Novel interactions of fission yeast kinesin 8 revealed through in vivo expression of truncation alleles

Fission yeast expresses two kinesin 8s, klp5+ and klp6+, which are important for diverse cellular functions: mitosis, meiosis, and the maintenance of normal cell morphology. During vegetative growth these motors display complex localization patterns, moving from the cytoplasm during interphase to the kinetochores in early mitosis, the interpolar spindle in anaphase B, and then back into the cytoplasm. We have expressed GFP-tagged alleles of domains from these motors, seeking the signals required for their localizations. The tail of Klp5p localized to the interphase nucleus, more specifically to telomeres. Addition of the neck re-directed this fragment to microtubules in the cytoplasm. Klp6-tail and the neck-tail domains of both motors localized at microtubule ends. Klp6-neck-tail localized to the spindle in early mitosis but to the pole-proximal ends of the spindle in anaphase B. The Klp5-motor and motor-neck localized to microtubules, often causing them to bundle. Over-expression of Klp6-motor or motor-neck resulted in shorter microtubules. These localization patterns were no different when constructs were expressed in strains lacking either or both of the endogenous, full-length proteins. Our results indicate that the localization signals for these kinesins are not derived from simple amino acid sequences but from complex interactions among multiple domains of each motor.     

Plk is an M-phase-specific protein kinase and interacts with a kinesin-like protein, CHO1/MKLP-1.

PLK (STPK13) encodes a murine protein kinase closely related to those encoded by the Drosophila melanogaster polo gene and the Saccharomyces cerevisiae CDC5 gene, which are required for normal mitotic and meiotic divisions. Affinity-purified antibody generated against the C-terminal 13 amino acids of Plk specifically recognizes a single polypeptide of 66 kDa in MELC, NIH 3T3, and HeLa cellular extracts. The expression levels of both poly(A)+ PLK mRNA and its encoded protein are most abundant about 17 h after serum stimulation of NIH 3T3 cells. Plk protein begins to accumulate at the S/G2 boundary and reaches the maximum level at the G2/M boundary in continuously cycling cells. Concurrent with cyclin B-associated cdc2 kinase activity, Plk kinase activity sharply peaks at the onset of mitosis. Plk enzymatic activity gradually decreases as M phase proceeds but persists longer than cyclin B-associated cdc2 kinase activity. Plk is localized to the area surrounding the chromosomes in prometaphase, appears condensed as several discrete bands along the spindle axis at the interzone in anaphase, and finally concentrates at the midbody during telophase and cytokinesis. Plk and CHO1/mitotic kinesin-like protein 1 (MKLP-1), which induces microtubule bundling and antiparallel movement in vitro, are colocalized during late M phase. In addition, CHO1/MKLP-1 appears to interact with Plk in vivo and to be phosphorylated by Plk-associated kinase activity in vitro.     

Human Shugoshin Mediates Kinetochore-Driven Formation of Kinetochore Microtubules

The conserved protein Shugoshin (Sgo) plays a role in the maintenance of centromeric cohesion in mitosis and meiosis. Human Shugoshin (hSgo) was first identified as an overexpressed protein in breast cancers. Here we demonstrate that hSgo mediates kinetochore-driven formation of kinetochore microtubules (MTs) during bipolar spindle assembly. The regulated overexpression of full-length hSgo, or of truncated proteins containing both the conserved N-terminal coiled-coil domain and C-terminal basic domain, resulted in hSgo localization at centromere at early mitosis and was associated with aberrant nucleation and formation of bundles of kinetochore MTs. The mid-portion of hSgo, between the N- and C-terminal domains, includes both a functional domain for centromeric cohesion and a regulatory domain for spindle assembly. The cells overexpressing natural alternative splicing isoforms, which are almost completely defective for the mid-portion of the hSgo protein, showed premature centromere separation (PCS) and aberrant MT connections. These isoforms are mildly overexpressed in HEK293 cells. On the other hand, cells expressing a truncated protein, defective in the lysine-rich region of the mid-portion, arrested at mitosis due to persistent abnormal MT connections and not because of PCS. Aberrant MT connections were predominantly observed in spindle regions where chromosomes were clustered. Interestingly, we also found that hSgo is rapidly exchanged at kinetochores at early mitosis. Based on these results, we conclude that hSgo may be diffusible and have a role in proper kinetochores-MTs attachment.     

