Protein synthesis and mitosis. 1. Influence of anti-tubulins on protein synthetic activity in synchronous M-phase and asynchronous populations of HeLa S-3 cells

Asynchronous and synchronous HeLa S-3 suspension cultures treated with colcemid and vinblastine (VLB) resulted, in the former case, in suppression of 3H-leucine incorporation into protein which became increasingly apparent as the percentage of M-phase-arrested cells increased. In the latter case, where no cells were allowed to enter M-phase, no significant inhibition of incorporation occurred. M-phase cells were collected by shake-off from asynchronous monolayers, or alternatively monolayers presynchronised 10 h before shake-off, either in the presence or absence of alkaloids. In both cases, alkaloid-treated cultures showed marked inhibition of protein synthesis, while controls were largely unaffected. The results indicate that marked suppression of protein synthesis in alkaloid-arrested M-phase population is primarily due to the inability of cells to complete mitosis. Arrested cells showed no increase in size or protein content with time, but began disintegrating approximately 6-7 h after alkaloid treatment. The necessity for cells to traverse M-phase quickly is emphasised, otherwise any transient decline of protein synthesis during M-phase becomes grossly exaggerated.     

S-phase and M-phase timing are under independent circadian control in the dinoflagellate Lingulodinium

In many phytoplankton species, cell division (mitosis) usually occurs at defined times of day. This timing is also observed under constant conditions, indicating that it is regulated by a circadian clock rather than by a simple response to the light-dark cycle. For those algae with cell cycles longer than a day, the clock opens a window of opportunity for mitosis at a particular time of day through which cells in an appropriate phase of the cell cycle can pass. Although the timing of mitosis is generally studied due to ease of measurement, for some phytoplankton the timing of S-phase is also circadian. This thus raises the possibility that mitosis is not directly gated by the clock but occurs instead at a defined interval (a constant G2 length) following a circadian controlled S-phase. To determine if the clock exercises independent control over the timing of both S- and M-phase, we measured the timing of both S- and M-phase in cultures of the dinoflagellate Lingulodinium grown under a variety of different photoperiods. We interpret the phase angles of both rhythms, in particular those resulting in a change in the length of G2, as an indication that the clock independently regulates the timing of S-phase and mitosis.     

Microsporogenesis inPinus sylvestris L. VIII. Tapetal and late pollen grain development

This last portion of our developmental study ofPinus sylvestris L. pollen grains extends from just prior to the first microspore mitosis to the microsporangial dehiscence preparatory to pollen shedding. In nine years of collecting each day the duration of the above period was 7 to 11 days. Tapetal cells extended into the loculus and embraced microspores during the initial part of the above period. Thereafter tapetal cells receded, became parallel to parietal cells and so imbricated that there appeared to be two or three layers of tapetal cells. Tapetal cells were present up to the day before pollen shedding, but only rER and some mitochondria appeared to be in good condition at that time. A callosic layer (outer intine) was initiated under the endexine before microspore mitosis. After the first mitosis the first prothallial cell migrated to the proximal wall and was covered on the side next to the pollen cytoplasm by a thin wall joining the thick outer intine. There are plasmodesmata between pollen cytoplasm and the prothallial cell. After the second mitosis the second prothallial cell became enveloped by the outer intine. The inner intine appears after formation of the two prothallial cells but before the third mitosis. During this two-prothallial cell period before the third mitosis, plastids had large and complex fibrillar assemblies shown to be modified starch grains. After the third mitosis plastids of the pollen cytoplasm contained starch and the generative cell (antheridial initial), the product of that mitosis, is enveloped by the inner intine. On the day of pollen shedding cells are removed from the microsporangial wall by what appears to be focal autolysis. The tapetal and endothecial cells for 10–15 µm on each side of the dehiscence slit are completely removed. One or more epidermal cells are lysed, but both a thin cuticle and the very thin sporopollenin-containing peritapetal membrane remain attached to the undamaged epidermal cells bordering the dehiscence slit. Our study terminates on the day of pollen shedding with mature pollen still within the open microsporangium. At that time there is no longer a clear morphological distinction between the outer and inner intine but, judging by stain reactions, there is a chemical difference. The exine of shed pollen grains was found to be covered by small spinules on the inner surface of alveoli. These had the same spacing as the Sporopollenin Acceptor Particles (SAPs) associated with exine initiation and growth.     

