Chromosome segregation in crane-fly spermatocytes: cold treatment and cold recovery induce anaphase lag

Anaphase lagging of autosomes was observed in 6.1±5.4% of the primary spermatocytes in untreated larvae of the crane fly, Nephrotoma suturalis. Lagging was induced by exposure of larvae to 6 ° C and during recovery at 22 ° C from exposure to 0.2, 2, and 6 ° C. The incidence of anaphase lag was maximal at 80 to 90 min of recovery. Induced lagging was observed at that recovery time after exposures of only 2.5 h to 2 or 0.2 ° C, but its incidence increased with longer exposures. As many as 85% of the cells in anaphase contained autosomal laggards after 61 h at 2 ° C and 80 to 90 min of recovery. At 2 ° C, cells reached the prophase-prometaphase transition, but spindles did not appear to form. Those cells proceeded through prometaphase during recovery, reaching mid-anaphase after 80 to 90 min of recovery. Chromosomes that lagged at anaphase during recovery from 2 ° C were observed in living cells to be half-bivalents derived from bivalents that congressed to the metaphase plate. One or both half-bivalents of any bivalent could lag. In some cells, one half-spindle had more half-bivalents than the other. Cells with autosomal laggards often did not cleave, and in uncleaved cells the second division employed spindles having two, three, or four poles. The basis of induced lagging might be a lapse in spindle attachment or motive force application at the start of anaphase or a failure of chromosomes to achieve proper orientation before the onset of anaphase.     

Centromeric dots in crane-fly spermatocytes: meiotic maturation and malorientation

During the first meiotic division in crane-fly spermatocytes, the two homologs of a metaphase bivalent each bear two sister kinetochores oriented toward the same pole. We have previously reported treatments that increase the percentage of metaphase bivalents in which one or both homologs have bipolar malorientations: kinetochore microtubules] extending from a homolog toward both poles. The maloriented homologs lag at anaphase. Treatments that induce this behavior include: (a) recoverey from exposure to low temperatures or Colcemid or Nocodazole concentrations that prevent spindle formation but allow nuclear membrane breakdown, and (b) exposure to 6° C, a temperature that permits spindle assembly but slows progression through meiosis. Giemsa staining methods reveal two 0.5 m diameter dots at the centromeric region of each metaphase homolog; these often are more separated in maloriented homologs. This investigation was undertaken to assess whether this separation precedes the establishment of bipolar malorientation, and hence may be a cause of it, or is only a consequence of forces resulting from bipolar malorientation. Analysis showed that, in untreated cells, the average center-to-center distance between sister centromeric dots increases during the course of meiosis I. After the above-mentioned treatments, center-to-center distances similar to those normally seen in untreated half-bivalents at anaphase I were seen in bivalents, both after and before nuclear membrane breakdown. Longer exposure to temperatures that arrested meiosis increased the degree of dot separation. Based on our data, we conclude that normal orientation during the first meiotic division is aided by the close apposition of centromeric dots, and that a time-dependent maturation occurs causing centromeric dots to separate for the second meiotic division and facilitating orientation of sister kinetochores to opposite poles. If centromeric maturation occurs either prior to or during early stages of the first meiotic division, then it may contribute to persisting bipolar malorientation.     

Centrifugation shearing exposes filamentous networks in cortical regions of crane-fly spermatocytes

Spermatocytes of the crane-fly, Nephrotoma suturalis, were attached to electron microscope grids and then sheared by applying centrifugal force. Transmission electron microscopy of exposed regions of the cell cortex revealed networks containing arrays of filamentous structures. Networks were present in sheared spermatocytes at all stages of meiosis. The networks of dividing spermatocytes (meta- through telophase) were denser and appeared to contain more aggregated material then networks of prophase cells. The appearance of networks in spermatocytes resembled actin-containing networks of sheared and detergent-extracted human erythrocytes. Networks treated with myosin subfragment 1 under conditions in which muscle F-actin was clearly decorated were not distinguishable from those of untreated cells. Exposure to deoxyribonuclease-1 caused the disruption of networks in sheared spermatocytes as well as in erythrocytes. The results of deoxyribonuclease experiments are interpreted as an indication that actin is a component of the cell cortex in crane-fly spermatocytes.     

