The gene complement for proteolysis in the cyanobacterium <Emphasis Type="Italic">Synechocystis</Emphasis> sp. PCC 6803 and <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> chloroplasts

The microtubule-organizing center (MTOC) is the organelle that manages the distribution of microtubule filaments in the cell. It includes such centers of microtubule organization as basal bodies, nucleus-associated bodies, spindle pole bodies and centrosomes. The centrosome is the MTOC in most animal cells. Despite the numerous studies that have been published on this organelle over the past 100 years, the protein composition of the animal centrosome remains poorly defined. In order to study the MTOC, many researchers have chosen the budding yeast Saccharomyces cerevisiae as a model organism. This review summarizes the budding yeast MTOC, referred to as the spindle pole body (SPB), including its structure and function, its components and the factors involved in its duplication. Electron microscopy and high-voltage electron tomographic analysis of this organelle have contributed to the understanding of its morphology, whereas analysis by matrix-assisted laser desorption/ionization has played a major role in identifying many of the spindle pole components. In addition, genetic and biochemical studies have revealed the functional and physical relationships of certain spindle pole components and proteins important for SPB duplication.     

Spindle pole body-anchored Kar3 drives the nucleus along microtubules from another nucleus in preparation for nuclear fusion during yeast karyogamy

Nuclear migration during yeast karyogamy, termed nuclear congression, is required to initiate nuclear fusion. Congression involves a specific regulation of the microtubule minus end-directed kinesin-14 motor Kar3 and a rearrangement of the cytoplasmic microtubule attachment sites at the spindle pole bodies (SPBs). However, how these elements interact to produce the forces necessary for nuclear migration is less clear. We used electron tomography, molecular genetics, quantitative imaging, and first principles modeling to investigate how cytoplasmic microtubules are organized during nuclear congression. We found that Kar3, with the help of its light chain, Cik1, is anchored during mating to the SPB component Spc72 that also serves as a nucleator and anchor for microtubules via their minus ends. Moreover, we show that no direct microtubule–microtubule interactions are required for nuclear migration. Instead, SPB-anchored Kar3 exerts the necessary pulling forces laterally on microtubules emanating from the SPB of the mating partner nucleus. Therefore, a twofold symmetrical application of the core principle that drives nuclear migration in higher cells is used in yeast to drive nuclei toward each other before nuclear fusion.     

Deletion of RNQ1 gene reveals novel functional relationship between divergently transcribed Bik1p/CLIP-170 and Sfi1p in spindle pole body separation

Spindle pole body (SPB; the microtubule organizing center in yeast) duplication is essential to form a bipolar spindle. The duplicated SPBs must then separate and migrate to opposite sides of the nucleus. We identified a novel functional relationship in SPB separation between the microtubule stabilizing protein Bik1p/CLIP-170 and the SPB half-bridge protein Sfi1p. A genetic interaction between BIK1 and SFI1 was discovered in a synthetic lethal screen using a strain deficient in the prion protein gene RNQ1. RNQ1 deletion reduced expression from the divergently transcribed BIK1, allowing us to identify genetic interactors with bik1. The sfi1-1 bik1 synthetic lethality was suppressed by over-expression of CIK1, KAR1, and PPH21. Genetic analysis indicated that the sfi1-1 bik1 synthetic lethality was unlikely related to the function of Bik1p in the dynein pathway or to defects in spindle position. Furthermore, a sfi1-1 Δkip2 mutant was viable, suggesting that the Bik1p pool at the cytoplasmic microtubule plus-ends may not be required in sfi1-1. Microscopic examination indicated the sfi1-1 mutant was delayed in SPB duplication, SPB separation, or spindle elongation and the sfi-1 Δbik1 double mutant arrested with duplicated but unseparated SPBs. These results suggest that Bik1p has a previously uncharacterized function in the separation of duplicated SPBs.     

