Origin of kinetochore microtubules in Chinese hamster ovary cells

We have attempted to determine whether chromosomal microtubules arise by kinetochore nucleation or by attachment of pre-existing microtubules. The appearance of new microtubules was investigated in vivo on kinetochores to which microtubules had not previously been attached. The mitotic apparatus of Chinese hamster ovary cells was reconstructed in three dimensions from 0.25 m thick serial sections, and the location of chromosomes, kinetochore outer disks, centrioles, virus-like particles and microtubules determined. Central to the interpretation of these data is a synchronization scheme in which cells entered Colcemid arrest without forming mitotic microtubules. Cells were synchronized by the excess thymidine method and exposed to 0.3 g/ml Colcemid for 8 h. Electron microscopic examination showed that this Colcemid concentration eliminated all microtubules. Mitotic cells were collected by shaking off, and cell counts showed that over 95% of the cells were in interphase when treatment began and thus were arrested without the kinetochores having been previously attached to microtubules. Cells were then incubated in fresh medium and fixed for high voltage electron microscopy at intervals during recovery. — In early stages of recovery, short microtubules were observed near and in contact with kinetochores and surrounding centrioles. Microtubules were associated with kinetochores facing away from centrosomes and far from any centrosomal microtubules, and thus were not of centrosomal origin. At a later stage of recovery, long parallel bundles of microtubules, terminating in the kinetochore outer disk, extended from kinetochores both toward and away from centrosomes. Because microtubules had never been attached to kinetochores, the possibility that kinetochore microtubles were initiated by microtubule stubs resistant to Colcemid was eliminated. Therefore we conclude that mammalian kinetochores can initiate microtubules in vivo, thus serving as microtubule organizing centers for the mitotic spindle, and that formation of kinetochore-microtubule bundles is not dependent on centrosomal activity.     

Structure of kinetochore fibers: Microtubule continuity and inter-microtubule bridges

To understand how microtubules interact in forming the mitotic apparatus and orienting and moving chromosomes, the precise arrangement of microtubules in kinetochore fibers in Chinese hamster ovary cells was examined. Individual microtubules were traced, using high voltage electron microscopy of serial 0.25 m sections, from the kinetochore toward the pole. Microtubule arrangement in kinetochore fibers in untreated mitotic cells and in cells recovering from Colcemid arrest were similar in two respects: the number of microtubules per kinetochore (mean 14 and 12, respectively) and the nearest neighbor intermicrotubule distance (mean90 nm). In Colcemid recovered cells, over 90% of the microtubules in kinetochore fibers were attached to the kinetochore (i.e. kinetochore microtubules) and extended most or all of the distance to the pole. Few free microtubules were present in the kinetochore fibers; most non-kinetochore microtubles terminated in the pole. Since kinetochores in this Colcemid-recovered system have been demonstrated to nucleate microtubules (Witt et al., 1980), it seems likely that most if not all of these kinetochore microtubules originated at the kinetochore. Some of the reconstructed kinetochore fibers were attached to chromosomes with bipolar orientation, suggesting that kinetochore microtubules need not interact with many polar microtubules for orientation to occur. In Colcemid recovered cells lysed to reduce cytoplasmic background, microtubules in kinetochore fibers were preferentially preserved. The parallel and near-hexagonal order typical of microtubules in kinetochore fibers was maintained, as was the number of kinetochore microtubules (mean, 13). The intermicrotubule distance was slightly reduced in lysed cells (mean, 60 nm). Crossbridges about 5 nm wide and 30–40 nm long were visible in kinetochore fibers of lysed cells. Such crossbridges probably contribute to the stabilization and parallel order of microtubules in kinetochore fibers, and may have a functional role as well.     