Direct visualization of microtubule flux during metaphase and anaphase in crane-fly spermatocytes

Microtubule flux in spindles of insect spermatocytes, long-used models for studies on chromosome behavior during meiosis, was revealed after iontophoretic microinjection of rhodamine-conjugated (rh)-tubulin and fluorescent speckle microscopy. In time-lapse movies of crane-fly spermtocytes, fluorescent speckles generated when rh-tubulin incorporated at microtubule plus ends moved poleward through each half-spindle and then were lost from microtubule minus ends at the spindle poles. The average poleward velocity of approximately 0.7 microm/min for speckles within kinetochore microtubules at metaphase increased during anaphase to approximately 0.9 microm/min. Segregating half-bivalents had an average poleward velocity of approximately 0.5 microm/min, about half that of speckles within shortening kinetochore fibers. When injected during anaphase, rhtubulin was incorporated at kinetochores, and kinetochore fiber fluorescence spread poleward as anaphase progressed. The results show that tubulin subunits are added to the plus end of kinetochore microtubules and are removed from their minus ends at the poles, all while attached chromosomes move poleward during anaphase A. The results cannot be explained by a Pac-man model, in which 1) kinetochore-based, minus end-directed motors generate poleward forces for anaphase A and 2) kinetochore microtubules shorten at their plus ends. Rather, in these cells, kinetochore fiber shortening during anaphase A occurs exclusively at the minus ends of kinetochore microtubules.     

Distance segregation of sex chromosomes in crane-fly spermatocytes studied using laser microbeam irradiations

Univalent sex chromosomes in crane-fly spermatocytes have kinetochore spindle fibres to each spindle pole (amphitelic orientation) from metaphase throughout anaphase. The univalents segregate in anaphase only after the autosomes approach the poles. As each univalent moves in anaphase, one spindle fibre shortens and the other spindle fibre elongates. To test whether the directionality of force production is fixed at anaphase, that is, whether one spindle fibre can only elongate and the other only shorten, we cut univalents in half with a laser microbeam, to create two chromatids. In both sex-chromosome metaphase and sex-chromosome anaphase, the two chromatids that were formed moved to opposite poles (to the poles to which their fibre was attached) at speeds about the same as autosomes, much faster than the usual speeds of univalent movements. Since the chromatids moved to the pole to which they were attached, independent of the direction to which the univalent as a whole was moving, the spindle fibre that normally elongates in anaphase still is able to shorten and produce force towards the pole when allowed (or caused) to do so.     

Actin and myosin inhibitors block elongation of kinetochore fibre stubs in metaphase crane-fly spermatocytes

Summary. We used an ultraviolet microbeam to cut individual kinetochore spindle fibres in metaphase crane-fly spermatocytes. We then followed the growth of the “kinetochore stubs”, the remnants of kinetochore fibres that remain attached to kinetochores. Kinetochore stubs elongate with constant velocity by adding tubulin subunits at the kinetochore, and thus elongation is related to tubulin flux in the kinetochore microtubules. Stub elongation was blocked by cytochalasin D and latrunculin A, actin inhibitors, and by butanedione monoxime, a myosin inhibitor. We conclude that actin and myosin are involved in generating elongation and thus in producing tubulin flux in kinetochore microtubules. We suggest that actin and myosin act in concert with a spindle matrix to propel kinetochore fibres poleward, thereby causing stub elongation and generating anaphase chromosome movement in nonirradiated cells. Correspondence: A. Forer, Biology Department, York University, 4700 Keele Street, Toronto, ON M3J 1P3, Canada.     

Backward chromosome movement in crane-fly spermatocytes after UV microbeam irradiation of the interzone and a kinetochore

Single anaphase chromosomes (in crane-fly spermatocytes) moved backwards after double irradiations with an ultraviolet light (UV) microbeam, first of the interzone and then of a kinetochore: the chromosome irradiated at the kinetochore moved backwards rapidly, across the equator and into the other half-spindle. High irradiation doses at the kinetochore were required to induce backward movement. Single irradiations of kinetochores or interzones were ineffective in inducing backward movements.     