小鼠卵母细胞减数分裂过程中活化Pak1的表达及其与染色体分离的相关性

目的研究活化的Pak1在小鼠卵母细胞减数分裂进程中的表达、亚细胞定位及其与染色体分离的相关性。方法用Western blot方法半定量分析活化的Pak1(~(Ser204)位点磷酸化,pPak1~(Ser204))在小鼠卵母细胞减数分裂各个时期的蛋白表达量;用免疫荧光染色法分析减数分裂进程中pPak1~(Ser204)的亚细胞定位模式及其与纺锤体和微管组织中心(MTOC)的时空相关性。结果 pPak1~(Ser204)在小鼠卵母细胞减数分裂重启时(GVBD)开始表达,其表达量随减数分裂进程逐渐升高,在第一次减数分裂中期(MⅠ)时达到峰值并持续保持至第二次减数分裂中期(MⅡ)。在第一次减数分裂前中期(pro-MⅠ)、MⅠ和MⅡ期,pPak1~(Ser204)与MTOC核心蛋白pericentrin和γ-tubulin共同定位于纺锤体两极,pPak1~(Ser204)同时存在于染色体上;在第一次减数分裂后期(AI)到末期(TelI)进程中pPak1~(Ser204)离开MTOC和染色体,聚集在收缩环部位。结论 pPak1~(Ser204)在卵母细胞减数分裂恢复时开始表达,是一种MTOC相关蛋白,可能通过参与纺锤体结构的形成和维持而调控染色体的分离。     

The Sec14 family glycerophospholipid-transfer protein is required for structural integrity of the spindle pole body during meiosis in fission yeast

The fission yeast spo20+ gene encodes a glycerophospholipid-transfer protein. spo20 mutants are unable to assemble the forespore membrane properly. Here we studied the structural integrity of the spindle pole body (SPB) in spo20-H6 mutants during meiosis. Meiotic cells expressing a GFP-tagged SPB marker protein, Spo15-GFP, showed an excess number of SPBs, some of which were not localized to the spindle poles and were termed 'pseudo-SPBs'. Formation of spindles for meiosis I was significantly delayed in spo20-H6 cells, although the morphology of spindles and segregation of the sister chromatids seemed normal. The SPB of spo20-H6 contained meiosis-specific outer plaques, though outermost layers were less evident. Time-lapse studies of spo20-H6 cells showed that the pseudo-SPBs originated from normal SPBs at the spindle poles during meiosis I. Among the SPB components tested, Spo15, Spo13, Sad1 and Cut12 were localized to the pseudo-SPBs, but Sid4 was not always present. Alp4, a component of the gamma-tubulin complex, was also present in about 40% of the pseudo-SPBs. The forespore membranes initiated from both the SPBs and the pseudo-SPBs. We conclude that Spo20 plays a role in maintaining the structural integrity of the meiotic SPB, besides supplying membrane vesicles for forespore membrane assembly.     

Dissection of fission yeast microtubule associating protein p93Dis1: regions implicated in regulated localization and microtubule interaction

Background : Fission yeast microtubule associating protein (MAP) p93^Dis1 functions for sister chromatid separation: dis1 mutants fail to separate chromosomes, while the spindle elongates but without cyclin destruction. p93^Dis1 localizes along microtubules in interphase cytoplasm, but shifts to the spindle pole body (SPB) and spindle microtubules upon the entry into mitosis. In this study, regions of p93^Dis1 were dissected to examine their role.
Results : Nitrocellulose filter blotting shows that recombinant Dis1 binds to bovine brain microtubules in vitro . A basic central region rich in S, T and P is essential for this association. However, the whole p93^Dis1 with N- and C-termini containing a conserved repeat motif and heptad repeats, respectively, is necessary for normal microtubule association in vivo . The N-truncated region also binds to microtubules but only to the portions near the SPBs. Overproduction phenotypes indicate that p93^Dis1 greatly affects spindle formation and cell morphogenesis. The central region is essential but, by itself, not sufficient for generating such effects.
Conclusions : We propose that p93^Dis1 consists of three regions which carry distinct properties for localization: the N-region for cell cycle dependent localization, the central region for direct microtubule association, and the C-region for SPB and nuclear localization. The essential role of p93^Dis1 is carried out in the C-region, while the N-region acts as a regulator.     

