Spindle Assembly and Mitosis without Centrosomes in Parthenogenetic Sciara Embryos

In Sciara, unfertilized embryos initiate parthenogenetic development without centrosomes. By comparing these embryos with normal fertilized embryos, spindle assembly and other microtubule-based events can be examined in the presence and absence of centrosomes. In both cases, functional mitotic spindles are formed that successfully proceed through anaphase and telophase, forming two daughter nuclei separated by a midbody. The spindles assembled without centrosomes are anastral, and it is likely that their microtubules are nucleated at or near the chromosomes. These spindles undergo anaphase B and successfully segregate sister chromosomes. However, without centrosomes the distance between the daughter nuclei in the next interphase is greatly reduced. This suggests that centrosomes are required to maintain nuclear spacing during the telophase to interphase transition. As in Drosophila, the initial embryonic divisions of Sciara are synchronous and syncytial. The nuclei in fertilized centrosome-bearing embryos maintain an even distribution as they divide and migrate to the cortex. In contrast, as division proceeds in embryos lacking centrosomes, nuclei collide and form large irregularly shaped nuclear clusters. These nuclei are not evenly distributed and never successfully migrate to the cortex. This phenotype is probably a direct result of a failure to form astral microtubules in parthenogenetic embryos lacking centrosomes. These results indicate that the primary function of centrosomes is to provide astral microtubules for proper nuclear spacing and migration during the syncytial divisions. Fertilized Sciara embryos produce a large population of centrosomes not associated with nuclei. These free centrosomes do not form spindles or migrate to the cortex and replicate at a significantly reduced rate. This suggests that the centrosome must maintain a proper association with the nucleus for migration and normal replication to occur.     

Multiple mechanisms of chromosome movement in vertebrate cells mediated through the Ndc80 complex and dynein/dynactin

Kinetochores bind microtubules laterally in a transient fashion and stably, by insertion of plus ends. These pathways may exist to carry out distinct tasks during different stages of mitosis and likely depend on distinct molecular mechanisms. On isolated chromosomes, we found microtubule nucleation/binding depended additively on both dynein/dynactin and on the Ndc80/Hec1 complex. Studying chromosome movement in living Xenopus cells within the simplified geometry of monopolar spindles, we quantified the relative contributions of dynein/dynactin and the Ndc80/Hec1 complex. Inhibition of dynein/dynactin alone had minor effects but did suppress transient, rapid, poleward movements. In contrast, inhibition of the Ndc80 complex blocked normal end-on attachments of microtubules to kinetochores resulting in persistent rapid poleward movements that required dynein/dynactin. In normal cells with bipolar spindles, dynein/dynactin activity on its own allowed attachment and rapid movement of chromosomes on prometaphase spindles but failed to support metaphase alignment and chromatid movement in anaphase. Thus, in prometaphase, dynein/dynactin likely mediates early transient, lateral interactions of kinetochores and microtubules. However, mature attachment via the Ndc80 complex is essential for metaphase alignment and anaphase A. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Three-dimensional ultrastructure of Saccharomyces cerevisiae meiotic spindles

Meiotic chromosome segregation leads to the production of haploid germ cells. During meiosis I (MI), the paired homologous chromosomes are separated. Meiosis II (MII) segregation leads to the separation of paired sister chromatids. In the budding yeast Saccharomyces cerevisiae, both of these divisions take place in a single nucleus, giving rise to the four-spored ascus. We have modeled the microtubules in 20 MI and 15 MII spindles by using reconstruction from electron micrographs of serially sectioned meiotic cells. Meiotic spindles contain more microtubules than their mitotic counterparts, with the highest number in MI spindles. It is possible to differentiate between MI versus MII spindles based on microtubule numbers and organization. Similar to mitotic spindles, kinetochores in either MI or MII are attached by a single microtubule. The models indicate that the kinetochores of paired homologous chromosomes in MI or sister chromatids in MII are separated at metaphase, similar to mitotic cells. Examination of both MI and MII spindles reveals that anaphase A likely occurs in addition to anaphase B and that these movements are concurrent. This analysis offers a structural basis for considering meiotic segregation in yeast and for the analysis of mutants defective in this process.     

