Changes in prometaphase chromosome motion are dependent on experimentally induced changes in kinetochore structure.

Prometaphase PtK₁ cells are treated with low concentrations of sucrose in order to analyze its effects on kinetochore structure, microtubule (MT) associations with the developing kinetochore and chromosome congression. Prometaphase cells treated with 0.15M sucrose slows chromosome congression, yet chromosomes form a metaphase configuration. However, 0.2M sucrose treatment prevents chromosome congression and affects some of the kinetochore MT linkages with the kinetochore, resulting in loss of chromosome congression. We use time lapse video microscopy and ultrastructural analysis to correlate changes in the linkages in the kinetochore MTs and the kinetochore to explain these findings. It appears hyperosmotic shock treatment can produce non-functional linkages between kinetochore MTs and kinetochores such that chromosome congression is affected. When non-functional linkages are formed, the presence of both a corona and matrix-like material is also present, proximal to the kinetochore. The role of this material and its organization at the klnetochore is discussed in its relation to generating mitotic forces.     

Model of chromosome motility in Drosophila embryos: adaptation of a general mechanism for rapid mitosis

During mitosis, ensembles of dynamic MTs and motors exert forces that coordinate chromosome segregation. Typically, chromosomes align at the metaphase spindle equator where they oscillate along the pole-pole axis before disjoining and moving poleward during anaphase A, but spindles in different cell types display differences in MT dynamicity, in the amplitude of chromosome oscillations and in rates of chromatid-to-pole motion. Drosophila embryonic mitotic spindles, for example, display remarkably dynamic MTs, barely detectable metaphase chromosome oscillations, and a rapid rate of "flux-pacman-dependent" anaphase chromatid-to-pole motility. Here we develop a force-balance model that describes Drosophila embryo chromosome motility in terms of a balance of forces acting on kinetochores and kMTs that is generated by multiple polymer ratchets and mitotic motors coupled to tension-dependent kMT dynamics. The model shows that i), multiple MTs displaying high dynamic instability can drive steady and rapid chromosome motion; ii), chromosome motility during metaphase and anaphase A can be described by a single mechanism; iii), high kinetochore dynein activity is deployed to dampen metaphase oscillations, to augment the basic flux-pacman mechanism, and to drive rapid anaphase A; iv), modulation of the MT rescue frequency by the kinetochore-associated kinesin-13 depolymerase promotes metaphase chromosome oscillations; and v), this basic mechanism can be adapted to a broad range of spindles.     

Sucrose-induced spindle elongation in mitotic PtK-1 cells

Brief treatment of mitotic metaphase and anaphase PtK-1 cells with tissue culture medium containing 0.5 M sucrose resulted in spindle elongation without chromosome motion. Spindle birefringence also changed from a uniform appearance to one of highly birefringent bundles. Electron microscopic analysis indicated these birefringent bundles were composed of tightly packed arrays of spindle microtubules. No kinetochores could be seen following a 10 min sucrose treatment. Upon removal of sucrose, metaphase spindles returned to pretreatment lengths and the normal birefringence pattern returned. Reduction in spindle length could be temporally coupled with the reappearance of kinetochores and the reassociation of microtubules with these structures. In contrast to treated and released metaphase cells, anaphase spindles did not return to pretreatment lengths. Replacement of sucrose with medium showed the resumption of chromosome-to-pole motion within 2 min of sucrose removal. Chromosome motion could be correlated with the reappearance of kinetochores and kinetochore microtubules. These data have led us to postulate the existence of two microtubule continuums in the spindle and to discuss their roles in spindle organization and chromosome motion.     

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)     

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.     

Immunofluorescence analysis of sucrose-induced changes in spindle morphology

Metaphase and anaphase PtK1 cells show spindle elongation without concomitant chromosome motion when treated with culture medium containing 0.5 M sucrose. Electron microscopy has shown sucrose-induced changes in microtubule (MT) organization, changes in trilaminar kinetochore structure, and specific kinetochore-MT associations which may account for these results. In this paper we employ double-label immunofluorescence techniques using antibodies against tubulin and the kinetochore to analyze changes in spindle microtubule and kinetochore distribution produced by sucrose treatment. Cells treated from prometaphase through anaphase with 0.5 M sucrose from 10 min to 2 h showed spindle elongation and a distinct rearrangement of spindle microtubules into bundles, with a pronounced increase in length of interpolar microtubule bundles. In sucrose-treated mitotic cells kinetochores remained as antigenically distinct structures, similar to those found in untreated interphase cells. Kinetochore determinants remained positioned within a diffuse chromatin mass, but the orientation of sister kinetochores to opposite spindle poles was lost. Instead, kinetochore pairs were found in lateral association with microtubule bundles, with several pairs of determinants associated with a single bundle in many instances. Cells released from 0.5 M sucrose treatment showed a return of the spindle to a pretreatment arrangement for both the microtubules and kinetochore determinants.     