Schizosaccharomyces pombe Bir1p, a nuclear protein that localizes to kinetochores and the spindle midzone, is essential for chromosome condensation and spindle elongation during mitosis

The inhibitor of apoptosis (IAP) family of proteins contains a subset of members characterized by the presence of highly conserved baculoviral IAP repeat (BIR) domains. Recent work has shown that some of these BIR-domain proteins play a prominent role in the regulation of cell division, in particular at the stage of chromosome segregation and cytokinesis. We and others have shown that the Schizosaccharomyces pombe BIR-domain protein, Bir1p/Pbh1p/Cut17p, is important for the regulation of mitosis. Here we further characterize S. pombe Bir1p using methods of cell biology and genetics. We show that Bir1p is dispersed throughout the nucleus during the cell cycle. In addition, a significant part of Bir1p is also detected at the kinetochores and the spindle midzone during mitosis and meiosis. Time-lapse microscopy studies suggest that Bir1p relocates from the kinetochores to the spindle at the end of anaphase A. Bir1p colocalizes with the S. pombe Aurora kinase homolog Aim1p, a protein essential for mitosis, at the kinetochores as well as the spindle midzone during mitosis, and functional Bir1p is essential for localization of Aim1p to the kinetochores and the spindle midzone. Analyses of bir1 conditional mutants revealed that Bir1p is essential for chromosome condensation during mitosis. In addition, anaphase cells show the presence of lagging chromosomes and a defect in spindle elongation. We conclude that Bir1p is important for multiple processes that occur during mitosis in S. pombe.     

The microtubule-destabilizing kinesin XKCM1 is required for chromosome positioning during spindle assembly

Xenopus kinesin catastrophe modulator-1 (XKCM1) is a Kin I kinesin family member that uses the energy of ATP hydrolysis to depolymerize microtubules. We demonstrated previously that XKCM1 is essential for mitotic-spindle assembly in vitro and acts by regulating microtubule dynamics as a pure protein, in extracts and in cells. A portion of the XKCM1 pool is specifically localized to centromeres during mitosis and may be important in chromosome movement. To selectively analyze the function of centromere-bound XKCM1, we generated glutathione-S-transferase (GST) fusion proteins containing the N-terminal globular domain (GST-NT), the centrally located catalytic domain (GST-CD), and the C-terminal alpha-helical tail (GST-CT) of XKCM1. The GST-NT protein targeted to centromeres during spindle assembly, suggesting that the N-terminal domain of XKCM1 is sufficient for centromere localization. Addition of GST-NT prior to or after spindle assembly replaced endogenous XKCM1, indicating that centromere targeting is a dynamic process. Loss of endogenous XKCM1 from centromeres caused a misalignment of chromosomes on the metaphase plate without affecting global spindle structure. These results suggest that centromere bound XKCM1 has an important role in chromosome positioning on the spindle.     

The mitotic checkpoint gene BubR1 has two distinct functions in mitosis

BubR1 is one of two putative vertebrate homologs of the yeast spindle checkpoint protein Bub1. We have used deletion and point mutants to elucidate the functions of BubR1 in mitosis. The nocodazole-activated spindle checkpoint of HeLa cells was disrupted by expression of a 39 amino acid fragment (residues 382-420) of BubR1 containing the Bub3-binding GLEBS motif. In contrast, we observed normal checkpoint function in a truncation mutant comprising residues 1-477, despite the lack of the C-terminal BubR1 kinase domain. In the absence of nocodazole, expression of the 477 amino acid fragment slowed progress through prometaphase of mitosis, causing accumulation of mitotic cells. This accumulation was also seen in a kinase dead mutant. The prolongation of mitosis required both kinetochore binding and an intact, functional spindle checkpoint. The prolongation of mitosis by kinase deficient BubR1 constructs indicates a crucial role for the BubR1 C-terminal kinase domain in chromosome movement, in addition to the role of the N-terminus in the checkpoint.     

