Contribution of noncentrosomal microtubules to spindle assembly in Drosophila spermatocytes

Previous data suggested that anastral spindles, morphologically similar to those found in oocytes, can assemble in a centrosome-independent manner in cells that contain centrosomes. It is assumed that the microtubules that build these acentrosomal spindles originate over the chromatin. However, the actual processes of centrosome-independent microtubule nucleation, polymerisation, and sorting have not been documented in centrosome-containing cells. We have identified two experimental conditions in which centrosomes are kept close to the plasma membrane, away from the nuclear region, throughout meiosis I in Drosophila spermatocytes. Time-lapse confocal microscopy of these cells labelled with fluorescent chimeras reveals centrosome-independent microtubule nucleation, growth, and sorting into a bipolar spindle array over the nuclear region, away from the asters. The onset of noncentrosomal microtubule nucleation is significantly delayed with respect to nuclear envelope breakdown and coincides with the end of chromosome condensation. It takes place in foci that are close to the membranes that ensheath the nuclear region, not over the condensed chromosomes. Metaphase plates are formed in these spindles, and, in a fraction of them, some degree of polewards chromosome segregation takes place. In these cells that contain both membrane-bound asters and an anastral spindle, the orientation of the cytokinesis furrow correlates with the position of the asters and is independent of the orientation of the spindle. We conclude that the fenestrated nuclear envelope may significantly contribute to the normal process of spindle assembly in Drosophila spermatocytes. We also conclude that the anastral spindles that we have observed are not likely to provide a robust back-up able to ensure successful cell division. We propose that these anastral microtubule arrays could be a constitutive component of wild-type spindles, normally masked by the abundance of centrosome-derived microtubules and revealed when asters are kept away. These observations are consistent with a model in which centrosomal and noncentrosomal microtubules contribute to the assembly and are required for the robustness of the cell division spindle in cells that contain centrosomes.     

Inhibition of Aurora kinases perturbs chromosome alignment and spindle checkpoint signaling in rat spermatocytes

In somatic cells, integrity of cell division is safeguarded by the spindle checkpoint, a signaling cascade that delays the separation of sister chromatids in the presence of misaligned chromosomes. Aurora kinases play important roles in this process by promoting centrosome maturation, chromosome bi-orientation, spindle checkpoint signaling, and cytokinesis. To investigate the functions of Aurora kinases in male meiosis, we applied a small molecule Aurora inhibitor, ZM447439, to seminiferous tubules in vitro. Primary and secondary spermatocytes exposed to ZM447439 exhibit defects in the spindle morphology and fail to align their chromosomes at the metaphase plate. Moreover, the treated spermatocytes undergo a forced exit from the meiotic M-phase without cytokinesis. These results suggest that the activities of Aurora kinases are required for normal spindle assembly as well as for establishment and maintenance of proper microtubule-kinetochore attachments and spindle checkpoint signaling in male mammalian meiosis.     

Chromosome attachment to the spindle in crane-fly spermatocytes requires actin and is necessary to initiate the anaphase-onset checkpoint

Summary We investigated the possible involvement of actin in the attachment of chromosomes to spindles in crane-fly primary spermatocytes. In a previous study, cytochalasin D, an inhibitor of actin polymerisation, prevented bivalent attachment to microtubules when applied at prophase, but did not cause the detachment of already attached bivalents. We were able to detach the already attached bivalents by first treating prometaphase cells with an antitubulin drug, nocodazole, to disrupt spindle microtubules. 2 min after nocodazole addition, we added cytochalasin D, to disrupt actin filaments; then 2 min later nocodazole was removed, and the cells were kept in cytochalasin D until the time of normal anaphase. Double treatment with nocodazole and cytochalasin D blocked reattachment of bivalents to the spindle. Single treatment with nocodazole alone caused chromosome detachment but did not prevent reattachment when nocodazole was washed out. Extended treatment with cytochalasin D alone starting in prometaphase did not cause bivalents to detach from the spindle. These data suggest that actin is needed for attachment of bivalents to spindle microtubules. This protocol is relevant to the anaphase-onset checkpoint. From previous experiments it was argued that the anaphase-onset checkpoint recognises unattached chromosomes only after those chromosomes first interact with (become attached to) the spindle. Our experiments showed that anaphase disjunction occurred at normal times when bivalents were prevented from attaching to the spindle (by adding cytochalasin D in prophase), while anaphase disjunction was greatly delayed when previously attached bivalents were detached (with nocodazole) and then prevented from re-attaching (with cytochalasin D) in the double treated cells. Thus the anaphaseonset checkpoint recognises only those unattached bivalents that previously were attached to the spindle. Other results provided further indication that actin-microtubule interactions are important in spindle organisation. Nocodazole treatment for 4 min caused most microtubules to disappear: bivalents aggregated around remnant microtubules. When cytochalasin D treatment followed nocodazole treatment, remnant spindle microtubules were not seen, suggesting that actin interactions help stabilise those microtubules.Abbreviations CD cytochalasin D - NMBD nuclear-membrane breakdown - NOC nocodazole     

