Mitotic progression in stamen hair cells of Tradescantia is accelerated by treatment with ruthenium red and Bay K-8644

The normally predictable duration of metaphase in stamen hair cells from the spiderwort, Tradescantia virginiana, is shortened significantly by treatment during prometaphase with either ruthenium red or Bay K-8644. Ruthenium red is an inhibitor of Ca2+ translocation and Bay K-8644 is a Ca2+-channel agonist. Their action on mitotic progression appears to involve a rise in the cytosolic Ca2+ level that in turn has a pronounced effect on the duration of metaphase. The timing of addition of ruthenium red for accelerated progression through metaphase is less critical than that for Bay K-8644 which will promote metaphase progression only if added 0 to 12 min after nuclear envelope breakdown. In contrast, ruthenium red can be added at any time from approximately 10 min prior to nuclear envelope breakdown up to 25 min afterward. A reduction of extracellular Ca2+ is sufficient by itself to prolong the duration of metaphase in stamen hair cells, but the duration of metaphase by ruthenium red or Bay K-8644 is significantly shortened in identical solutions with Ca2+ buffered at levels greater than 1 microM. Metaphase progression rates with either agent are independent of changes in extracellular Mg2+ levels. Correlated with the precocious entry into anaphase was rapid formation of the spindle and a marked reduction in spindle rotation during metaphase. Interestingly, we observed a modest increase in the rate of anaphase chromosome separation, but the appearance of cell plate vesicles at the site of incipient cell plate formation occurred normally approximately 19 min after anaphase onset. Similarly, the initial appearance of cell plate vesicles in Bay K-8644 was normal, approximately 19 min after the onset of anaphase. These results further implicate shifts in cytosolic Ca2+ in the regulation of mitotic events.     

The role of calcium ions during mitosis

Calcium-containing solutions were microinjected into dividing PtK1 cells to assess the effect of calcium ion concentration on the morphology and physiology of the mitotic spindle. Solutions containing 50 microM or more CaCl2 are immediately and irreversibly toxic to PtK1 cells. Those containing 5-10 microM CaCl2 cause reversible reduction in spindle birefringence followed by normal anaphase and cytokinesis. Microinjection of 5 microM or less CaCl2 into anaphase PtK1 cells has no detectable effect on the rate or extent of chromosome movement. Metaphase cells tend to enter anaphase 4-5 min after injection with 1-10 microM CaCl2, compared with an average of 16 min after injection with calcium-free buffer. Reducing the intracellular calcium concentration by injection of EGTA-CaCl2 buffers increases the lag between injection and anaphase to 20 min or more. Microinjection of calcium solutions does not promote precocious chromatid separation in nocodazole-arrested metaphase cells, indicating that the increase in calcium concentration does not induce centromere separation directly. An increase in the concentration of free calcium ions during metaphase appears to stimulate the onset of anaphase. Such an increase, regulated by the cell itself, may contribute to the initiation of chromosome separation in mammalian cells.     

Nifedipine reversibly arrests mitosis in stamen hair cells of tradescantia

Mitotic stamen hair cells of Tradescantia virginiana (cv. Zwanenburg Blue) become arrested in metaphase following a 30-min treatment with 10 to 100 microM nifedipine, a Ca2+-channel entry blocker. The time interval between nuclear envelope breakdown and anaphase onset in untreated cells is approximately 33 min +/- 4 min; nifedipine extends this "metaphase transit time" beyond 70 min. Nifedipine can be photoreversed in situ by exposure to 365 nm light. UV illumination inactivates the drug, its inhibitory effect on Ca2+ is abolished, and cells arrested in metaphase enter anaphase within 3 to 18 min of UV exposure if CaCl2 is present in the medium. The interval between UV illumination and anaphase onset is inversely related to the extracellular concentration of CaCl2. If CaCl2 is not added to the medium, the interval between UV exposure and anaphase onset is usually longer than 18 min. The sole addition of 100 microM CaCl2 to the medium is insufficient to reverse nifedipine inhibition; unless the cells are exposed to UV light, anaphase will not commence. The threshold concentration of free Ca2+ for rapid anaphase onset (less than 10 min after UV photoreversal) is between 1 and 10 microM. These results suggest that an influx of Ca2+ from the extracellular medium to the cytosolic compartment is necessary for normal progression from metaphase to anaphase and that this influx may serve as a trigger for chromosome separation.     