Polarity of kinetochore microtubules in Chinese hamster ovary cells after recovery from a colcemid block

The polarity of kinetochore microtubules was determined in a system for which kinetochore-initiated microtubule assembly has been demonstrated. Chinese hamster ovary cells were treated with 0.3 micrograms/ml colcemid for 8 h and then released from the block. Prior to recovery, microtubules were completely absent from the cells. The recovery was monitored using light and electron microscopy to establish that the cells progress through anaphase and that the kinetochore fibers are fully functional. Since early stages of recovery are characterized by short microtubule segments that terminate in the kinetochore fibrous corona rather than on the outer disk, microtubule polarity was determined at later stages of recovery when longer kinetochore bundles had formed, allowing us to establish unambiguously the spatial relationship between microtubules, kinetochores, and chromosomes. The cells were lysed in a detergent mixture containing bovine brain tubulin under conditions that allowed the formation of polarity-revealing hooks. 20 kinetochore bundles were assayed for microtubule polarity in either thick or thin serial sections. We found that 95% of the decorated kinetochore microtubules had the same polarity and that, according to the hook curvature, the plus ends of the microtubules were at the kinetochores. Hence, the polarity of kinetochore microtubules in Chinese hamster ovary cells recovering from a colcemid block is the same as in normal untreated cells. This result suggests that microtubule polarity is likely to be important for spindle function since kinetochore microtubules show the same polarity, regardless of the pattern of spindle formation.     

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.     

Localization of CENP-E in the fibrous corona and outer plate of mammalian kinetochores from prometaphase through anaphase

We have conducted a detailed ultrastructural analysis of the distribution of the kinesin-related centromere protein CENP-E during mitosis in cultured human, rat kangaroo and Indian muntjac cells. Using an affinity-purified polyclonal antibody and detection by 0.8 nm colloidal gold particles, CENP-E was localized primarily to the fibrous corona of the kinetochore in prometaphase and metaphase cells. Some labeling of the kinetochore outer plate was also observed. The distribution of fibrous corona-associated CENP-E did not change dramatically following the attachment of microtubules to the kinetochore. Thus, the normal disappearance of this kinetochore substructure in conventional electron micrographs of mitotic chromosomes with attached kinetochores is not due to the corona becoming stretched along the spindle microtubules as has been suggested. Examination of cells undergoing anaphase chromatid movement revealed the presence of CENP-E still associated with the outer surface of the kinetochore plate. At the same time, the majority of detectable CENP-E in these cells was associated with the bundles of antiparallel microtubules in the central spindle. CENP-E in this region of the cell is apparently associated with the stem body matrix material. The simultaneous localization of CENP-E on centromeres and the central spindle during anaphase was confirmed by both wide-field microscopy of human cells and conventional fluorescence microscopy of rat kangaroo cells. Together, the observations reported here are consistent with models in which CENP-E has a role in promoting the poleward migration of sister chromatids during anaphase A. Received: 21 July 1997 /Accepted: 19 September 1997     

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.     

The human Mis12 complex is required for kinetochore assembly and proper chromosome segregation

During cell division, kinetochores form the primary chromosomal attachment sites for spindle microtubules. We previously identified a network of 10 interacting kinetochore proteins conserved between Caenorhabditis elegans and humans. In this study, we investigate three proteins in the human network (hDsn1Q9H410, hNnf1PMF1, and hNsl1DC31). Using coexpression in bacteria and fractionation of mitotic extracts, we demonstrate that these proteins form a stable complex with the conserved kinetochore component hMis12. Human or chicken cells depleted of Mis12 complex subunits are delayed in mitosis with misaligned chromosomes and defects in chromosome biorientation. Aligned chromosomes exhibited reduced centromere stretch and diminished kinetochore microtubule bundles. Consistent with this, localization of the outer plate constituent Ndc80HEC1 was severely reduced. The checkpoint protein BubR1, the fibrous corona component centromere protein (CENP) E, and the inner kinetochore proteins CENP-A and CENP-H also failed to accumulate to wild-type levels in depleted cells. These results indicate that a four-subunit Mis12 complex plays an essential role in chromosome segregation in vertebrates and contributes to mitotic kinetochore assembly.     