Micronuclear division and microtubular stability in the ciliate Colpoda steinii

The first microtubules which appear in the prophase micronucleus of Colpoda steinii are located beneath the nuclear envelope and not connected to the chromosomes. Most microtubules of the metaphase spindle are connected to the tapered tips of the micronucleus and terminate singly at the chromosomes surrounded by a conical, RNA-containing kinetochore which disappears upon cold treatment. During anaphase, an interzonal stembody is formed which is maximally stretched at telophase before the daughter micronuclei are pinched off from its ends. The macronucleus, which also stretches parallel to the micronuclear stembody, has fewer microtubules which insert at the inner nuclear envelope but are not attached to the chromatin. Based upon the effects of depolymerizing factors different classes of microtubules can be distinguished. Kinetochore microtubules are sensitive to cold and vinblastine (VLB). In 2.5×10^–5 M VLB their number is drastically reduced and the interzonal microtubules of early anaphase, which are also highly sensitive to nocodazole, become completely disassembled. The cross-bridged microtubules of the fully formed stembody of late anaphase display the highest resistance to depolymerization. They show signs of partial disassembly only after prolonged cold exposure and withstand higher concentrations of VLB or nocodazole than other micronuclear microtubules. Microtubules in the elongating macronucleus are fairly insensitive to cold but are depolymerized by 5×10^–5 M VLB while 1.66×10^–5 M nocodazole, which leaves only traces of stembody microtubules, merely reduces their number and length. All microtubules are fairly resistant to colchicine since high concentrations (5×10^–2 M) are required to prevent assembly while fully formed stembodies are unaffected. Macronuclear microtubules are depolymerized at this concentration. Nocodazole, which depolymerizes all premetaphase microtubules at 6.6×10^–6 M, leads to multipolar metaphase spindles with numerous microtubules, even at 1.66×10^–5 M, an effect ascribed to the activity of the nuclear envelope as a microtubule organizing centre. At twice this concentration multipolar spindles are no longer found and the remaining microtubules show no apparent order. A stabilizing influence of the micronuclear envelope is indicated by the fact that whenever remnants of microtubules are found after depolymerizing treatments, they are located in its vicinity.     

Caenorhabditis elegans Aurora A kinase is required for the formation of spindle microtubules in female meiosis

In many animals, female meiotic spindles are assembled in the absence of centrosomes, the major microtubule (MT)-organizing centers. How MTs are formed and organized into meiotic spindles is poorly understood. Here we report that, in Caenorhabditis elegans, Aurora A kinase/AIR-1 is required for the formation of spindle microtubules during female meiosis. When AIR-1 was depleted or its kinase activity was inhibited in C. elegans oocytes, although MTs were formed around chromosomes at germinal vesicle breakdown (GVBD), they were decreased during meiotic prometaphase and failed to form a bipolar spindle, and chromosomes were not separated into two masses. Whereas AIR-1 protein was detected on and around meiotic spindles, its kinase-active form was concentrated on chromosomes at prometaphase and on interchromosomal MTs during late anaphase and telophase. We also found that AIR-1 is involved in the assembly of short, dynamic MTs in the meiotic cytoplasm, and these short MTs were actively incorporated into meiotic spindles. Collectively our results suggest that, after GVBD, the kinase activity of AIR-1 is continuously required for the assembly and/or stabilization of female meiotic spindle MTs.     

Bub1-mediated adaptation of the spindle checkpoint

During cell division, the spindle checkpoint ensures accurate chromosome segregation by monitoring the kinetochore-microtubule interaction and delaying the onset of anaphase until each pair of sister chromosomes is properly attached to microtubules. The spindle checkpoint is deactivated as chromosomes start moving toward the spindles in anaphase, but the mechanisms by which this deactivation and adaptation to prolonged mitotic arrest occur remain obscure. Our results strongly suggest that Cdc28-mediated phosphorylation of Bub1 at T566 plays an important role for the degradation of Bub1 in anaphase, and the phosphorylation is required for adaptation of the spindle checkpoint to prolonged mitotic arrest.     