Cdk1-Clb4 controls the interaction of astral microtubule plus ends with subdomains of the daughter cell cortex

As in many polarized cells, spindle alignment in yeast is essential and cell cycle regulated. A key step that governs spindle alignment is the selective binding of the Kar9 protein to only one of the two spindle pole bodies (SPBs). It has been suggested that cyclin-dependent kinase Cdc28, in complex with cyclin Clb4, associates only with the SPB in the mother cell and so prevents Kar9 binding to this SPB. However, here we show that the nonoverexpressed Clb4 associates with the budward-directed SPB through Kar9. Cdc28-Clb4 then uses Kar9 as a carrier to move from this SPB to the plus ends of astral microtubules, where Cdc28-Clb4 regulates the interactions between microtubule ends and subdomains of the bud cortex. In the absence of Cdc28-Clb4 activity (G1/S phase), astral microtubules interact with the bud tip in a manner dependent on actin, Myo2, and Kar9. Coincidentally with reaching the bud cortex in S phase, Cdc28-Clb4 facilitates the dissociation of the microtubule bud tip interaction and their capture by the bud neck. This transition prevents the preanaphase spindle from becoming prematurely pulled into the bud. Thus, Cdc28-Clb4 facilitates spindle alignment by regulating the interaction of astral microtubules with subdomains of the bud cortex.     

Mps3 SUN domain is important for chromosome motion and juxtaposition of homologous chromosomes during meiosis

In budding yeast, Mps3 is essential for duplicating the spindle pole body (SPB) and is critical for promoting chromosome motion during meiosis. It is a member of the SUN (Sad1-Unc-84) domain family of proteins that localizes to the inner nuclear envelope (NE) in many eukaryotic organisms and preferentially localizes to the SPB in vegetative growth; in meiotic prophase I, it redistributes to many sites within the NE. We constructed an mps3 mutant, mps3-sun, which completely lacks the SUN domain. Surprisingly, the mps3-sun mutation does not disrupt SPB duplication or Mps3 localization to the NE in meiosis. However, it confers several defects during meiotic prophase I including reduced chromosome motion, premature synapsis between homologous chromosomes, and reduced levels of closely juxtaposed homologous loci in pachytene. These findings suggest that in meiosis, the Mps3 SUN domain is important for modulating chromosome motion events that act in meiotic chromosome juxtaposition and by extension, promoting proper morphogenesis of the synaptonemal complex.     

Chromosome segregation in fission yeast with mutations in the tubulin folding cofactor D

Faithful chromosome segregation requires the combined activities of the microtubule-based mitotic spindle and the multiple proteins that form mitotic kinetochores. Here, we show that the fission yeast mitotic mutant, tsm1-512, is an allele of the tubulin folding chaperone, cofactor D. Chromosome segregation in this and in an additional cofactor D mutant depends on growth conditions that are monitored specifically by the mitotic checkpoint proteins Mad1, 2, 3 and Bub3. The temperature-sensitive mutants we have used disrupt the function of cofactor D to different extents, but both strains form a mitotic spindle in which the poles separate in anaphase. However, chromosome segregation is often unequal, apparently due to a defect in kinetochore–microtubule interactions. Mutations in cofactor D render cells particularly sensitive to the expression levels of a CENP-B-like protein, Abp1p, which works as an allele-specific, high-copy suppressor of cofactor D. This and other genetic interactions between cofactor D mutants and specific kinetochore and spindle components suggest their critical role in establishing the normal kinetochore–microtubule interface.Communicated by M. Yamamoto.     

The SESA network links duplication of the yeast centrosome with the protein translation machinery

The yeast spindle pole body (SPB), the functional equivalent of mammalian centrosome, duplicates in G1/S phase of the cell cycle and then becomes inserted into the nuclear envelope. Here we describe a link between SPB duplication and targeted translation control. When insertion of the newly formed SPB into the nuclear envelope fails, the SESA network comprising the GYF domain protein Smy2, the translation inhibitor Eap1, the mRNA-binding protein Scp160 and the Asc1 protein, specifically inhibits initiation of translation of POM34 mRNA that encodes an integral membrane protein of the nuclear pore complex, while having no impact on other mRNAs. In response to SESA, POM34 mRNA accumulates in the cytoplasm and is not targeted to the ER for cotranslational translocation of the protein. Reduced level of Pom34 is sufficient to restore viability of mutants with defects in SPB duplication. We suggest that the SESA network provides a mechanism by which cells can regulate the translation of specific mRNAs. This regulation is used to coordinate competing events in the nuclear envelope.     