Localization of tubulin in the mitotic apparatus of mammalian cells by immunofluorescence and immunoelectron microscopy

Antitubulin antibody was used as an immunofluorescent and immunoelectron microscopic probe to localize tubulin in components of the mitotic apparatus of rat kangaroo (strain PtK₁) cells in vitro. In addition to the detection of tubulin in the spindle microtubules and centrioles, other structures were found to display specific staining including kinetochores, amorphous pericentriolar material and small virus-like particles associated with the centrioles. The kinetochores consisted of a densely stained outer layer about 400 Å thick which is separated from an inner layer of the same dimension by a lightly staining middle layer. Microtubules were primarily associated with the outermost plate of the kinetochore but tubulin was uniformly distributed in both outer and inner plates. Colcemid treatment prevented the assembly of spindle microtubules and resulted in specific alterations of the kinetochore but failed to diminish the staining of the kinetochores. These observations suggest that tubulin molecules may comprise an important structural component of the kinetochore.     

The mechanism of kinetochore-spindle attachment and polewards movement analyzed in PtK2 cells at the prophase-prometaphase transition

PtK2 cells at the prophase-prometaphase transition were analyzed to study the origin of kinetochore microtubules, the mode of kinetochore fiber construction and the mechanism of polewards movement. Attention was focused on chromosomes which, as deduced from video time-lapse tapes, had just started their initial characteristic movement towards one of the poles. In the same cell, the arrangement of microtubules in the vicinity of the kinetochore region was visualized either with indirect immunofluorescence and confocal fluorescence microscopy, or with electron microscopy in semithin sections of cells, immunostained for microtubules and embedded in epon. The results strengthen the evidence that kinetochore microtubules are nucleated in the centrosomal region. Bundles of microtubules, some ending at the kinetochore and others passing beyond it, are formed rapidly, seemingly without influencing the rapid rate of movement. They also show that microtubules often establish contact with kinetochores by lateral interaction, prior to kinetochore-pole orientation, and that kinetochores can move polewards along the microtubule wall of attached microtubules, independently of the latter's dynamics. These findings confirm and extend to the earliest chromosome movements at the prophase-prometaphase transition, the results of Rieder and Alexander (J. Cell Biol. 110, 81-95, (1990)), who studied the attachment and polewards movement of chromosomes strongly delayed in forming an attachment to the spindle. They are discussed in the light of recent evidence for the localization of dynein to kinetochores and contemporary models for kinetochore structure and function.     

A new look at kinetochore structure in vertebrate somatic cells using high-pressure freezing and freeze substitution

Three decades of structural analysis have produced the view that the kinetochore in vertebrate cells is a disk-shaped structure composed of three distinct structural domains. The most prominent of these consists of a conspicuous electron opaque outer plate that is separated by a light-staining electron-translucent middle plate from an inner plate associated with the surface of the pericentric heterochromatin. Spindle microtubules terminate in the outer plate and, in their absence, a conspicuous corona of fine filaments radiates from the cytoplasmic surface of this plate. Here we report for the first time the ultrastructure of kinetochores in untreated and Colcemid-treated vertebrate somatic (PtK₁) cells prepared for optimal structural preservation using high-pressure freezing and freeze substitution. In serial thin sections, and electron tomographic reconstructions, the kinetochore appears as a 50–75 nm thick mat of light-staining fibrous material that is directly connected with the more electron-opaque surface of the centromeric heterochromatin. This mat corresponds to the outer plate in conventional preparations, and is surrounded on its cytoplasmic surface by a conspicuous 100–150 nm wide zone that excludes ribosomes and other cytoplasmic components. High magnification views of this zone reveal that it contains a loose network of light-staining, thin (<9 nm diameter) fibers that are analogous to the corona fibers in conventional preparations. Unlike the chromosome arms, which appear uniformly electron opaque, the chromatin in the primary constriction appears mottled. Since the middle plate is not visible in these kinetochore preparations this feature is likely an artifact produced by extraction and coagulation during conventional fixation and/or dehydration procedures. Received: 7 August 1998; in revised form: 18 August 1998 / Accepted: 20 August 1998     

Holokinetic composite chromosomes with “diffuse” kinetochores in the micronuclear mitosis of a heterotrichous ciliate

