Sorting Nexin 9 Recruits Clathrin Heavy Chain to the Mitotic Spindle for Chromosome Alignment and Segregation

Sorting nexin 9 (SNX9) and clathrin heavy chain (CHC) each have roles in mitosis during metaphase. Since the two proteins directly interact for their other cellular function in endocytosis we investigated whether they also interact for metaphase and operate on the same pathway. We report that SNX9 and CHC functionally interact during metaphase in a specific molecular pathway that contributes to stabilization of mitotic spindle kinetochore (K)-fibres for chromosome alignment and segregation. This function is independent of their endocytic role. SNX9 residues in the clathrin-binding low complexity domain are required for CHC association and for targeting both CHC and transforming acidic coiled-coil protein 3 (TACC3) to the mitotic spindle. Mutation of these sites to serine increases the metaphase plate width, indicating inefficient chromosome congression. Therefore SNX9 and CHC function in the same molecular pathway for chromosome alignment and segregation, which is dependent on their direct association.     

Late mitotic functions of Aurora kinases

The coordination between late mitotic events such as poleward chromosome motion, spindle elongation, DNA decondensation, and nuclear envelope reformation (NER) is crucial for the completion of chromosome segregation at the anaphase-telophase transition. Mitotic exit is driven by a decrease of Cdk1 kinase activity and an increase of PP1/PP2A phosphatase activities. More recently, Aurora kinases have also emerged as master regulators of late mitotic events and cytokinesis. Aurora A is mainly associated with spindle poles throughout mitosis and midbody during telophase, whereas Aurora B re-localizes from centromeres in early mitosis to the spindle midzone and midbody as cells progress from anaphase to the completion of cytokinesis. Functional studies, together with the identification of a phosphorylation gradient during anaphase, established Aurora B as a major player in the organization of the spindle midzone and in the spatiotemporal coordination between chromosome segregation and NER. Aurora A has been less explored, but a cooperative role in spindle midzone stability has also been proposed, implying that both Aurora A and B contribute to accurate chromosome segregation during mitotic exit. Here, we review the roles of the Aurora kinases in the regulation of late mitotic events and discuss how they work together with other mitotic players to ensure an error-free mitosis.     

Phosphorylation of dynamin II at serine-764 is associated with cytokinesis

Calcineurin is a phosphatase that is activated at the last known stage of mitosis, abscission. Among its many substrates, it dephosphorylates dynamin II during cytokinesis at the midbody of dividing cells. However, dynamin II has several cellular roles including clathrin-mediated endocytosis, centrosome cohesion and cytokinesis. It is not known whether dynamin II phosphorylation plays a role in any of these functions nor have the phosphosites involved in cytokinesis been directly identified. We now report that dynamin II from rat lung is phosphorylated to a low stoichiometry on a single major site, Ser-764, in the proline-rich domain. Phosphorylation on Ser-764 also occurred in asynchronously growing HeLa cells and was greatly increased upon mitotic entry. Tryptic phospho-peptides isolated by TiO₂ chromatography revealed only a single phosphosite in mitotic cells. Mitotic phosphorylation was abolished by roscovitine, suggesting the mitotic kinase is cyclin-dependent kinase 1. Cyclin-dependent kinase 1 phosphorylated full length dynamin II and Glutathione-S-Transferase-tagged-dynamin II-proline-rich domain in vitro, and mutation of Ser-764 to alanine reduced proline-rich domain phosphorylation by 80%, supporting that there is only a single major phosphosite. Ser-764 phosphorylation did not affect clathrin-mediated endocytosis or bulk endocytosis using penetratin-based phospho-deficient or phospho-mimetic peptides or following siRNA depletion/rescue experiments. Phospho-dynamin II was enriched at the mitotic centrosome, but this targeting was unaffected by the phospho-deficient or phospho-mimetic peptides. In contrast, the phospho-mimetic peptide displaced endogenous dynamin II, but not calcineurin, from the midbody and induced cytokinesis failure. Therefore, phosphorylation of dynamin II primarily occurs on a single site that regulates cytokinesis downstream of calcineurin, rather than regulating endocytosis or centrosome function.     

Endocytic traffic in animal cell cytokinesis

Cytokinesis is the final step of mitosis whereby two daughter cells physically separate. It is initiated by the assembly of an actomyosin contractile ring at the mitotic cell equator, which constricts the cytoplasm between the two reforming nuclei resulting in the formation of a narrow intercellular bridge filled with central spindle microtubule bundles. Cytokinesis terminates with the cleavage of the intercellular bridge in a poorly understood process called abscission. Recent work has highlighted the importance of membrane trafficking events occurring from membrane compartments flanking the bridge to the central midbody region. In particular, polarized delivery of endocytic recycling membranes is essential for completion of animal cell cytokinesis. Why endocytic traffic occurs within the intercellular bridge remains largely mysterious and its significance for cytokinesis will be discussed.     