Properties of the nonhelical end domains of vimentin suggest a role in maintaining intermediate filament network structure

To investigate the functional role of the nonhelical domains of the intermediate filament (IF) protein vimentin, we carried out transient transfection of constructs encoding fusion proteins of these domains with enhanced green fluorescent protein (EGFP). Expression of these fusion proteins did not have any effect on the endogenous IF networks of transfected cells. However, the head domain-EGFP fusion protein localized almost exclusively to the nucleus. This localization could be disrupted in a reversible fashion by chilling cells. Furthermore, the head domain was capable of targeting to the nucleus a strictly cytoplasmic protein, pyruvate kinase. Thus, the vimentin head domain contains information that specifically directs proteins into the nucleus. In contrast, the nonhelical tail domain of vimentin, when expressed as a fusion protein with EGFP, was retained in the cytoplasm. Cytoplasmic retention of tail domain-containing fusion proteins appeared to be dependent on the integrity of the microtubule network. Our results are consistent with a proposal that the nonhelical end domains of vimentin are involved in maintaining an extended IF network by exerting oppositely directed forces along the filaments. The head domains exert a nuclear-directed force while the tail domains extend the IF network toward the cell periphery via a microtubule-dependent mechanism.     

The human kinesin-like protein RB6K is under tight cell cycle control and is essential for cytokinesis

Several members of the kinesin superfamily are known to play a prominent role in the motor-driven transport processes that occur in mitotic cells. Here we describe a new mitotic human kinesin-like protein, RB6K (Rabkinesin 6), distantly related to MKLP-1. Expression of RB6K is regulated during the cell cycle at both the mRNA and protein level and, similar to cyclin B, shows a maximum during M phase. Isolation of the RB6K promoter allowed identification of a CDE-CHR element and promoter activity was shown to be maximal during M phase. Immunofluorescence microscopy using antibodies raised against RB6K showed a weak signal in interphase Golgi but a 10-fold higher signal in prophase nuclei. During M phase, the newly synthesized RB6K does not colocalise with Rab6. In later stages of mitosis RB6K localized to the spindle midzone and appeared on the midbodies during cytokinesis. The functional significance of this localization during M phase was revealed by antibody microinjection studies which resulted exclusively in binucleate cells, showing a complete failure of cytokinesis. These results substantiate a crucial role for RB6K in late anaphase B and/or cytokinesis, clearly distinct from the role of MKLP-1.     

Distribution of cytoskeletal proteins sharing a conserved phosphorylated epitope

A group of antigens related by their reactivity with monoclonal antibodies MPM-1 and MPM-2 appear as cells enter mitosis. These antibodies bind to a phosphorylated epitope on certain proteins, and therefore the antigens are presumed to be a group of phosphoproteins. A subset of these proteins has been shown previously to be components of mitotic microtubule organizing centers in PtK1 cells. We present here evidence that the mitosis-specific appearance of these phosphoproteins is a phenomenon common to all eukaryotic cells. The MPM reactive phosphoproteins were localized to mitotic spindle poles regardless of whether the spindle formed in the cytoplasm after nuclear envelope breakdown (open mitosis) or within the nucleus (closed mitosis). This reactivity was not dependent upon the presence of centrioles at the spindle poles. Proteins that contained the phosphorylated epitope were not, however, restricted to mitotic cells. Cells of neuronal derivation and flagellated cells showed specific localization of MPM antibody to the microtubule network and basal bodies respectively. On immunoblots, the MPM antibody reacted with brain MAP-1 among a number of other phosphoproteins. The identification of microtubule-associated protein (MAP)-1 correlates with the localization of the antibody to microtubules of neuroblastoma cells. These results suggest, that different phosphoprotein molecules detected by the MPM antibody may be specific for different mitotic microtubule organizing centers, basal bodies, and other specialized cytoskeletal structures; and the presence of a related phosphorylated domain on these proteins may be important for their proper function and/or interaction with microtubules.     