During micronuclear mitosis of the heterotrichous ciliate Nyctotherus ovalis Leidy rod-shaped composite chromosomes are formed by lateral association of telokinetic chromosomes. The formation of these composite chromosomes seems to be a highly ordered process since only nuclei with either 18 or 24 such chromosomes can be observed, and nuclei with the same chromosome number show a similar length distribution of their chromosomes. Further, these data indicate that we examined two otherwise indistinguishable races. During metaphase the composite chromosomes become arranged in the spindle equator in a holokinetic fashion, their entire poleward surfaces being covered by kinetochore material. These diffuse kinetochores have a trilaminar appearance comparable to those of monokinetic chromosomes. Their electron density after employing Bernhard's procedure revealed the same ribonucleoprotein distribution as reported for the localized kinetochores formed during the extranuclear mitosis in other cells. During early anaphase the outer kinetochore layer remains continuous while the individual chromosomes in the composite group show a tendency to separate leaving chromatin-free spaces of about 40 nm diameter. Kinetochore microtubules which are still anchored in the outer kinetochore layer seem to elongate and to extend into the interpolar spindle region predominantly through these holes in the chromatin. These observations suggest a like polarity of kinetochore and interpolar microtubules in the polar spindle region while microtubules in the interpolar space seem to interdigitate in an antiparallel fashion. The activity of the kinetochore to act as a microtubule-organizing center (MTOC) seems to be modulated by the chromatin underlying the outer kinetochore layer which may prevent further outgrowth of kinetochore microtubules.     

Measuring the stoichiometry and physical interactions between components elucidates the architecture of the vertebrate kinetochore

Vertebrate kinetochores contain over 50 different proteins organized into three distinct regions: the inner plate, outer plate, and fibrous corona. The present study characterizes numerous precursors of kinetochore assembly in a system free of centromeric chromatin, Xenopus extracts. Hydrodynamic analysis suggests there are a minimum of two monomeric proteins and six pre-assembled complexes that accumulate on centromeres to form the kinetochore. The inner and outer kinetochore assemble from at least two distinct kinetochore complexes containing the proteins Mis12, Zwint, and Ndc80, all of which interact by immunoprecipitation. There is also a network of interactions between the fibrous corona proteins that is dissociated by microtubules. We quantify the number of molecules of specific proteins assembled into a single kinetochore. There are between 800 and 1200 molecules of the measured inner and outer kinetochore proteins, demonstrating that the components in these regions are in similar stoichiometry. In contrast, the measured fibrous corona proteins are present at 250-300 molecules per kinetochore. Zwint, but not Mis12, requires the Ndc80 complex for assembly into the kinetochore. Further, Ndc80 requires Zwint for assembly, indicating a co-dependency for these two proteins. Our data provide a model for the structural architecture and assembly pathway of the vertebrate kinetochore.     

Cell division in two large pennate diatoms Hantzschia and Nitzschia III. A new proposal for kinetochore function during prometaphase

Prometaphase in two large species of diatoms is examined, using the following techniques: (a) time-lapse cinematography of chromosome movements in vivo; (b) electron microscopy of corresponding stages: (c) reconstruction of the microtubules (MTs) in the kinetochore fiber of chromosomes attached to the spindle. In vivo, the chromosomes independently commence oscillations back and forth to one pole. The kinetochore is usually at the leading edge of such chromosome movements; a variable time later both kinetochores undergo such oscillations but toward opposite poles and soon stretch poleward to establish stable bipolar attachment. Electron microscopy of early prometaphase shows that the kinetochores usually laterally associate with MTs that have one end attached to the spindle pole. At late prometaphase, most chromosomes are fully attached to the spindle, but the kinetochores on unattached chromosomes are bare of MTs. Reconstruction of the kinetochore fiber demonstrates that most of its MTs (96%) extend past the kinetochore and are thus apparently not nucleated there. At least one MT terminates at each kinetochore analyzed. Our interpretation is that the conventional view of kinetochore function cannot apply to diatoms. The kinetochore fiber in diatoms appears to be primarily composed of MTs from the poles, in contrast to the conventional view that many MTs of the kinetochore fiber are nucleated by the kinetochore. Similarly, chromosomes appear to initially orient their kinetochores to opposite poles by moving along MTs attached to the poles, instead of orientation effected by kinetochore MTs laterally associating with other MTs in the spindle. The function of the kinetochore in diatoms and other cell types is discussed.     