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.     

Mitosis of the free-living flagellate Bodo saltans strain Ps+ (Kinetoplastidea, Bodonida)

Mitosis of the free-living flagellate Bodo saltans of the Ps+ strain characterized by the presence of prokaryotic cytobionts in the perinuclear space was studied. Division of B. saltans Ps+ nuclei occurs by the closed intranuclear type of mitosis without condensation of chromosomes. At the initial stages of nuclear division, consecutive anlage of two spatially separated microtubular spindles begins. The spindle containing about 20 microtubules appears first, then, at an angle of 30–40° to it, the second spindle containing half as many microtubules is formed. The microtubules of the first spindle are associated with 4 pairs of kinetochores, the microtubules of the second one—with 2 pairs. The kinetochores of B. saltans Ps+ have a pronounced laminar structure. Both spindles rest with their ends directly on the internal membrane of the nuclear envelope and form 4 well-pronounced poles. The equatorial phase of mitosis in B. saltans Ps+ is not revealed. The divergence of sister kinetochores towards the poles occurs independently in each spindle. At the elongation phase of mitosis, the poles of both spindles are united in pairs to form a single bipolar structure composed of two loose bundles of microtubules. At this stage of nuclear division, the kinetochores reach the poles of the subspindles and cease to be visible. At subsequent nuclear division stages the nucleus acquires a dumbbell shape. During the reorganization phase the sister nuclei are separated. In the perinuclear space of the interphase nuclei of B. saltans Ps+, 1–2 prokaryotic cytobionts are present. In the course of mitosis, these organisms divide intensively, such that their number can reach 20 and more per nucleus. During separation of sister nuclei, the “excessive” cytobionts are released into the cytoplasmic vacuoles formed by external membranes of the nuclear envelope.     

A Chromatin-associated Kinesin-related Protein Required for Normal Mitotic Chromosome Segregation in Drosophila

The tiovivo (tio) gene of Drosophila encodes a kinesin-related protein, KLP38B, that colocalizes with condensed chromatin during cell division. Wild-type function of the tio gene product KLP38B is required for normal chromosome segregation during mitosis. Mitotic cells in tio larval brains displayed circular mitotic figures, increased ploidy, and abnormal anaphase figures. KLP38B mRNA is maternally provided and expressed in cells about to undergo division. We propose that KLP38B, perhaps redundantly with other chromosome-associated microtubule motor proteins, contributes to interactions between chromosome arms and microtubules important for establishing bipolar attachment of chromosomes and assembly of stable bipolar spindles.     

Kinetochore and microtubules in two members of Chlorophyceae,Cladophora fracta and Spirogyra majuscula

Evidence is presented for the existence of a localised kinetochore with stratified fine structure in Cladophora and in Spirogyra. In the latter, there is the possibility of two kinetochores on the longer chromosomes. There is no evidence for a diffuse kinetochore. The nucleolus persists during mitosis in Cladophora on the nucleolar organising chromosomes, the granular material being lost from it very largely during metaphase and anaphase but the fibrillar material remaining. The persistent nucleolar material at metaphase and anaphase in Spirogyra is not attached to the nucleolar organising chromosomes but accumulates around all the chromosomes and chromatids, the microtubules of the spindle at anaphase passing through and possibly attaching to this nucleolar material and possibly assisting in the movement of the chromatids which are embedded within it.     