Function and regulation of Aurora／Ipllp kinase family in cell division

During mitosis,the parent cell distributes its genetic materials equally into two daughter cells through chromosome segregation,a complex movements orchestrated by mitotic kinases and its effector proteins.Faithful chromosome segregation and cytokinesis ensure that each daughter cell receives a full copy of genetic materials of parent cell.Defects in these processes can lead to aneuploidy or polyploidy.Aurora/Ipllp family, a class of conserved serine/threonine kinases,plays key roles in chromosome segregation and cytokinesis.This article highlights the function and regulation of Aurora/Ipllp family in mitosis and provides potential links between aberrant regulation of Aurora/Ipllp kinases and pathogenesis of human cancer.     

Role of chromosomal passenger complex in chromosome segregation and cytokinesis

Chromosomal passenger proteins associate with chromosomes early in mitosis and transfer to the spindle at ana/telophase. Recent results show that aurora B/AIM-1 (aurora and Ipl1-like midbody-associated protein kinase), which is responsible for mitotic histone H3 phosphorylation, INCENP (Inner Centromere protein) and Survivin/BIR are in a macromolecular complex as novel chromosomal passenger proteins. Aurora B/AIM-1 can bind to Survivin and the C-terminal region of INCENP, respectively, and colocalizes with both proteins to the centromeres, midzone and midbody. Disruption of either aurora B/AIM-1 or INCENP function leads to sever defects in chromosome segregation and cytokinesis. Moreover, the formation of the central spindle through anaphase to cytokinesis is also disrupted severely. These data suggest that chromosomal passenger complex is required for proper chromosome segregation by phosphorylating histone H3, and cytokinesis by ensuring the correct assembly of the midzone and midbody microtubule. Chromosomal passenger protein complex may couple chromosome segregation with cytokinesis.     

Epsin: inducing membrane curvature

Epsin was originally discovered by virtue of its binding to another accessory protein, Eps15. Members of the epsin family play an important role as accessory proteins in clathrin-mediated endocytosis. Epsin isoforms have been described that differ in intracellular site of action and/or in tissue distribution, although all epsins essentially contribute to membrane deformation. Besides inducing membrane curvature, epsin also plays a key function as adaptor protein, coupling various components of the clathrin-assisted uptake and fulfils an important role in selecting and recognizing cargo. Furthermore, epsin possesses the ability to block vesicle formation during mitosis. To perform all these functions, epsin, apart from interacting with PtdIns(4,5)P2 via its ENTH domain, also engages in several protein interactions with different components of the clathrin-mediated endocytic system. Recently, RNA interference has successfully been exploited to generate a cell line constitutively silencing epsin expression, which can be used to study internalization of multiple ligands.     

Endocytosis resumes during late mitosis and is required for cytokinesis

Recent work has underscored the importance of membrane trafficking events during cytokinesis. For example, targeted membrane secretion occurs at the cleavage furrow in animal cells, and proteins that regulate endocytosis also influence the process of cytokinesis. Nonetheless, the prevailing dogma is that endosomal membrane trafficking ceases during mitosis and resumes after cell division is complete. In this study, we have characterized endocytic membrane trafficking events that occur during mammalian cell cytokinesis. We have found that, although endocytosis ceases during the early stages of mitosis, it resumes during late mitosis in a temporally and spatially regulated pattern as cells progress from anaphase to cytokinesis. Using fixed and live cell imaging, we have found that, during cleavage furrow ingression, vesicles are internalized from the polar region and subsequently trafficked to the midbody area during later stages of cytokinesis. In addition, we have demonstrated that cytokinesis is inhibited when clathrin-mediated endocytosis is blocked using a series of dominant negative mutants. In contrast to previous thought, we conclude that endocytosis resumes during the later stages of mitosis, before cytokinesis is completed. Furthermore, based on our findings, we propose that the proper regulation of endosomal membrane traffic is necessary for the successful completion of cytokinesis.     

Unusual structural organization of the endocytic proteins AP180 and epsin 1.

Epsin and AP180/CALM are important endocytic accessory proteins that are believed to be involved in the formation of clathrin coats. Both proteins associate with phosphorylated membrane inositol lipids through their epsin N-terminal homology domains and with other components of the endocytic machinery through short peptide motifs in their carboxyl-terminal segments. Using hydrodynamic and spectroscopic methods, we demonstrate that the parts of epsin 1 and AP180 that are involved in protein-protein interactions behave as poorly structured flexible polypeptide chains with little or no conventional secondary structure. The predominant cytosolic forms of both proteins are monomers. Furthermore, we show that recombinant epsin 1, like AP180, drives in vitro assembly of clathrin cages. We conclude that the epsin N-terminal homology domain-containing proteins AP180/CALM and epsin 1 have a very similar molecular architecture that is designed for the rapid and efficient recruitment of the principal coat components clathrin and AP-2 at the sites of coated pit assembly.     