Cell-cycle-dependent cortical localization of pEg3 protein kinase in Xenopus and human cells

BACKGROUND INFORMATION: Protein kinase pEg3 belongs to the evolutionarily conserved KIN1/PAR-1/MARK family, whose members are involved in a variety of functions, including cell polarity, microtubule stability, intracellular signalling and the cell cycle. Activity and phosphorylation of pEg3 are cell-cycle dependent and rise to maximum levels during mitosis. pEg3 was shown to interact with and phosphorylate phosphatase CDC25B, and to potentially control cell-cycle progression. Subcellular localization of pEg3 was investigated in Xenopus and human cultured cells. RESULTS: By expression of GFP (green fluorescent protein)-tagged pEg3 and indirect immunofluorescence with specific antibodies, pEg3 was found to be localized in the cytoplasm and the nucleus in interphase cells. During mitosis pEg3 was also found in the cytoplasm. From anaphase to telophase, a proportion of the protein was detected at the cell cortex. The cortical distribution in mitotic cells was dependent on F-actin, because the actin-depolymerization-inducing drugs cytochalasin D or latrunculin A prevented pEg3 cortical localization. The protein lacking the conserved C-terminal domain was not detected at the cell cortex, whereas the C-terminal domain was targeted to the cell periphery. In contrast with full-length pEg3, the cortical localization of the C-terminal domain and construct lacking the N-terminal domain was cell-cycle independent, and these constructs were found at the cell periphery in interphase cells. CONCLUSIONS: pEg3 is localized at the cell periphery specifically during mitosis. The C-terminal domain is the only pEg3 domain found to be necessary and sufficient for cortical targeting. Cortical distribution of pEg3 also requires the F-actin cytoskeleton. The cell-cycle-independent cortical localization of the pEg3 C-terminal domain and a construct lacking the N-terminal domain indicates that a negative control mechanism involving the pEg3 catalytic N-terminal domain probably acts to prevent pEg3 cortical distribution during interphase. These results suggest that pEg3 might play a role at the cell cortex during mitosis.     

Plant TPX2 and related proteins

At the onset of mitosis, microtubules form a bipolar spindle around the prophase nucleus. TPX2 is phosphorylated during mitosis and acts as a spindle assembly factor that nucleates microtubules in the close vicinity of chromosomes, independent of the centrosomes. Furthermore, it activates the kinase Aurora A and targets the Xenopus kinesin-like protein 2 to spindle poles. We have characterized the plant orthologue of TPX2 that possesses all identified functional domains of its animal counterpart. Moreover, we have demonstrated that it is exported before nuclear envelope breakdown and that its activity around the nuclear envelope is essential for prospindle assembly. Here, we compare the sequences of several characterized TPX2 domains, allowing us to define TPX2. We propose that true TPX2 orthologues share simultaneously all these conserved domains and that other proteins possessing only some of these functional blocks may be considered as TPX2-related proteins.Key words: mitosis, microtubules, spindle assembly, TPX2 signature, targeting domains, Prosite motifs, evolution     

EFHC1, a protein mutated in juvenile myoclonic epilepsy, associates with the mitotic spindle through its N-terminus

A novel gene, EFHC1, mutated in juvenile myoclonic epilepsy (JME) encodes a protein with three DM10 domains of unknown function and one putative EF-hand motif. To study the properties of EFHC1, we expressed EGFP-tagged protein in various cell lines. In interphase cells, the fusion protein was present in the cytoplasm and in the nucleus with specific accumulation at the centrosome. During mitosis EGFP-EFHC1 colocalized with the mitotic spindle, especially at spindle poles and with the midbody during cytokinesis. Using a specific antibody, we demonstrated the same distribution of the endogenous protein. Deletion analyses revealed that the N-terminal region of EFHC1 is crucial for the association with the mitotic spindle and the midbody. Our results suggest that EFHC1 could play an important role during cell division.     