Jasplakinolide, an actin stabilizing agent, alters anaphase chromosome movements in crane-fly spermatocytes

We added jasplakinolide to anaphase crane-fly spermatocytes and determined its effects on chromosome movement. Previous work showed that the actin depolymerizing agents cytochalasin D or latrunculin B blocked or slowed chromosome movements. We studied the effects of jasplakinolide, a compound that stabilizes actin filaments. Jasplakinolide had the same effect on movements of each half- bivalent in a separating pair of half-bivalents, but different half-bivalent pairs in the same cell often responded differently, even when the concentrations of jasplakinolide varied by a factor of two. Jasplakinolide had no effect on about 20% of the pairs, but otherwise caused movements to slow, or to stop, or, rarely, to accelerate. When cells were kept in jasplakinolide, stopped pairs eventually resumed movement; slowed pairs did not change their speeds. Confocal microscopy indicated that neither the distributions of spindle actin filaments nor the distributions of spindle microtubules were altered by the jasplakinolide. It is possible that jasplakinolide binds to spindle actin and blocks critical binding sites, but we suggest that jasplakinolide affects anaphase chromosome movement by preventing actin-filament depolymerization that is necessary for anaphase to proceed. Overall, our data indicate that actin is involved in one of the redundant mechanisms cells use to move chromosomes.     

A comparative study of orientation at behavior of univalent in living grasshopper spermatocytes

Orientational movements and modes of segregation at anaphase I were analyzed in three different types of univalents in living spermatocytes of the grasshopper species Eyprepocnemis plorans, namely the sex univalent, three types of accessory chromosomes and spontaneous and induced autosomal univalents. When two or more univalents were present in the same spindle, their dynamics were directly compared. Chromosomes may show variable velocity and number of reorientations: the X and the most common B types (B₁ and B₂) are slow and rarely reorient, a more geographically restricted B (B₅) is faster and reorients more often, and autosomal univalents are the fastest and show the highest frequency of reorientations. Nonetheless, the X and the accessories are rigorously reductional at anaphase I whereas autosomal univalents often fail to migrate or divide equationally. This indicates that orientational and segregational behavior are controlled mainly by chromosomal rather than cellular characteristics and that chromosomes may display a great variety of strategies to achieve regular segregation.     

Effects of anti-myosin drugs on anaphase chromosome movement and cytokinesis in crane-fly primary spermatocytes.

To investigate whether myosin is involved in crane-fly primary spermatocyte division, we studied the effects of myosin inhibitors on chromosome movement and on cytokinesis. With respect to chromosome movement, the myosin ATPase inhibitor 2,3-butanedione 2-monoxime (BDM) added during autosomal anaphase reversibly perturbed the movements of all autosomes: autosomes stopped, slowed, or moved backwards during treatment. BDM added before anaphase onset altered chromosome movement less than when BDM was added during anaphase: chromosome movements only rarely were stopped. They often were normal initially and then, if altered at all, were slowed. To confirm that the effects of BDM were due to myosin inhibition, we treated cells with ML-7, a drug that inhibits myosin light chain kinase (MLCK), an enzyme necessary to activate myosin. ML-7 affected anaphase movement only when added in early prometaphase: this treatment prevented chromosome attachment to the spindle. We treated cells with H-7 as a control for possible non-myosin effects of ML-7. H-7, which has a lower affinity than ML-7 for MLCK but a higher affinity than ML-7 for other potential targets, had no effect. These data confirm that the BDM effect is on myosin and indicate that the myosin used for chromosome movement is activated near the start of prometaphase. With respect to cytokinesis, BDM did not block furrow initiation but did block subsequent contraction of the contractile ring. When BDM was added after initiation of the furrow, the contractile ring either stalled or relaxed. ML-7 blocked contractile ring contraction when added at all stages after autosomal anaphase onset, including when added during cytokinesis. H-7 had no effect. These results confirm that the effects of BDM are on myosin and indicate that the myosin used for cytokinesis is activated starting from autosomal anaphase and continuing throughout cytokinesis.     

