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.     

Kip3, the yeast kinesin-8, is required for clustering of kinetochores at metaphase

In Saccharomyces cerevisiae, chromosome congression clusters kinetochores on either side of the spindle equator at metaphase. Many organisms require one or more kinesin-8 molecular motors to achieve chromosome alignment. The yeast kinesin-8, Kip3, has been well studied in vitro but a role in chromosome congression has not beenreported. We investigated Kip3's role in this process using semi-automated, quantitative fluorescence microscopy and time-lapse imaging and found that Kip3 is required for congression. Deletion of KIP3 increases inter-kinetochore distances and increases the variability in the position of sister kinetochores along the spindle axis during metaphase. Kip3 does not regulate spindle length and is not required for kinetochore-microtubule attachment. Instead, Kip3 clusters kinetochores on the metaphase spindle by tightly regulating kinetochore microtubule lengths.     

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)     

The ultrastructure of the diffuse kinetochore in Luzula nivea

Material of Luzula nivea was fixed and processed in the normal way for sectioning and use of the transmission electron microscope. In addition, irradiated as well as control material was employed. Irradiation is known to produce chromosome breaks which rejoin. Apparent side-by-side adherence at metaphase of the chromosomes of Luzula nivea in control material disappeared at the earliest moment of anaphase and because of the high visibility of the kinetochores of this species, one pair of sister kinetochores could be readily associated with one pair of chromatids. Rejoining of chromosome breaks which does not disappear at anaphase, could not be distinguished at metaphase from the above described adherence. Chromatids also were apparently adherent at metaphase and it is pointed out that this is commonly seen in most organisms sectioned for the electron microscope. The apparent adherence is regarded as an artifact of fixation and subsequent processing. The authors do not agree with the interpretation of the chromosomes of Luzula as polycentric. From serial sections it has been established that in Luzula nivea a single diffuse kinetochore extends along most of the length of the chromosome, but does not occupy the whole width.     

ZW10 Helps Recruit Dynactin and Dynein to the Kinetochore

Mutations in the Drosophila melanogaster zw10 gene, which encodes a conserved, essential kinetochore component, abolish the ability of dynein to localize to kinetochores. Several similarities between the behavior of ZW10 protein and dynein further support a role for ZW10 in the recruitment of dynein to the kinetochore: (a) in response to bipolar tension across the chromosomes, both proteins mostly leave the kinetochore at metaphase, when their association with the spindle becomes apparent; (b) ZW10 and dynein both bind to functional neocentromeres of structurally acentric minichromosomes; and (c) the localization of both ZW10 and dynein to the kinetochore is abolished in cells mutant for the gene rough deal. ZW10''s role in the recruitment of dynein to the kinetochore is likely to be reasonably direct, because dynamitin, the p50 subunit of the dynactin complex, interacts with ZW10 in a yeast two-hybrid screen. Since in zw10 mutants no defects in chromosome behavior are observed before anaphase onset, our results suggest that dynein at the kinetochore is essential for neither microtubule capture nor congression to the metaphase plate. Instead, dynein''s role at the kinetochore is more likely to be involved in the coordination of chromosome separation and/or poleward movement at anaphase onset.     

Kip3, the yeast kinesin-8, is required for clustering of kinetochores at metaphase

In Saccharomyces cerevisiae, chromosome congression clusters kinetochores on either side of the spindle equator at metaphase. Many organisms require one or more kinesin-8 molecular motors to achieve chromosome alignment. the yeast kinesin-8, Kip3, has been well studied in vitro but a role in chromosome congression has not been reported. We investigated Kip3''s role in this process using semi-automated, quantitative fluorescence microscopy and time-lapse imaging and found that Kip3 is required for congression. Deletion of KIP3 increases inter-kinetochore distances and increases the variability in the position of sister kinetochores along the spindle axis during metaphase. Kip3 does not regulate spindle length and is not required for kinetochore-microtubule attachment. Instead, Kip3 clusters kinetochores on the metaphase spindle by tightly regulating kinetochore microtubule lengths.Key words: Cin8, cluster, GFP-tubulin, kinesin-5, kinesin-8, kinetochore, Kip3, metaphase, microtubule, mitosis, spindle     

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.     

Differential expression of a phosphoepitope at the kinetochores of moving chromosomes

A phosphorylated epitope is differentially expressed at the kinetochores of chromosomes in mitotic cells and may be involved in regulating chromosome movement and cell cycle progression. During prophase and early prometaphase, the phosphoepitope is expressed equally among all the kinetochores. In mid-prometaphase, some chromosomes show strong labeling on both kinetochores; others exhibit weak or no labeling; while in other chromosomes, one kinetochore is intensely labeled while its sister kinetochore is unlabeled. Chromosomes moving toward the metaphase plate express the phosphoepitope strongly on the leading kinetochore but weakly on the trailing kinetochore. This is the first demonstration of a biochemical difference between the two kinetochores of a single chromosome. During metaphase and anaphase, the kinetochores are unlabeled. At metaphase, a single misaligned chromosome can inhibit further progression into anaphase. Misaligned chromosomes express the phosphoepitope strongly on both kinetochores, even when all the other chromosomes of a cell are assembled at the metaphase plate and lack expression. This phosphoepitope may be involved in regulating chromosome movement to the metaphase plate during prometaphase and may be part of a cell cycle checkpoint by which the onset of anaphase is inhibited until complete metaphase alignment is achieved.     

