furthermore, overexpression of a phospho‐resistant CPAP mutant resulted in the failure to form elongated centrioles. On the basis of these results, we propose that phosphorylated CPAP is involved in procentriole assembly, possibly for centriole elongation. This work demonstrates an example of how procentriole formation is linked to the progression of the cell cycle.     

A mammalian in vitro centriole duplication system: evidence for involvement of CDK2/cyclin E and nucleophosmin/B23 in centrosome duplication

Centrosome duplication in mammalian cells is a highly regulated process, occurs in coordination of other cell cycle events. However, molecular exploration of this important cellular process had been difficult due to unavailability of a simple assay system. Here, using centrosomes loosely associated with nuclei isolated from cultured cells, we developed a cell-free centriole (duplication unit of the centrosome) duplication system: unduplicated centrosomes bound to the nuclei are able to undergo duplication in the presence of G1/S extracts. We show that the ability of G1/S extracts to induce centriole duplication in vitro depends on the presence of active CDK2/cyclin E. It has been shown that dissociation of centro-somal nucleophosmin (NPM)/B23 triggered by CDK2/cyclin E-mediated phosphorylation is required for initiation of centrosome duplication. We show that centriole duplication is blocked when nuclei were preincubated with the anti-NPM/B23 antibody that prevents phosphorylation of NPM/B23 by CDK2/cyclin E. These studies provide not only direct evidence for the requirement of CDK2/cyclin E and phosphorylation of NPM/B23 for centrosomes to initiate duplication, but a valuable experimental system for further exploration of the molecular regulation of centrosome duplication in somatic cells of higher animals.     

Plk2 regulated centriole duplication is dependent on its localization to the centrosome and a functional polo-box domain

In mammalian cells, the centrosome consists of a pair of centrioles and amorphous pericentriolar material. The centrosome duplicates once per cell cycle. Polo like kinases (Plks) perform crucial functions in cell-cycle progression and during mitosis. The polo-like kinase-2, Plk2, is activated near the G1/S phase transition, and plays an important role in the reproduction of centrosomes. In this study, we show that the polo-box of Plk2 is required both for association to the centrosome and centriole duplication. Mutation of critical sites in the Plk2 polo-box prevents centrosomal localization and impairs centriole duplication. Plk2 is localized to centrosomes during early G1 phase where it only associates to the mother centriole and then distributes equally to both mother and daughter centrioles at the onset of S phase. Furthermore, our results imply that Plk2 mediated centriole duplication is dependent on Plk4 function. In addition, we find that siRNA-mediated down-regulation of Plk2 leads to the formation of abnormal mitotic spindles confirming that Plk2 may have a function in the reproduction of centrioles.     

A Mammalian In Vitro Centriole Duplication System: Evidence for Involvement of CDK2/Cyclin E and Nucleophosmin/B23 in Centrosome Duplication

Centrosome duplication in mammalian cells is a highly regulated process, occurs in coordination of other cell cycle events. However, molecular exploration of this important cellular process had been difficult due to unavailability of a simple assay system. Here, using centrosomes loosely associated with nuclei isolated from cultured cells, we developed a cell-free centriole (duplication unit of the centrosome) duplication system: unduplicated centrosomes bound to the nuclei are able to undergo duplication in the presence of G1/S extracts. We show that the ability of G1/S extracts to induce centriole duplication in vitro depends on the presence of active CDK2/cyclin E. It has been shown that dissociation of centrosomal nucleophosmin (NPM)/B23 triggered by CDK2/cyclin E-mediated phosphorylation is required for initiation of centrosome duplication. We show that centriole duplication is blocked when nuclei were preincubated with the anti-NPM/B23 antibody that prevents phosphorylation of NPM/B23 by CDK2/cyclin E. These studies provide not only direct evidence for the requirement of CDK2/cyclin E and phosphorylation of NPM/B23 for centrosomes to initiate duplication, but a valuable experimental system for further exploration of the molecular regulation of centrosome duplication in somatic cells of higher animals.     

A subset of centrosomal proteins are arranged in a tubular conformation that is reproduced during centrosome duplication

The centrosome plays a fundamental role in organizing the interphase cytoskeleton and the mitotic spindle, and its protein complexity is modulated to support these functions. The centrosome must also duplicate itself once during each cell cycle, thus ensuring the formation of a bipolar spindle and its continuity through successive cell divisions. In this study, we have used a battery of antibodies directed against centrosomal components to study the general organization of the centrosome during the cell cycle and during the centrosome duplication process. We demonstrate that a subset of centrosomal proteins are arranged together to form a tubular pattern within the centrosome. The tubular conformation defined by these proteins has a polarity and is closed at one end. The centriole complement of the centrosome is normally placed near this end. We show that the "wall" of the tube is enriched in proteins such as CDC2, ninein, and pericentrin as well as gamma-tubulin. In addition, a subset of gamma-tubulin is localized to the "lumen" of the tube. We also demonstrate, for the first time, that antibody staining can be used to detect centrosome duplication allowing the identification of duplication intermediates. We show that one product of centrosome duplication is the replication of the tubular structure found within the centrosome. The position of the centriole duplexes prior to and during centrosome duplication is documented and a model of the morphogenesis of the centrosome during the duplication process is proposed.     

Two-way traffic: centrosomes and the cell cycle

The well recognized activities of the mammalian centrosome--microtubule nucleation, duplication, and organization of the primary cilium--are under the control of the cell cycle. However, the centrosome is more than just a follower of the cell cycle; it can also be essential for the cell to transit G1 and enter S phase. How the centrosome influences G1 progression is a mystery.     

Parthenogenesis in Xenopus eggs injected with centrosomes from synchronized human lymphoid cells

In Xenopus eggs, normal development requires the participation of the centrosome provided by the sperm. Injection of foreign centrosomes purified from exponentially growing mammalian cells enables the eggs to undertake parthenogenesis. In order to know whether such a complementation required centrosomes already committed to duplication, we have prepared centrosomes from human cells synchronized at different stages of the cell cycle (G0, G1, G2). We show that the three types of centrosome possess a similar parthenogenetic activity and conclude that duplication of heterologous centrosome can be triggered in Xenopus eggs.     

Autophosphorylation of Polo-like Kinase 4 and Its Role in Centriole Duplication

Centrosome duplication occurs once every cell cycle in a strictly controlled manner. Polo-like kinase 4 (PLK4) is a key regulator of this process whose kinase activity is essential for centriole duplication. Here, we show that PLK4 autophosphorylation of serine S305 is a consequence of kinase activation and enables the active fraction to be identified in the cell. Active PLK4 is detectable on the replicating mother centriole in G1/S, with the proportion of active kinase increasing through interphase to reach a maximum in mitosis. Activation of PLK4 at the replicating daughter centriole is delayed until G2, but a level equivalent to the replicating mother centriole is achieved in M phase. Active PLK4 is regulated by the proteasome, because either proteasome inhibition or mutation of the degron motif of PLK4 results in the accumulation of S305-phosphorylated PLK4. Autophosphorylation probably plays a role in the process of centriole duplication, because mimicking S305 phosphorylation enhances the ability of overexpressed PLK4 to induce centriole amplification. Importantly, we show that S305-phosphorylated PLK4 is specifically sequestered at the centrosome contrary to the nonphosphorylated form. These data suggest that PLK4 activity is restricted to the centrosome to prevent aberrant centriole assembly and sustained kinase activity is required for centriole duplication.