The Microtubule-dependent Motor Centromere–associated Protein E (CENP-E) Is an Integral Component of Kinetochore Corona Fibers That Link Centromeres to Spindle Microtubules

Centromere-associated protein E (CENP-E) is a kinesin-related microtubule motor protein that is essential for chromosome congression during mitosis. Using immunoelectron microscopy, CENP-E is shown to be an integral component of the kinetochore corona fibers that tether centromeres to the spindle. Immediately upon nuclear envelope fragmentation, an associated plus end motor trafficks cytoplasmic CENP-E toward chromosomes along astral microtubules that enter the nuclear volume. Before or concurrently with initial lateral attachment of spindle microtubules, CENP-E targets to the outermost region of the developing kinetochores. After stable attachment, throughout chromosome congression, at metaphase, and throughout anaphase A, CENP-E is a constituent of the corona fibers, extending at least 50 nm away from the kinetochore outer plate and intertwining with spindle microtubules. In congressing chromosomes, CENP-E is preferentially associated with (or accessible at) the stretched, leading kinetochore known to provide the primary power for chromosome movement. Taken together, this evidence strongly supports a model in which CENP-E functions in congression to tether kinetochores to the disassembling microtubule plus ends.     

Structure of the colcemid-treated PtK1 kinetochore outer plate as determined by high voltage electron microscopic tomography

High voltage electron microscopic tomography was used to determine the organization of the kinetochore plate and its attachment to the underlying chromosome. Six reconstructions were computed from thick sections of Colcemid-treated PtK1 cells and analyzed by a number of computer graphics methods including extensive thin slicing, three- dimensional masking, and volume rendering. When viewed en-face the kinetochore plate appeared to be constructed from a scaffold of numerous 10-20-nm thick fibers or rods. Although the fibers exhibited regions of parallel alignment and hints of a lattice, they were highly variable in length, orientation and spacing. When viewed in stereo, groups of these fibers were often seen oriented in different directions at different depths to give an overall matted appearance to the structure. When viewed "on edge," the plate was 35-40 nm thick, and in thin slices many regions were tripartite with electron-opaque domains, separated by a more translucent middle layer, forming the inner and outer plate boundaries. These domains were joined at irregular intervals. In some slices, each domain appeared as a linear array of 10- 20-nm dots or rods embedded in a less electron-opaque matrix, and adjacent dots within or between domains often appeared fused to form larger blocks. The plate was connected to the underlying chromosome by less densely arrayed 10-20-nm thick fibers that contacted the chromosome-facing (i.e., inner) surface of the plate in numerous patches. These patches tended to be arrayed in parallel rows perpendicular to the long axis of the chromosome. In contrast to connecting fibers, corona fibers were more uniformly distributed over the cytoplasmic-facing (i.e., outer) surface of the plate. When large portions of the reconstructions were viewed, either en-face or in successive slices parallel to the long axis of the chromosome, the edges of the plate appeared splayed into multiple "fingers" that partly encircled the primary constriction. Together these observations reveal that regions of the kinetochore outer plate contain separate structural domains, which we hypothesize to serve separate functional roles. Our three-dimensional images of the kinetochore are largely consistent with the hypothesis that the outer plate is composed of multiple identical subunits (Zinkowski, R. P., J. Meyne, and B. R. Brinkley. 1991. J. Cell Biol. 113:1091-1110).     