Role of the C terminus in antigen P1 surface localization in Streptococcus mutans and two related cocci.

The C terminus of the major surface protein P1 from Streptococcus mutans is composed of a hydrophilic domain, an LPNTGV motif, a hydrophobic domain, and a charged tail. These features are shared by surface proteins from many gram-positive coccal bacteria. To investigate the role of the C-terminal domains in antigen P1 surface localization, full-length and truncated P1 gene constructs, which were expressed on the shuttle vector pDL276, were transformed into the P1-negative mutant S. mutans SM3352, Streptococcus gordonii DL-1, and Enterococcus faecalis UV202. Transformants were tested for expression of P1 by enzyme-linked immunosorbent assaying and Western blotting. The results showed that full-length P1 was expressed by transformants of all three bacteria and was localized on the cell surface. A fusion protein composed of the Staphylococcus aureus fibronectin binding protein C terminus and the P1 protein N terminus was found to surface localize in S. mutans. Deletion of the entire C-terminal domains resulted in P1 being expressed in the culture supernatant. A P1 truncation, which carried only the hydrophilic domain at its C terminus, was found partially associated with the cell surface. This truncated P1 was readily removed from the isolated cell wall by hot sodium dodecyl sulfate-mercaptoethanol extraction. In contrast, the full-length P1 remained associated with the isolated cell wall after similar treatment, suggesting covalent linkages between the full-length P1 and the cell wall. The results described above showed that antigen P1 was anchored to the cell wall by its C-terminal domains probably via covalent linkages with the cell wall. The results also support a universal mechanism involving the C-terminal domains for protein surface localization among this group of gram-positive bacteria.     

Membrane targeting and asymmetric localization of Drosophila partner of inscuteable are discrete steps controlled by distinct regions of the protein

Asymmetric division of neural progenitors is a key mechanism by which neuronal diversity in the Drosophila central nervous system is generated. The distinct fates of the daughter cells derived from these divisions are achieved through preferential segregation of the cell fate determinants Prospero and Numb to one of the two daughters. This is achieved by coordinating apical and basal mitotic spindle orientation with the basal cortical localization of the cell fate determinants during mitosis. A complex of apically localized proteins, including Inscuteable (Insc), Partner of Inscuteable (Pins), Bazooka (Baz), DmPar-6, DaPKC, and G alpha i, is required to mediate and coordinate basal protein localization with mitotic spindle orientation. Pins, a molecule which directly interacts with Insc, is a key component required for the integrity of this complex; in the absence of Pins, other components become mislocalized or destabilized, and basal protein localization and mitotic spindle orientation are defective. Here we define the functional domains of Pins. We show that the C-terminal region containing the G alpha i binding GoLoco motifs is necessary and sufficient for targeting to the neuroblast cortex, which appears to be a prerequisite for apical localization of Pins. The N-terminal tetratricopeptide repeat-containing region of Pins is required for two processes; TPR repeats 1 to 3 plus the C-terminal region are required for apical localization but are insufficient to recruit Insc to the apical cortex, whereas TPR repeats 1 to 7 plus C-terminal Pins can perform both functions. Hence, the abilities of Pins to cortically localize, to apically localize, and to restore Insc apical localization are all separable, and all three capabilities are necessary to mediate asymmetric division. Moreover, the need for N-terminal Pins can be obviated by fusing a minimal Insc functional domain with the C-terminal region of Pins; this chimeric molecule is apically localized and can fulfill the functions of both Insc and Pins.     