Cell division and the microtubular cytoskeleton]

Kinetochore microtubules result from an interaction between astral microtubules and the kinetochore of the chromosomes after breakdown of the nuclear envelope at the end of prophase. In this process, the end of a microtubule projecting from one of the polar regions contacts the primary constriction of a chromosome. The latter then undergoes rapid poleward movement. Concerning the mechanism of anaphase chromosome movement, the motive force for the chromosome-to-pole movement appears to be generated at the kinetochore or in the region very close to it. It has not been determined whether chromosomes propel themselves along stationary kinetochore microtubules by a motor at the kinetochore, or they are pulled poleward by a traction fiber consisting of kinetochore microtubules and associated motors. As chromosomes move poleward coordinate disassembly of kinetochore microtubules might occur from their kinetochore ends. In diatom and yeast spindles, elongation of the spindle in anaphase (anaphase B) may be explained by microtubule assembly at polar microtubule ends in the spindle mid-zone and sliding of the antiparallel microtubules from the opposite poles. The sliding force appears to be generated through an ATP-dependent microtubule motor. In isolated sea urchin spindles, the microtubule assembly at the equator alone might provide the force for spindle elongation, although, in addition, involvement of microtubule sliding by a GTP-requiring mechanochemical enzyme cannot be excluded. Discussions were made on possible participation in anaphase chromosome movement of such microtubule motors as dynein, kinesin, dynamin and the claret segregation protein.     

THE MITOTIC APPARATUS IN FUNGI, CERATOCYSTIS FAGACEARUM AND FUSARIUM OXYSPORUM

Vegetative nuclei of fungi Ceratocystis fagacearum and Fusarium oxysporum were studied both in the living condition with phase-contrast microscopy and after fixation and staining by HCl-Giemsa, aceto-orcein, and acid fuchsin techniques. Nucleoli, chromosomes, centrioles, spindles, and nuclear envelopes were seen in living hyphae of both fungi. The entire division process occurred within an intact nuclear envelope. Spindles were produced between separating daughter centrioles. At metaphase the chromosomes became attached to the spindle at different points. In F. oxysporum the metaphase chromosomes were clear enough to allow counts to be made, and longitudinal splitting of the chromosomes into chromatids was observed. Anaphase was characterized in both fungi by separation of chromosomes to poles established by the centrioles, and in F. oxysporum anaphase separation of chromosomes was observed in vivo. Continued elongation of the spindles further separated the daughter nuclei. Maturing daughter nuclei of both fungi were quite motile; and in C. fagacearum the centriole preceded the bulk of the nucleus during migration. The above observations on living cells were corroborated by observations on fixed and stained material.     

IMMUNOFLUORESCENT LOCALIZATION OF MICROTUBULES THROUGHOUT THE CELL CYCLE IN THE GREEN ALGA MOUGEOTIA (ZYGNEMATACEAE)

Indirect immunofluorescence microscopy was used to survey the three-dimensional distribution of microtubules throughout the cell cycle in the green alga Mougeotia. The network of microtubules present in the cortex of the cells at interphase gradually disappeared before mitosis. A band of cortical microtubules reminiscent of the preprophase band of higher plants surrounded the nuclei of some preprophase cells undergoing cortical microtubule disassembly. Longitudinally oriented bundles of microtubules appeared at the future spindle poles on either side of the nuclei in prophase. These bundles disappeared gradually as the spindle microtubule arrays formed. New spindles had broad poles but these became quite pointed before anaphase. Interzonal microtubules appearing at anaphase persisted until the end of nuclear migration, by which time they were concentrated into narrow bundles on either side of the centripetally forming crosswalls. During decondensation of the chromosomes and early nuclear migration, the spindle poles persisted as sites of microtubule concentration. New arrays of microtubules radiated from these microtubule centers into the cytoplasm ahead of the migrating nuclei. After cytokinesis, reinstatement of cortical microtubules was best observed in regions of the cells remote from the nuclei and associated microtubules. In contrast to higher plants, the first detectable cortical microtubules were short and already oriented transverse to the long axes of the cells.     

