The organization of the mitotic apparatus poles in etoposide-treated CHO-K1 cells

In this study, we have examined the organization of the mitotic spindle poles in CHO-K1 cells dividing after treatment with the etoposide (1 h, 25 microM). We studied at various periods after the treatment: 1) the distribution of gamma-tubulin in mitotic cells by immunofluorescent staining; 2) the level of posttranslational modification of a-tubulin in the spindle microtubules by immunoelectron microscopy; 3) the ultrastructure of the mitotic apparatus poles by standard electron microscopy. In 48 h after the addition of the agent we identified considerable changes in the ultrastructure of poles in etoposide-treated CHO-K1 cells with bipolar and multipolar spindles. The number of centrioles increased. The centrioles were unevenly distributed among the poles, and some centrioles were not explicitly involved in the organization of mitotic spindle, furthermore they can differ in the number of outgrowing microtubules. Most centrioles were without fibrillar halo. In 48 h after the addition of etoposide, electron microscopy of cells after immunoperoxidase staining with antibodies to acetylated and tyrosinated alpha-tubulin has shown that different poles of a multipolar spindle within the same cell are stained differently for tyr-tubulin but not for acet-tubulin. Immunofluorescence staining for gamma-tubulin also points to different organization of poles in the same spindle. Our findings provide the first evidence that the pattern of immunostaning and the ultrastructure of mitotic apparatus poles differ in the cells dividing at various periods after etoposide treatment.     

Reorganization of mitotic apparatus in the etoposide-treated CHO-K1 cells precedes apoptotic death

In a culture of CHO-K1 cells, etoposide (1 h, 25 μM) has been shown to produce interphase arrest, after which the cells resume mitotic division and, after some time, are submitted to apoptotic death. Accumulation of apoptotic cells in the culture follows a gradual increase in the number of multipolar mitoses. Our findings provide the first evidence for differences in the pattern of immunofluorescent staining of multipolar mitotic spindle microtubules with antibodies to α-tubulin, acetylated α-tubulin, and tyrosinated α-tubulin in mitotic cells dividing in the period preceding apoptosis. Moreover, some parts of the multipolar mitotic spindle can differ by the presence of antigenic determinants accessible to anti-tyrosinated α-tubulin antibodies. These abnormalities of the mitotic apparatus are aggravated immediately before the increase in the number of cells submitted to apoptosis. Our data have also shown that some cells pass through at least two mitotic cycles prior to a sharp increase in the number of apoptotic cells in the cell culture.     

Ultrastructural disorders of the mitotic apparatus during cytochalasin B action

A correlation between the number of chromosome sets and the number of centrioles (8n--8 centrioles) was observed in polyploid metaphase cells, during cytochalasin B treatment on the cultured Chinese hamster cells. There is no correlation between the number of chromosome sets and the centriole number after stopping the action of the drug in many cells, but a great variation is observed in maintenance of chromosomes and centrioles (up 6 to 25 n and up 4 to 22 centrioles). In multipolar mitosis, either during the drug action or after its stopping, different numbers of chromosomes are directed towards the poles not depending on the number of centrioles in the poles. During the cytochalasin B treatment, either in bipolar or multipolar metaphases, there are destructions in the ultrastructure of the mitotic apparatus: there are no astral microtubules; in the poles there are diplosomes and duplex of centrioles with fibrillar material around both centrioles; kinetochores are of prometaphase type. After stopping the drug action the astral microtubules appear, but no other patterns of normalization in the mitotic apparatus occur. Desynchronization of three cycles (chromosomal, centriolar and centrosomal) is discussed as a factor of abnormal development of the mitotic apparatus and as a factor of stabilization of aneuploidy in the cell culture.     

TRANSIENT LOCALIZATION OF γ-TUBULIN AROUND THE CENTRIOLES IN THE NUCLEAR DIVISION OF BOERGESENIA FORBESII (SIPHONOCLADALES, CHLOROPHYTA)