Nucleotide binding of the C-terminal domains of the major histocompatibility complex-encoded transporter expressed in Drosophila melanogaster cells

The C-terminal domains of the mouse transporter associated with antigen processing (TAP) were expressed as soluble proteins in Drosophila melanogaster cells and labeled by [-³²P]8-azido-ATP after UV-irradiation. The relative potencies of the nucleotides in preventing azido-ATP labeling were in the order of ATP> GTP> CTP> ITP> UTP for both the TAP1 and TAP2 C-terminal domains, suggesting ATP to be the natural substrate of the transporter. Our data provide the first evidence that the individual C-terminal domain of either TAP1 or TAP2 can be expressed as a functional ATP-binding protein.     

The Spindle Midzone Microtubule-Associated Proteins Ase1p and Cin8p Affect the Number and Orientation of Astral Microtubules in Saccharomyces cerevisiae

The nucleus of the budding yeast S. cerevisiae has to move to the bud neck during mitosis in order for proper DNA segregation to take place. This movement is mediated by spindle and astral microtubules, and it relies on forces generated by microtubule-associated motor proteins. When budding yeast cells express the non-cleavable cohesin subunit, Scc1-RRDD, sister chromatid separation is blocked, preventing the spindle from elongating. Thus, in the presence of Scc1-RRDD nuclear positioning is mediated solely by forces acting through astral microtubules. We have previously shown that under these conditions cells exit mitosis with the nucleus in the mother cells, and that the position of the nucleus is determined, at least in part, by the FEAR pathway, which regulates various aspects of mitotic exit. When the FEAR pathway is inactivated, cells expressing Scc1-RRDD exit mitosis with the nucleus in the daughter cells (referred to as a “daughterly phenotype”). In order to find additional proteins that participate in nuclear positioning, we screened a series of mutant strains for those that displayed a daughterly phenotype when Scc1-RRDD was expressed. The most prominent defects were seen in ase1Δ and cin8Δ mutant cells. Both Ase1p and Cin8p were previously shown to be nuclear and to be involved in spindle function. We show here that deletion of ASE1 or CIN8 causes a defect in SPB separation and leads to an abnormal number of astral microtubules and a change in their orientation within the cell. Taken together, these results suggest that in budding yeast Ase1p and Cin8p affect nuclear positioning through astral microtubule-dependent mechanisms.     

An aurora kinase homologue is involved in regulating both mitosis and cytokinesis in Trypanosoma brucei

The chromosomal passenger protein aurora kinases have been implicated in regulating chromosome segregation and cell division. Three aurora kinase homologues were identified (TbAUK1, -2 and -3) in the Trypanosome Genomic Data Base, and their expressions in the procyclic form of Trypanosoma brucei were knocked down individually by using the RNA interference technique. Only a knockdown of TbAUK1 arrested the cells in G(2)/M phase with each cell showing an extended posterior end, two kinetoplasts, and an enlarged nucleus, apparently the result of an inhibited kinetoplast multiplication and a failed mitosis. There is no mitotic spindle structure in the TbAUK1-depleted cell. The two kinetoplasts moved apart from each other but stopped just before cytokinesis, suggesting that cytokinesis was blocked in its early phase. Overexpression of TbAUK1 in the cells resulted in little change in cell growth. By immunofluorescence, TbAUK1 was primarily localized to the nucleus in interphase and to the mitotic spindle during apparent metaphase and anaphase. Thus, differing from other eukaryotes, TbAUK1 has an apparent triple function in coupling mitosis and kinetoplast replication with cytokinesis in T. brucei. T. brucei polo-like kinase, previously identified as the initiator of cytokinesis without apparent involvement in mitosis in the trypanosome, was either depleted or overexpressed in the TbAUK1-deficient cells. A dominant TbAUK1-depleted phenotype was demonstrated in both cases, suggesting that TbAUK1 plays an essential role in cytokinesis that cannot be affected by changes in the level of T. brucei polo-like kinase. To our knowledge, this is the first time that the function of an aurora B-like kinase is a prerequisite for polo-like kinase action in initiating cytokinesis. TbAUK1 is also the first identified protein that couples both mitosis and kinetoplast replication with cytokinesis in the trypanosome.