Complexity in the spindle checkpoint

Cell viability requires accurate chromosome segregation at mitosis. The spindle checkpoint ensures that anaphase is not attempted until the sister chromatids of each chromosome are attached to spindle microtubules from opposite poles. The checkpoint mechanism involves a signal transduction cascade that is more complex than was originally envisioned.     

The spindle checkpoint

Prior to sister-chromatid separation, the spindle checkpoint inhibits cell-cycle progression in response to a signal generated by mitotic spindle damage or by chromosomes that have not attached to microtubules. Recent work has shown that the spindle checkpoint inhibits cell-cycle progression by direct binding of components of the spindle checkpoint pathway to components of a specialized ubiquitin-conjugating system that is responsible for triggering sister-chromatid separation.     

The spindle assembly checkpoint

The spindle assembly checkpoint monitors proper chromosome attachment to spindle microtubules and is conserved from yeast to humans. Checkpoint components reside on kinetochores of chromosomes and show changes in phosphorylation and localization as cells proceed through mitosis. Adaptation to prolonged checkpoint arrest can occur by inhibitory phosphorylation of Cdc2.     

Drosophila checkpoint kinase 2 couples centrosome function and spindle assembly to genomic integrity

In syncytial Drosophila embryos, damaged or incompletely replicated DNA triggers centrosome disruption in mitosis, leading to defects in spindle assembly and anaphase chromosome segregation. The damaged nuclei drop from the cortex and are not incorporated into the cells that form the embryo proper. A null mutation in the Drosophila checkpoint kinase 2 tumor suppressor homolog (DmChk2) blocks this mitotic response to DNA lesions and also prevents loss of defective nuclei from the cortex. In addition, DNA damage leads to increased DmChk2 localization to the centrosome and spindle microtubules. DmChk2 is therefore essential for a "mitotic catastrophe" signal that disrupts centrosome function in response to genotoxic stress and ensures that mutant and aneuploid nuclei are eliminated from the embryonic precursor pool.     

Taxol affects meiotic spindle function in locust spermatocytes

Summary Addition of 0.1 to 10 M taxol to meiotic spindles in locust spermatocytes leads to a concentration dependent promotion of MT assembly at the centrosomes and depletion of MTs at the kinetochores, leading to the formation of prominent asters. In anaphase spindles, the equatorial region of the interzone becomes partly depleted of MTs, too. Microcinematographically, cytostatic effects are highly concentration/time dependent, being most rapid and nearly complete at 10 M taxol, but even in 0.1 M and 1 M taxol anaphase A movement is clearly affected. The drug strongly reduces the rate of chromosome-to-pole movement (anaphase A), leading to an insufficient separation of the chromosomes which indirectly hampers cytokinesis. Obviously, the chromosomal movement seems to be ratelimited by the compactness of the centrosomal asters reaching the equatorial plane in meta- and anaphase. Although the interzonal MT-number has become strongly reduced, anaphase B is not seriously affected but appears even slightly accelerated. Together with an occasional broadening of the cell equator (transverse elongation) instead of normal elongation, these results could be taken as an indication of the previously suggested active role of the cell's cortex in spindle pole separation during anaphase B (Daub andHauser 1986).Prof. Dr. K.-E.Wohlfarth-Bottermann on the occasion of his 65th birthday.     

Flies without a spindle checkpoint

Mad2 has a key role in the spindle-assembly checkpoint (SAC) - the mechanism delaying anaphase onset until all chromosomes correctly attach to the spindle. Here, we show that unlike every other reported case of SAC inactivation in metazoans, mad2-null Drosophila are viable and fertile, and their cells almost always divide correctly despite having no SAC and an accelerated 'clock', which is caused by premature degradation of cyclin B. Mitosis in Drosophila does not need the SAC because correct chromosome attachment is achieved very rapidly, before even the cell lacking Mad2 can initiate anaphase. Experimentally reducing spindle-assembly efficiency renders the cells Mad2-dependent. In fact, the robustness of the SAC may generally mask minor mitotic defects of mutations affecting spindle function. The reported lethality of other Drosophila SAC mutations may be explained by their multifunctionality, and thus the 'checkpoint' phenotypes previously ascribed to these mutations should be considered the consequence of eliminating both the checkpoint and a second mitotic function.     

