Asynchronous entry into anaphase induced by okadaic acid: spindle microtubule organization and microtubule/kinetochore attachments

Summary We have found that a brief treatment of either PtK₂ cells or stamen hair cells ofTradescantia virginiana during metaphase with okadaic acid, a potent protein phosphatase inhibitor, results in asynchronous entry into anaphase. After this treatment, the interval for the separation of sister chromatids can be expanded from a few seconds to approximately 5 min. We have performed a series of immunolocalizations of cells with anti-tubulin antibodies and CREST serum, asking whether okadaic acid induces asynchronous entry into anaphase through changes in the organization of the spindle microtubules or through a loss in the attachment of spindle microtubules to the kinetochores. Our experiments clearly indicate that asynchronous entry into anaphase after phosphatase inhibitor treatment is not the result of either altered spindle microtubule organization or the long-term loss of microtubule attachment to kinetochores. The kinetochore fiber bundles for all of the separating chromosomes are normally of uniform length throughout anaphase, but after asynchronous entry into anaphase, different groups of kinetochore fiber bundles have distinctly different lengths. The reason for this difference in length is that once split apart, the daughter chromosomes begin their movement toward the spindle poles, with normal shortening of the kinetochore fiber bundle microtubules. Thus, okadaic acid treatment during metaphase does not affect anaphase chromosome movement once it has begun. Our results suggest that one or more protein phosphatases appear to play an important role during metaphase in the regulatory cascade that culminates in synchronous sister chromatid separation.     

The mechanism of anaphase spindle elongation: uncoupling of tubulin incorporation and microtubule sliding during in vitro spindle reactivation

To study tubulin polymerization and microtubule sliding during spindle elongation in vitro, we developed a method of uncoupling the two processes. When isolated diatom spindles were incubated with biotinylated tubulin (biot-tb) without ATP, biot-tb was incorporated into two regions flanking the zone of microtubule overlap, but the spindles did not elongate. After biot-tb was removed, spindle elongation was initiated by addition of ATP. The incorporated biot-tb was found in the midzone between the original half-spindles. The extent and rate of elongation were increased by preincubation in biot-tb. Serial section reconstruction of spindles elongating in tubulin and ATP showed that the average length of half-spindle microtubules increased due to growth of microtubules from the ends of native microtubules. The characteristic packing pattern between antiparallel microtubules was retained even in the "new" overlap region. Our results suggest that the forces required for spindle elongation are generated by enzymes in the overlap zone that mediate the sliding apart of antiparallel microtubules, and that tubulin polymerization does not contribute to force generation. Changes in the extent of microtubule overlap during spindle elongation were affected by tubulin and ATP concentration in the incubation medium. Spindles continued to elongate even after the overlap zone was composed entirely of newly polymerized microtubules, suggesting that the enzyme responsible for microtubule translocation either is bound to a matrix in the spindle midzone, or else can move on one microtubule toward the spindle midzone and push another microtubule of opposite polarity toward the pole.     

Aurora B and Kif2A control microtubule length for assembly of a functional central spindle during anaphase

The central spindle is built during anaphase by coupling antiparallel microtubules (MTs) at a central overlap zone, which provides a signaling scaffold for the regulation of cytokinesis. The mechanisms underlying central spindle morphogenesis are still poorly understood. In this paper, we show that the MT depolymerase Kif2A controls the length and alignment of central spindle MTs through depolymerization at their minus ends. The distribution of Kif2A was limited to the distal ends of the central spindle through Aurora B–dependent phosphorylation and exclusion from the spindle midzone. Overactivation or inhibition of Kif2A affected interchromosomal MT length and disorganized the central spindle, resulting in uncoordinated cell division. Experimental data and model simulations suggest that the steady-state length of the central spindle and its symmetric position between segregating chromosomes are predominantly determined by the Aurora B activity gradient. On the basis of these results, we propose a robust self-organization mechanism for central spindle formation.     

