Nucleophosmin/B23 is a target of CDK2/cyclin E in centrosome duplication

In animal cells, duplication of centrosomes and DNA is coordinated. Since CDK2/cyclin E triggers initiation of both events, activation of CDK2/cyclin E is thought to link these two events. We identified nucleophosmin (NPM/B23) as a substrate of CDK2/cyclin E in centrosome duplication. NPM/B23 associates specifically with unduplicated centrosomes, and NPM/B23 dissociates from centrosomes by CDK2/cyclin E-mediated phosphorylation. An anti-NPM/B23 antibody, which blocks this phosphorylation, suppresses the initiation of centrosome duplication in vivo. Moreover, expression of a nonphosphorylatable mutant NPM/ B23 in cells effectively blocks centrosome duplication. Thus, NPM/B23 is a target of CDK2/cyclin E in the initiation of centrosome duplication.     

Specific phosphorylation of nucleophosmin on Thr(199) by cyclin-dependent kinase 2-cyclin E and its role in centrosome duplication

The kinase activity of cyclin-dependent kinase 2 (CDK2)-cyclin E is required for centrosomes to initiate duplication. We have recently found that nucleophosmin (NPM/B23), a phosphoprotein primarily found in nucleolus, associates with unduplicated centrosomes and is a direct substrate of CDK2-cyclin E in centrosome duplication. Upon phosphorylation by CDK2-cyclin E, NPM/B23 dissociates from centrosomes, which is a prerequisite step for centrosomes to initiate duplication. Here, we identified that threonine 199 (Thr(199)) of NPM/B23 is the major phosphorylation target site of CDK2-cyclin E in vitro, and the same site is phosphorylated in vivo. NPM/T199A, a nonphosphorylatable NPM/B23 substitution mutant (Thr(199) --> Ala) acts as dominant negative when expressed in cells, resulting in specific inhibition of centrosome duplication. As expected, NPM/T199A remains associated with the centrosomes. These observations provide direct evidence that the CDK2-cyclin E-mediated phosphorylation on Thr(199) determines association and dissociation of NPM/B23 to the centrosomes, which is a critical control for the centrosome to initiate duplication.     

Cep97 and CP110 suppress a cilia assembly program

Mammalian centrioles play a dynamic role in centrosome function, but they also have the capacity to nucleate the assembly of cilia. Although controls must exist to specify these different fates, the key regulators remain largely undefined. We have purified complexes associated with CP110, a protein that plays an essential role in centrosome duplication and cytokinesis, and have identified a previously uncharacterized protein, Cep97, that recruits CP110 to centrosomes. Depletion of Cep97 or expression of dominant-negative mutants results in CP110 disappearance from centrosomes, spindle defects, and polyploidy. Remarkably, loss of Cep97 or CP110 promotes primary cilia formation in growing cells, and enforced expression of CP110 in quiescent cells suppresses their ability to assemble cilia, suggesting that Cep97 and CP110 collaborate to inhibit a ciliogenesis program. Identification of Cep97 and other genes involved in regulation of cilia assembly may accelerate our understanding of human ciliary diseases, including renal disease and retinal degeneration.     

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 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.     

Neurl4, a novel daughter centriole protein, prevents formation of ectopic microtubule organizing centres

Here we identify Neuralized homologue 4 (Neurl4) as a protein that interacts with CP110, a centrosomal protein that regulates centrosome duplication. Neurl4 uses a Neuralized homology repeat to preferentially localize to procentrioles and daughter centrioles. Neurl4 depletion results in ectopic microtubular organizing centres (MTOCs), leading to accumulation of CP110 and recruitment of a cohort of centrosomal proteins. We show that these ectopic MTOCs persist through mitosis and assemble aberrant mitotic spindles. Interestingly, Neurl4 promotes ubiquitylation of CP110, thereby destabilizing this protein. Our results indicate that Neurl4 counteracts accumulation of CP110, thereby maintaining normal centriolar homeostasis and preventing formation of ectopic MTOCs.     