The spindle checkpoint in the dinoflagellate Crypthecodinium cohnii

Dinoflagellates are a major group of organisms with an extranuclear spindle. As the purpose of the spindle checkpoint is to ensure proper alignment of the chromosomes on the spindle, dinoflagellate cell cycle control may be compromised to accomodate the extranuclear spindle. In the present study, we demonstrated that nocodazole reversibly prolonged the G2 + M phase of the dinoflagellate cell cycle, in both metaphase and anaphase. The regulation of the spindle checkpoint involves the activation and inhibition of the anaphase promoting complex (APC), which in turn degrades specific cell cycle regulators in the metaphase to anaphase transition. In Crypthecodinium cohnii, nocodazole was also able to induce a prolongation of the degradation of mitotic cyclins and a delay in the inactivation of p13(suc1)-associated histone kinase activities. In addition, cell extracts prepared from C. cohnii in G1 phase and G2/M phase (or nocodazole treated) were able to activate and inhibit, respectively, the degradation of exogenous human cyclin B1 in vitro. The present study thus demonstrated the presence of the spindle checkpoint and APC-mediated cyclin degradation in dinoflagellates. This is discussed in relation to a possible role of the nuclear membrane in mitosis in dinoflagellates.     

Control of spindle form and function in grasshopper spermatocytes

The influence of the mitotic organizing centers, the kinetochores and the polar organizers, in controlling the dynamic spindle form and function has been investigated in the primary spermatocytes of two grasshoppers, Arphia xanthoptera and Melanoplus differentialis. A new measure of the total birefringent material in the spindle is introduced—volume-birefringence. This measure avoids many of the problems associated with the traditional retardation measurements of spindle organization.—The number of chromosomes (and their kinetochores) in a spindle can be altered with a piezoelectric micromanipulator in three ways: 1) chromosomes can be removed permanently from the cell, 2) chromosomes can be detached from the spindle and allowed to reenter the spindle at a later time, and 3) chromosomes can be transferred from one spindle to another in cells containing two spindles. Such operations show the volume-birefringence of the spindle is proportional to the number of chromosomes in the spindle. A residual volume-birefringence is seen and attributed to the contribution of the polar organizers to spindle structure. The relative polar contribution differs in the two species. Chromosome motion and spindle elongation in anaphase are unaffected by the number of chromosomes in the spindle. The proportion of volume-birefringence associated with a kinetochore is used to estimate the number of microtubules one might expect to see if the birefringence of the spindle is of microtubular origin. These calculations predict about twice the number of microtubules per kinetochore than seen with the electron microscope. Reasons are suggested to explain this discrepancy.— It is argued that chromosome detachment releases spindle component subunits into the total subunit pool, but that these excess subunits do not influence the metaphase form nor the anaphase function of the spindle; therefore, spindle dynamics are under the direct control of the kinetochores and the polar organizing centers.     

Linking kinetochore-microtubule binding to the spindle checkpoint

The spindle checkpoint blocks cell-cycle progression until chromosomes are properly attached to the mitotic spindle. Popular models propose that checkpoint proteins associate with kinetochores to produce a "wait anaphase" signal that inhibits anaphase. Recent data suggest that a two-state switch results from using the same kinetochore proteins to bind microtubules and checkpoint proteins. At least eight protein kinases are implicated in spindle checkpoint signaling, arguing that a traditional signal transduction cascade is integral to spindle checkpoint signaling.     

A new view of the spindle checkpoint

Previous studies of the spindle checkpoint suggested that its ability to prevent entry into anaphase was mediated by the inhibition of the anaphase-promoting complex (APC) ubiquitin ligase by Mad2. Two new studies challenge that view by demonstrating that another checkpoint protein, BubR1, is a far more potent inhibitor of APC function.     

