John R. Daum

Histone H3 Thr-3 phosphorylation by Haspin positions Aurora B at centromeres in mitosis

Location, Location, Location Cell division is orchestrated by a complex signaling pathway that ensures the correct segregation of newly replicated chromosomes to the two daughter cells. The pathway is controlled in part by restricting the activity of critical regulators to specific subcellular locations. For example, the chromosomal passenger complex (CPC) is recruited to chromosomes during mitosis where it oversees kinetochore activity and cytokinesis (see Perspective by Musacchio). Wang et al. (p. 231, published online 12 August), Kelly et al. (p. 235, published online 12 August), and Yamagishi et al. (p. 239) now show that the phosphorylation of the chromatin protein, histone H3, acts to bring the CPC to chromosomes, thereby activating its aurora B kinase subunit. The Survivin subunit of CPC binds specifically to phosphorylated H3, with the phosphorylation at centromeres being carried out by the mitosis-specific kinase, haspin. Furthermore, Bub1 phosphorylation of histone H2A recruits shugoshin, a centromeric CPC adapter. Thus, these two histone marks in combination define the inner centromere. A critical regulator of cell division is recruited to chromosomes through the specific phosphorylation of a chromatin protein. Aurora B is a component of the chromosomal passenger complex (CPC) required for correct spindle-kinetochore attachments during chromosome segregation and for cytokinesis. The chromatin factors that recruit the CPC to centromeres are unknown, however. Here we show that phosphorylation of histone H3 threonine 3 (H3T3ph) by Haspin is necessary for CPC accumulation at centromeres and that the CPC subunit Survivin binds directly to H3T3ph. A nonbinding Survivin-D70A/D71A mutant does not support centromeric CPC concentration, and both Haspin depletion and Survivin-D70A/D71A mutation diminish centromere localization of the kinesin MCAK and the mitotic checkpoint response to taxol. Survivin-D70A/D71A mutation and microinjection of H3T3ph-specific antibody both compromise centromeric Aurora B functions but do not prevent cytokinesis. Therefore, H3T3ph generated by Haspin positions the CPC at centromeres to regulate selected targets of Aurora B during mitosis.

The Reversibility of Mitotic Exit in Vertebrate Cells

A guiding hypothesis for cell-cycle regulation asserts that regulated proteolysis constrains the directionality of certain cell-cycle transitions. Here we test this hypothesis for mitotic exit, which is regulated by degradation of the cyclin-dependent kinase 1 (Cdk1) activator, cyclin B. Application of chemical Cdk1 inhibitors to cells in mitosis induces cytokinesis and other normal aspects of mitotic exit, including cyclin B degradation. However, chromatid segregation fails, resulting in entrapment of chromatin in the midbody. If cyclin B degradation is blocked with a proteasome inhibitor or by expression of non-degradable cyclin B, Cdk inhibitors will nonetheless induce mitotic exit and cytokinesis. However, if after mitotic exit, the Cdk1 inhibitor is washed free from cells in which cyclin B degradation is blocked, the cells can revert back to M phase. This reversal is characterized by chromosome recondensation, nuclear envelope breakdown, assembly of microtubules into a mitotic spindle, and in most cases, dissolution of the midbody, reopening of the cleavage furrow, and realignment of chromosomes at the metaphase plate. These findings demonstrate that proteasome-dependent degradation of cyclin B provides directionality for the M phase to G1 transition.

Polo-like kinase 1 creates the tension-sensing 3F3/2 phosphoepitope and modulates the association of spindle-checkpoint proteins at kinetochores

BACKGROUND In mitosis, a mechanochemical system recognizes tension that is generated by bipolar microtubule attachment to sister kinetochores. This is translated into multiple outputs including the stabilization of microtubule attachments, changes in kinetochore protein dynamics, and the silencing of the spindle checkpoint. How kinetochores sense tension and translate this into various signals represent critical unanswered questions. The kinetochores of chromosomes not under tension are specifically phosphorylated at an epitope recognized by the 3F3/2 monoclonal antibody. Determining the kinase that generates the 3F3/2 phosphoepitope at kinetochores should reveal an important component of this system that regulates mitotic progression. RESULTS We demonstrate that Polo-like kinase 1 (Plk1) creates the 3F3/2 phosphoepitope on mitotic kinetochores. In a permeabilized in vitro cell system, the depletion of Xenopus Plk1 from M phase extract leads to the loss of 3F3/2 kinase activity. Purified recombinant Plk1 is sufficient to generate the 3F3/2 phosphoepitope in this system. Using siRNA, we show that the reduction of Plk1 protein levels significantly diminishes 3F3/2 phosphoepitope expression at kinetochores. The consensus phosphorylation sites of Plk1 show strong similarity to the 3F3/2 phosphoepitope sequence determined by phosphopeptide mapping. The inhibition of Plk1 by siRNA alters the normal kinetochore association of Mad2, Cenp-E, Hec1/Ndc80, Spc24, and Cdc20 and induces a spindle-checkpoint-mediated mitotic arrest. CONCLUSIONS Plk1 generates the 3F3/2 phosphoepitope at kinetochores that are not under tension and contributes to the normal kinetochore association of several key proteins important in checkpoint signaling. Mechanical tension regulates Plk1 accumulation at kinetochores and possibly its kinase activity.