Interaction between ROCK II and nucleophosmin/B23 in the regulation of centrosome duplication

Nucleophosmin (NPM)/B23 has been implicated in the regulation of centrosome duplication. NPM/B23 localizes between two centrioles in the unduplicated centrosome. Upon phosphorylation on Thr¹⁹⁹ by cyclin-dependent kinase 2 (CDK2)/cyclin E, the majority of centrosomal NPM/B23 dissociates from centrosomes, but some NPM/B23 phosphorylated on Thr¹⁹⁹ remains at centrosomes. It has been shown that Thr¹⁹⁹ phosphorylation of NPM/B23 is critical for the physical separation of the paired centrioles, an initial event of the centrosome duplication process. Here, we identified ROCK II kinase, an effector of Rho small GTPase, as a protein that localizes to centrosomes and physically interacts with NPM/B23. Expression of the constitutively active form of ROCK II promotes centrosome duplication, while down-regulation of ROCK II expression results in the suppression of centrosome duplication, especially delaying the initiation of centrosome duplication during the cell cycle. Moreover, ROCK II regulates centrosome duplication in its kinase and centrosome localization activity-dependent manner. We further found that ROCK II kinase activity is significantly enhanced by binding to NPM/B23 and that NPM/B23 acquires a higher binding affinity to ROCK II upon phosphorylation on Thr¹⁹⁹. Moreover, physical interaction between ROCK II and NPM/B23 in vivo occurs in association with CDK2/cyclin E activation and the emergence of Thr¹⁹⁹-phosphorylated NPM/B23. All these findings point to ROCK II as the effector of the CDK2/cyclin E-NPM/B23 pathway in the regulation of centrosome duplication.     

Interaction proteomics identify NEURL4 and the HECT E3 ligase HERC2 as novel modulators of centrosome architecture

Centrosomes are composed of a centriole pair surrounded by an intricate proteinaceous matrix referred to as pericentriolar material. Although the mechanisms underpinning the control of centriole duplication are now well understood, we know relatively little about the control of centrosome size and shape. Here we used interaction proteomics to identify the E3 ligase HERC2 and the neuralized homologue NEURL4 as novel interaction partners of the centrosomal protein CP110. Using high resolution imaging, we find that HERC2 and NEURL4 localize to the centrosome and that interfering with their function alters centrosome morphology through the appearance of aberrant filamentous structures that stain for a subset of pericentriolar material proteins including pericentrin and CEP135. Using an RNA interference-resistant transgene approach in combination with structure-function analyses, we show that the association between CP110 and HERC2 depends on nonoverlapping regions of NEURL4. Whereas CP110 binding to NEURL4 is dispensable for the regulation of pericentriolar material architecture, its association with HERC2 is required to maintain normal centrosome integrity. NEURL4 is a substrate of HERC2, and together these results indicate that the NEURL4-HERC2 complex participates in the ubiquitin-dependent regulation of centrosome architecture.     

CP110 cooperates with two calcium-binding proteins to regulate cytokinesis and genome stability

The centrosome is an integral component of the eukaryotic cell cycle machinery, yet very few centrosomal proteins have been fully characterized to date. We have undertaken a series of biochemical and RNA interference (RNAi) studies to elucidate a role for CP110 in the centrosome cycle. Using a combination of yeast two-hybrid screens and biochemical analyses, we report that CP110 interacts with two different Ca2+-binding proteins, calmodulin (CaM) and centrin, in vivo. In vitro binding experiments reveal a direct, robust interaction between CP110 and CaM and the existence of multiple high-affinity CaM-binding domains in CP110. Native CP110 exists in large (approximately 300 kDa to 3 MDa) complexes that contain both centrin and CaM. We investigated a role for CP110 in CaM-mediated events using RNAi and show that its depletion leads to a failure at a late stage of cytokinesis and the formation of binucleate cells, mirroring the defects resulting from ablation of either CaM or centrin function. Importantly, expression of a CP110 mutant unable to bind CaM also promotes cytokinesis failure and binucleate cell formation. Taken together, our data demonstrate a functional role for CaM binding to CP110 and suggest that CP110 cooperates with CaM and centrin to regulate progression through cytokinesis.     