Redundant mechanisms for anaphase chromosome movements: crane-fly spermatocyte spindles normally use actin filaments but also can function without them

Summary. Actin inhibitors block or slow anaphase chromosome movements in crane-fly spermatocytes, but stopping of movement is only temporary; we assumed that cells adapt to loss of actin by switching to mechanism(s) involving only microtubules. To test this, we produced actin-filament-free spindles: we added latrunculin B during prometaphase, 9–80 min before anaphase, after which chromosomes generally moved normally during anaphase. We confirmed the absence of actin filaments by staining with fluorescent phalloidin and by showing that cytochalasin D had no effect on chromosome movement. Thus, actin filaments are involved in normal anaphase movements, but in vivo, spindles nonetheless can function normally without them. We tested whether chromosome movements in actin-filament-free spindles arise via microtubules by challenging such spindles with anti-myosin drugs. Y-27632 and BDM (2,3-butanedione monoxime), inhibitors that affect myosin at different regulatory levels, blocked chromosome movement in normal spindles and in actin-filament-free spindles. We tested whether BDM has side effects on microtubule motors. BDM had no effect on ciliary and sperm motility or on ATPase activity of isolated ciliary axonemes, and thus it does not directly block dynein. Nor does it block kinesin, assayed by a microtubule sliding assay. BDM could conceivably indirectly affect these microtubule motors, though it is unlikely that it would have the same side effect on the motors as Y-27632. Since BDM and Y-27632 both affect chromosome movement in the same way, it would seem that both affect spindle myosin; this suggests that spindle myosin interacts with kinetochore microtubules, either directly or via an intermediate component. Supplementary material to this paper is available in electronic form at http://dx.doi.org/10.1007/s00709-005-0094-6 Correspondence and reprints: Biology Department, York University, 4700 Keele Street, Toronto, ON M3J 1P3, Canada.     

Disruption of organization of mitotic microtubules in root meristem cells of Allium cepa induced by chloral hydrate

Data are presented on the effect of chlorahydrate on microtubule organization in the root meristem of Allium cepa. Our studies show that an incomplete preprophase band commonly appears during G2-prophase transition, yet the major effect is the lack of perinuclear microtubules, leading to inhibition of the prophase spindle formation and transition to C-mitosis. Upon chloralhydrate treatment of metaphase cells, we found cells with chromosomes regularly aligned within the metaphase plate and differently disorganized mitotic spindles. Concurrently, C-metaphase cells with remnants of kinetochore fibers were present. In addition, normal bipolar and abnormal irregular types of chromosome segregation were detected, this representing multipolar and diffuse anaphases. The major difference between them is the presence of polar microtubules during multipolar anaphase, and their lacking during diffuse anaphase. Alternatively, microtubule clusters between segregated groups of chromosomes are typical for cells with diffuse anaphase. During bipolar anaphase, excessive aster-like microtubules emanate from the spindle poles, and in telophase accessory phragmoplasts are observed at the cell periphery. The formation of incomplete phragmoplasts was observed after normal bipolar and abnormal chromosome segregation. We conclude that chloralhydrate may affect the nuclear surface capability to initiate the growth of perinuclear microtubules, thus blocking the prophase spindle formation. It also disturbs the spatial interaction between microtubules, which is crucial for the formation and functioning of various microtubular systems (preprophase band, spindle and phragmoplast).     

Anastral Spindle Assembly: A Mathematical Model

Assembly of an anastral spindle was modeled as a two-stage process: first, the aggregation of microtubule foci or asters around the chromosomes, and second, the elongation of cross-linked microtubules and onset of bipolarity. Several possibilities involving diffusion and transport were investigated for the first stage, and the most feasible was found to be binding of the asters to cytoskeletal filaments and directed transport toward the chromosomes. For the second stage, a differential-equation model was formulated and solved numerically; it involves cross-linking of microtubules with those aligned with the spindle axis and between microtubules bound to different chromosomes, and sliding of microtubules along the spindle axis to elongate the spindle. Ncd was postulated to perform both functions. The model shows that spindle formation begins with rapid cross-linking of microtubules, followed by elongation, which continues until the population of microtubules aligned with the spindle axis is depleted and microtubules cross-linking different chromosomes dominate. It also shows that when sliding is inhibited, short bipolar spindles still form, and if clustering is enhanced, normal-length spindles can form, although requiring longer assembly time. These findings are consistent with spindle assembly in live wild-type and ncd mutant Drosophila oocytes.     