A switch in microtubule dynamics at the onset of anaphase B in the mitotic spindle of Schizosaccharomyces pombe

Microtubule dynamics have key roles in mitotic spindle assembly and chromosome movement [1]. Fast turnover of spindle microtubules at metaphase and polewards flux of microtubules (polewards movement of the microtubule lattice with depolymerization at the poles) at both metaphase and anaphase have been observed in mammalian cells [2]. Imaging spindle dynamics in genetically tractable yeasts is now possible using green fluorescent protein (GFP)-tagging of tubulin and sites on chromosomes [3] [4] [5] [6] [7] [8]. We used photobleaching of GFP-labeled tubulin to observe microtubule dynamics in the fission yeast Schizosaccharomyces pombe. Photobleaching did not perturb progress through mitosis. Bleached marks made on the spindle during metaphase recovered their fluorescence rapidly, indicating fast microtubule turnover. Recovery was spatially non-uniform, but we found no evidence for polewards flux. Marks made during anaphase B did not recover fluorescence, and were observed to slide away from each other at the same rate as spindle elongation. Fast microtubule turnover at metaphase and a switch to stable microtubules at anaphase suggest the existence of a cell-cycle-regulated molecular switch that controls microtubule dynamics and that may be conserved in evolution. Unlike the situation for vertebrate spindles, microtubule depolymerization at poles and polewards flux may not occur in S. pombe mitosis. We conclude that GFP-tubulin photobleaching in conjunction with mutant cells should aid research on molecular mechanisms causing and regulating dynamics.     

Dynamics of spindle fibers and microtubules during anaphase and phragmoplast formation

Detailed correlation of in vitro observations with the arrangement of microtubules (MTs) during anaphase-telophase were made on endosperm of Haemanthus katherinae. It is stressed that the general course of events leading to the formation of the phragmoplast is the same in all cells, but considerable variation of details may be found in different objects and even in various cells of the same tissue. The changes of MT arrangement in the interzonal region responsible for formation of the phragmoplast already occur in anaphase. During this stage continuous fibers (composed of numerous MTs) lengthen, become thinner (the number of MTs on a cross-section decreases), and often seem to break. After mid-anaphase, thin fibers begin to oscillate transversely to the axis of the phragmoplast and often are considerably laterally displaced (lateral movements). The longest MTs in the phragmoplast are present during oscillations and lateral movements. The new MTs arise in the phragmoplast regions depleted of MTs as a result of lateral movements (usually geometric central region of the phragmoplast). Clusters of vesicles, which accumulate in relation to MTs which move, fuse and form the cell plate. After the fusion, the number and the length of MTs decrease. Several processes are superimposed and occur simultaneously. Also the cell plate is, as a rule, in different stages of development in various regions of the phragmoplast. The movements of MTs and fusion of the vesicles is complex and the details of these processes are not entirely clear. The data supplied here modify some generally accepted concepts of phragmoplast formation and development. This concerns the center of origin of new MTs, the moment when they arise, and the way they subsequently behave.     

Functional central spindle assembly requires de novo microtubule generation in the interchromosomal region during anaphase

The central spindle forms between segregating chromosomes during anaphase and is required for cytokinesis. Although anaphase-specific bundling and stabilization of interpolar microtubules (MTs) contribute to formation of the central spindle, it remains largely unknown how these MTs are prepared. Using live imaging of MT plus ends and an MT depolymerization and regrowth assay, we show that de novo MT generation in the interchromosomal region during anaphase is important for central spindle formation in human cells. Generation of interchromosomal MTs and subsequent formation of the central spindle occur independently of preanaphase MTs or centrosomal MT nucleation but require augmin, a protein complex implicated in nucleation of noncentrosomal MTs during preanaphase. MTs generated in a hepatoma up-regulated protein (HURP)-dependent manner during anaphase also contribute to central spindle formation redundantly with preanaphase MTs. Based on these results, a new model for central spindle assembly is proposed.     

The kinesin-8 Kip3 scales anaphase spindle length by suppression of midzone microtubule polymerization

Mitotic spindle function is critical for cell division and genomic stability. During anaphase, the elongating spindle physically segregates the sister chromatids. However, the molecular mechanisms that determine the extent of anaphase spindle elongation remain largely unclear. In a screen of yeast mutants with altered spindle length, we identified the kinesin-8 Kip3 as essential to scale spindle length with cell size. Kip3 is a multifunctional motor protein with microtubule depolymerase, plus-end motility, and antiparallel sliding activities. Here we demonstrate that the depolymerase activity is indispensable to control spindle length, whereas the motility and sliding activities are not sufficient. Furthermore, the microtubule-destabilizing activity is required to counteract Stu2/XMAP215-mediated microtubule polymerization so that spindle elongation terminates once spindles reach the appropriate final length. Our data support a model where Kip3 directly suppresses spindle microtubule polymerization, limiting midzone length. As a result, sliding forces within the midzone cannot buckle spindle microtubules, which allows the cell boundary to define the extent of spindle elongation.     