The behaviour of kinetochore microtubules during meiosis in the fungusSaprolegnia

Summary InSaprolegnia, kinetochore microtubules persist throughout the mitotic nuclear cycle but, whilst present at leptotene, they disappear coincidently with the formation of synaptonemal complexes at pachytene and reform at metaphase I. In some other fungi chromosomal segregation is random in meiosis and non-random in mitosis. The attachment of chromosomes to persistent kinetochore microtubules in mitosis, but not meiosis, inSaprolegnia provides a plausible explanation for such behaviour. At metaphase I each bivalent is connected to the spindle by 2 laterally paired kinetochore microtubules whereas at metaphase II (as in mitosis) each univalent bears only one kinetochore microtubule, thus showing that all kinetochores are fully active at all stages of meiosis.     

Behaviour of chromosomal spindle fibres in living cells

Summary Mitosis in endosperm of Haemanthus katherinae was studied in vitro by the use of 16 mm time-lapse microcinematography. In several cells, chromosomal fibres were seen in phase contrast microscope. The fibres are more convergent in late metaphase and anaphase than in prometaphase. There exist two distinct fibre attachments at each daughter kinetochore, i.e. there are four in metaphase chromosome.Details of the division of a nearly cytoplasm-free mitotic apparatus are also reported as well as some data concerning the elongation of the spindle and activity of the phragmoplast.Dedicated to Professor H. Bauer on the occasion of his sixtieth birthday.     

The influence of heterochromatin, inversion-heterozygosity and somatic pairing on x-ray induced mitotic recombination in Drosophila melanogaster

Summary Mitotic recombination has been induced with X-rays in Drosophila melanogaster larvae and assayed later as twin mosaic spots in the adult eyes. When the X-chromosomes are marked with zeste and white and the third chromosomes with roughoid and sepia, the frequency of twin spots was about 20 times higher for the X-chromosome than for the third chromosome. The greater amount of heterochromatin in the X-chromosome was considered responsible for the difference.Experiments with different inversion heterozygotes support this interpretation. Euchromatic inversions of different lengths have, when heterozygous, little or no influence on the twin spot frequency. The shorter the heterochromatic segment between the kinetochore and the proxomal break point of the inversion the stronger is the reduction of the twin spot frequency.The heterozygotes for the long sc ⁸ and sc ^S1 inversions gave exceptionally low twin spot frequencies. It seems possible that potential twin spot daughter cells die after recombination because of genetic imbalance and/or lack of proper cell separation resulting from the persistence of the dikinetic chromosome elements.To test whether inaccurate somatic pairing in inversion heterozygotes could help explain the low twin spot frequencies in those of sc ⁸ and sc ^S1, neuroblast chromosomes were investigated. They show that chromosomal arrangement during metaphase is determined exclusively by the location of the kinetochore, which always points, irrespective of earlier somatic pairing, toward the center of the metaphase plate. It is possible that there is a lack of proper chromosome alignment at the X-ray sensitive stage for mitotic recombination.     

Dynein participates in chromosome segregation in fission yeast

Background information. In eukaryotic cells, proper formation of the spindle is necessary for successful cell division. For faithful segregation of sister chromatids, each sister kinetochore must attach to microtubules that extend to opposite poles (chromosome bi‐orientation). At the metaphase—anaphase transition, cohesion between sister chromatids is removed, and each sister chromatid is pulled to opposite poles of the cell by microtubule‐dependent forces. Results. We have studied the role of the minus‐end‐directed motor protein dynein by analysing kinetochore dynamics in fission yeast cells deleted for the dynein heavy chain (Dhc1) or the light chain (Dlc1). In these mutants, we found an increased frequency of cells showing defects in chromosome segregation, which leads to the appearance of lagging chromosomes and an increased rate of chromosome loss. By following simultaneously kinetochore dynamics and localization of the checkpoint protein Mad2, we provide evidence that dynein function is not necessary for spindle‐assembly checkpoint inactivation. Instead, we have demonstrated that loss of dynein function alters chromosome segregation and activates the Mad2‐dependent spindle‐assembly checkpoint. Conclusions. These results show an unexpected role for dynein in the control of chromosome segregation in fission yeast, most probably operating during the process of bi‐orientation during early mitosis.     

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.     

Kinetochore and microtubules in two members of Chlorophyceae,Cladophora fracta and Spirogyra majuscula

Evidence is presented for the existence of a localised kinetochore with stratified fine structure in Cladophora and in Spirogyra. In the latter, there is the possibility of two kinetochores on the longer chromosomes. There is no evidence for a diffuse kinetochore. The nucleolus persists during mitosis in Cladophora on the nucleolar organising chromosomes, the granular material being lost from it very largely during metaphase and anaphase but the fibrillar material remaining. The persistent nucleolar material at metaphase and anaphase in Spirogyra is not attached to the nucleolar organising chromosomes but accumulates around all the chromosomes and chromatids, the microtubules of the spindle at anaphase passing through and possibly attaching to this nucleolar material and possibly assisting in the movement of the chromatids which are embedded within it.     

