Comparison of hyperosmotic shock-induced changes in kinetochore structure with chromosome motion in PtK1 cells

Summary Treatment of metaphase PtK₁ cells with 0.2 M to 0.5 M sucrose and anaphase cells with 0.5 M sucrose has previously been shown to stop chromosome motion probably due to a significant alteration in the functional attachment of kinetochore microtubules (kMTs) with the kinetochore lamina. The work presented here examines the effects of 0.15 M to 0.25 M sucrose on PtK₁ metaphase and anaphase cells with a focus on the ultrastructural changes in the kinetochore and rates of chromosome motion. Metaphase PtK₁ cells treated with 0.15 M and 0.20 M sucrose from 5 to 15 min showed spindle elongation with sister chromatids remaining at the metaphase plate; these cells failed to enter anaphase. Ultrastructural analysis revealed MTs did not insert directly into the kinetochore lamina but rather associated tangentially with an amorphous material proximal to the kinetochore region much like that described previously with higher concentrations of osmotica. Treatment of metaphase cells with 0.25 M sucrose arrested the cell in metaphase and ultrastructural analysis revealed novel osmiophilic spherical structures approximately 0.50 m in diameter located proximal to kinetochores. MTs appeared to stop just short of. or associate laterally with, these spherical structures. Anaphase PtK₁ cells treated with 0.15 M and 0.20 M sucrose showed reduced rates of chromosome segregation during 5 min treatments, suggesting they retained functional kinetochore/kMT interactions. However, treatment of anaphase cells with 0.25 M sucrose blocked anaphase A chromosome motion and produced electron dense spherical structures approximately 0.50 m in diameter, identical to those observed in similarly treated metaphase cells. Removal of 0.25 M sucrose in treated anaphase cells resulted in normal chromosome segregation within 1 min. Cells released from sucrose treatment showed the absence of spherical structures and reformation of normal kinetochore/MT interactions which was temporally correlated with the resumption of chromosome motion.Abbreviations DIC differential interference contrast - kMT(s) kinetochore microtubule(s) - MT(s) microtubule(s) - nkMT(s) non-kinetochore microtubule(s)     

Spindle dynamics and arrangement of microtubules

Changes in microtubule (MT) arrangement were studied in endosperm of Haemanthus katherinae. Individual cells were selected in the light microscope and sectioned perpendicular or parallel to the long axis of the spindle. The following data and conclusions were drawn: During anaphase kinetochore fibers (bundles of kinetochore MTs) always intermingle with non-kinetochore (continuous) fibers (bundles of non-kinetochore MTs). The latter often branch and some free ends are present. Often one non-kinetochore fiber is connected with more than one kinetochore fiber, explaining why chromosomes may lose their ability for independent movement. During anaphase kinetochore fibers move to the poles, the number of kinetochore MTs decreases by one-half and the MTs tend to become more splayed out. At the same time the number of MTs between trailing chromosome arms increases, probably representing segments of kinetochore MTs which break during anaphase. The number of non-kinetochore MTs in the equatorial region at anaphase is twice the number of non-kinetochore MTs in metaphase. The above data agree perfectly with those in polarized light and indicate that a simple sliding system does not exist in the spindle of Haemanthus.     

Kinetochore Fiber Maturation in PtK1 Cells and Its Implications for the Mechanisms of Chromosome Congression and Anaphase Onset