Mitosis in Boergesenia forbesii (Harvey) Feldman was studied by immunofluorescence microscopy using anti-β–tubulin, anti-γ–tubulin, and anti-centrin antibodies. In the interphase nucleus, one, two, or rarely three anti-centrin staining spots were located around the nucleus, indicating the existence of centrioles. Microtubules (MTs) elongated randomly from the circumference of the nuclear envelope, but distinct microtubule organizing centers could not be observed. In prophase, MTs located around the interphase nuclei became fragmented and eventually disappeared. Instead, numerous MTs elongated along the nuclear envelope from the discrete anti-centrin staining spots. Anti-centrin staining spots duplicated and migrated to the two mitotic poles. γ–Tubulin was not detected at the centrioles during interphase but began to localize there from prophase onward. The mitotic spindle in B. forbesii was a typical closed type, the nuclear envelope remaining intact during nuclear division. From late prophase, accompanying the chromosome condensation, spindle MTs could be observed within the nuclear envelope. A bipolar mitotic spindle was formed at metaphase, when the most intense staining of γ-tubulin around the centrioles could also be seen. Both spindle MT poles were formed inside the nuclear envelope, independent of the position of the centrioles outside. In early anaphase, MTs between separating daughter chromosomes were not detected. Afterward, characteristic interzonal spindle MTs developed and separated both sets of the daughter chromosomes. From late anaphase to telophase, γ-tubulin could not be detected around the centrioles and MT radiation from the centrioles became diminished at both poles. γ-Tubulin was not detected at the ends of the interzonal spindle fibers. When MTs were depolymerized with amiprophos methyl during mitosis, γ-tubulin localization around the centrioles was clearly confirmed. Moreover, an influx of tubulin molecules into the nucleus for the mitotic spindle occurred at chromosome condensation in mitosis.     

Influence of centriole behavior on the first spindle formation in zygotes of the brown alga Fucus distichus (Fucales, Phaeophyceae)

The influence of centrioles, derived from the sperm flagellar basal bodies, and the centrosomal material (MTOCs) on spindle formation in the brown alga Fucus distichus (oogamous) was studied by immunofluorescence microscopy using anti-centrin and anti-beta-tubulin antibodies. In contrast to a bipolar spindle, which is formed after normal fertilization, a multipolar spindle was formed in polyspermic zygote. The number of mitotic poles in polyspermic zygotes was double the number of sperm involved in fertilization. As an anti-centrin staining spot (centrioles) was located at these poles, the multipolar spindles in polyspermic zygotes were produced by the supplementary centrioles. When anucleate egg fragments were fertilized, chromosome condensation and mitosis did not occur in the sperm nucleus. Two anti-centrin staining spots could be detected, microtubules (MTs) radiated from nearby, but the mitotic spindle was never produced. When a single sperm fertilized multinucleate eggs (polygyny), abnormal spindles were also observed. In addition to two mitotic poles containing anti-centrin staining spots, extra mitotic poles without anti-centrin staining spots were also formed, and as a result multipolar spindles were formed. When karyogamy was blocked with colchicine, it became clear that the egg nucleus proceeded independently into mitosis accompanying chromosome condensation. A monoastral spindle could be frequently observed, and in rare cases a barrel-shaped spindle was formed. However, when a sperm nucleus was located near an egg nucleus, the two anti-centrin staining spots shifted to the egg nucleus from the sperm nucleus. In this case, a normal spindle was formed, the egg chromosomes arranged at the equator, and the associated MTs elongated from one pole of the egg spindle toward the sperm chromosomes which were scattered. From these results, it became clear that paternal centrioles derived from the sperm have a crucial role in spindle formation in the brown algae, such as they do during animal fertilization. However, paternal centrioles were not adequate for the functional centrosome during spindle formation. We speculated that centrosomal materials from the egg cytoplasm aggregate around the sperm centrioles and are needed for centrosomal activation.     

Ultrastructure of the mitotic apparatus of metaphase cells in a pig embryo kidney tissue culture after stopping the action of 2-mercaptoethanol

The ultrastructure of the metaphase mitotic apparatus has been studied in the KEPV cells during 6 hours after the removal of 2-mercaptoethanol (0.001 M). Starting from the analysis of chromosome disposition, the structures of the kinetochore regions and of the mitotic spindle poles, and the degree of integrity of the mitotic spindle microtubules, six types of metaphase cells were revealed. A comparison of the results of the present paper with those of the earlier studies enabled us to present the dynamics of the metaphase mitotic apparatus reconstruction. Four basic stages are revealed in this process. At the first stage, the K-metaphase centrioles form diplosomes again, the number and extent of kinetochore microtubules increase too. At the second stage, the metaphase plate forms, but interpolar and astral microtubules are absent. At the third stage, the structure of the kinetochore regions becomes normal. Thus, the metaphase plate may have formed before the orientation of kinetochores to the poles took place. At the fourth stage, the interpolar and astral microtubules appear; the mitotic spindle reestablishes completely. It is supposed that the formation and functioning of the mitotic apparatus is not confined to the interaction of microtubules of different types.     