Cytochalasin induces abnormal anaphase in crane-fly spermatocytes and causes altered distribution of actin and centromeric antigens

Inhibition of cytokinesis by cytochalasins without an effect on karyokinesis has been demonstrated in several types of cells. We report here that treating crane-fly spermatocytes with cytochalasins at concentrations (10 M CE, 100 M CD, and 200 CB) in excess of that needed to inhibit cell division induces one or more half-bivalents to lag at anaphase during the first meiotic division. The behavior of the laggards is similar to that of maloriented half-bivalents. Following treatment at these concentrations, probing with rhodamine-phalloidin or bodipy-phallacidin reveals loss of filamentous actin from the poles and its appearance in the spindle, predominantly in regions where centromeres and kinetochores are normally found. When either N350 anti-actin monoclonal antibody or rhodamine DNase I was used to probe for actin in cytochalasin-treated cells, a similar redistribution of actin was observed. CD and CE treatments alter the pattern of fluorescence at centromere/kinetochore regions after staining with scleroderma CREST serum: CREST-positive structures become broader, with spikes extending from them toward the pole; in addition, some strands of CREST fluorescence appear that are apparently extraneous, and not associated with chromosomes. Probes for actin yield staining patterns in centromere/kinetochore regions that match closely the cytochalasin-altered pattern of CREST staining. Our finding of actin in the vicinity of kinetochores under conditions that result in abnormal chromosome behavior raises numerous questions about the possible role(s) of actin in meiosis, particularly in chromosome orientation.Abbreviations CREST calcinosis, Raynaud's phenomenon, esophageal dysmotility, sclerodactyly, telangiectasia by W.C. Earnshaw     

Rhodamine-labelled phalloidin stains components in the chromosomal spindle fibres of crane-fly spermatocytes and Haemanthus endosperm cells.

In crane-fly spermatocytes and Haemanthus endosperm, all metaphase and anaphase chromosomal spindle fibres were stained with rhodamine-labelled phalloidin. In crane-fly spermatocytes, each kinetochore was stained with rhodamine-labelled phalloidin at diakinesis of prophase and after colcemid caused metaphase spindles to depolymerize. Since phalloidin stains actin filaments, the distributions of rhodamine-labelled phalloidin-stained material in crane-fly spermatocytes and Haemanthus endosperm suggest that actin filaments might interact with microtubules to produce forces that move chromosomes during cell division, either directly or via an intermediate motor molecule.     

Biochemical analysis of actin in crane-fly gonial cells: evidence for actin in spermatocytes and spermatids--but not sperm

A biochemical assay employing DNase-I affinity chromatography, two- dimensional peptide analysis and SDS polyacrylamide gel electrophoresis was used to isolate, identify, and assess the amount of actin from gonial cells of the crane fly, Nephrotoma suturalis. Based on the analysis of cell homogenates under conditions in which all cellular actin is converted to the monomeric DNase-binding form, actin comprises approximately 1% of the total protein in homogenates of spermatocytes and spermatids. SDS gel analysis of mature sperm reveals no polypeptides with a molecular weight similar to that of actin. Under conditions that preserve native supramolecular states of actin, approximately 80% of the spermatocyte actin is in a sedimentable form whereas only approximately 30% of the spermatid actin is sedimentable. These differences could be meaningful with regard to strutural changes that occur during spermiogenesis. A comparative analysis of two- dimensional peptide maps of several radioiodinated actins reveals similarities among spermatocyte, spermatid, and human erythrocyte actins. The results suggest the general applicability of this approach to other cell types that contain limited amounts of actin.     

Kinetochore-driven outgrowth of microtubules is a central contributor to kinetochore fiber maturation in crane-fly spermatocytes

We use liquid crystal polarized light imaging to record the life histories of single kinetochore (K-) fibers in living crane-fly spermatocytes, from their origins as nascent K-fibers in early prometaphase to their fully matured form at metaphase, just before anaphase onset. Increased image brightness due to increased retardance reveals where microtubules are added during K-fiber formation. Analysis of experimentally generated bipolar spindles with only one centrosome, as well as of regular, bicentrosomal spindles, reveals that microtubule addition occurs at the kinetochore-proximal ends of K-fibers, and added polymer expands poleward, giving rise to the robust K-fibers of metaphase cells. These results are not compatible with a model for K-fiber formation in which microtubules are added to nascent fibers solely by repetitive “search and capture” of centrosomal microtubule plus ends. Our interpretation is that capture of centrosomal microtubules—when deployed—is limited to early stages in establishment of nascent K-fibers, which then mature through kinetochore-driven outgrowth. When kinetochore capture of centrosomal microtubules is not used, the polar ends of K-fibers grow outward from their kinetochores and usually converge to make a centrosome-free pole.     