Kinetochore microtubules (kMts) are a subset of spindle microtubules that bind directly to the kinetochore to form the kinetochore fiber (K-fiber). The K-fiber in turn interacts with the kinetochore to produce chromosome motion toward the attached spindle pole. We have examined K-fiber maturation in PtK₁ cells using same-cell video light microscopy/serial section EM. During congression, the kinetochore moving away from its spindle pole (i.e., the trailing kinetochore) and its leading, poleward moving sister both have variable numbers of kMts, but the trailing kinetochore always has at least twice as many kMts as the leading kinetochore. A comparison of Mt numbers on sister kinetochores of congressing chromosomes with their direction of motion, as well as distance from their associated spindle poles, reveals that the direction of motion is not determined by kMt number or total kMt length. The same result was observed for oscillating metaphase chromosomes. These data demonstrate that the tendency of a kinetochore to move poleward is not positively correlated with the kMt number. At late prometaphase, the average number of Mts on fully congressed kinetochores is 19.7 ± 6.7 (n = 94), at late metaphase 24.3 ± 4.9 (n = 62), and at early anaphase 27.8 ± 6.3 (n = 65). Differences between these distributions are statistically significant. The increased kMt number during early anaphase, relative to late metaphase, reflects the increased kMt stability at anaphase onset. Treatment of late metaphase cells with 1 μM taxol inhibits anaphase onset, but produces the same kMt distribution as in early anaphase: 28.7 ± 7.4 (n = 54). Thus, a full complement of kMts is not sufficient to induce anaphase onset. We also measured the time course for kMt acquisition and determined an initial rate of 1.9 kMts/min. This rate accelerates up to 10-fold during the course of K-fiber maturation, suggesting an increased concentration of Mt plus ends in the vicinity of the kinetochore at late metaphase and/or cooperativity for kMt acquisition.     

Metabolic inhibitors and mitosis: II. Effects of dinitrophenol/deoxyglucose and nocodazole on the microtubule cytoskeleton

Summary To examine the effects exerted on the microtubule (MT) cytoskeleton by dinitrophenol/deoxyglucose (DNP/DOG) and nocodazole, live PtK₁ cells were treated with the drugs and then fixed and examined by immunofluorescence staining and electronmicroscopy. DNP/DOG had little effect on interphase MTs. In mitotic cells, kinetochore and some astral fibers were clearly shortened in metaphase figures by DNP/DOG. Nocodazole rapidly broke down spindle MTs (except those in the midbody), while interphase cells showed considerable variation in the susceptibility of their MTs. Nocodazole had little effect on MTs in energy-depleted (DNP/DOG-treated) cells. When cytoplasmic MTs had all been broken down by prolonged nocodazole treatment and the cells then released from the nocodazole block into DNP/DOG, some MT reassembly occurred in the ATP-depleted state. MTs in permeabilized, extracted cells were also examined with antitubulin staining; the well-preserved interphase and mitotic arrays of MTs showed no susceptibility to nocodazole. In contrast, MTs suffered considerable breakdown by ATP, GTP and ATPS; AMPPNP had little effect. This susceptibility of extracted MT cytoskeleton to nucleotide phosphates was highly variable; some interphase cells lost all MTs, most were severely affected, but some retained extensive MT networks; mitotic spindles were diminished but structurally coherent and more stable than most interphase MT arrays.We suggest that: 1. in the living cell, ATP or nucleotide triphosphates (NTPs) are necessary for normal and nocodazole-induced MT disassembly; 2. the NTP requirement may be for phosphorylation; 3. shortening of kinetochore fibers may be modulated by compression and require ATP; 4. many of these results cannot be accomodated by the dynamic equilibrium theory of MT assembly/disassembly; 5. the use and role of ATP on isolated spindles may have to be reevaluated due to the effects ATP has on the spindle cytoskeleton of permeabilized cells.     

Role of microtubule organization in centrosome migration and mitotic spindle formation in PtK1 cells

Summary Quinacrine, an acridine derivative, has previously been shown to disrupt lateral associations between non-kinetochore microtubules (nkMTs) of opposite polarity in PtK₁ metaphase spindles such that the balance of spindle forces is significantly altered. We extended the analysis of the spatial relationship of spindle microtubules (MTs) in this study by using quinacrine to compare ATP-dependent requirements for early prometaphase centrosome separation and spindle formation. The route used for centrosome migration can take a variety of pathways in PtK₁ cells, depending on the location of the centrosomes at the time of nuclear envelope breakdown. Following quinacrine treatment centrosome separation decresased by 1.9 to 14.0 m depending on the pathway utilized. However, birefringence of the centrosomal region increased approximately 50% after quinacrine treatment. Quinacrine-treated mid-prometaphase cells, where chromosome attachment to MTs had occurred, showed a decrease in spindle length of approximately 6.0 m with only a slight increase in astral birefringence. Computer-generated reconstructions of quinacrine-treated prometaphase cells were used to confirm changes in MT reorganization. Early-prometaphase cells showed more astral MTs (aMTs) of varied length while mid-prometaphase cells showed only a few short aMTs. Late prometaphase cells again showed a large number of aMTs. Our results suggest that: (1) quinacrine treatment affects centrosome separation, (2) recruitment of nkMTs by kinetochores is quinacrine-sensitive, and (3) development of the prometaphase spindle is dependent on quinacrine-sensitive lateral interactions between nkMTs of opposite polarity. These data also suggest that lateral interactions between MTs formed during prometaphase are necessary for centrosome separation and normal spindle formation but not necessarily chromosome motion.Abbreviations aMT(s) astral microtubule(s) - DIC differential interference contrast - MT(s) microtubule(s) - kMT(s) kinetochore microtubule(s) - NEB nuclear envelope breakdown - nkMT(s) non-kinetochore microtubule(s)     