The effect of the UV microirradiation of the centrosome on cell behavior. III. The ultrastructure of the centrosome after irradiation]

One of the spindle poles of mitotic PK cells was irradiated with UV microbeam in metaphase or in anaphase. Electron microscopy showed that immediately after irradiation the microtubules around the centrosome were maintained, and that the ultrastructure of both irradiated and nonirradiated poles was similar. After microirradiation of the centrosome in metaphase, the mitotic halo around this centrosome was retained, but in due time the number of microtubules was getting less compared to that around the nonirradiated centrosome. When daughter cells with irradiated centrosomes are passing into the interphase, their centrioles are not separated from each other, no primary cilia are formed, and no replication of centrioles occurs. In the interphase cells with irradiated centrosomes, satellites are formed on the active centriole, but centrosome-attached microtubules are practically absent.     

The reorganization of the mitotic apparatus in etoposide-treated CHO-K1 cells precedes accumulation of the apoptotic cells

Etoposide (1 h, 25 microM) causes interphase arrest in CHO-K1 after which cells resume mitotic division and die due to apoptosis after a certain time period. Accumulation of apoptotically dying cells in the culture follows a gradual increase in the number ofmultipolar mitoses. Our findings provide the first evidence that the pattern of immunostaning for alpha-tubulin, acetylated alpha-tubulin and tyrosinated alpha-tubulin in cells dividing at various periods after etoposide treatment. Moreover, some parts of the multipolar mitotic spindle differ in the presence of antigenic determinants accessible to anti-tyrosinated alpha-tubulin antibodies. It is noteworthy that these abnormalities are aggravated just before the increase in the number of apoptotically died cells. Our findings also suggest that some cells pass through at least two mitotic cycles prior to a sharp increase in the number of apoptotically died cells in the cell culture.     

Division of cell nuclei, mitochondria, plastids, and microbodies mediated by mitotic spindle poles in the primitive red alga Cyanidioschyzon merolae

To understand the cell cycle, we must understand not only mitotic division but also organelle division cycles. Plant and animal cells contain many organelles which divide randomly; therefore, it has been difficult to elucidate these organelle division cycles. We used the primitive red alga Cyanidioschyzon merolae, as it contains a single mitochondrion and plastid per cell, and organelle division can be highly synchronized by a light/dark cycle. We demonstrated that mitochondria and plastids multiplied by independent division cycles (organelle G1, S, G2 and M phases) and organelle division occurred before cell–nuclear division. Additionally, organelle division was found to be dependent on microtubules as well as cell–nuclear division. We have observed five stages of microtubule dynamics: (1) the microtubule disappears during the G1 phase; (2) α-tubulin is dispersed within the cytoplasm without forming microtubules during the S phase; (3) α-tubulin is assembled into spindle poles during the G2 phase; (4) polar microtubules are organized along the mitochondrion during prophase; and (5) mitotic spindles in cell nuclei are organized during the M phase. Microfluorometry demonstrated that the intensity peak of localization of α-tubulin changed in the order to spindle poles, mitochondria, spindle poles, and central spindle area, but total fluorescent intensity did not change remarkably throughout mitotic phases suggesting that division and separation of the cell nucleus and mitochondrion is mediated by spindle pole bodies. Inhibition of microtubule organization induced cell–nuclear division, mitochondria separation, and division of a single membrane-bound microbody, suggesting that similar to cell–nuclear division, mitochondrion separation and microbody division are dependent on microtubules.     

The absence of centrioles from spindle poles of rat kangaroo (PtK2) cells undergoing meiotic-like reduction division in vitro

Light and electron microscopy were used to study somatic cell reduction division occurring spontaneously in tetraploid populations of rat kangaroo Potorous tridactylis (PtK2) cells in vitro. Light microscopy coupled with time-lapse photography documented the pattern of reduction division which includes an anaphase-like movement of double chromatid chromosomes to opposite spindle poles followed by the organization of two separate metaphase plates and synchronous anaphase division to form four poles and four daughter nuclei. The resulting daughter cells were isolated and cloned, showing their viability, and karyotyped to determine their ploidy. Ultrastructural analysis of cells undergoing reduction consistently revealed two duplexes of centrioles (one at each of two spindle poles) and two spindle poles in each cell that lacked centrioles but with microtubules terminating in a pericentriolar-like cloud of material. These results suggest that the centriole is not essential for spindle pole formation and division and implicate the could region as a necessary component of the spindle apparatus.     