The timing of protein kinase activation events in the cascade that regulates mitotic progression in Tradescantia stamen hair cells.

Stamen hair cells of the spiderwort plant Tradescantia virginiana exhibit unusually predictable rates of progression through mitosis, particularly from the time of nuclear envelope breakdown (NEBD) through the initiation of cytokinesis. The predictable rate of progression through prometaphase and metaphase has made these cells a useful model system for the determination of the timing of regulatory events that trigger entry into anaphase. A number of studies suggest that the elevation of one or more protein kinase activities is a necessary prerequisite for entry into anaphase. The current experiments employ two strategies to test when these elevations in protein kinase activity actually occur during metaphase. In perfusions, we added the protein kinase inhibitors K-252a, staurosporine, or calphostin C to living stamen hair cells for 10-min intervals at known times during prometaphase or metaphase and monitored the subsequent rate of progression into anaphase. Metaphase transit times were altered as a function of the time of addition of K-252a or staurosporine to the cells; metaphase transit times were extended significantly by treatments initiated in prometaphase through early metaphase and again late in metaphase. Transit times were normal after treatments initiated in mid-metaphase, approximately 15 to 21 min after NEBD. Calphostin C had no significant effect on the metaphase transit times. In parallel, cells were microinjected with known quantities of a general-purpose protein kinase substrate peptide, VRKRTLRRL, at predefined time points during prometaphase and metaphase. At a cytosolic concentration of 100 nM to 1 microM, the peptide doubled or tripled the metaphase transit times when injected into the cytosol of mitotic cells within the first 4 min after NEBD, at any point from 7.5 to 9 min after NEBD, at any point from 14 to 16 min after NEBD, at 21 min after NEBD, or at 24 min after NEBD. At the concentration used and during these brief intervals, the peptide appeared to act as a competitive inhibitor to reveal inflection points when protein kinase activation was occurring or when endogenous substrate levels approached levels of the peptide. The timing of these inflection points coincides with the changes in protein kinase activities during prometaphase and metaphase, as indicated by our perfusions of cells with the broad spectrum kinase inhibitors. Collectively, our results suggest that the cascade that culminates in anaphase is complex and involves several successive protein kinase activation steps punctuated by the activation of one or more protein phosphatases in mid-metaphase.     

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)     

Anaphase motions in dilute colchicine. Evidence of two phases in chromosome segregation

We have examined the rates of chromosome and pole motion during anaphase in HeLa cells using differential interference contrast and polarization optics. In early anaphase both chromosomes and poles move apart. When the chromosomes are separated by a distance about equal to the metaphase spindle length, both chromosomes and poles slow but continue to move at a reduced rate. Throughout anaphase, the chromosomes move faster than the poles, so the chromosome-to-pole distance decreases. Treatment of the cells with about 5 × 10^?8 M colchicine up to 45 min before observation tends to block normal formation of metaphase spindles, but more than half of the cells in metaphase go on through anaphase. In these cells, both chromosome and pole motions are essentially normal until the chromosomes are separated by a distance equal to the length of the metaphase spindle. After that time, chromosome motion is supressed and the poles move slowly toward one another. These data suggest that the mechanism of anaphase motion changes character when the chromosomes become spaced by the metaphase spindle length. We call anaphase before and after that time phase 1 and phase 2, respectively. The results are discussed in the light of a sliding tubule model for chromosome motion.     

The effects of colchicine and dinitrophenol on the in vivo rates of anaphase A and B in the diatom Surirella