Myosin localization during meiosis I of crane-fly spermatocytes gives indications about its role in division

We showed previously that in crane-fly spermatocytes myosin is required for tubulin flux [Silverman-Gavrila and Forer, 2000a: J Cell Sci 113:597-609], and for normal anaphase chromosome movement and contractile ring contraction [Silverman-Gavrila and Forer, 2001: Cell Motil Cytoskeleton 50:180-197]. Neither the identity nor the distribution of myosin(s) were known. In the present work, we used immunofluorescence and confocal microscopy to study myosin during meiosis-I of crane-fly spermatocytes compared to tubulin, actin, and skeletor, a spindle matrix protein, in order to further understand how myosin might function during cell division. Antibodies to myosin II regulatory light chain and myosin II heavy chain gave similar staining patterns, both dependent on stage: myosin is associated with nuclei, asters, centrosomes, chromosomes, spindle microtubules, midbody microtubules, and contractile rings. Myosin and actin colocalization along kinetochore fibers from prometaphase to anaphase are consistent with suggestions that acto-myosin forces in these stages propel kinetochore fibres poleward and trigger tubulin flux in kinetochore fibres, contributing in this way to poleward chromosome movement. Myosin and actin colocalization at the cell equator in cytokinesis, similar to studies in other cells [e.g., Fujiwara and Pollard, 1978: J Cell Biol 77:182-195], supports a role of actin-myosin interactions in contractile ring function. Myosin and skeletor colocalization in prometaphase spindles is consistent with a role of these proteins in spindle formation. After microtubules or actin were disrupted, myosin remained in spindles and contractile rings, suggesting that the presence of myosin in these structures does not require the continued presence of microtubules or actin. BDM (2,3 butanedione, 2 monoxime) treatment that inhibits chromosome movement and cytokinesis also altered myosin distributions in anaphase spindles and contractile rings, consistent with the physiological effects, suggesting also that myosin needs to be active in order to be properly distributed.     

Kinetochore microtubules in crane-fly spermatocytes: untreated, 2 degrees C-treated, and 6 degrees C-grown spindles

We investigated the involvement of kinetochore microtubules (kMTs) in mediating chromosome-to-pole connections in crane-fly (Nephrotoma suturalis and Nephrotoma ferruginea) spermatocytes. Two experimental treatments were used to yield spindles with reduced numbers of nonkinetochore microtubules (nkMTs). Short-term (10-15 min) exposure of spermatocytes to 2 degrees C caused depolymerization of the majority of nkMTs, resulting in a kMT:(kMT + nkMT) ratio of 0.76. Long-term (24h) exposure to 2 degrees C followed by recovery at 6 degrees C resulted in a kMT:(kMT + nkMT) ratio of 0.55, the spindle having more nkMTs than a 2 degrees C-treated spindle but fewer than an untreated spindle, in which the kMT:(kMT + nkMT) ratio was 0.27. The numbers and lengths of kMTs in 6 degrees C-grown spindles were similar to those in untreated cells, suggesting that the overall inhibition of MT assembly at 6 degrees C apparently did not affect the mechanism by which kMTs are formed. We observed most kMTs of early anaphase spindles to be long (greater than 3 microns), and many extended to the polar regions of the spindle. Thus, the crane-fly spindle appears not to be as atypical as it was previously suggested to be.     