{gamma}-Tubulin and microtubule organization during meiosis in the liverwort Ricciocarpus natans (Ricciaceae)

Extant liverworts are "living fossils" considered sister to all other plants and as such provide clues to the evolution of the microtubule organizing center (MTOC) in anastral cells. This report is the first on microtubule arrays and their γ-tubulin-nucleating sites during meiosis in a member of the Ricciales, a specialized, species-rich group of complex thalloid (marchantioid) liverworts. In meiotic prophase, γ-tubulin becomes concentrated at several sites adjacent to the nuclear envelope. Microtubules organized at these foci give rise to a multipolar prometaphase spindle. By metaphase I, the spindle has matured into a bipolar structure with truncated poles. In both first and second meiosis, γ-tubulin forms box-like caps at the spindle poles. γ-Tubulin moves from spindle poles to the proximal surfaces of telophase chromosomes where interzonal microtubules are nucleated. Although a phragmoplast is organized, no cell plate is deposited, and second division occurs simultaneously in the undivided sporocyte. γ-Tubulin surrounds each of the tetrad nuclei, and phragmoplasts initiated between both sister and nonsister nuclei direct simultaneous cytokinesis. The overall pattern of meiosis (unlobed polyplastidic sporocytes, nuclear envelope MTOC, multipolar spindle origin, spindles with box-like poles, and simultaneous cytokinesis) more closely resembles that of Conocephalum than other marchantiod liverworts.     

Centriolar complex in somatic cell hybrids (mouse X Chinese hamster)

The ultrastructure of centriolar complex in interphase cells and in for a long time dividing somatic hybrid cells (mouse X Chinese hamster) has been investigated. It was found that in the majority of hybrid cells (about 80%) the centriolar complex consists of a higher quantity of centrioles than in the parent cells; the fine structure of the centriolar complex has features characteristic of the centrioles of both the parents; the numerous centrioles have a capacity of organizing individual poles of the spindle of division to constitute the ground for multipolar mitosis in the hybrid cells. Besides that, hybrid cells were found with the centriole number corresponding to that in diploid cells. According to our preliminary data, the ultrastructure of these hybrid centrioles is like that in murine cells.     

γ-微管蛋白在猪卵母细胞成熟和活化中的分布

微管蛋白(tubulin)是一蛋白质超家族,其中α-,β-微管蛋白是主要的微管蛋白,而γ-微管蛋白主要在微管组装中起作用. 我们利用蛋白质印迹和激光共聚焦技术研究了γ-微管蛋白在猪卵母细胞成熟、受精和活化中的分布. γ-微管蛋白存在于猪卵母细胞中,并且在减数分裂成熟各个时期的量保持不变. 它聚集在微管上,特别是中期纺锤体的两极和后末期的中板. 体外受精和孤雌活化后,γ-微管蛋白聚集在雌雄原核的周围.另外它也存在于精子的顶体帽和颈部.在早期卵裂中,γ-微管蛋白聚集在胚胎的细胞核周围.实验结果表明,γ-微管蛋白在猪卵母细胞、精子和胚胎的微管组装中起重要的调节作用,在猪受精过程中,精子和卵子都向受精卵贡献中心体物质.     

In situ analysis of normal and abnormal patterns of the mitotic apparatus in cultured rat-kangaroo cells

Dividing cells in monolayers of the rat-kangaroo (Potorous tridactylis) cell line Pt-K₁ have large spindles and are flat, thus making possible studies of interactions between the achromatic and chromatic parts of the mitotic apparatus during the cell cycle. At prophase, asters and centrioles seem to exert pressure on the nuclear membrane leading to its rupture and penetrance of the centrioles. Apparently, the long axis of the spindle is shorter than the nuclear diameter. What appears as persistent, large portions of the nuclear membrane were observed in some metaphase and anaphase cells. Such a condition might also indicate an arrested mitosis. The midbody, which was often bipartite, was found to be of a ribonucleoprotein nature. — Three-group metaphases were of common occurrence and might represent early stages of chromosome orientation preceding the final alignment of the chromosomes on the equatorial plate. They could also be an expression of an anomalous condition as a result of mitotic arrest during prometaphase owing to spindle inactivation or breakage, errors in centromere-spindle attachments, interference with chromosome movement, or a duplicated centriolar constitution. Most of these aberrations could be attributed to the flatness of dividing cells, which might also bring about the failure of centriole separation and spindle organization in prometaphase stages, as well as multipolar mitosis.De novo organization of half spindles might take place in cells with ruptured spindles. Anaphase cells showing signs of a previous three-group orientation were rare. — Multipolar mitoses were prevalent mainly in cells with high chromosome numbers. They were often star-shaped with the chromosomes oriented between opposite and adjacent poles, and rarely as end-to-end associations of spindles. Apparently, one or more centrioles might share a common polar region. Multipolar configurations have either a mono- or multinuclear origin. Nuclei usually enter division synchronously in binucleate cells and the spindles become organized between centrioles associated with individual or different nuclei.     