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.     

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.     

The kinetochore microtubule minus-end disassembly associated with poleward flux produces a force that can do work.

During metaphase and anaphase in newt lung cells, tubulin subunits within the kinetochore microtubule (kMT) lattice flux slowly poleward as kMTs depolymerize at their minus-ends within in the pole. Very little is known about how and where the force that moves the tubulin subunits poleward is generated and what function it serves during mitosis. We found that treatment with the drug taxol (10 microM) caused separated centrosomes in metaphase newt lung cells to move toward one another with an average velocity of 0.89 microns/min, until the interpolar distance was reduced by 22-62%. This taxol-induced spindle shortening occurred as kMTs between the chromosomes and the poles shortened. Photoactivation of fluorescent marks on kMTs revealed that taxol inhibited kinetochore microtubule assembly/disassembly at kinetochores, whereas minus-end MT disassembly continued at a rate typical of poleward flux in untreated metaphase cells. This poleward flux was strong enough to stretch the centromeric chromatin between sister kinetochores as much as it is stretched in control metaphase cells. In anaphase, taxol blocked kMT disassembly/assembly at the kinetochore whereas minus-end disassembly continued at a rate similar to flux in control cells (approximately 0.2 microns/min). These results reveal that the mechanism for kMT poleward flux 1) is not dependent on kMT plus-end dynamics and 2) produces pulling forces capable of generating tension across the centromeres of bioriented chromosomes.     

The outer plate in vertebrate kinetochores is a flexible network with multiple microtubule interactions

Intricate interactions between kinetochores and microtubules are essential for the proper distribution of chromosomes during mitosis. A crucial long-standing question is how vertebrate kinetochores generate chromosome motion while maintaining attachments to the dynamic plus ends of the multiple kinetochore MTs (kMTs) in a kinetochore fibre. Here, we demonstrate that individual kMTs in PtK(1) cells are attached to the kinetochore outer plate by several fibres that either embed the microtubule plus-end tips in a radial mesh, or extend out from the outer plate to bind microtubule walls. The extended fibres also interact with the walls of nearby microtubules that are not part of the kinetochore fibre. These structural data, in combination with other recent reports, support a network model of kMT attachment wherein the fibrous network in the unbound outer plate, including the Hec1-Ndc80 complex, dissociates and rearranges to form kMT attachments.     

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.     

Microinjection of biotin-tubulin into anaphase cells induces transient elongation of kinetochore microtubules and reversal of chromosome-to- pole motion

During prometaphase and metaphase of mitosis, tubulin subunit incorporation into kinetochore microtubules occurs proximal to the kinetochore, at the plus-ends of kinetochore microtubules. During anaphase, subunit loss from kinetochore fiber microtubules is also thought to occur mainly from microtubule plus-ends, proximal to the kinetochore. Thus, the kinetochore can mediate both subunit addition and loss while maintaining an attachment to kinetochore microtubules. To examine the relationship between chromosome motion and tubulin subunit assembly in anaphase, we have injected anaphase cells with biotin-labeled tubulin subunits. The pattern of biotin-tubulin incorporation was revealed using immunoelectron and confocal fluorescence microscopy of cells fixed after injection; chromosome motion was analyzed using video records of living injected cells. When anaphase cells are examined approximately 30 s after injection with biotin-tubulin, bright "tufts" of fluorescence are detected proximal to the kinetochores. Electron microscopic immunocytochemistry further reveals that these tufts of biotin-tubulin-containing microtubules are continuous with unlabeled kinetochore fiber microtubules. Biotin-tubulin incorporation proximal to the kinetochore in anaphase cells is detected after injection of 3-30 mg/ml biotin-tubulin, but not in cells injected with 0.3 mg/ml biotin-tubulin. At intermediate concentrations of biotin-tubulin (3-5 mg/ml), incorporation at the kinetochore can be detected within 15 s after injection; by approximately 1 min after injection discrete tufts of fluorescence are no longer detected, although some incorporation throughout the kinetochore fiber and into nonkinetochore microtubules is observed. At higher concentrations of injected biotin-tubulin (13 mg/ml), incorporation at the kinetochore is more extensive and occurs for longer periods of time than at intermediate concentrations. Incorporation of biotin-tubulin proximal to the kinetochore can be detected in cells injected during anaphase A, but not during anaphase B. Analysis of video records of microinjection experiments reveals that kinetochore proximal incorporation of biotin-tubulin is accompanied by a transient reversal of chromosome-to-pole motion. Chromosome motion is not altered after injection of 0.3 mg/ml biotin-tubulin or 5 mg/ml BSA. These results demonstrate that kinetochore microtubules in anaphase cells can elongate in response to the elevation of the tubulin concentration and that kinetochores retain the ability to mediate plus-end-dependent assembly of KMTs and plus-end-directed chromosome motion after anaphase onset.     