Light and electron microscopy of rat kangaroo cells in mitosis

Kinetochores in rat kangaroo (PtK₂) cells in prophase of mitosis are finely fibrillar, globular bodies, 5000–8000 Å in diameter. Sister kinetochores are attached to opposite lateral faces in the primary constriction of chromosomes. No microtubules (MTs) occur in prophase nuclei. During prometaphase the ball-shaped kinetochores differentiate into trilaminar plaques. An outer kinetochore layer, less electron dense than chromatin, appears first in the fibrillar matrix. The inner layer, continuous with, but more electron dense than the chromosome, is formed later. Kinetochore-spindle MT interaction is evident at the very beginning of prometaphase. As a result, kinetochore shape is very variable, but three types of kinetochores can be distinguished by fine structure analysis. A comparison of kinetochore structure and chromosome position in the mitotic spindle yielded clues regarding initial orientation and congression. At the time the nuclear envelope (NE) breaks down chromosomes near asters orient first. Chromosomes approximately equidistant from the two spindle poles amphi-orient immediately. Chromosomes closer to one pole probably achieve mono-orientation first, then amphi-orient and congress. In normal metaphase all the chromosomes lie at or near the spindle equator and kinetochores are structurally uniform. Paraxial and para-equatorial sections revealed that they are trilaminar, roughly circular plaques of 4000–6000 Å diameter. Inner and outer layers are 400 Å, and the electron translucent middle layer which separates them is 270 Å thick. From 16 to 40 MTs are anchored in the outer layer. In cold-treated cells the kinetochores are trilaminar, but in colcemid-treated cells the inner layer is lacking. Both kinetochores and their MTs are disorganized beginning in late anaphase. In telophase the inner layer persists for some time as an electron dense patch apposed to the NE, while the outer layer disintegrates.     

The attachment of kinetochores to the pro-metaphase spindle in PtK1 cells

When late prophase PtK₁ cells are chilled to 6 ° C the nuclear envelope (NE) breaks down as in normal cells but the spindle is inhibited from forming. When these cells are subsequently warmed to 18 ° C the spindle slowly forms and pro-metaphase congression ensues. Using this approach we have been able to experimentally eliminate the influence of asynchronous NE breakdown on the formation and development of the spindle, and also to slow down (and thus increase the temporal separation of) the subsequent events which occur during the initial stages of spindle formation. Correlative light and high voltage electron microscopic studies on these cells, fixed after various times of recovery, reveal the following results: 1) the centrosomes generate microtubules (MTs) well before MTs are seen to be associated with the kinetochores; 2) as in untreated PtK₁ cells (Roos, 1973a, 1976) the order in which chromosomes attach to the forming spindle is influenced by their proximity to a centrosome-kinetochores closest to a centrosome appear stretched towards the centrosome at a time during recovery when other kinetochores, more distal to the centrosome appear unstretched and unoriented; 3) as in untreated cells (Heneen, 1970; Roos, 1976) the predominant behavior during recovery is for a chromosome to initially mono-orient and associate with the near centrosome and only later to develop a bipolar association; and 4) MTs associated with early pro-metaphase kinetochores are almost always oriented towards a centrosome. — From our results we conclude that the proximity effect and the tendency of pro-metaphase chromosomes in PtK₁ to initially mono-orient and associate with the near centrosome cannot be ascribed, as suggested by Roos (1976), to influences arising during the asynchronous breakdown of the NE. Rather, our data clearly demonstrate that a kinetochore-centrosome interaction occurs during spindle formation which cannot be attributed to transient influences. The proximity effect and the predominant tendency of PtK₁ pro-metaphase chromosomes to mono-orient to the near pole are taken to signify the existance of a centrosomal influence on the attachment and orientation of chromosomes. Two possible mechanisms for this influence, both involving a structural interaction between the centrosome and the kinetochore, are outlined.     