Cyclin dependent kinases and their role in regulation of plant cell cycle

Plants have capability to optimize its architecture by using CDK pathways. It involves diverse types of cyclin dependent kinase enzymes (CDKs). CDKs are classified in to eight classes (CDKA to CDKG and CKL) based on the recognized cyclin-binding domains. These enzymes require specific cyclin proteins to get activated. They form complex with cyclin subunits and phosphorylate key target proteins. Phosphorylation of these target proteins is essential to drive cell cycle further from one phase to another phase. During cell division, the activity of cyclin dependent kinase is controlled by CDK interactor/inhibitor of CDKs (ICK) and Kip-related proteins (KRPs). They bind with specific CDK/cyclin complex and help in controlling CDKs activity. Since cell cycle can be progressed further only by synthesis and destruction of cyclins, they are quickly degraded using ubiquitination-proteasome pathway. Ubiquitylation reaction is followed by DNA duplication and cell division process. These two processes are regulated by two complexes known as Skp1/cullin/F-box (SCF)-related complex and the anaphase-promoting complex/cyclosome (APC/C). SCF allows cell to enter from G1 to S phase and APC/C allows cell to enter from G2 to M phase. When all these above processes of cell division are going on, genes of cyclin dependent kinases gets activated one by one simultaneously and help in regulation of CDK pathways. How cell cycle is regulated by CDKs is discussed.     

p53-Driven apoptosis limits centrosome amplification and genomic instability downstream of NPM1 phosphorylation

Chromosome loss or gain is associated with a large number of solid cancers, providing genomic plasticity and thus adaptability to cancer cells. Numerical centrosome abnormalities arising from centrosome over-duplication or failed cytokinesis are a recognized cause of aneuploidy. In higher eukaryotic cells, the centrosome duplicates only once per cell cycle to ensure the formation of a bipolar mitotic spindle that orchestrates the balanced distribution of the sister chromatids to the respective daughter cells. Here we delineate the events that allow abnormal centrosome duplication, resulting in mitotic errors and incorrect chromosome segregation in cells with sustained cyclin-dependent kinase (CDK) activity. We have identified NPM1 as a substrate for CDK6 activated by the Kaposi's sarcoma herpesvirus (KSHV) D-type cyclin and shown that p53-driven apoptosis occurs downstream of NPM1 phosphorylation as a checkpoint mechanism that prevents accumulation of cells with supernumerary centrosomes. Our findings provide evidence that abnormal chromosome segregation in KSHV-infected cells is a direct consequence of NPM1 phosphorylation and predict that genomic instability is an inevitable consequence of latent KSHV infection.     

Activation of the Cdc42p GTPase by cyclin-dependent protein kinases in budding yeast

Cyclin-dependent kinases (CDKs) trigger essential cell cycle processes including critical events in G1 phase that culminate in bud emergence, spindle pole body duplication, and DNA replication. Localized activation of the Rho-type GTPase Cdc42p is crucial for establishment of cell polarity during G1, but CDK targets that link the Cdc42p module with cell growth and cell cycle commitment have remained largely elusive. Here, we identify the GTPase-activating protein (GAP) Rga2p as an important substrate related to the cell polarity function of G1 CDKs. Overexpression of RGA2 in the absence of functional Pho85p or Cdc28p CDK complexes is toxic, due to an inability to polarize growth. Mutation of CDK consensus sites in Rga2p that are phosphorylated both in vivo and in vitro by Pho85p and Cdc28p CDKs results in a loss of G1 phase-specific phosphorylation. A failure to phosphorylate Rga2p leads to defects in localization and impaired polarized growth, in a manner dependent on Rga2p GAP function. Taken together, our data suggest that CDK-dependent phosphorylation restrains Rga2p activity to ensure appropriate activation of Cdc42p during cell polarity establishment. Inhibition of GAPs by CDK phosphorylation may be a general mechanism to promote proper G1-phase progression.     