Ska3 Is Required for Spindle Checkpoint Silencing and the Maintenance of Chromosome Cohesion in Mitosis

The mitotic spindle checkpoint monitors proper bipolar attachment of chromosomes to the mitotic spindle. Previously, depletion of the novel kinetochore complex Ska1/Ska2 was found to induce a metaphase delay. By using bioinformatics, we identified C13orf3, predicted to associate with kinetochores. Recently, three laboratories independently indentified C13orf3 as an additional Ska complex component, and therefore we adopted the name Ska3. We found that cells depleted of Ska3 by RNAi achieve metaphase alignment but fail to silence the spindle checkpoint or enter anaphase. After hours of metaphase arrest, chromatids separate but retain robust kinetochore-microtubule attachments. Ska3-depleted cells accumulate high levels of the checkpoint protein Bub1 at kinetochores. Ska3 protein accumulation at kinetochores in prometaphase is dependent on Sgo1 protein. Sgo1, which accumulates at the centromeres earlier, in prophase, is not dependent on Ska3. Sgo1-depleted cells show a stronger premature chromatid separation phenotype than those depleted of Ska3. We hypothesize that Ska3 functions to coordinate checkpoint signaling from the microtubule binding sites within a kinetochore by laterally linking the individual binding sites. We suggest that this network plays a major role in silencing the spindle checkpoint when chromosomes are aligned at metaphase to allow timely anaphase onset and mitotic exit.

Fine Tuning the Cell Cycle: Activation of the Cdk1 Inhibitory Phosphorylation Pathway during Mitotic Exit

Inactivation of cyclin-dependent kinase (Cdk) 1 promotes exit from mitosis and establishes G1. Proteolysis of cyclin B is the major known mechanism that turns off Cdk1 during mitotic exit. Here, we show that mitotic exit also activates pathways that catalyze inhibitory phosphorylation of Cdk1, a mechanism previously known to repress Cdk1 only during S and G2 phases of the cell cycle. We present evidence that down-regulation of Cdk1 activates Wee1 and Myt1 kinases and inhibits Cdc25 phosphatase during the M to G1 transition. If cyclin B/Cdk1 complex is present in G1, the inhibitory sites on Cdk1 become phosphorylated. Exit from mitosis induced by chemical Cdk inhibition can be reversed if cyclin B is preserved. However, this reversibility decreases with time after mitotic exit despite the continued presence of the cyclin. We show that this G1 block is due to phosphorylation of Cdk1 on inhibitory residues T14 and Y15. Chemical inhibition of Wee1 and Myt1 or expression of Cdk1 phosphorylation site mutants allows reversal to M phase even from late G1. This late Cdk1 reactivation often results in caspase-dependent cell death. Thus, in G1, the Cdk inhibitory phosphorylation pathway is functional and can lock Cdk1 in the inactive state.

Haspin inhibitors reveal centromeric functions of Aurora B in chromosome segregation

Haspin inhibitors reveal that Aurora B at centromeres is required for metaphase chromosome alignment and spindle checkpoint signaling.

Casein kinase II catalyzes a mitotic phosphorylation on threonine 1342 of human DNA topoisomerase IIα, which is recognized by the 3F3/2 phosphoepitope antibody

The 3F3/2 antibody recognizes a phosphoepitope that is implicated in the mitotic checkpoint regulating the metaphase-to-anaphase transition. Immunoprecipitation and Western blotting revealed that the 3F3/2 antibody binds to human DNA topoisomerase II α (HsTIIα) from mitotic but not interphase HeLa cells. Extracts from mitotic cells efficiently catalyzed the formation of the 3F3/2 phosphoepitope on fragments of HsTIIα expressed in bacteria. Expression and site-directed mutagenesis of various HsTIIα protein fragments mapped the 3F3/2 phosphoepitope to the region of HsTIIα containing phosphorylated threonine 1342. This threonine lies within a consensus sequence for phosphorylation by casein kinase II (CKII). CKII is present in cellular extracts and is associated with isolated mitotic chromosomes. The 3F3/2 phosphoepitope kinase present in mitotic cell extracts was able to create the epitope using GTP and was inhibited by heparin. A kinase associated with the isolated chromosomes also generated the 3F3/2 phosphoepitope on HsTIIα. Recombinant CKII catalyzed the formation of the 3F3/2 phosphoepitope on fragments of HsTIIα containing threonine 1342. These results indicate that the mitotic 3F3/2 phosphoepitope kinase activity is attributable to CKII. We suggest that the 3F3/2 phosphoepitope reflects a CKII-catalyzed phosphorylation of threonine 1342 that may regulate mitotic functions of HsTIIα.