Localization of kinetochore fragments isolated from single chromatids in mitotic CHO cells

Summary Chinese hamster ovary (CHO) cells are treated with hydroxurea followed by a caffeine treatment to form detached kinetochore fragments in the absence of sister chromatids. Detached kinetochores in mitotic CHO cells display a functional association with MTs initiated from one or both centrosomes such that these association(s) have a significant influence on the location and orientation of detached kinetochores and/or their fragments. Kinetochore fragments which are amphitelically oriented are positioned approximately midway between the two centrosomes. Thus, a kinetochore isolated from a single chromatid can capture MTs from both poles. Monotelic orientation of these fragments is more frequently observed with kinetochore fragments located an average distance of 2.5 m from the nearest centrosome, compared to an average distance of 4.4 m in amphitelically oriented fragments. In cells treated with the potent MT poison, nocodazole, kinetochore isolation also occurs and therefore is not dependent on the presence of MTs. CHO cells treated to produce isolated kinetochores or kinetochore fragments then subsequently hyperosmotically shocked show no MTs directly inserted into kinetochore lamina, similar to the response of sucrose-treated metapbase PtK₁ cells. This treatment shows circular kinetochores tangentially associated with bundles of MTs that are located an average of 1.5 m from the centrosome. Our results suggest that a single kinetochore fragment can attach to MTs initiated from one or both centrosomes and that their specific association to MT fibers defines orientation of detached kinetochores within the spindle domain.     

Kinetochore microtubule numbers of different sized chromosomes

For three species of grasshoppers the volumes of the largest and the smallest metaphase chromosome differ by a factor of 10, but the microtubules (MTs) attached to the individual kinetochores show no corresponding range in numbers. Locusta mitotic metaphase chromosomes range from 2 to 21 μm, and the average number of MTs per kinetochore is 21 with an SD of 4.6. Locusta meiotic bivalents at late metaphase I range from 4 to 40 μm(3), and the kinetochore regions (= two sister kinetochores facing the same spindle pole) have an average of 25 kinetochore microtubules (kMTs) with an SD of 4.9. Anaphase velocities are the same at mitosis and meiosis I. The smaller mitotic metaphase chromosomes of neopodismopsis are similar in size, 6 to 45 μm(3), to Locusta, but they have an average more kMTs, 33, SD = 9.2. The four large Robertsonian fusion chromosomes of neopodismopsis have an average of 67 MTs per kinetochore, the large number possibly the result of a permanent dicentric condition. Chloealtis has three pairs of Robertsonian fusion chromosomes which, at late meiotic metaphase I, form bivalents of 116, 134, and 152 μm (3) with an average of 67 MTs per kinetochore similar to Locusta bivalents, but with a much higher average of 42 MTs per kinetochore region. It is speculated that, in addition to mechanical demands of force, load, and viscosity, the kMT numbers are governed by cell type and evolutionary history of the karyotype in these grasshoppers.     