The rates of chromosome-to-pole movement (anaphase A) and pole-pole separation (anaphase B) in vivo were measured in the pennate diatom Surirella, using differential interference contrast (DIC) light microscopy. In control cells, the rate of anaphase A is 1.6 +/- 0.6 micron/min, the rate of anaphase B is 2.3 +/- 0.3 micron/min, and the extent of anaphase B is 26.7 +/- 9.7% of metaphase spindle length. Colchicine was added to metaphase cells in order to inhibit any further addition of microtubule (MT) subunits onto the spindle. Colchicine, which does not break down the well-ordered Surirella central spindle, caused no significant change in the rate of anaphase A (1.3 +/- 0.3 micron/min) while it significantly decreased both the rate of anaphase B (1.2 +/- 0.4 micron/min) and the extent of anaphase B (14.8 +/- 8.3% of metaphase spindle length). Surirella cells were also treated with the metabolic inhibitor 2-4-dinitrophenol (DNP) in order to test the effects of energy depletion on anaphase. When DNP was added early in anaphase A, prior to the completion of sister chromosome separation, anaphase A was inhibited. When DNP was added after initiation of sister chromosome separation, anaphase A continued to completion, although at a lower rate than control cells (0.5 +/- 0.2 micron/min). Anaphase B was completely inhibited by DNP, but upon recovery from DNP resumed at a normal rate (2.2 +/- 0.5 micron/min) and progressed to a slightly larger than normal extent (44.0 +/- 13.0% of metaphase length).(ABSTRACT TRUNCATED AT 250 WORDS)     

On the mechanism of anaphase A: evidence that ATP is needed for microtubule disassembly and not generation of polewards force

As anaphase began, mitotic PtK1 and newt lung epithelial cells were permeabilized with digitonin in permeabilization medium (PM). Permeabilization stopped cytoplasmic activity, chromosome movement, and cytokinesis within about 3 min, presumably due to the loss of endogenous ATP. ATP, GTP, or ATP-gamma-S added in the PM 4-7 min later restarted anaphase A while kinetochore fibers shortened. AMPPNP could not restart anaphase A; ATP was ineffective if the spindle was stabilized in PM + DMSO. Cells permeabilized in PM + taxol varied in their response to ATP depending on the stage of anaphase reached: one mid-anaphase cell showed initial movement of chromosomes back to the metaphase plate upon permeabilization but later, anaphase A resumed when ATP was added. Anaphase A was also reactivated by cold PM (approximately 16 degrees C) or PM containing calcium (1-10 mM). Staining of fixed cells with antitubulin showed that microtubules (MTs) were relatively stable after permeabilization and MT assembly was usually promoted in asters. Astral and kinetochore MTs were sensitive to MT disassembly conditions, and shortening of kinetochore MTs always accompanied reactivation of anaphase A. Interphase and interzonal spindle MTs were relatively stable to cold and calcium until extraction of cells was promoted by longer periods in the PM, or by higher concentrations of detergent. Since we cannot envisage how both cold treatment or relatively high calcium levels can reactivate spindle motility in quiescent, permeabilized, and presumably energy-depleted cells, we conclude that anaphase A is powered by energy stored in the spindle. The nucleotide triphosphates effective in reactivating anaphase A could be necessary for the kinetochore MT disassembly without which anaphase movement cannot proceed.     

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.     

Micromanipulation of mitotic chromosomes in PTK2 cells using laser-induced optical forces ("optical tweezers")

To study the potential use of optical forces to manipulate chromosome movement, we have used a Nd:YAG laser at a wavelength of 1.06 microns focused into a phase contrast microscope. Metaphase and anaphase chromosomes were exposed while being monitored by video microscopy. The results indicated that when optical forces were applied to late-moving metaphase chromosomes on the side closest to the nearest spindle pole, the trapped chromosomes initiated movement to the metaphase plate. The chromosome velocities were two to eight times the normal rate depending on the chromosome size, geometry, and trapping site. At the initiation of anaphase, a pair of chromatids could be held by the optical trap and kept motionless throughout anaphase while the other pairs of chromatids separated and moved to opposite spindle poles. As a result, the trapped chromosome either was incorporated into one of the daughter cells or was lost in the cleavage furrow, or the two chromatids eventually separated and moved to their respective daughter cells. If the trap was removed at the beginning of anaphase B, the chromosome moved back to the poles. Our experiments demonstrate that the laser-induced optical force trap is a potential new technique to study noninvasively the mitotic spindle of living cells.     