Analysis of spindle microtubule organization in untreated and taxol-treated PtK1 cells.

Taxol, a microtubule stabilizing agent, has been used to study changes in spindle microtubule organization during mitosis. PtK₁ cells have been treated with 5 μg/ml taxol for brief periods to determine its effect on spindle architecture. During prophase taxol induces microtubules to aggregate, particularly evident in the region between the nucleus and cell periphery. Taxol induces astral microtubule formation in prometaphase and metaphase cells concomitant with a reduction in spindle length. At anaphase taxol induces an increase in length in astral microtubules and reduces microtubule length in the interzone. Taxol-treated telophase cells show a reduction in the rate of furrowing and astral microtubules lack a discrete focus and are arranged more diffusely on the surface of the nuclear envelope. In summary, taxol treatment of cells prior to anaphase produces an increase in astral microtubules, a reduction in kinetochore microtubules and a decrease in spindle length. Brief taxol treatments during anaphase through early G₁ promotes stabilization of microtubules, an increase in the length of astral microtubules and a delayed rate of cytokinesis.     

Structural implications of kinetochore function in sucrose-treated PtK1 cells

Treatment of PtK1 cells during metaphase with solutions containing hyperosmotic concentrations of sucrose resulted in an alteration of kinetochore structure and function in a concentration-dependent manner. This alteration in kinetochore morphology was shown to be rapidly reversible upon removal of the sucrose-containing tissue culture medium. A 10-min treatment with both 0.2 M and 0.4 M sucrose resulted in a concentration-dependent aggregation of spindle fibers into bundles, loss of trilaminar kinetochore morphology as judged by electron microscopy, and induction of anaphase B-like spindle elongation as previously described. Electron microscopy showed that a 10-min treatment of metaphase cells with hyperosmotic concentrations of sucrose changed the trilaminar kinetochore structure to one of a single lamina, with an amorphous, lightly staining material distally associated with it. Sucrose-induced bundles of microtubules could usually be seen embedded or tangentially associated with this material. Rate and extent of spindle elongation in sucrose-treated metaphase cells were greater in the higher concentrations of sucrose employed. The degree of microtubule bundling was also concentration dependent, with reduced bundling occurring at lower sucrose concentrations. Within 2 min after sucrose removal kinetochores returned to a bi- or trilaminar morphology with reduction in the amount of amorphous material. Reformation of the kinetochore trilaminar structure resembled that of the normal maturation process which occurs from prophase through anaphase. These rapid changes in kinetochore morphology following release from sucrose treatment were temporally associated with restoration of spindle function and suggested that kinetochore integrity was necessary for the expression of spindle forces responsible for spindle shortening. These forces are probably generated or transduced by the continuum formed between the two spindle poles, the kinetochore microtubules, and the sister chromatids.     

Effect of metabolic inhibitors on sucrose-induced metaphase spindle elongation and spindle recovery