Localization of Mad2 to Kinetochores Depends on Microtubule Attachment, Not Tension

A single unattached kinetochore can delay anaphase onset in mitotic tissue culture cells (Rieder, C.L., A. Schultz, R. Cole, G. Sluder. 1994. J. Cell Biol. 127:1301–1310). Kinetochores in vertebrate cells contain multiple binding sites, and tension is generated at kinetochores after attachment to the plus ends of spindle microtubules. Checkpoint component Mad2 localizes selectively to unattached kinetochores (Chen, R.-H., J.C. Waters, E.D. Salmon, and A.W. Murray. 1996. Science. 274:242–246; Li, Y., and R. Benezra. Science. 274: 246–248) and disappears from kinetochores by late metaphase, when chromosomes are properly attached to the spindle. Here we show that Mad2 is lost from PtK₁ cell kinetochores as they accumulate microtubules and re-binds previously attached kinetochores after microtubules are depolymerized with nocodazole. We also show that when kinetochore microtubules in metaphase cells are stabilized with taxol, tension at kinetochores is lost. The phosphoepitope 3f3/2, which has been shown to become dephosphorylated in response to tension at the kinetochore (Nicklas, R.B., S.C. Ward, and G.J. Gorbsky. 1995. J. Cell Biol. 130:929–939), is phosphorylated on all 22 kinetochores after tension is reduced with taxol. In contrast, Mad2 only localized to an average of 2.6 out of the 22 kinetochores in taxol-treated PtK₁ cells. Therefore, loss of tension at kinetochores occupied by microtubules is insufficient to induce Mad2 to accumulate on kinetochores, whereas unattached kinetochores consistently bind Mad2. We also found that microinjecting antibodies against Mad2 caused cells arrested with taxol to exit mitosis after ~12 min, while uninjected cells remained in mitosis for at least 6 h, demonstrating that Mad2 is necessary for maintenance of the taxol-induced mitotic arrest. We conclude that kinetochore microtubule attachment stops the Mad2 interactions at kinetochores which are important for inhibiting anaphase onset.     

FAM29A promotes microtubule amplification via recruitment of the NEDD1–γ-tubulin complex to the mitotic spindle

Microtubules (MTs) are nucleated from centrosomes and chromatin. In addition, MTs can be generated from preexiting MTs in a γ-tubulin–dependent manner in yeast, plant, and Drosophila cells, although the underlying mechanism remains unknown. Here we show the spindle-associated protein FAM29A promotes MT-dependent MT amplification and is required for efficient chromosome congression and segregation in mammalian cells. Depletion of FAM29A reduces spindle MT density. FAM29A is not involved in the nucleation of MTs from centrosomes and chromatin, but is required for a subsequent increase in MT mass in cells released from nocodazole. FAM29A interacts with the NEDD1–γ-tubulin complex and recruits this complex to the spindle, which, in turn, promotes MT polymerization. FAM29A preferentially associates with kinetochore MTs and knockdown of FAM29A reduces the number of MTs in a kinetochore fiber, activates the spindle checkpoint, and delays the mitotic progression. Our study provides a biochemical mechanism for MT-dependent MT amplification and for the maturation of kinetochore fibers in mammalian cells.     

Ultrastructure of meiosis in the hollyhock rust fungus,Puccinia malvacearum I. Prophase I — Prometaphase I

Summary A thoroughly documented account of the ultrastructure of the meiotic spindle pole body (SPB) cycle in a rust (Basidiomycota, Uredinales) is presented for the first time. The three-dimensional structure of the SPB and spindle during meiosis in the hollyhock rust fungusPuccinia malvacearum is analyzed from serial sections of preselected stages. This paper covers prophase I to prometaphase I. At late prophase I, the nucleolus disperses and does not reappear until the end of meiosis. The SPB at late prophase I consists of two, 4-layered discs, 0.8–1.0 m in diameter, connected by a middle piece (MP). The SPB is associated with a differentiated region of the nuclear envelope and nucleoplasm. At late diplotene to diakinesis, each disc generates a half spindle as it inserts into an otherwise intact nuclear envelope. The MP connecting the interdigitating half spindles elongates and eventually splits transversely during subsequent spindle elongation. Each half MP, which is attached to a SPB disc, becomes inserted in a sheath-like extension of the nuclear envelope. The intranuclear late prometaphase I spindle always becomes oriented perpendicularly to the longitudinal axis and sagittal plane of the metabasidium. There are 200–290 spindle microtubules (MTs) at each SPB at late prometaphase. The nonkinetochore MTs form a coherent central spindle around which the kinetochore MTs and bivalents are spread. A metaphase plate is absent. The results are compared with SPB behavior and spindle structure in early meiosis of other basidiomycetes and ascomycetes.     