Interaction between Epsin/Yap180 adaptors and the scaffolds Ede1/Pan1 is required for endocytosis

The spatial and temporal regulation of the interactions among the approximately 60 proteins required for endocytosis is under active investigation in many laboratories. We have identified the interaction between monomeric clathrin adaptors and endocytic scaffold proteins as a critical prerequisite for the recruitment and/or spatiotemporal dynamics of endocytic proteins at early and late stages of internalization. Quadruple deletion yeast cells (DeltaDeltaDeltaDelta) lacking four putative adaptors, Ent1/2 and Yap1801/2 (homologues of epsin and AP180/CALM proteins), with a plasmid encoding Ent1 or Yap1802 mutants, have defects in endocytosis and growth at 37 degrees C. Live-cell imaging revealed that the dynamics of the early- and late-acting scaffold proteins Ede1 and Pan1, respectively, depend upon adaptor interactions mediated by adaptor asparagine-proline-phenylalanine motifs binding to scaffold Eps15 homology domains. These results suggest that adaptor/scaffold interactions regulate transitions from early to late events and that clathrin adaptor/scaffold protein interaction is essential for clathrin-mediated endocytosis.     

The endocytic adaptor protein ARH associates with motor and centrosomal proteins and is involved in centrosome assembly and cytokinesis

Numerous proteins involved in endocytosis at the plasma membrane have been shown to be present at novel intracellular locations and to have previously unrecognized functions. ARH (autosomal recessive hypercholesterolemia) is an endocytic clathrin-associated adaptor protein that sorts members of the LDL receptor superfamily (LDLR, megalin, LRP). We report here that ARH also associates with centrosomes in several cell types. ARH interacts with centrosomal (gamma-tubulin and GPC2 and GPC3) and motor (dynein heavy and intermediate chains) proteins. ARH cofractionates with gamma-tubulin on isolated centrosomes, and gamma-tubulin and ARH interact on isolated membrane vesicles. During mitosis, ARH sequentially localizes to the nuclear membrane, kinetochores, spindle poles and the midbody. Arh(-/-) embryonic fibroblasts (MEFs) show smaller or absent centrosomes suggesting ARH plays a role in centrosome assembly. Rat-1 fibroblasts depleted of ARH by siRNA and Arh(-/-) MEFs exhibit a slower rate of growth and prolonged cytokinesis. Taken together the data suggest that the defects in centrosome assembly in ARH depleted cells may give rise to cell cycle and mitotic/cytokinesis defects. We propose that ARH participates in centrosomal and mitotic dynamics by interacting with centrosomal proteins. Whether the centrosomal and mitotic functions of ARH are related to its endocytic role remains to be established.     

Caenorhabditis elegans TLK-1 controls cytokinesis by localizing AIR-2/Aurora B to midzone microtubules

Defects in chromosome condensation, segregation or cytokinesis during mitosis disrupt genome integrity and cause organismal death or tumorigenesis. The conserved kinase AIR-2/Aurora B is required for normal execution of all these important mitotic events in Caenorhabditis elegans. TLK-1 has been recently shown to be a substrate and activator of AIR-2 in the presence of another AIR-2 activator ICP-1/INCENP, and to cooperate with AIR-2 to ensure proper mitotic chromosome segregation. However, whether TLK-1 may contribute to chromosome condensation or cytokinesis is unclear. A time-lapse microscopy analysis showed that tlk-1 mutants are defective in chromosome condensation and cytokinesis, in addition to chromosome segregation, during mitosis. Our data indicate that TLK-1 contributes to chromosome condensation and segregation, at least in part, in a manner that is distinct from the ICP-1-mediated mechanism and does not involve loading AIR-2 or condensin proteins to mitotic chromosomes. Moreover, TLK-1 functions in cytokinesis by localizing AIR-2 to the midzone microtubules. The localization pattern of TLK-1 is different from those of ICP-1 and AIR-2, revealing differences in dynamic regulation and association of TLK-1 and ICP-1 towards AIR-2 in vivo. Interestingly, human TLK2 could functionally substitute for tlk-1, suggesting that the mitotic roles of TLK members might be evolutionarily conserved.     