The fission yeast SPB component Cut12 links bipolar spindle formation to mitotic control

During fission yeast mitosis, the duplicated spindle pole bodies (SPBs) nucleate microtubule arrays that interdigitate to form the mitotic spindle. cut12.1 mutants form a monopolar mitotic spindle, chromosome segregation fails, and the mutant undergoes a lethal cytokinesis. The cut12⁺ gene encodes a novel 62-kD protein with two predicted coiled coil regions, and one consensus phosphorylation site for p34^cdc2 and two for MAP kinase. Cut12 is localized to the SPB throughout the cell cycle, predominantly around the inner face of the interphase SPB, adjacent to the nucleus. cut12⁺ is allelic to stf1⁺; stf1.1 is a gain-of-function mutation bypassing the requirement for the Cdc25 tyrosine phosphatase, which normally dephosphorylates and activates the p34^cdc2/cyclin B kinase to promote the onset of mitosis. Expressing a cut12⁺ cDNA carrying the stf1.1 mutation also suppressed cdc25.22. The spindle defect in cut12.1 is exacerbated by the cdc25.22 mutation, and stf1.1 cells formed defective spindles in a cdc25.22 background at high temperatures. We propose that Cut12 may be a regulator or substrate of the p34^cdc2 mitotic kinase.     

The evolutionary conserved <Emphasis Type="Italic">BER1</Emphasis> gene is involved in microtubule stability in yeast

In yeast, microtubules are dynamic filaments necessary for spindle and nucleus positioning, as well as for proper chromosome segregation. We identify a function for the yeast gene BER1 (Benomyl REsistant 1) in microtubule stability. BER1 belongs to an evolutionary conserved gene family whose founding member Sensitivity to Red light Reduced is involved in red-light perception and circadian rhythms in Arabidopsis. Here, we present data showing that the ber1Δ mutant is affected in microtubule stability, particularly in presence of microtubule-depolymerising drugs. The pattern of synthetic lethal interactions obtained with the ber1Δ mutant suggests that Ber1 may function in N-terminal protein acetylation. Our work thus suggests that microtubule stability might be regulated through this post-translational modification on yet-to-be determined proteins. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Regulation of Saccharomyces cerevisiae kinetochores by the type 1 phosphatase Glc7p

We have investigated the role of protein phosphorylation in regulation of Saccharomyces cerevisiae kinetochores. By use of phosphatase inhibitors and a type 1 protein phosphatase mutant (glc7-10), we show that the microtubule binding activity, but not the centromeric DNA-binding activity, of the kinetochore complex is regulated by a balance between a protein kinase and the type 1 protein phosphatase (PP1) encoded by the GLC7 gene. glc7-10 mutant cells exhibit low kinetochore-microtubule binding activity in vitro and a high frequency of chromosome loss in vivo. Specifically, the Ndc10p component of the centromere DNA-binding CBF3 complex is altered by the glc7-10 mutation; Ndc10p is hyperphosphorylated in glc7-10 extracts. Furthermore, addition of recombinant Ndc10p reconstitutes the microtubule-binding activity of a glc7-10 extract to wild-type levels. Finally, the glc7-10-induced mitotic arrest is abolished in spindle checkpoint mutants, suggesting that defects in kinetochore-microtubule interactions caused by hyperphosphorylation of kinetochore proteins activate the spindle checkpoint.     

The fission yeast DASH complex is essential for satisfying the spindle assembly checkpoint induced by defects in the inner-kinetochore proteins

Spindle assembly checkpoint (SAC) is an evolutionarily conserved surveillance system for chromosome missegregation. We isolated fission yeast Hos2, a component of the Dam1/DASH complex, as a multicopy suppressor of temperature-sensitive (ts) growth of nnf1-495 mutant that exhibits the minichromosome instability (mis) phenotype, producing lethal aneuploids without prominent mitotic delay. It remains elusive why SAC is satisfied in mis mutants despite the occurrence of missegregation. We found that Hos2 binds to the inner-kinetochore regions in both prometaphase and metaphase. Hos2 is essential for kinetochore localization of Dis1, a microtubule (MT) associated Dis1/XMAP215/TOG family protein that is required for proper MT dynamics. Cells lacking DASH exhibit cold-sensitive (cs) growth with the defective in sister-chromatid disjoining (dis) phenotype, which is characterized by hyper-condensed sister-chromatid pairs and elongated spindle MTs. Although DASH-deficient cells are viable at high temperatures, DASH-deletion transforms all the inner-kinetochore mis mutants so far tested into a constitutively active state of SAC, leading to the dis phenotype. We also discovered that Hos2 over-expression commonly suppresses growth retardation in a variety of inner-kinetochore mutants. These genetic interactions highlight the DASH-action(s) in satisfying SAC when aneuploids are formed during mitosis in the inner-kinetochore-defective mis mutants.     