Releasing the spindle assembly checkpoint without tension

Proteins of the Bcl-2 family are critical regulators of apoptosis, but how its BH3-only members activate the essential effectors Bax and Bak remains controversial. The indirect activation model suggests that they simply must neutralize all of the prosurvival Bcl-2 family members, whereas the direct activation model proposes that Bim and Bid must activate Bax and Bak directly. As numerous in vitro studies have not resolved this issue, we have investigated Bim''s activity in vivo by a genetic approach. Because the BH3 domain determines binding specificity for Bcl-2 relatives, we generated mice having the Bim BH3 domain replaced by that of Bad, Noxa, or Puma. The mutants bound the expected subsets of prosurvival relatives but lost interaction with Bax. Analysis of the mice showed that Bim''s proapoptotic activity is not solely caused by its ability to engage its prosurvival relatives or solely to its binding to Bax. Thus, initiation of apoptosis in vivo appears to require features of both models.     

Kinetochore stretching inactivates the spindle assembly checkpoint

The spindle assembly checkpoint (SAC) monitors the attachment of microtubules to the kinetochore and inhibits anaphase when microtubule binding is incomplete. The SAC might also respond to tension; however, how cells can sense tension and whether its detection is important to satisfy the SAC remain controversial. We generated a HeLa cell line in which two components of the kinetochore, centromere protein A and Mis12, are labeled with green and red fluorophores, respectively. Live cell imaging of these cells reveals repetitive cycles of kinetochore extension and recoiling after biorientation. Under conditions in which kinetochore stretching is suppressed, cells fail to silence the SAC and enter anaphase after a delay, regardless of centromere stretching. Monitoring cyclin B levels as a readout for anaphase-promoting complex/cyclosome activity, we find that suppression of kinetochore stretching delays and decelerates cyclin B degradation. These observations suggest that the SAC monitors stretching of kinetochores rather than centromeres and that kinetochore stretching promotes silencing of the SAC signal.     

Mad2-independent spindle assembly checkpoint activation and controlled metaphase-anaphase transition in Drosophila S2 cells

The spindle assembly checkpoint is essential to maintain genomic stability during cell division. We analyzed the role of the putative Drosophila Mad2 homologue in the spindle assembly checkpoint and mitotic progression. Depletion of Mad2 by RNAi from S2 cells shows that it is essential to prevent mitotic exit after spindle damage, demonstrating its conserved role. Mad2-depleted cells also show accelerated transit through prometaphase and premature sister chromatid separation, fail to form metaphases, and exit mitosis soon after nuclear envelope breakdown with extensive chromatin bridges that result in severe aneuploidy. Interestingly, preventing Mad2-depleted cells from exiting mitosis by a checkpoint-independent arrest allows congression of normally condensed chromosomes. More importantly, a transient mitotic arrest is sufficient for Mad2-depleted cells to exit mitosis with normal patterns of chromosome segregation, suggesting that all the associated phenotypes result from a highly accelerated exit from mitosis. Surprisingly, if Mad2-depleted cells are blocked transiently in mitosis and then released into a media containing a microtubule poison, they arrest with high levels of kinetochore-associated BubR1, properly localized cohesin complex and fail to exit mitosis revealing normal spindle assembly checkpoint activity. This behavior is specific for Mad2 because BubR1-depleted cells fail to arrest in mitosis under these experimental conditions. Taken together our results strongly suggest that Mad2 is exclusively required to delay progression through early stages of prometaphase so that cells have time to fully engage the spindle assembly checkpoint, allowing a controlled metaphase-anaphase transition and normal patterns of chromosome segregation.     

Evidence that the spindle assembly checkpoint does not regulate APC(Fzy) activity in Drosophila female meiosis

The spindle assembly checkpoint (SAC) plays an important role in mitotic cells to sense improper chromosome attachment to spindle microtubules and to inhibit APC(Fzy)-dependent destruction of cyclin B and Securin; consequent initiation of anaphase until correct attachments are made. In Drosophila , SAC genes have been found to play a role in ensuring proper chromosome segregation in meiosis, possibly reflecting a similar role for the SAC in APC(Fzy) inhibition during meiosis. We found that loss of function mutations in SAC genes, Mad2, zwilch, and mps1, do not lead to the predicted rise in APC(Fzy)-dependent degradation of cyclin B either globally throughout the egg or locally on the meiotic spindle. Further, the SAC is not responsible for the inability of APC(Fzy) to target cyclin B and promote anaphase in metaphase II arrested eggs from cort mutant females. Our findings support the argument that SAC proteins play checkpoint independent roles in Drosophila female meiosis and that other mechanisms must function to control APC activity.