Curcumin disrupts mitotic spindle structure and induces micronucleation in MCF-7 breast cancer cells

The dietary phytochemical curcumin possesses anti-inflammatory, -oxidant, and cytostatic properties, and exhibits significant potential as a chemopreventative agent in humans. Although many cell types are arrested in the G2/M-phase of the cell cycle after curcumin treatment, the mechanisms by which this occurs are not well understood. The purpose of this study was to examine the effects of curcumin on the cell cycle of MCF-7 breast cancer cells to determine whether growth arrest is associated with structural changes in cellular organization during mitosis. For this purpose, MCF-7 breast cancer cells were treated with 10-20 microM curcumin, and the effects on cell proliferation and mitosis studied. Structural changes were monitored by immunolabeling cells with antibodies to a number of cytoplasmic and nuclear proteins, including beta-tubulin, NuMA, lamins A/C and B1, lamin B receptor, and centromere antigens. At the concentrations used, a single dose of curcumin does not induce significant apoptosis, but is highly effective in inhibiting cell proliferation for over 6 days. During the first 24-48 h of treatment, many cells are arrested in M-phase, and DNA synthesis is almost completely inhibited. Remarkably, arrested mitotic cells exhibit monopolar spindles, and chromosomes do not undergo normal anaphase movements. After 48 h, most cells eventually leave M-phase, and many form multiple micronuclei instead of individual daughter nuclei. These observations indicate that the curcumin-induced G2/M arrest previously described for MCF-7 cells is due to the assembly of aberrant, monopolar mitotic spindles that are impaired in their ability to segregate chromosomes. The production of cells with extensive micronucleation after curcumin treatment suggests that at least some of the cytostatic effects of this phytochemical are due to its ability to disrupt normal mitosis, and raises the possibility that curcumin may promote genetic instability under some circumstances.     

A morphometric study of developing pancreatic acinar cells of rats during prenatal life

Summary The pancreatic acinar cells of rat embryos obtained at 15, 17, 19 and 21 days of gestation have been examined using fine-structural and morphometric techniques.Morphometric analysis demonstrates significant variations in the average volume of the cell, nucleus and cytoplasm, and the volume, surface and numerical densities of various cytoplasmic organelles during fetal life. In particular, the volume and surface densities of rER exhibit maximal values at 19 days of gestation, suggesting that secretory proteins are produced most actively at this time. Further-more, membrane continuity between the nuclear envelope and rER is frequently discernible in acinar cells, indicating that at this stage the rER is mainly derived from the nuclear envelope. Zymogen granules first appear at 17 days of gesstation. By 21 days, they occupy the greater part of the cytoplasm of the acinar cells, no polarity being seen in their distribution pattern. No direct evidence for the secretion of zymogen granules has been observed during fetal life.It therefore appears that membrane transport involved with intracellular movement of newly synthesized proteins from rER via the Golgi complex to zymogen granules occurs in one direction and lacks regulation.     

Morphological study of the development of the disseminate prostate in intact and castrated male pigs aged two to six months.

The light-microscopical and ultrastructural differentiation of the disseminate prostate was studied in 12 boars and 8 barrows, ranging in age from 8 to 28 and 12 to 27 weeks, respectively. The barrows had been castrated at the age of 8 weeks. In young boars the prostate is organized in an inner zone and an outer zone. The glandular tubules of the latter are more differentiated than those in the inner zone. Sexual maturation in the prostate is characterized by almost complete reduction of the inner zone and concomitant enlargement of the outer zone. This differentiation of the inner zone occurs progressively and is manifested by a higher density of the glandular tubules, by a decrease in the number of basal cells and by an increase in the secretory tubular cells containing more microvilli, organelles and secretory vesicles. A few weeks after castration, the characteristic morphology of the undifferentiated inner zone is found throughout the entire glandular layer. The number of glandular tubules in barrows has decreased, and their cells show minimal secretory activity, nuclear indentations and a decrease in their organelles. A further castration effect is vacuolization of the perinuclear cytoplasm in numerous glandular cells.     

Interaction of antibodies against nuclear envelope-associated proteins from rat liver nuclei with rodent and human cells

Antibodies have been prepared against the three major polypeptides of the nuclear pore complex-lamina fraction from rat liver nuclei. The three antisera prepared in chickens give similar results in indirect immunofluorescence microscopy. In rat embryo fibroblasts we observe bright fluorescence at the level of the nuclear envelope, with no fluorescence of the nuclear interior and little or no fluorescence of the cytoplasm. The nuclear envelope regions of rat hepatoma cells, mouse A9 cells, HeLa cells and rat liver nuclei also fluoresce brightly. HeLa nucleoids, which are depleted of nuclear envelope components, still exhibit specific fluorescence when reacted with these antibodies. Distribution of the antigens changes during mitosis. Fluorescence in the cytoplasm is observed following the breakdown of the nuclear envelope at prometaphase. The antigens appear to progressively accumulate at the periphery of the chromosomes until telophase. In late telophase fluorescence occurs predominantly at the periphery of the chromosomes where the new nuclear envelope is formed.     