Lithium alters mitotic progression in stamen hair cells of Tradescantia in a time-dependent and reversible fashion

Stamen hair cells of Tradescantia exhibit remarkable precision in the timing of their mitotic events. This precision is altered dramatically with treatment in 50 microM to 1 mM LiCl, an inhibitor of the polyphosphoinositide cycle. Mitotic progression is altered as a function of the time of treatment with LiCl. If cells are treated during late prophase, greater than 80% fail to enter metaphase. Most of the cells that undergo nuclear envelope breakdown become arrested in metaphase. Treatment with LiCl earlier in prophase also results in metaphase arrest. Metaphase arrest can be reversed by the addition of 10 microM myo-inositol or 100 microM CaCl2 to the extracellular medium. The timing of reversal by myo-inositol takes 10 to 14 min while CaCl2 promotes anaphase onset in 2 to 5 min. The difference in kinetics for reversal between these two treatments suggests that myo-inositol addition overrides a biochemical pathway while Ca2+ addition supplants a phosphoinositide-mediated rise in the cation that may be necessary for anaphase onset. Buffer without myo-inositol or CaCl2 is insufficient for reversal. If the cells are treated with LiCl in mid-late-metaphase, at least 5 min prior to the expected time of anaphase onset, sister chromatids split at the normal time, 33 +/- 4 min after nuclear envelope breakdown, but further chromosome separation is arrested. Anaphase chromosome movement can be restored by treatment with either 10 microM myo-inositol or 100 microM CaCl2 in the medium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Microinjection of mitotic cells with the 3F3/2 anti-phosphoepitope antibody delays the onset of anaphase

The transition from metaphase to anaphase is regulated by a checkpoint system that prevents chromosome segregation in anaphase until all the chromosomes have aligned at the metaphase plate. We provide evidence indicating that a kinetochore phosphoepitope plays a role in this checkpoint pathway. The 3F3/2 monoclonal antibody recognizes a kinetochore phosphoepitope in mammalian cells that is expressed on chromosomes before their congression to the metaphase plate. Once chromosomes are aligned, expression is lost and cells enter anaphase shortly thereafter. When microinjected into prophase cells, the 3F3/2 antibody caused a concentration-dependent delay in the onset of anaphase. Injected antibody inhibited the normal dephosphorylation of the 3F3/2 phosphoepitope at kinetochores. Microinjection of the antibody eliminated the asymmetric expression of the phosphoepitope normally seen on sister kinetochores of chromosomes during their movement to the metaphase plate. Chromosome movement to the metaphase plate appeared unaffected in cells injected with the antibody suggesting that asymmetric expression of the phosphoepitope on sister kinetochores is not required for chromosome congression to the metaphase plate. In antibody-injected cells, the epitope remained expressed at kinetochores throughout the prolonged metaphase, but had disappeared by the onset of anaphase. When normal cells in metaphase, lacking the epitope at kinetochores, were treated with agents that perturb microtubules, the 3F3/2 phosphoepitope quickly reappeared at kinetochores. Immunoelectron microscopy revealed that the 3F3/2 epitope is concentrated in the middle electronlucent layer of the trilaminar kinetochore structure. We propose that the 3F3/2 kinetochore phosphoepitope is involved in detecting stable kinetochore-microtubule attachment or is a signaling component of the checkpoint pathway regulating the metaphase to anaphase transition.     

1,2-Dioctanoylglycerol accelerates or retards mitotic progression in Tradescantia stamen hair cells as a function of the time of its addition