Kinetochore structure: electron spectroscopic imaging of the kinetochore

The structure of the kinetochore in thin section has been studied in the Indian muntjac by an electron spectroscopic imaging technique. This procedures allows the analysis of the distribution of phosphorus within the layers of the kinetochore. The results indicate that this element is a major component of both the inner and outer plates whereas it is largely absent in the middle plate and fibrous corona. The majority of the phosphorus is localized to a 30-nm fiber(s) that is woven through the layers of the kinetochore. The presence of phosphorus within this fiber, along with its morphological and biochemical features, indicates that it contains DNA. The fiber(s) occupies a major portion of the inner and outer plate where it forms a series of rows. It is rarely observed in the middle layer except where it passes between the inner and outer layers. The absence of structure in the middle plate suggests that it may represent a space rather than a plate that in turn may be related to the function of this region. The distribution of phosphorus within the kinetochore is neither altered by treatment with colcemid nor by the presence of microtubules at the kinetochore. Analysis of conventional micrographs of the kinetochore together with structural information obtained by electron spectroscopic imaging suggests that most microtubules insert and terminate between the rows of kinetochore fibers in the outer plate. However, some microtubules continue through the middle layer and terminate at the lower plate. The insertion of microtubules at different levels of the kinetochore may reflect the existence of functionally distinct microtubule classes. Electron spectroscopic imaging indicates that the microtubules associated with the kinetochore are phosphorylated.     

Beclin‐1 is required for chromosome congression and proper outer kinetochore assembly

The functions of Beclin‐1 in macroautophagy, tumorigenesis and cytokinesis are thought to be mediated by its association with the PI3K‐III complex. Here, we describe a new role for Beclin‐1 in mitotic chromosome congression that is independent of the PI3K‐III complex and its role in autophagy. Beclin‐1 depletion in HeLa cells leads to a significant reduction of the outer kinetochore proteins CENP‐E, CENP‐F and ZW10, and, consequently, the cells present severe problems in chromosome congression. Beclin‐1 associates with kinetochore microtubules and forms discrete foci near the kinetochores of attached chromosomes. We show that Beclin‐1 interacts directly with Zwint‐1—a component of the KMN (KNL‐1/Mis12/Ndc80) complex—which is essential for kinetochore–microtubule interactions. This suggests that Beclin‐1 acts downstream of the KMN complex to influence the recruitment of outer kinetochore proteins and promotes accurate kinetochore anchoring to the spindle during mitosis.     

Quantitative initiation of microtubule assembly by chromosomes from Chinese hamster ovary cells

The microtubule nucleating capacity of chromosomes was tested in vitro in lysates of Chinese hamster ovary cells. Colcemid-blocked mitotic cells were lysed with the detergent Triton X-100, incubated with exogenous porcine brain tubulin, attached to electron microscope grids and observed as whole-mounts. Under suitable conditions, greater than 98% of the chromosomes gave rise to microtubules at their kinetochore regions, thus unequivocally demonstrating that chromosomes are competent to initiate specifically microtubule formation. The average number of microtubules that polymerized onto a chromosome was 8 +/- 5, and greater than 36% of the chromosomes had between 10 and 19 microtubules per kinetochore region. We conclude that under the lysis conditions employed, virtually all the chromosomes retain their kinetochores, and that the kinetochores retain a substantial fraction of their microtubule nucleating capacity.     

The three-dimensional architecture of chromosome fibres in the crane fly

Microtubules of amphitelically oriented sex univalent chromosome fibres were traced in longitudinal serial sections. The investigated chromosomes were from four different cells representing consecutive stages of anaphase segregation. A correlation was found between chromosome movement and a characteristic distribution of free microtubules (fMTs) oriented obliquely with respect to the kinetochore microtubules. During chromosome segregation the proportion of these skew fMTs (the proportion of skew fMTs is a measure of the degree of disorder in the fibre) is higher in the fibre pointing in the direction of movement than in the trailing fibre. The results are discussed in relation to spindle forces. Although the anaphase of amphitelic sex chromosomes is different in several respects (orientation of chromosome fibres, mutual connexion of chromosomes via kinetochore microtubules, spindle elongation occurring simultaneously), the observations on the distribution of fMTs in the chromosome fibres is, in principle, compatible with those previously made on syntelic autosomes.