The kinetochore fiber structure in the acentric spindles of the green algaOedogonium

Summary The microtubule (MT) arrangement in three kinetochore fibers in the acentric spindles of the green algaOedogonium cardiacum were reconstructed from serial sections of prometaphase and metaphase cells. The majority of the MTs attached to the kinetochore (kMTs) are relatively short, extending less than a third of the distance to the putative spindle pole region, and none extended the full distance. Fine filaments and a matrix described earlier (Schibler andPickett-Heaps 1980) were associated with the MTs all along the fibers. Live cells ofOedogonium were also studied by time lapse cinematography for correlation with the ultrastructural observations. Late prometaphase and metaphase kinetochore fibers appear to move independently as if unattached at their poleward ends. These observations suggest that kinetochore fibers inOedogonium are not attached to a specific pole structure from late prometaphase until the inception of anaphase. The results are discussed with reference to spindle structure and function in general.     

Kinesin 5-independent poleward flux of kinetochore microtubules in PtK1 cells

Forces in the spindle that align and segregate chromosomes produce a steady poleward flux of kinetochore microtubules (MTs [kMTs]) in higher eukaryotes. In several nonmammalian systems, flux is driven by the tetrameric kinesin Eg5 (kinesin 5), which slides antiparallel MTs toward their minus ends. However, we find that the inhibition of kinesin 5 in mammalian cultured cells (PtK1) results in only minor reduction in the rate of kMT flux from approximately 0.7 to approximately 0.5 microm/min, the same rate measured in monopolar spindles that lack antiparallel MTs. These data reveal that the majority of poleward flux of kMTs in these cells is not driven by Eg5. Instead, we favor a polar "pulling-in" mechanism in which a depolymerase localized at kinetochore fiber minus ends makes a major contribution to poleward flux. One candidate, Kif2a (kinesin 13), was detected at minus ends of fluxing kinetochore fibers. Kif2a remains associated with the ends of K fibers upon disruption of the spindle by dynein/dynactin inhibition, and these K fibers flux.     

Formation of spindle fibers,kinetochore orientation,and behavior of the nuclear envelope during mitosis in endosperm

The formation of kinetochore (chromosomal) and continuous fibers, and the behavior of the nuclear envelope (NE) was described in studies combining light and electron microscopy. Microtubules (MTs) push and pull the NE which becomes progressively weaker before breaking. It breaks to a certain extent due to mechanical pressure. Clear zone MTs penetrate into the nuclear area as dense bundles and form continuous fibers. These MTs also attach to some kinetochores during this process. Some kinetochore fibers seem to be formed by the kinetochores themselves which are also responsible for further development and changes of kinetochore fibers. Formation of kinetochore fibers is asynchronous for different chromosomes and even for two sister kinetochores. Often temporary faulty connections between different kinetochores or the polar regions are formed which usually break in later stages. This results in movements of chromosomes toward the poles and across the spindle during prometaphase. The NE, whose fine structure has been described, breaks into small pieces which often persist to the next mitosis. Old pieces of NE are utilized in the formation of new NE at telophase. Several problems concerning the mechanism of chromosome movements, visibility of the NE, etc., have also been discussed.     

Maloriented bivalents have metaphase positions at the spindle equator with more kinetochore microtubules to one pole than to the other

To test the "traction fiber" model for metaphase positioning of bivalents during meiosis, kinetochore fibers of maloriented bivalents, induced during recovery from cold arrest, were analyzed with a liquid crystal polarizing microscope. The measured birefringence retardation of kinetochore fibers is proportional to the number of microtubules in a fiber. Five of the 11 maloriented bivalents analyzed exhibited bipolar malorientations that had at least four times more kinetochore microtubules to one pole than to the other pole, and two had microtubules directed to only one pole. Yet all maloriented bivalents had positions at or near the spindle equator. The traction fiber model predicts such maloriented bivalents should be positioned closer to the pole with more kinetochore microtubules. A metaphase position at the spindle equator, according to the model, requires equal numbers of kinetochore microtubules to both poles. Data from polarizing microscope images were not in accord with those predictions, leading to the conclusion that other factors, in addition to traction forces, must be involved in metaphase positioning in crane-fly spermatocytes. Although the identity of additional factors has not been established, one possibility is that polar ejection forces operate to exert away-from-the-pole forces that could counteract pole-directed traction forces. Another is that kinetochores are "smart," meaning they embody a position-sensitive mechanism that controls their activity.     