MITOSIS IN THE AQUATIC FUNGUS RHIZOPHYDIUM SPHEROTHECA (CHYTRIDIALES)

The structure of centric, intranuclear mitosis and of organelles associated with nuclei are described in developing zoosporangia of the chytrid Rhizophydium spherotheca. Frequently dictyosomes partially encompass the sides of diplosomes (paired centrioles). A single, incomplete layer of endoplasmic reticulum with tubular connections to the nuclear envelope is found around dividing nuclei. The nuclear envelope remains intact during mitosis except for polar fenestrae which appear during spindle incursion. During prophase, when diplosomes first define the nuclear poles, secondary centrioles occur adjacent and at right angles to the sides of primary centrioles. By late metaphase the centrioles in a diplosome are positioned at a 40° angle to each other and are joined by an electron-dense band; by telophase the centrioles lie almost parallel to each other. Astral microtubules radiate into the cytoplasm from centrioles during interphase, but by metaphase few cytoplasmic microtubules are found. Cytoplasmic microtubules increase during late anaphase and telophase as spindle microtubules gradually disappear. The mitotic spindle, which contains chromosomal and interzonal microtubules, converges at the base of the primary centriole. Throughout mitosis the semipersistent nucleolus is adjacent to the nuclear envelope and remains in the interzonal region of the nucleus as chromosomes separate and the nucleus elongates. During telophase the nuclear envelope constricts around the chromosomal mass, and the daughter nuclei separate from each end of the interzonal region of the nucleus. The envelope of the interzonal region is relatively intact and encircles the nucleolus, but later the membranes of the interzonal region scatter and the nucleolus disperses. The structure of the mitotic apparatus is similar to that of the chytrid Phlyctochytrium irregulare.     

Microtubule Cytoskeleton Remodeling by Acentriolar Microtubule-organizing Centers at the Entry and Exit from Mitosis in Drosophila Somatic Cells

Cytoskeleton microtubules undergo a reversible metamorphosis as cells enter and exit mitosis to build a transient mitotic spindle required for chromosome segregation. Centrosomes play a dominant but dispensable role in microtubule (MT) organization throughout the animal cell cycle, supporting the existence of concurrent mechanisms that remain unclear. Here we investigated MT organization at the entry and exit from mitosis, after perturbation of centriole function in Drosophila S2 cells. We found that several MTs originate from acentriolar microtubule-organizing centers (aMTOCs) that contain γ-tubulin and require Centrosomin (Cnn) for normal architecture and function. During spindle assembly, aMTOCs associated with peripheral MTs are recruited to acentriolar spindle poles by an Ncd/dynein-dependent clustering mechanism to form rudimentary aster-like structures. At anaphase onset, down-regulation of CDK1 triggers massive formation of cytoplasmic MTs de novo, many of which nucleated directly from aMTOCs. CDK1 down-regulation at anaphase coordinates the activity of Msps/XMAP215 and the kinesin-13 KLP10A to favor net MT growth and stability from aMTOCs. Finally, we show that microtubule nucleation from aMTOCs also occurs in cells containing centrosomes. Our data reveal a new form of cell cycle–regulated MTOCs that contribute for MT cytoskeleton remodeling during mitotic spindle assembly/disassembly in animal somatic cells, independently of centrioles.     

Human Nek7-interactor RGS2 is required for mitotic spindle organization

The mitotic spindle apparatus is composed of microtubule (MT) networks attached to kinetochores organized from 2 centrosomes (a.k.a. spindle poles). In addition to this central spindle apparatus, astral MTs assemble at the mitotic spindle pole and attach to the cell cortex to ensure appropriate spindle orientation. We propose that cell cycle-related kinase, Nek7, and its novel interacting protein RGS2, are involved in mitosis regulation and spindle formation. We found that RGS2 localizes to the mitotic spindle in a Nek7-dependent manner, and along with Nek7 contributes to spindle morphology and mitotic spindle pole integrity. RGS2-depletion leads to a mitotic-delay and severe defects in the chromosomes alignment and congression. Importantly, RGS2 or Nek7 depletion or even overexpression of wild-type or kinase-dead Nek7, reduced γ-tubulin from the mitotic spindle poles. In addition to causing a mitotic delay, RGS2 depletion induced mitotic spindle misorientation coinciding with astral MT-reduction. We propose that these phenotypes directly contribute to a failure in mitotic spindle alignment to the substratum. In conclusion, we suggest a molecular mechanism whereupon Nek7 and RGS2 may act cooperatively to ensure proper mitotic spindle organization.     