We have treated living, intact stamen hair cells from the spiderwort plant, Tradescantia virginiana, with 0.5 microgram/ml or 60 micrograms/ml 1,2-dioctanoylglycerol, a potent and permeant activator of protein kinase C, and have observed the rates of progression of mitosis from prophase through anaphase. We have found that in addition to the concentration used, the time of initial treatment with 1,2-dioctanoylglycerol defines the response by the cells. The cells rapidly undergo nuclear envelope breakdown when this diglyceride is added in very late prophase, 0 to approximately 8 min prior to the time of normal nuclear envelope breakdown. Anaphase onset occurs 28 min after nuclear envelope breakdown, rather than after the 33 min interval observed in untreated cells. Rapid progression through metaphase is also observed if cells are treated with 0.5 microgram/ml 1,2-dioctanoylglycerol during prometaphase, up to 15 min after nuclear envelope breakdown. The addition of 0.5 microgram/ml 1,2-dioctanoylglycerol in late metaphase, approximately 26 min after nuclear envelope breakdown, results in sister chromatid separation slightly ahead of its normal time, 33 min after nuclear envelope breakdown, and in precocious cell plate vesicle aggregation, 3-5 min earlier than that observed in untreated cells. Treatment of cells with 60 micrograms/ml of 1,2-dioctanoylglycerol at any point during the interval from 0 to approximately 5 min prior to nuclear envelope breakdown results in precocious entry into anaphase. If cells are treated with either 0.5 microgram/ml or 60 micrograms/ml 1,2-dioctanoylglycerol earlier than 20 min before nuclear envelope breakdown, they do not enter mitosis, but instead revert to interphase without dividing. When 1,2-dioctanoylglycerol is added at other times during mitosis, the rate of subsequent mitotic progression is dramatically slowed; the cells require greater than 55 min to progress from nuclear envelope breakdown to anaphase onset, though once in anaphase, the cells progress onward to cytokinesis at normal rates. Treatments o of cells with 1,3-dioctanoylglycerol at any point during prophase, prometaphase, or metaphase are without effect on the rate of subsequent mitotic progression. The shifts in response by cells treated at specific times with 1,2-dioctanoylglycerol during mid- and late metaphase may be indicative of the existence of one or more regulatory switch points (i.e., checkpoints) just prior to anaphase onset.     

Metabolic inhibitors block anaphase A in vivo

Anaphase in dividing guard mother cells of Allium cepa and stamen hair cells of Tradescantia virginiana consists almost entirely of chromosome-to-pole motion, or anaphase A. Little or no separation of the poles (anaphase B) occurs. Anaphase is reversibly blocked at any point by azide or dinitrophenol, with chromosome motion ceasing 1-10 min after application of the drugs. Motion can be stopped and restarted several times in the same cell. Prometaphase, metaphase, and cytoplasmic streaming are also arrested. Carbonyl cyanide m-chlorophenyl hydrazone also stops anaphase, but its effects are not reversible. Whereas the spindle collapses in the presence of colchicine, the chromosomes seem to "freeze" in place when cells are exposed to respiratory inhibitors. Electron microscope examination of dividing guard mother cells fixed during azide and dinitrophenol treatment reveals that spindle microtubules are still present. Our results show that chromosome-to-pole motion in these cells is sensitive to proton ionophores and electron transport inhibitors. They therefore disagree with recent reports that anaphase A does not require a continuous supply of energy. It is possible, however, that anaphase does not directly use ATP but instead depends on the energy of chemical and/or electrical gradients generated by cellular membranes.     

Microtubule Flux Mediates Poleward Motion of Acentric Chromosome Fragments during Meiosis in Insect Spermatocytes

We applied a combination of laser microsurgery and quantitative polarization microscopy to study kinetochore-independent forces that act on chromosome arms during meiosis in crane fly spermatocytes. When chromosome arms located within one of the half-spindles during prometa- or metaphase were cut with the laser, the acentric fragments (lacking kinetochores) that were generated moved poleward with velocities similar to those of anaphase chromosomes (approximately 0.5 microm/min). To determine the mechanism underlying this poleward motion of detached arms, we treated spermatocytes with the microtubule-stabilizing drug taxol. Spindles in taxol-treated cells were noticeably short, yet with polarized light, the distribution and densities of microtubules in domains where fragment movement occurred were not different from those in control cells. When acentric fragments were generated in taxol-treated spermatocytes, 22 of 24 fragments failed to exhibit poleward motion, and the two that did move had velocities attenuated by 80% (to approximately 0.1 microm/min). In these cells, taxol did not inhibit the disjunction of chromosomes nor prevent their poleward segregation during anaphase, but the velocity of anaphase was also decreased 80% (approximately 0.1 microm/min) relative to untreated controls. Together, these data reveal that microtubule flux exerts pole-directed forces on chromosome arms during meiosis in crane fly spermatocytes and strongly suggest that the mechanism underlying microtubule flux also is used in the anaphase motion of kinetochores in these cells.     

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.     