Density and distribution of α-bungarotoxin-binding sites in postsynaptic structures of regenerated rat skeletal muscle

The polarity of kinetochore microtubules (MTs) has been studied in lysed PtK1 cells by polymerizing hook-shaped sheets of neurotubulin onto walls of preexisting cellular MTs in a fashion that reveals their structural polarity. Three different approaches are presented here: (a) we have screened the polarity of all MTs in a given spindle cross section taken from the region between the kinetochores and the poles, (b) we have determined the polarity of kinetochore MTs are more stable to cold-treated spindles; this approach takes advantage of the fact that kinetochore MTs are more stable to cold treatment than other spindle MTs; and (c) we have tracked bundles of kinetochore MTs from the vicinity of the pole to the outer layer of the kinetochore in cold- treated cells. In an anaphase cell, 90-95% of all MTs in an area between the kinetochores and the poles are of uniform polarity with their plus ends (i.e., fast growing ends) distal to the pole. In cold- treated cells, all bundles of kinetochore MTs show the same polarity; the plus ends of the MTs are located at the kinetochores. We therefore conclude that kinetochore MTs in both metaphase and anaphase cells have the same polarity as the aster MTs in each half-spindle. These results can be interpreted in two ways: (a) virtually all MTs are initiated at the spindle poles and some of the are "captured" by matured kinetochores using an as yet unknown mechanism to bind the plus ends of existing MTs; (b) the growth of kinetochore MTs is initiated at the kinetochore in such a way that the fast growing MT end is proximal to the kinetochore. Our data are inconsistent with previous kinetochore MT polarity determinations based on growth rate measurements in vitro. These studies used drug-treated cells from which chromosomes were isolated to serve as seeds for initiation of neurotubule polymerization. It is possible that under these conditions kinetochores will initiate MTs with a polarity opposite to the one described here.     

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.     

Both actin and myosin inhibitors affect spindle architecture in PtK1 cells: does an actomyosin system contribute to mitotic spindle forces by regulating attachment and movements of chromosomes in mammalian cells?

Immunocytochemical techniques are used to analyze the effects of both an actin and myosin inhibitor on spindle architecture in PtK₁ cells to understand why both these inhibitors slow or block chromosome motion and detach chromosomes. Cytochalasin J, an actin inhibitor and a myosin inhibitor, 2, 3 butanedione 2-monoxime, have similar effects on changes in spindle organization. Using primary antibodies and stains, changes are studied in microtubule (MT), actin, myosin, and chromatin localization. Treatment of mitotic cells with both inhibitors results in detachment or misalignment of chromosomes from the spindle and a prominent buckling of MTs within the spindle, particularly evident in kinetochore fibers. Evidence is presented to suggest that an actomyosin system may help to regulate the initial and continued attachment of chromosomes to the mammalian spindle and could also influence spindle checkpoint(s).     

Sites of microtubule assembly and disassembly in the mitotic spindle

We have microinjected biotinylated tubulin into mitotic fibroblast cells to identify the sites in the spindle at which new subunits are incorporated into microtubules (MTs). Labeled subunits were visualized in the electron microscope using an antibody to biotin followed by a secondary antibody coupled to colloidal gold. Astral MTs incorporate labeled subunits very rapidly by elongation of existing MTs and by new nucleation from the centrosome. At a slower rate, kinetochore MTs incorporate subunits at the kinetochore progressively during metaphase, suggesting a slow poleward flux of subunits in the kinetochore fiber. When cells injected in metaphase were examined in anaphase, a significant fraction of kinetochore MTs was unlabeled, suggesting that depolymerization had occurred at the kinetochore concomitant with chromosome to pole movement. The existence of opposite fluxes at the kinetochore during metaphase and anaphase suggests that two separate forces are responsible for chromosome congression and anaphase movement.