The microtubule cross-linker Feo controls the midzone stability,motor composition,and elongation of the anaphase B spindle in Drosophila embryos

Chromosome segregation during anaphase depends on chromosome-to-pole motility and pole-to-pole separation. We propose that in Drosophila embryos, the latter process (anaphase B) depends on a persistent kinesin-5–generated interpolar (ip) microtubule (MT) sliding filament mechanism that “engages” to push apart the spindle poles when poleward flux is turned off. Here we investigated the contribution of the midzonal, antiparallel MT-cross-linking nonmotor MAP, Feo, to this “slide-and-flux-or-elongate” mechanism. Whereas Feo homologues in other systems enhance the midzone localization of the MT-MT cross-linking motors kinesin-4, -5 and -6, the midzone localization of these motors is respectively enhanced, reduced, and unaffected by Feo. Strikingly, kinesin-5 localizes all along ipMTs of the anaphase B spindle in the presence of Feo, including at the midzone, but the antibody-induced dissociation of Feo increases kinesin-5 association with the midzone, which becomes abnormally narrow, leading to impaired anaphase B and incomplete chromosome segregation. Thus, although Feo and kinesin-5 both preferentially cross-link MTs into antiparallel polarity patterns, kinesin-5 cannot substitute for loss of Feo function. We propose that Feo controls the organization, stability, and motor composition of antiparallel ipMTs at the midzone, thereby facilitating the kinesin-5–driven sliding filament mechanism underlying proper anaphase B spindle elongation and chromosome segregation.     

Aurora A and Aurora B jointly coordinate chromosome segregation and anaphase microtubule dynamics

We established a conditional deletion of Aurora A kinase (AurA) in Cdk1 analogue-sensitive DT40 cells to analyze AurA knockout phenotypes after Cdk1 activation. In the absence of AurA, cells form bipolar spindles but fail to properly align their chromosomes and exit mitosis with segregation errors. The resulting daughter cells exhibit a variety of phenotypes and are highly aneuploid. Aurora B kinase (AurB)-inhibited cells show a similar chromosome alignment problem and cytokinesis defects, resulting in binucleate daughter cells. Conversely, cells lacking AurA and AurB activity exit mitosis without anaphase, forming polyploid daughter cells with a single nucleus. Strikingly, inhibition of both AurA and AurB results in a failure to depolymerize spindle microtubules (MTs) in anaphase after Cdk1 inactivation. These results suggest an essential combined function of AurA and AurB in chromosome segregation and anaphase MT dynamics.     

Poleward microtubule flux is a major component of spindle dynamics and anaphase a in mitotic Drosophila embryos

During cell division, eukaryotic cells assemble dynamic microtubule-based spindles to segregate replicated chromosomes. Rapid spindle microtubule turnover, likely derived from dynamic instability, has been documented in yeasts, plants and vertebrates. Less studied is concerted spindle microtubule poleward translocation (flux) coupled to depolymerization at spindle poles. Microtubule flux has been observed only in vertebrates, although there is indirect evidence for it in insect spermatocytes and higher plants. Here we use fluorescent speckle microscopy (FSM) to demonstrate that mitotic spindles of syncytial Drosophila embryos exhibit poleward microtubule flux, indicating that flux is a widely conserved property of spindles. By simultaneously imaging chromosomes (or kinetochores) and flux, we provide evidence that flux is the dominant mechanism driving chromosome-to-pole movement (anaphase A) in these spindles. At 18 degrees C and 24 degrees C, separated sister chromatids moved poleward at average rates (3.6 and 6.6 microm/min, respectively) slightly greater than the mean rates of poleward flux (3.2 and 5.2 microm/min, respectively). However, at 24 degrees C the rate of kinetochore-to-pole movement varied from slower than to twice the mean rate of flux, suggesting that although flux is the dominant mechanism, kinetochore-associated microtubule depolymerization contributes to anaphase A.     