Identification and characterization of a Jem1p ortholog of Candida albicans: dissection of Jem1p functions in karyogamy and protein quality control in Saccharomyces cerevisiae

Jem1p of yeast Saccharomyces cerevisiae is a J-domain containing co-chaperone (J protein) in the endoplasmic reticulum (ER) lumen. Jem1p is required for nuclear fusion during mating (karyogamy) and functions together with another J protein, Scj1p, in protein folding and quality control in the ER as a partner for the ER Hsp70 (BiP/Kar2p). Candida albicans has a gene encoding a homolog of S. cerevisiae Jem1p, CaJem1p. CaJem1p localized in the ER when expressed in S. cerevisiae, and expression of CaJem1p from a single-copy plasmid suppressed the temperature sensitive growth and the ER quality control defect of the jem1Deltascj1Delta mutant, indicating that CaJem1p is functional in S. cerevisiae. However, CaJem1p suppressed the karyogamy defect of the jem1Deltamutant only when it was over-expressed from a multicopy plasmid. Domain-swapping experiments showed that this was due to the difference between the N-terminal domains of ScJem1p and CaJem1p. The N-terminal domain of ScJem1p is essential for its function and interacts with Nep98p, a component of the spindle pole body involved in karyogamy. Since the interaction of CaJem1p with Nep98p is weaker than that of ScJem1p, the Nep98p-ScJem1p interaction is likely important for promoting karyogamy in S. cerevisiae.     

The highly conserved Ndc80 complex is required for kinetochore assembly,chromosome congression,and spindle checkpoint activity

We show that the Xenopus homologs of Ndc80/Tid3/HEC1 (xNdc80) and Nuf2/MPP1/Him-10 (xNuf2) proteins physically interact in a 190-kD complex that associates with the outer kinetochore from prometaphase through anaphase. Injecting function-blocking antibodies to either xNdc80 or xNuf2 into XTC cells caused premature exit from mitosis without detectable chromosome congression or anaphase movements. Injected cells did not arrest in response to microtubule drugs, showing that the complex is required for the spindle checkpoint. Kinetochores assembled in Xenopus extracts after immunodepletion of the complex did not contain xRod, xZw10, xP150 glued (Dynactin), xMad1, xMad2, xBub1, and xBub3, demonstrating that the xNdc80 complex is required for functional kinetochore assembly. In contrast, function-blocking antibodies did not affect the localization of other kinetochore proteins when added to extracts containing previously assembled kinetochores. These extracts with intact kinetochores were deficient in checkpoint signaling, suggesting that the Ndc80 complex participates in the spindle checkpoint. We also demonstrate that the spindle checkpoint can arrest budding yeast cells lacking Ndc80 or Nuf2, whereas yeast lacking both proteins fail to arrest in mitosis. Systematic deletion of yeast kinetochore genes suggests that the Ndc80 complex has a unique role in spindle checkpoint signaling. We propose that the Ndc80 complex has conserved roles in kinetochore assembly, chromosome congression, and spindle checkpoint signaling.     

The C-terminus of Bfa1p in budding yeast is essential to induce mitotic arrest in response to diverse checkpoint-activating signals

During mitosis, genomic integrity is maintained by the proper coordination of anaphase entry and mitotic exit through mitotic checkpoints. In budding yeast, exit from mitosis is triggered by the activation of the small GTPase Tem1p. Bfa1p in association with Bub2p negatively regulates Tem1p in response to spindle damage, spindle misorientation, and DNA damage, resulting in cell cycle arrest. To delineate the Bfa1p domains that respond to distinct checkpoint signals, we constructed 13 Bfa1 deletion mutants. The C-terminal 184 amino acids of Bfa1p (Bfa1-D8(391-574)) contained the entire capacity of Bfa1p to generate mitotic arrest in response to spindle damage, spindle misorientation, and DNA damage. This domain was also enough to interact with the mitotic exit network proteins Tem1p, Bub2p, and Cdc5p, and to localize to the spindle pole body (SPB). Over-expression of Bfa1-D8(391-574) induced late anaphase arrest as efficient as the full-length Bfa1p in a Bub2p-dependent manner. In contrast, the N-terminal portion of Bfa1p (Bfa1-D16(1-376)) could not localize to SPB and did not block mitotic exit in response to diverse checkpoint signals. Bfa1-D16(1-376) interacted with Tem1p but not with Bub2p and its over-expression partially arrested cells in mitosis in the absence of Bub2p. By random mutagenesis of Bfa1-D8(391-574) with hydroxylamine, we isolated a point mutant of D8, D8(E438K), which interacts with both Tem1p and Bub2p but cannot respond to checkpoint signals. This mutant also showed reduced efficiency in the localization to SPB. Taken together, our study demonstrated that various checkpoint signals are transmitted to the C-terminal domain of Bfa1 (Bfa1-D8(391-574)) and that Bfa1p localization to SPB is necessary but not sufficient to regulate mitotic exit in response to various checkpoint signals.     