Shugoshin 1 plays a central role in kinetochore assembly and is required for kinetochore targeting of Plk1

Physical connection between the sister chromatids is mediated by the cohesin protein complex. During prophase, cohesin is removed from the chromosome arms while the centromeres remain united. Shugoshin1 (Sgo1) is required for maintenance of centromeric cohesion from prophase to the metaphase-anaphase transition. Furthermore, Sgo1 has been proposed to regulate kinetochore microtubule stability and sense interkinetochore tension, two tasks which are tightly coupled with the function of the Chromosomal Passenger Complex (CPC) and Polo-like kinase 1 (Plk1). Here we show that depletion or chemical inhibition of Aurora B kinase (AurB), the catalytic subunit of the CPC, disrupts accumulation of Sgo1 on the kinetochores in HeLa cells and causes Sgo1 to localize on the chromosome arms. RNAi assays show that depletion of Sgo1 did not affect AurB localization but diminished Plk1 kinetochore binding. Furthermore, we demonstrate that vertebrate Sgo1 is phosphorylated by both AurB and Plk1 in vitro. The data presented here includes an extensive analysis of kinetochore targeting interdependencies of mitotic proteins that propose a novel branch in kinetochore assembly where Sgo1 and Plk1 have central roles. Furthermore our studies implicate Sgo1 in the tension sensing mechanism of the spindle checkpoint by regulating Plk1 kinetochore affinity.

The dephosphorylated form of the anaphase-promoting complex protein Cdc27/Apc3 concentrates on kinetochores and chromosome arms in mitosis.

Cell cycle regulated protein ubiquitination and degradation within subcellular domains may be essential for the normal progression of mitosis. Cdc27 is a conserved component of an essential M-phase ubiquitin-protein ligase called the anaphase-promoting complex/cyclosome. We examined the subcellular distribution of Cdc27 in greater detail in mammalian cells and found Cdc27 concentrated at spindle poles and on spindle microtubules as previously described, but also found Cdc27 at kinetochores and along chromosome arms. This localization was not dependent on intact microtubules. While the great majority of Cdc27 protein in M phase cells is highly phosphorylated, only the dephosphorylated form of Cdc27 was found associated with isolated chromosomes. Kinases that also associate with isolated chromosomes catalyzed the in vitro phosphorylation of the chromosome-associated Cdc27. Microinjection of anti-Cdc27 antibody into cells causes arrest at metaphase. Microinjection of cells with anti-Mad2 antibody normally induces premature anaphase onset resulting in catastrophic nondisjunction of the chromosomes. However, coinjection of anti-Cdc27 antibody with anti-Mad2 antibody resulted in metaphase arrest. The association of dephosphorylated APC/C components with mitotic chromosomes suggests mechanisms by which the spindle checkpoint may regulate APC/C activity at mitosis. Key Words: Centromere, Ubiquitin, Checkpoint, Cell cycle, Proteasome

The spindle checkpoint of Saccharomyces cerevisiae responds to separable microtubule-dependent events

The spindle checkpoint regulates microtubule-based chromosome segregation and helps to maintain genomic stability [1,2]. Mutational inactivation of spindle checkpoint genes has been implicated in the progression of several types of human cancer. Recent evidence from budding yeast suggests that the spindle checkpoint is complex. Order-of-function experiments have defined two separable pathways within the checkpoint. One pathway, defined by MAD2, controls the metaphase-to-anaphase transition and the other, defined by BUB2, controls the exit from mitosis [3-6]. The relationships between the separate branches of the checkpoint, and especially the events that trigger the pathways, have not been defined. We localized a Bub2p-GFP fusion protein to the cytoplasmic side of the spindle pole body and used a kar9 mutant to show that cells with misoriented spindles are arrested in anaphase of mitosis. We used a kar9 bub2 double mutant to show that the arrest is BUB2 dependent. We conclude that the separate pathways of the spindle checkpoint respond to different classes of microtubules. The MAD2 branch of the pathway responds to kinetochore microtubule interactions and the BUB2 branch of the pathway operates within the cytoplasm, responding to spindle misorientation.