Intrinsic and cyclin-dependent kinase-dependent control of spindle pole body duplication in budding yeast

Centrosome duplication must be tightly controlled so that duplication occurs only once each cell cycle. Accumulation of multiple centrosomes can result in the assembly of a multipolar spindle and lead to chromosome mis-segregation and genomic instability. In metazoans, a centrosome-intrinsic mechanism prevents reduplication until centriole disengagement. Mitotic cyclin/cyclin-dependent kinases (CDKs) prevent reduplication of the budding yeast centrosome, called a spindle pole body (SPB), in late S-phase and G2/M, but the mechanism remains unclear. How SPB reduplication is prevented early in the cell cycle is also not understood. Here we show that, similar to metazoans, an SPB-intrinsic mechanism prevents reduplication early in the cell cycle. We also show that mitotic cyclins can inhibit SPB duplication when expressed before satellite assembly in early G1, but not later in G1, after the satellite had assembled. Moreover, electron microscopy revealed that SPBs do not assemble a satellite in cells expressing Clb2 in early G1. Finally, we demonstrate that Clb2 must localize to the cytoplasm in order to inhibit SPB duplication, suggesting the possibility for direct CDK inhibition of satellite components. These two mechanisms, intrinsic and extrinsic control by CDK, evoke two-step system that prevents SPB reduplication throughout the cell cycle.     

NDEL1 phosphorylation by Aurora-A kinase is essential for centrosomal maturation, separation, and TACC3 recruitment

NDEL1 is a binding partner of LIS1 that participates in the regulation of cytoplasmic dynein function and microtubule organization during mitotic cell division and neuronal migration. NDEL1 preferentially localizes to the centrosome and is a likely target for cell cycle-activated kinases, including CDK1. In particular, NDEL1 phosphorylation by CDK1 facilitates katanin p60 recruitment to the centrosome and triggers microtubule remodeling. Here, we show that Aurora-A phosphorylates NDEL1 at Ser251 at the beginning of mitotic entry. Interestingly, NDEL1 phosphorylated by Aurora-A was rapidly downregulated thereafter by ubiquitination-mediated protein degradation. In addition, NDEL1 is required for centrosome targeting of TACC3 through the interaction with TACC3. The expression of Aurora-A phosphorylation-mimetic mutants of NDEL1 efficiently rescued the defects of centrosomal maturation and separation which are characteristic of Aurora-A-depleted cells. Our findings suggest that Aurora-A-mediated phosphorylation of NDEL1 is essential for centrosomal separation and centrosomal maturation and for mitotic entry.     

Silencing of CDK2, but not CDK1, separates mitogenic from anti-apoptotic signaling,sensitizing p53 defective cells for synthetic lethality

Small molecule inhibitors targeting CDK1/CDK2 have been clinically proven effective against a variety of tumors, albeit at the cost of profound off target toxicities. To separate potential therapeutic from toxic effects, we selectively knocked down CDK1 or CDK2 in p53 mutated HACAT cells by siRNA silencing. Using dynamic, cell cycle wide proteome arrays, we observed minor changes in overall abundance of proteins critically involved in cell cycle transition despite profound G₂/M or G₁/S arrest, respectively. Employing phospho site specific analyses, we identified uncoupled mitogenic, yet pro-apoptotic signaling from counter balancing anti-apoptotic activity in CDK2 disrupted cells. Moreover, a crucial role of CDK2 activity in early serum response was observed, extending well-established roles of CDKs outside their cell cycle regulating functions. In contrast, disruption of CDK1 only marginally affected phosphorylation events of crucial signaling nodes prior to G₂/S transition. The data presented here suggest that the temporal separation of pro- and anti-apoptotic pathways by selective inhibition of CDK2 disrupts coherent signaling modules and may synergize with anti-proliferative drugs, averting toxic side effects from CDK1 inhibition.     

CDK11(p58) is required for centriole duplication and Plk4 recruitment to mitotic centrosomes

Background

CDK11^p58 is a mitotic protein kinase, which has been shown to be required for different mitotic events such as centrosome maturation, chromatid cohesion and cytokinesis.

Methodology/Principal Findings

In addition to these previously described roles, our study shows that CDK11^p58 inhibition induces a failure in the centriole duplication process in different human cell lines. We propose that this effect is mediated by the defective centrosomal recruitment of proteins at the onset of mitosis. Indeed, Plk4 protein kinase and the centrosomal protein Cep192, which are key components of the centriole duplication machinery, showed reduced levels at centrosomes of mitotic CDK11-depleted cells. CDK11^p58, which accumulates only in the vicinity of mitotic centrosomes, directly interacts with the centriole-associated protein kinase Plk4 that regulates centriole number in cells. In addition, we show that centriole from CDK11 defective cells are not able to be over duplicated following Plk4 overexpression.