Cell cycle control of spindle elongation

Different organisms employ a variety of strategies to segregate their chromosomes during mitosis. Despite these differences, however, the basic regulatory principles that govern this intricate process are evolutionarily conserved. Above all, rapid dephosphorylation of mitotic phosphoproteins upon the metaphase-to-anaphase transition has proven to be essential for proper function of the mitotic spindle and accurate chromosome segregation in all eukaryotes. Recently, a central midzone component, the microtubule crosslinker Ase1/PRC1 (anaphase spindle elongation 1/protein regulating cytokinesis 1), was uncovered as a universal target of such control mechanism. Depending on its phosphorylation status, Ase1 either restrains spindle elongation in metaphase or promotes it after anaphase onset via recruitment of kinesin motor proteins to the midzone. Here we discuss the potential role of Ase1/PRC1 as a central regulatory platform that interconnects distinct functions of the midzone such as spindle stability, spindle elongation and cytokinesis. Additionally, we provide a comparative overview of the chromosome segregation strategies used by the main model organisms.     

Protein phosphorylation is required for endocytosis in nerve terminals: potential role for the dephosphins dynamin I and synaptojanin, but not AP180 or amphiphysin

Dynamin I and at least five other nerve terminal proteins, amphiphysins I and II, synaptojanin, epsin and eps15 (collectively called dephosphins), are coordinately dephosphorylated by calcineurin during endocytosis of synaptic vesicles. Here we have identified a new dephosphin, the essential endocytic protein AP180. Blocking dephosphorylation of the dephosphins is known to inhibit endocytosis, but the role of phosphorylation has not been determined. We show that the protein kinase C (PKC) antagonists Ro 31-8220 and Go 7874 block the rephosphorylation of dynamin I and synaptojanin that occurs during recovery from an initial depolarizing stimulus (S1). The rephosphorylation of AP180 and amphiphysins 1 and 2, however, were unaffected by Ro 31-8220. Although these dephosphins share a single phosphatase, different protein kinases phosphorylated them after nerve terminal stimulation. The inhibitors were used to selectively examine the role of dynamin I and/or synaptojanin phosphorylation in endocytosis. Ro 31-8220 and Go 7874 did not block the initial S1 cycle of endocytosis, but strongly inhibited endocytosis following a second stimulus (S2). Therefore, phosphorylation of a subset of dephosphins, which includes dynamin I and synaptojanin, is required for the next round of stimulated synaptic vesicle retrieval.     

Mitotic phosphorylation of the peripheral Golgi protein Nir2 by Cdk1 provides a docking mechanism for Plk1 and affects cytokinesis completion

The rearrangement of the Golgi apparatus during mitosis is regulated by several protein kinases, including Cdk1 and Plk1. Several peripheral Golgi proteins that dissociate from the Golgi during mitosis are implicated in regulation of cytokinesis or chromosome segregation, thereby coordinating mitotic and cytokinetic events to Golgi rearrangement. Here we show that, at the onset of mitosis, Cdk1 phosphorylates the peripheral Golgi protein Nir2 at multiple sites; of these, S382 is the most prominent. Phosphorylation of Nir2 by Cdk1 facilitates its dissociation from the Golgi apparatus, and phospho-Nir2(pS382) is localized in the cleavage furrow and midbody during cytokinesis. Mitotic phosphorylation of Nir2 is required for docking of the phospho-Ser/Thr binding module, the Polo box domain of Plk1, and overexpression of a Nir2 mutant, which fails to interact with Plk1, affects the completion of cytokinesis. These results demonstrate a mechanism for coordinating mitotic and cytokinetic events with Golgi rearrangement during cell division.     

Chromosomal passengers and the (aurora) ABCs of mitosis

Chromosomal passengers are proteins that move from centromeres to the spindle midzone during mitosis. Recent experiments show that the passengers inner centromere protein (INCENP) and aurora-B kinase are in a macromolecular complex that might also contain a third passenger, survivin. The chromosomal passenger complex functions throughout mitosis in chromosome condensation and segregation, and at the end of mitosis, in the completion of cytokinesis.     

Septin1, a new interaction partner for human serine/threonine kinase aurora-B

Several families of kinases work together to ensure the rate and precision of mitosis. Aurora-B is an important serine/threonine kinase required for chromosome segregation and cytokinesis. Identification of Aurora-B substrates will help to enhance our understanding of the molecular mechanism of mitosis. Through a yeast two-hybrid screen, we found a novel partner of Aurora-B, Septin1, belonging to a conserved family of GTPase proteins that localize to the cleavage furrow and are involved in cytokinesis. We confirmed this interaction using Co-immunoprecipitation experiments in mammalian cells and GST-pull-down analysis in vitro. Moreover, Aurora-B can phosphorylate Septin1 in vitro. We identified that Ser248, Ser307, and Ser315 are the main phosphorylation sites in Septin1. These two proteins partially co-localize to the midbody during cytokinesis. So, it is possible that Septin1's role in the regulation of cytokinesis is related to its phosphorylation by Aurora-B. Unlike previous reports that Septins function in cytokinesis and localize to the cleavage furrow, we found that Septin1 localizes to the spindle pole throughout mitosis, indicating that Septin1 may function in chromosome segregation as well.