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.     

Dissection of CENP-C–directed Centromere and Kinetochore Assembly

Eukaryotic cells ensure accurate chromosome segregation in mitosis by assembling a microtubule-binding site on each chromosome called the kinetochore that attaches to the mitotic spindle. The kinetochore is assembled specifically during mitosis on a specialized region of each chromosome called the centromere, which is constitutively bound by >15 centromere-specific proteins. These proteins, including centromere proteins A and C (CENP-A and -C), are essential for kinetochore assembly and proper chromosome segregation. How the centromere is assembled and how the centromere promotes mitotic kinetochore formation are poorly understood. We have used Xenopus egg extracts as an in vitro system to study the role of CENP-C in centromere and kinetochore assembly. We show that, unlike the histone variant CENP-A, CENP-C is not maintained at centromeres through spermatogenesis but is assembled at the sperm centromere from the egg cytoplasm. Immunodepletion of CENP-C from metaphase egg extract prevents kinetochore formation on sperm chromatin, and depleted extracts can be complemented with in vitro–translated CENP-C. Using this complementation assay, we have identified CENP-C mutants that localized to centromeres but failed to support kinetochore assembly. We find that the amino terminus of CENP-C promotes kinetochore assembly by ensuring proper targeting of the Mis12/MIND complex and CENP-K.     

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.     

Bub3 promotes Cdc20-dependent activation of the APC/C in S. cerevisiae

The spindle checkpoint ensures accurate chromosome segregation by sending a signal from an unattached kinetochore to inhibit anaphase onset. Numerous studies have described the role of Bub3 in checkpoint activation, but less is known about its functions apart from the spindle checkpoint. In this paper, we demonstrate that Bub3 has an unexpected role promoting metaphase progression in budding yeast. Loss of Bub3 resulted in a metaphase delay that was not a consequence of aneuploidy or the activation of a checkpoint. Instead, bub3Δ cells had impaired binding of the anaphase-promoting complex/cyclosome (APC/C) with its activator Cdc20, and the delay could be rescued by Cdc20 overexpression. Kinetochore localization of Bub3 was required for normal mitotic progression, and Bub3 and Cdc20 colocalized at the kinetochore. Although Bub1 binds Bub3 at the kinetochore, bub1Δ cells did not have compromised APC/C and Cdc20 binding. The results demonstrate that Bub3 has a previously unknown function at the kinetochore in activating APC/C-Cdc20 for normal mitotic progression.     

Mitosis in the protostelidPlanoprotostelium aurantium

Summary Mitosis in the protostelidPlanoprotostelium aurantium Olive andStoianovich is characterized by an open, centric spindle. The nuclear envelope breaks down prior to metaphase, begins to reform during late anaphase, and is complete by telophase. Centrioles are present at the poles throughout mitosis and are devoid of rootlet microtubules from metaphase to late anaphase. Chromosomes are small and numerous and are attached to single kinetochore microtubules during metaphase and early anaphase. Chromosome separation takes place by a presumed shortening of the chromosome to pole spindle followed by a lengthening of the interzonal spindle. Mitosis inP. aurantium is similar to that of certain other protostelid amoebae and to myxomycete amoebae, but it is considerably different from that of dictyostelid amoebae. The phylogenetic significance of this is discussed.This research represents part of a Ph.D. dissertation presented to the University of North Carolina.     

Malorientation in half-bivalents at anaphase in crane fly spermatocytes following Colcemid treatment

Addition of Colcemid to the medium in which larvae of the crane fly Nephrotoma suturalis are cultivated induces a number of anomalous patterns of chromosome segregation. One of these is the anaphase lagging of autosomal half-bivalents. To investigate the cause of anaphase lagging, the orientation of sister kinetochores in Colcemidtreated spermatocytes having lagging half-bivalents was analyzed in serial sections. In contrast to nonlaggard halfbivalents that had pure syntelic orientation (sister kinetochores having all of their kinetochores microtubules (KMTs) extending to the same pole), six of the seven autosomal laggards that were selected for analysis had kinetochores with either amphitelic orientation (sister kinetochores each with a bundle of KMTs extending to opposite poles) or merotelic orientation (a single kinetochore having KMTs extending toward both poles). An additional laggard had syntelic orientation but two of the microtubules that were in its kinetochore fiber passed through the kinetochore and extended beyond it toward the equator. The bipolar malorientations observed in anaphase half-bivalents are interpreted to be a cause of the anaphase lagging induced by Colcemid treatment. Furthermore, it is hypothesized that such bipolar malorientations also may be stabilized at metaphase and thus explain the unusual tilting of metaphase bivalents commonly observed in Colcemid-treated cells.