KLP-7 acts through the Ndc80 complex to limit pole number in C. elegans oocyte meiotic spindle assembly

During oocyte meiotic cell division in many animals, bipolar spindles assemble in the absence of centrosomes, but the mechanisms that restrict pole assembly to a bipolar state are unknown. We show that KLP-7, the single mitotic centromere–associated kinesin (MCAK)/kinesin-13 in Caenorhabditis elegans, is required for bipolar oocyte meiotic spindle assembly. In klp-7(−) mutants, extra microtubules accumulated, extra functional spindle poles assembled, and chromosomes frequently segregated as three distinct masses during meiosis I anaphase. Moreover, reducing KLP-7 function in monopolar klp-18(−) mutants often restored spindle bipolarity and chromosome segregation. MCAKs act at kinetochores to correct improper kinetochore–microtubule (k–MT) attachments, and depletion of the Ndc-80 kinetochore complex, which binds microtubules to mediate kinetochore attachment, restored bipolarity in klp-7(−) mutant oocytes. We propose a model in which KLP-7/MCAK regulates k–MT attachment and spindle tension to promote the coalescence of early spindle pole foci that produces a bipolar structure during the acentrosomal process of oocyte meiotic spindle assembly.     

In vitro reactivation of anaphase B in isolated spindles of the sea urchin egg

Spindles may be isolated from sea urchin eggs so that some mitotic processes can be reactivated in vitro. The isolation media allow spindles to remain stable for days. Transfer of the spindles to reactivation media results in loss of birefringence and breakdown of the matrix within which the microtubules function. If, however, tubulin and either guanosine triphosphate or adenosine triphosphate are present in these media so that tubulin can cycle, the spindles do not break down but grow in size and birefringence and show some of the movements of in vivo spindles. The most prominent is that of anaphase B if the mitotic apparatuses (MAs) have been isolated at a time when anaphase was initiated. When isolated during metaphase, MAs either do not show chromosome movement or, if they do, it is a random movement which causes redistribution of the chromosomes on the spindle surface. In either case, such metaphase spindles grow in size and birefringence. Thus under the proper conditions, cycling microtubules can interact with the spindle matrix to induce chromosome movements which resemble those seen in in vivo cells in the case of anaphase B and show some aspects of anaphase A in at least half the spindles isolated at metaphase, although such movements are not coordinated to show a true anaphase movement.     

An actin-like component in spermatocytes of a crane fly (Nephrotoma suturalis Loew)

Decorated actin-like filaments were seen in spindles after crane fly spermatocytes were glycerinated and then treated with rabbit skeletal muscle heavy meromyosin (HMM). Both ATP and pyrophosphate inhibited the HMM reaction. In prometaphase, metaphase, and mid-anaphase cells, actin-like filaments were seen near regions where chromosomal spindle fibres are seen in living cells, and were oriented in the pole-to-pole direction. In the interzone of anaphase cells, actin-like filaments were not oriented in a preferential direction when they were not associated with the microtubules attached to the sex chromosomes. No filaments were seen in glycerinated spindles not treated with HMM. We discuss reasons why filaments might not be seen without prior HMM treatment, and we discuss the possible role of the actin-like filaments in the spindles. — Spindle microtubules often were not seen in cells treated with HMM. This depended on the stage of division: in prometaphase no microtubules were seen; in metaphase microtubules were seen, in apparently normal numbers; in mid-anaphase, microtubules between the autosomes and the poles were seen in reduced numbers, those associated with the equatorial sex-chromosomes were seen in apparently normal numbers, while those between the separating autosomal half-bivalents were not seen. Microtubules were not seen in glycerinated spindles not treated with HMM, suggesting that HMM in some way affects microtubule stability. The question of microtubule stability is briefly discussed.     

The mechanism of anaphase spindle elongation

At anaphase chromosomes move to the spindle poles (anaphase A) and the spindle poles move apart (anaphase B). In vitro studies using isolated diatom spindles demonstrate that the primary mechanochemical event responsible for spindle elongation is the sliding apart of half-spindle microtubules. Further, these forces are generated within the zone of microtubule overlap in the spindle mid-zone.