Quantitative analysis of an anaphase B switch: predicted role for a microtubule catastrophe gradient

Anaphase B in Drosophila embryos is initiated by the inhibition of microtubule (MT) depolymerization at spindle poles, which allows outwardly sliding interpolar (ip) MTs to drive pole-pole separation. Using fluorescence recovery after photobleaching, we observed that MTs throughout the preanaphase B spindle are very dynamic and display complete recovery of fluorescence, but during anaphase B, MTs proximal to the poles stabilize and therefore display lower recovery than those elsewhere. Fluorescence microscopy of the MT tip tracker EB1 revealed that growing MT plus ends localize throughout the preanaphase B spindle but concentrate in the overlap region of interpolar MTs (ipMTs) at anaphase B onset. None of these changes occurred in the presence of nondegradable cyclin B. Modeling suggests that they depend on the establishment of a spatial gradient of MT plus-end catastrophe frequencies, decreasing toward the equator. The resulting redistribution of ipMT plus ends to the overlap zone, together with the suppression of minus-end depolymerization at the poles, could constitute a mechanical switch that initiates spindle elongation.     

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.     

The role of chromosomes in anaphase trigger and nuclear envelope activity in spindle formation

In order to analyse the role of the nuclear envelope (NE) and chromosomes themselves in spindle dynamics, two events were selected: prophase clear-zone formation and anaphase. Data in vivo were precisely correlated with fine structure. Spore mother cells of the moss Mnium hornum and endosperm of Haemanthus albiflos and H. katherinae were used as material.During Pachytene, in Mnium, which occurs between +5° to –5° C in natural environmental conditions, microtubules (Mts) are formed and regularly distributed on the surface of the nucleus, particularly in regions facing the poles. They are anchored to the NE. During NE breakage, followed by rapid Mt assembly, fragments of the envelope are entirely surrounded with evenly spaced Mts and often migrate to the poles. In prophase of Haemanthus, at 22° C, Mts are irregularly arranged around the nucleus and direct connections with NE are evident. The data presented suggest that NE is a Mt nucleating site during initial stages of spindle development. Mt distribution is correlated to temperature conditions of Mt assembly. — Effects of recovery at 22° C after cold shock (+3° C) were studied: Mt nucleation is experimentally speeded up and Mts grow with random orientation, never found in controls, at all stages of mitosis. — Start of anaphase and course of kinetochore splitting was followed in vivo (time lapse) during normal division and under inhibition of Mt assembly in cells treated with colchicine and vinblastine. Autonomous chromatid repulsion and kinetochore separation up to 3.5 to 4 m take place without traces of kinetochore Mts. This process is general but is obscured in normal divisions by chromosome alignment at equatorial plane. It is concluded that spindle independent kinetochore splitting is a chromosomal trigger for poleward migration. It preceeds anaphase movements and occurs at a precise stage of the chromosome cycle.This paper is dedicated to Professor H. Bauer for the celebration of his 75th birthday     

XRHAMM functions in ran-dependent microtubule nucleation and pole formation during anastral spindle assembly

BACKGROUND: The regulated assembly of microtubules is essential for bipolar spindle formation. Depending on cell type, microtubules nucleate through two different pathways: centrosome-driven or chromatin-driven. The chromatin-driven pathway dominates in cells lacking centrosomes. RESULTS: Human RHAMM (receptor for hyaluronic-acid-mediated motility) was originally implicated in hyaluronic-acid-induced motility but has since been shown to associate with centrosomes and play a role in astral spindle pole integrity in mitotic systems. We have identified the Xenopus ortholog of human RHAMM as a microtubule-associated protein that plays a role in focusing spindle poles and is essential for efficient microtubule nucleation during spindle assembly without centrosomes. XRHAMM associates both with gamma-TuRC, a complex required for microtubule nucleation and with TPX2, a protein required for microtubule nucleation and spindle pole organization. CONCLUSIONS: XRHAMM facilitates Ran-dependent, chromatin-driven nucleation in a process that may require coordinate activation of TPX2 and gamma-TuRC.     