Conclusion/Significance

We thus propose that CDK11 is required for centriole duplication by two non-mutually-exclusive mechanisms. On one hand, the observed duplication defect could be caused indirectly by a failure of the centrosome to fully maturate during mitosis. On the other hand, CDK11^p58 could also directly regulate key centriole components such as Plk4 during mitosis to trigger essential mitotic centriole modifications, required for centriole duplication during subsequent interphase.     

Why minimal is not optimal: Driving the mammalian cell cycle—and drug discovery—with a physiologic CDK control network

Progression through the eukaryotic cell division cycle is governed by the activity of cyclin-dependent kinases (CDKs). For a CDK to become active it must (1) bind a positive regulatory subunit (cyclin) and (2) be phosphorylated on its activation (T) loop. In metazoans, multiple CDK catalytic subunits, each with a distinct set of preferred cyclin partners, regulate the cell cycle, but it has been difficult to assign functions to individual CDKs in vivo. Biochemical analyses and experiments with dominant-negative alleles suggested that specific CDK/cyclin complexes regulate different events, but genetic loss of interphase CDKs (Cdk2, -4 and -6), alone or in combination, did not block proliferation of cells in culture. These knockout and knockdown studies suggested redundancy or plasticity built into the CDK network but did not address whether there was true redundancy in normal cells with a full complement of CDKs. Here, we discuss recent work that took a chemical-genetic approach to reveal that the activity of a genetically non-essential CDK, Cdk2, is required for cell proliferation when normal cyclin pairing is maintained. These results have implications for the systems-level organization of the cell cycle, for regulation of the restriction point and G₁/S transition and for efforts to target Cdk2 therapeutically in human cancers.     

Why minimal is not optimal: Driving the mammalian cell cycle—and drug discovery—with a physiologic CDK control network

Progression through the eukaryotic cell division cycle is governed by the activity of cyclin-dependent kinases (CDKs). For a CDK to become active it must (1) bind a positive regulatory subunit (cyclin) and (2) be phosphorylated on its activation (T) loop. In metazoans, multiple CDK catalytic subunits, each with a distinct set of preferred cyclin partners, regulate the cell cycle, but it has been difficult to assign functions to individual CDKs in vivo. Biochemical analyses and experiments with dominant-negative alleles suggested that specific CDK/cyclin complexes regulate different events, but genetic loss of interphase CDKs (Cdk2, -4 and -6), alone or in combination, did not block proliferation of cells in culture. These knockout and knockdown studies suggested redundancy or plasticity built into the CDK network but did not address whether there was true redundancy in normal cells with a full complement of CDKs. Here, we discuss recent work that took a chemical-genetic approach to reveal that the activity of a genetically non-essential CDK, Cdk2, is required for cell proliferation when normal cyclin pairing is maintained. These results have implications for the systems-level organization of the cell cycle, for regulation of the restriction point and G?/S transition and for efforts to target Cdk2 therapeutically in human cancers.     

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.     

P53, cyclin-dependent kinase and abnormal amplification of centrosomes

Centrosomes play a critical role in formation of bipolar mitotic spindles, an essential event for accurate chromosome segregation into daughter cells. Numeral abnormalities of centrosomes (centrosome amplification) occur frequently in cancers, and are considered to be the major cause of chromosome instability, which accelerates acquisition of malignant phenotypes during tumor progression. Loss or mutational inactivation of p53 tumor suppressor protein, one of the most common mutations found in cancers, results in a high frequency of centrosome amplification in part via allowing the activation of the cyclin-dependent kinase (CDK) 2-cyclin E (as well as CDK2-cyclin A) which is a key factor for the initiation of centrosome duplication. In this review, the role of centrosome amplification in tumor progression, and mechanistic view of how centrosomes are amplified in cells through focusing on loss of p53 and aberrant activities of CDK2-cyclins will be discussed.