Microtubule capture by the cleavage apparatus is required for proper spindle positioning in yeast

Cell division is the result of two major cytoskeletal events: partition of the chromatids by the mitotic spindle and cleavage of the cell by the cytokinetic apparatus. Spatial coordination of these events ensures that each daughter cell inherits a nucleus. Here we show that, in budding yeast, capture and shrinkage of astral microtubules at the bud neck is required to position the spindle relative to the cleavage apparatus. Capture required the septins and the microtubule-associated protein Kar9. Like Kar9-defective cells, cells lacking the septin ring failed to position their spindle correctly and showed an increased frequency of nuclear missegregation. Microtubule attachment at the bud neck was followed by shrinkage and a pulling action on the spindle. Enhancement of microtubule shrinkage at the bud neck required the Par-1-related, septin-dependent kinases (SDK) Hsl1 and Gin4. Neither the formin Bnr1 nor the actomyosin contractile ring was required for either microtubule capture or microtubule shrinkage. Together, our results indicate that septins and septin-dependent kinases may coordinate microtubule and actin functions in cell division.     

Maelstrom coordinates microtubule organization during Drosophila oogenesis through interaction with components of the MTOC

The establishment of body axes in multicellular organisms requires accurate control of microtubule polarization. Mutations in Drosophila PIWI-interacting RNA (piRNA) pathway genes often disrupt the axes of the oocyte. This results from the activation of the DNA damage checkpoint factor Checkpoint kinase 2 (Chk2) due to transposon derepression. A piRNA pathway gene, maelstrom (mael), is critical for the establishment of oocyte polarity in the developing egg chamber during Drosophila oogenesis. We show that Mael forms complexes with microtubule-organizing center (MTOC) components, including Centrosomin, Mini spindles, and γTubulin. We also show that Mael colocalizes with αTubulin and γTubulin to centrosomes in dividing cyst cells and follicle cells. MTOC components mislocalize in mael mutant germarium and egg chambers, leading to centrosome migration defects. During oogenesis, the loss of mael affects oocyte determination and induces egg chamber fusion. Finally, we show that the axis specification defects in mael mutants are not suppressed by a mutation in mnk, which encodes a Chk2 homolog. These findings suggest a model in which Mael serves as a platform that nucleates other MTOC components to form a functional MTOC in early oocyte development, which is independent of Chk2 activation and DNA damage signaling.     

Centrosomal microtubule plus end tracking proteins and their role in Dictyostelium cell dynamics

Microtubules interact with huge protein complexes not only with their minus ends but also with their peripheral plus ends. The centrosome at their minus ends nucleates and organizes the microtubule cytoskeleton. The microtubule plus end complex seems to be required for the capture of microtubule tips at cortical sites by mediating interactions of microtubule tips with cortical actin as well as with membrane proteins. This process plays a major role in nuclear migration, spindle orientation and directional cell movement. Five potential members of the microtubule plus end complex have already been identified in Dictyostelium, DdCP224, DdEB1, DdLIS1, the dynein heavy chain and dynein intermediate chain. DdCP224 and DdEB1 are the Dictyostelium representatives of the XMAP215- and EB1-family, respectively. Both are not only concentrated at microtubule tips, they are also centrosomal components. The centrosomal binding domain of DdCP224 resides within the C-terminal fifth of the protein. DdCP224 is involved in the centrosome duplication cycle and cytokinesis. DdEB1 is the first member of the EB1 protein family that is also a genuine centrosomal component. A DdEB1 null mutant revealed that DdEB1 is required for mitotic spindle formation. DdEB1 coprecipitates and colocalizes with DdCP224 suggesting that these proteins act together in their functions. One of these functions could be dynein/dynactin-dependent interaction of microtubule tips with the cell cortex that is thought to determine the positioning of the microtubule-organizing center (MTOC) and the direction of migration.