ZYG-9, A Caenorhabditis elegans Protein Required for Microtubule Organization and Function, Is a Component of Meiotic and Mitotic Spindle Poles

We describe the molecular characterization of zyg-9, a maternally acting gene essential for microtubule organization and function in early Caenorhabditis elegans embryos. Defects in zyg-9 mutants suggest that the zyg-9 product functions in the organization of the meiotic spindle and the formation of long microtubules. One-cell zyg-9 embryos exhibit both meiotic and mitotic spindle defects. Meiotic spindles are disorganized, pronuclear migration fails, and the mitotic apparatus forms at the posterior, orients incorrectly, and contains unusually short microtubules. We find that zyg-9 encodes a component of the meiotic and mitotic spindle poles. In addition to the strong staining of spindle poles, we consistently detect staining in the region of the kinetochore microtubules at metaphase and early anaphase in mitotic spindles. The ZYG-9 signal at the mitotic centrosomes is not reduced by nocodazole treatment, indicating that ZYG-9 localization to the mitotic centrosomes is not dependent upon long astral microtubules. Interestingly, in embryos lacking an organized meiotic spindle, produced either by nocodazole treatment or mutations in the mei-1 gene, ZYG-9 forms a halo around the meiotic chromosomes. The protein sequence shows partial similarity to a small set of proteins that also localize to spindle poles, suggesting a common activity of the proteins.     

Furry Protein Promotes Aurora A-mediated Polo-like Kinase 1 Activation

Bipolar mitotic spindle organization is fundamental to faithful chromosome segregation. Furry (Fry) is an evolutionarily conserved protein implicated in cell division and morphology. In human cells, Fry localizes to centrosomes and spindle microtubules in early mitosis, and depletion of Fry causes multipolar spindle formation. However, it remains unknown how Fry controls bipolar spindle organization. This study demonstrates that Fry binds to polo-like kinase 1 (Plk1) through the polo-box domain of Plk1 in a manner dependent on the cyclin-dependent kinase 1-mediated Fry phosphorylation at Thr-2516. Fry also binds to Aurora A and promotes Plk1 activity by binding to the polo-box domain of Plk1 and by facilitating Aurora A-mediated Plk1 phosphorylation at Thr-210. Depletion of Fry causes centrosome and centriole splitting in mitotic spindles and reduces the kinase activity of Plk1 in mitotic cells and the accumulation of Thr-210-phosphorylated Plk1 at the spindle poles. Our results suggest that Fry plays a crucial role in the structural integrity of mitotic centrosomes and in the maintenance of spindle bipolarity by promoting Plk1 activity at the spindle poles in early mitosis.     

CEP70 protein interacts with γ-tubulin to localize at the centrosome and is critical for mitotic spindle assembly

Deregulation of the mitotic spindle has been implicated in genomic instability, an important aspect of tumorigenesis and malignant transformation. To ensure the fidelity of chromosome transmission, the mitotic spindle is assembled by exquisite mechanisms and orchestrated by centrosomes in animal cells. Centrosomal proteins especially are thought to act coordinately to ensure accurate spindle formation, but the molecular details remain to be investigated. In this study, we report the molecular characterization and functional analysis of a novel centrosomal protein, Cep70. Our data show that Cep70 localizes to the centrosome throughout the cell cycle and binds to the key centrosomal component, γ-tubulin, through the peptide fragments that contain the coiled-coil domains. Our data further reveal that the centrosomal localization pattern of Cep70 is dependent on its interaction with γ-tubulin. Strikingly, Cep70 plays a significant role in the organization of both preexisting and nascent microtubules in interphase cells. In addition, Cep70 is necessary for the organization and orientation of the bipolar spindle during mitosis. These results thus report for the first time the identification of Cep70 as an important centrosomal protein that interacts with γ-tubulin and underscore its critical role in the regulation of mitotic spindle assembly.