Interzone microtubule behavior in late anaphase and telophase spindles

We have studied microtubule behavior in late anaphase and telophase spindles of PtK1 cells, using fluoresceinated tubulin (DTAF-tubulin), microinjection, and laser microbeam photobleaching. We present the results of two novel tests which add to the evidence that DTAF-tubulin closely mimics the behavior of native tubulin in vivo. (a) Microinjected DTAF-tubulin was as effective as injected native tubulin in promoting division of taxol-dependent mitotic mutant cells that had been deprived of taxol. (b) Microinjected colchicine-DTAF-tubulin complex was similar to injected colchicine-native tubulin complex in causing depolymerization of spindles. Immediately after microinjection of DTAF-tubulin into wild-type cells during late anaphase or telophase, fluorescence incorporation by microtubules was seen in chromosomal half-spindles and just behind the chromosomes, but there was no fluorescence incorporation near the middle of the interzone. Over the next few minutes, tubulin fluorescence accumulated at the center of the interzone (the equator), becoming progressively more intense. In other experiments, cells were microinjected with DTAF-tubulin at prophase and allowed to equilibrate for 30 min. Cells that had progressed to late anaphase were then photobleached to reduce the fluorescence in the central portion of the interzone. Over a period of several minutes, the only substantial redistribution of fluorescence was the appearance of a bright area at the equator of the interzone. Both the site of fluorescence incorporation and the photobleaching data suggest that tubulin adds to the elongating spindle interzone near the equator where the plus ends of the interdigitated microtubules are located. In further experiments, several dark lines were photobleached perpendicular to the pole-to-pole axis of fluorescent anaphase-telophase spindles. Time-dependent changes in the spacings between the lines indicated that the two halves of the interzone lying on opposite sides of the spindle equator moved away from one another. This shows that the interdigitated microtubules, which make up most of the interzone, can undergo antiparallel sliding. Our data support a model for anaphase B in which plus end elongation of interdigitated microtubules and antiparallel sliding contribute to chromosome separation.     

Temperature dependence of anaphase chromosome velocity and microtubule depolymerization

The time course of chromosome movement and decay of half-spindle birefringence retardation in anaphase have been precisely determined in the endosperm cell of a plant Tilia americana and in the egg of an animal Asterias forbesi. For each species, the anaphase retardation decay rate constant and chromosome velocity are similar exponential functions of temperature. Over the temperature range at which these cells can complete anaphase, chromosome velocity and retardation rate constant yield a positive linear relationship when plotted against each other. At the higher temperatures where the chromosomes move faster, the spindle retardation decays faster, even though the absolute spindle retardation is greater. Chromosome velocity thus parallels the anaphase spindle retardation decay rate, or rate of spindle microtubule depolymerization, rather than absolute spindle retardation, or the amount of microtubules in the spindle. These observations suggest that a common mechanism exists for mitosis in plant and animal cells. The rate of anaphase chromosome movement is associated with an apparent first-order process of spindle fiber disassembly. This process irreversibly prevents spindle fiber subunits from participating in the polymerization equilibrium and removes microtubular subunits from chromosomal spindle fibers.     

Augmin-dependent microtubule nucleation at microtubule walls in the spindle

The formation of a functional spindle requires microtubule (MT) nucleation from within the spindle, which depends on augmin. How augmin contributes to MT formation and organization is not known because augmin-dependent MTs have never been specifically visualized. In this paper, we identify augmin-dependent MTs and their connections to other MTs by electron tomography and 3D modeling. In metaphase spindles of human cells, the minus ends of MTs were located both around the centriole and in the body of the spindle. When augmin was knocked down, the latter population of MTs was significantly reduced. In control cells, we identified connections between the wall of one MT and the minus end of a neighboring MT. Interestingly, the connected MTs were nearly parallel, unlike other examples of end–wall connections between cytoskeletal polymers. Our observations support the concept of augmin-dependent MT nucleation at the walls of existing spindle MTs. Furthermore, they suggest a mechanism for maintaining polarized MT organization, even when noncentrosomal MT initiation is widespread.     

Chromator is required for proper microtubule spindle formation and mitosis in Drosophila

The chromodomain protein, Chromator, has been shown to have multiple functions that include regulation of chromatin structure as well as coordination of muscle remodeling during metamorphosis depending on the developmental context. In this study we show that mitotic neuroblasts from brain squash preparations from larvae heteroallelic for the two Chromator loss-of-function alleles Chro⁷¹ and Chro⁶¹² have severe microtubule spindle and chromosome segregation defects that were associated with a reduction in brain size. The microtubule spindles formed were incomplete, unfocused, and/or without clear spindle poles and at anaphase chromosomes were lagging and scattered. Time-lapse analysis of mitosis in S2 cells depleted of Chromator by RNAi treatment suggested that the lagging and scattered chromosome phenotypes were caused by incomplete alignment of chromosomes at the metaphase plate, possibly due to a defective spindle-assembly checkpoint, as well as of frayed and unstable microtubule spindles during anaphase. Expression of full-length Chromator transgenes under endogenous promoter control restored both microtubule spindle morphology as well as brain size strongly indicating that the observed mutant defects were directly attributable to lack of Chromator function.