Long-lasting and rapid calcium changes during mitosis

A more complete understanding of calcium's role in cell division requires knowledge of the timing, magnitude, and duration of changes in cytoplasmic-free calcium, [Ca2+]i, associated with specific mitotic events. To define the temporal relationship of changes in [Ca2+]i to cellular and chromosomal movements, we have measured [Ca2+]i every 6-7 s in single-dividing Pt K2 cells using fura-2 and microspectrophotometry, coupling each calcium measurement with a bright-field observation. In the 12 min before discernable chromosome some separation, 90% of metaphase cells show at least one transient of increased [Ca2+]i, 72% show their last transient within 5 min, and a peak of activity is seen at 3 min before chromosome separation. The mean [Ca2+]i of the metaphase transients is 148 +/- 31 nM (61 transients in 35 cells) with an average duration of 21 +/- 14 s. The timing of these increases makes it unlikely that these transient increases in [Ca2+]i are acting directly to trigger the start of anaphase. However, it is possible that a transient rise in calcium during late metaphase is part of a more complex progression to anaphase. In addition to these transient changes, a gradual increase in [Ca2+]i was observed starting in late anaphase. Within the 2 min surrounding cytokinesis onset, 82% of cells show a transient increase in [Ca2+]i to 171 +/- 48 nM (53 transients in 32 cells). The close temporal correlation of these changes with cleavage is consistent with a more direct role for calcium in this event, possibly by activating the contractile system. To assess the specificity of these changes to the mitotic cycle, we examined calcium changes in interphase cells. Two-thirds of interphase cells show no transient increases in calcium with a mean [Ca2+]i of 100 +/- 18 nM (n = 12). However, one-third demonstrate dramatic and repeated transient increases in [Ca2+]i. The mean peak [Ca2+]i of these transients is 389 +/- 70 nM with an average duration of 77 s. The necessity of any of these transient changes in calcium for the completion of mitotic or interphase activities remains under investigation.     

The force for poleward chromosome motion in Haemanthus cells acts along the length of the chromosome during metaphase but only at the kinetochore during anaphase

The force for poleward chromosome motion during mitosis is thought to act, in all higher organisms, exclusively through the kinetochore. We have used time-lapse. video-enhanced, differential interference contrast light microscopy to determine the behavior of kinetochore-free "acentric" chromosome fragments and "monocentric" chromosomes containing one kinetochore, created at various stages of mitosis in living higher plant (Haemanthus) cells by laser microsurgery. Acentric fragments and monocentric chromosomes generated during spindle formation and metaphase both moved towards the closest spindle pole at a rate (approximately 1.0 microm/min) similar to the poleward motion of anaphase chromosomes. This poleward transport of chromosome fragments ceased near the onset of anaphase and was replaced. near midanaphase, by another force that now transported the fragments to the spindle equator at 1.5-2.0 microm/min. These fragments then remained near the spindle midzone until phragmoplast development, at which time they were again transported randomly poleward but now at approximately 3 microm/min. This behavior of acentric chromosome fragments on anastral plant spindles differs from that reported for the astral spindles of vertebrate cells, and demonstrates that in forming plant spindles, a force for poleward chromosome motion is generated independent of the kinetochore. The data further suggest that the three stages of non- kinetochore chromosome transport we observed are all mediated by the spindle microtubules. Finally, our findings reveal that there are fundamental differences between the transport properties of forming mitotic spindles in plants and vertebrates.     

Chk1 and Wee1 kinases coordinate DNA replication, chromosome condensation, and anaphase entry

Defects in DNA replication and chromosome condensation are common phenotypes in cancer cells. A link between replication and condensation has been established, but little is known about the role of checkpoints in monitoring chromosome condensation. We investigate this function by live analysis, using the rapid division cycles in the early Drosophila embryo. We find that S-phase and topoisomerase inhibitors delay both the initiation and the rate of chromosome condensation. These cell cycle delays are mediated by the cell cycle kinases chk1 and wee1. Inhibitors that cause severe defects in chromosome condensation and congression on the metaphase plate result in delayed anaphase entry. These delays are mediated by wee1 and are not the result of spindle assembly checkpoint activation. In addition, we provide the first detailed live analysis of the direct effect of widely used anticancer agents (aclarubicin, ICRF-193, VM26, doxorubicin, camptothecin, aphidicolin, hydroxyurea, cisplatin, mechlorethamine and x-rays) on key nuclear and cytoplasmic cell cycle events.     

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.