Chromosome attachment to the spindle in crane-fly spermatocytes requires actin and is necessary to initiate the anaphase-onset checkpoint

Summary We investigated the possible involvement of actin in the attachment of chromosomes to spindles in crane-fly primary spermatocytes. In a previous study, cytochalasin D, an inhibitor of actin polymerisation, prevented bivalent attachment to microtubules when applied at prophase, but did not cause the detachment of already attached bivalents. We were able to detach the already attached bivalents by first treating prometaphase cells with an antitubulin drug, nocodazole, to disrupt spindle microtubules. 2 min after nocodazole addition, we added cytochalasin D, to disrupt actin filaments; then 2 min later nocodazole was removed, and the cells were kept in cytochalasin D until the time of normal anaphase. Double treatment with nocodazole and cytochalasin D blocked reattachment of bivalents to the spindle. Single treatment with nocodazole alone caused chromosome detachment but did not prevent reattachment when nocodazole was washed out. Extended treatment with cytochalasin D alone starting in prometaphase did not cause bivalents to detach from the spindle. These data suggest that actin is needed for attachment of bivalents to spindle microtubules. This protocol is relevant to the anaphase-onset checkpoint. From previous experiments it was argued that the anaphase-onset checkpoint recognises unattached chromosomes only after those chromosomes first interact with (become attached to) the spindle. Our experiments showed that anaphase disjunction occurred at normal times when bivalents were prevented from attaching to the spindle (by adding cytochalasin D in prophase), while anaphase disjunction was greatly delayed when previously attached bivalents were detached (with nocodazole) and then prevented from re-attaching (with cytochalasin D) in the double treated cells. Thus the anaphaseonset checkpoint recognises only those unattached bivalents that previously were attached to the spindle. Other results provided further indication that actin-microtubule interactions are important in spindle organisation. Nocodazole treatment for 4 min caused most microtubules to disappear: bivalents aggregated around remnant microtubules. When cytochalasin D treatment followed nocodazole treatment, remnant spindle microtubules were not seen, suggesting that actin interactions help stabilise those microtubules.Abbreviations CD cytochalasin D - NMBD nuclear-membrane breakdown - NOC nocodazole     

Ultraviolet microbeam irradiations of spindle fibres in crane-fly spermatocytes and newt epithelial cells: Resolution of previously conflicting observations

Summary In order to resolve apparent differences in reported experiments, we directly compared the effects of ultraviolet (UV) microbeam irradiations on the behaviour of spindle fibres in newt epithelial cells and crane-fly spermatocytes, using the same apparatus for both cell types. This work represents the first time that irradiated crane-fly spermatocytes have been followed using a high-NA objective and video-enhancement of images. In both cell types, irradiation of a kinetochore fibre in metaphase produced an area of reduced birefringence (ARB), known to be devoid of spindle microtubules (MTs). Subsequently the kinetochore-ward edge of the ARB moved poleward with average velocities of 0.5 m/min (n=20) in spermatocytes and 1.1 m/min (n=6) in epithelial cells. The poleward edge of the ARB rapidly disappeared when viewed using a ×100, high-NA objective but generally remained visible when viewed with a ×32, low-NA objective; this difference suggests that MTs poleward from the ARB disperse vertically out of the narrow depth of field of the ×100 objective but that many remain encompassed by that of the ×32 objective. The primary difference in response between the two cell types was in the behaviour of the spindle poles after an ARB formed. In spermatocytes the spindle maintained its original length whereas in epithelial cells the pole on the irradiated side very soon moved towards the chromosomes, after which the other pole did the same and a much shortened functional metaphase spindle was formed.     

Polar ejection forces are operative in crane-fly spermatocytes, but their action is limited to the spindle periphery.

Laser microsurgery was employed to reveal kinetochore-independent forces acting on chromosome arms in crane-fly spermatocytes. When a portion of an arm situated along the interpolar axis between the equator and a pole was cut off, the resultant acentric fragment was transported poleward and outward into the peripheral domain of the spindle. If the fragment was generated well in advance of the onset of anaphase, then at the spindle periphery, it changed direction and moved away from the pole and back toward the equator. That domain-specific movement-poleward in the central spindle and away from the pole at the spindle periphery-not only provides the first evidence for polar ejection forces acting on acentric fragments in a meiotic system, but it is the first example of kinetochore-independent forces in both directions at the same stage of division. Sniglets generated by laser pulses directed at specific sites in the spindle revealed that the mechanism underlying ejection forces was specific to chromosomes. At anaphase onset, polar ejection forces ceased, and pole-directed forces took over. At that time, chromosome fragments that had been ejected to the equator moved poleward again, providing clear evidence for kinetochore-independent forces on chromosome arms during anaphase.