Hyperosmotic sucrose treatment of metaphase PtK-1 cells has been shown to produce a reversible concentration-dependent effect on spindle elongation linked to a functional alteration in the connection of the chromosome to the spindle (Pover et al.: European Journal of Cell Biology 39:366-372, 1985). Spindle elongation, similar to that which occurs at anaphase B, is thought to be driven by the compression stored in the form of microtubule curvature in the nonkinetochore (nkMT) population of microtubules at metaphase (Snyder et al.: European Journal of Cell Biology 35:62-69, 1984 and 39:373-379, 1985). Addition of metabolic inhibitors to Ham's F-12 salts with deoxyglucose (D/F-12 medium) containing 0.4 M sucrose and 1 mM DNP does not within statistical error affect the rate and extent of sucrose-induced spindle elongation; rates and extents are 60-75% of normal anaphase B motions. Electron microscopic analysis of metaphase cells treated with D/F-12 medium and 0.4 M sucrose with 1 mM DNP demonstrates that spindle microtubules lose curvature and become straight in appearance, typical of microtubule organization in untreated anaphase cells. Sucrose-treated cells released into D/F-12 medium show a rapid reduction in spindle length; however, cells treated with either 0.4 M sucrose or 0.4 M sucrose and 1 mM DNP-containing D/F-12 medium and released into DNP-containing D/F-12 medium do not exhibit a significant reduction in spindle length. Electron microscopic analysis links changes in spindle length with microtubule/kinetochore associations. These data suggest that energy required for the initial phases of spindle elongation during anaphase is preloaded into the mitotic spindle by metaphase and does not require additional energy to be expressed as examined by sucrose-induced spindle elongation in the presence of metabolic inhibitors. Second, energy is required to make or maintain (or both) functional chromosome associations with the spindle as measured by reduction in spindle length following sucrose removal.     

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).     

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.     

An immunofluorescence study of mitosis in a mite-pathogen,Neozygites sp. (Zygomycetes: Entomophthorales)

Summary Mitosis in a mite-pathogenic species ofNeozygites (Zygomycetes: Entomophthorales) was investigated by indirect immunofluorescence microscopy using an antibody against -tubulin for visualization of microtubules (MTs). DAPI and rhodamine-conjugated phalloidin were used to stain chromatin and actin, respectively. Salient features of mitosis inNeozygites sp. are (1) a strong tendency for mitotic synchrony in any given cell, (2) conical protrusions at the poles of metaphase and anaphase nuclei revealed by actin staining, (3) absence of astral and other cytoplasmic MTs, (4) a spindle that occupies most of the nuclear volume at metaphase, (5) a spindle that remains symmetrical throughout most of mitosis, (6) kinetochore MTs that shorten during anaphase A, (7) a central spindle that elongates during anaphase B, pushing the daughter nuclei into the cell apices, and (8) interpolar MTs that continue to elongate even after separation of the daughter nuclei. Cortical cytoplasmic MTs are present in a few interphasic and post-cytokinetic cells. The data presented show thatNeozygites possesses features unique to this genus and support the erection of theNeozygitaceae as a separate family in theEntomophthorales.Abbreviations DAPI 4,6-diamidino-2-phenylindole - MT microtubule - SPB spindle pole body     

The structure of the cold-stable kinetochore fiber in metaphase PtK1 cells

When metaphase PtK₁ cells are cooled to 6–8 ° C for 4–6 h the free, polar, and astral spindle microtubules (MTs) disassemble while the MTs of each kinetochore fiber cluster together and persist as bundles of cold-stable MTs. These cold-stable kinetochore fibers are similar to untreated kinetochore fibers in both their length (i.e., 5–6 m) and in the number of kinetochore-associated MTs (i.e., 20–45) of which they are comprised. Quantitative information concerning the lengths of MTs within these fibers was obtained by tracking individual MTs between serial transverse sections. Approximately 1/2 of the kinetochore MTs in each fiber were found to run uninterrupted into the polar region of the spindle. It can be inferred from this and other data that a substantial number of MTs run uninterrupted between the kinetochore and the polar region in untreated metaphase PtK₁ cells.     

Meiosis in Drosophila melanogaster

Individual bivalents or chromosomes have been identified in Drosophila melanogaster spermatocytes at metaphase I, anaphase I, metaphase II and anaphase II in electron micrographs of serial sections. Identification was based on a combination of chromosome volume analysis, bivalent topology, and kinetochore position. — Kinetochore microtubule numbers have been obtained for the identified chromosomes at all four meiotic stages. Average numbers in D. melanogaster are relatively low compared to reported numbers of other higher eukaryotes. There are no differences in kinetochore microtubule numbers within a stage despite a large (approximately tenfold) difference in chromosome volume between the largest and the smallest chromosome. A comparison between the two meiotic metaphases (metaphase I and metaphase II) reveals that metaphase I kinetochores possess twice as many microtubules as metaphase II kinetochores. — Other microtubules in addition to those that end on or penetrate the kinetochore are found in the vicinity of the kinetochore. These microtubules penetrate the chromosome rather than the kinetochore proper and are more numerous at metaphase I than at the other division stages.