Enrichment of cell populations in metaphase, anaphase, and telophase by synchronization using nocodazole and blebbistatin: a novel method suitable for examining dynamic changes in proteins during mitotic progression

Mitosis is a continuous process to separate replicated chromosomes into two daughter cells through prophase, metaphase, anaphase, and telophase. Although a number of methods have been established to synchronize cells at different phases of the cell cycle, it is difficult to synchronize cells at the specific phases, anaphase and telophase, during mitosis because of the short duration of anaphase. Here, we show that HeLa S3 cells in anaphase and in telophase are successfully enriched by treatment with a combination of low concentrations of the microtubule-depolymerizing agent nocodazole and the myosin II inhibitor blebbistatin. After 9-h release from thymidine block at G1/S phase, addition of nocodazole at 20 ng/ml but not 40 ng/ml ensures rapid release from the nocodazole arrest. Subsequently, the cells are cultured in the presence of 50 μM blebbistatin for 20 and 50 min to enrich cells in anaphase and telophase, respectively. Western blot analysis verifies down-regulation of phospho-histone H3-Ser10, phospho-Aurora A/B/C, and cyclin B1 during M-phase progression. Furthermore, we show how the electrophoretic mobility shifts of the Src-family kinases c-Yes and c-Src can change in each phase of mitosis. These results provide a useful synchronization method for biochemically examining protein dynamics during M-phase progression.     

Behavior of vacuoles during microspore and pollen development in Arabidopsis thaliana

Using the cryo-fixation/freeze-substitution method, we studied the ultrastructural changes and behavior of vacuoles and related organelles (rER and Golgi bodies) during microspore and pollen development, and pollen maturation of Arabidopsis thaliana. In young microspores forming exine (pollen outer cell wall), vacuoles looked like those of somatic cells. In microspores during the formation of intine (inner cell wall), a large vacuole appeared which was made by fusion of pre-existing vacuoles and probably absorption of solutions. In the young pollen grain after the first mitosis, a large vacuole was divided into small vacuoles. The manner of division was not by binary fission and centripetally, but by the invagination of tonoplasts from one side to the opposite side of a vacuole. After the second mitosis, somatic type vacuoles disappeared. In mature pollen grains just before germination, membrane-bound structures containing fine fibrillar substances (MBFs) appeared. The MBFs were considered to be storage vacuoles. In pollen grains from flowers in bloom, MBFs changed to lysosomal structures with acid phosphatases (lytic vacuole). They gradually increased in number and volume, and decomposed the cytoplasm. The autolysis of pollen grains is the first finding in this study, which may contribute to the loss of ability of pollen germination after anthesis.     

p63cdc13, a B-type cyclin, is associated with both the nucleolar and chromatin domains of the fission yeast nucleus.

The cellular distribution of the fission yeast mitotic cyclin B, p63cdc13, was investigated by a combination of indirect immunofluorescence light microscopy, immunogold electron microscopy, and nuclear isolation and fractionation. Immunofluorescence microscopy of wild-type cells and the cold-sensitive mutant dis2.11 with a monospecific anti-p63cdc13 antiserum was consistent with the association of a major subpopulation of fission yeast M-phase protein kinase with the nucleolus. Immunogold electron microscopy of freeze-substituted wild-type cells identified two nuclear populations of p63cdc13, one associated with the nucleolus, the other with the chromatin domain. To investigate the cell cycle regulation of nuclear labeling, the mutant cdc25.22 was synchronized through mitosis by temperature arrest and release. Immunogold labeling of cells arrested at G2M revealed gold particles present abundantly over the nucleolus and less densely over the chromatin region of the nucleus. Small vesicles around the nucleus were also labeled by anti-p63cdc13, but few gold particles were detected over the cytoplasm. Labeling of all cell compartments declined to zero through mitosis. Cell fractionation confirmed that p63cdc13 was substantially enriched in both isolated nuclei and in a fraction containing small vesicles and organelles. p63cdc13 was not extracted from nuclei by treatment with RNase A, Nonidet P40 (NP-40), Triton X-100, and 0.1 M NaCl, although partial solubilization was observed with DNase I and 1 M NaCl. A known nucleolar protein NOP1, partitioned in a similar manner to p63cdc13, as did p34cdc2, the other subunit of the M-phase protein kinase. We conclude that a major subpopulation of the fission yeast mitotic cyclin B is targeted to structural elements of the nucleus and nucleolus.     

Overexpression of cyclin A in human HeLa cells induces detachment of kinetochores and spindle pole/centrosome overproduction

The combination of hydroxyurea (HU) and caffeine has been used for inducing kinetochore dissociation from mitotic chromosomes and for causing centrosome/spindle pole amplification. However, these effects on microtubule organizing centers (MTOCs) are limited to certain cell types. It was reasoned that if the biochemical differences in MTOC behavior between cells following HU treatment could be identified, then critical information concerning the regulation of these organelles would be obtained. During these studies, it was determined that cells from hamster, rat, and deer could be induced to enter mitosis with dissociated kinetochores and to synthesize centrosomes during arrest with HU, while cells from human and mouse could not. Comparisons between human HeLa cells and CHO cells determined that cyclin A levels were depressed in HeLa cells relative to CHO cells following HU addition. Overexpression of cyclin A in HeLa cells converted them to a cell type capable of detaching kinetochores from mitotic chromosomes. Ultrastructural analyses determined that the detached human kinetochores exhibited a normal plate-like morphology and appeared capable of associating with microtubules. In addition, HeLa cells overexpressing cyclin A also overproduced spindle poles during HU arrest, demonstrating that cyclin A activity also is important for centrosome replication during interphase. In summary, elevated cyclin A levels are important for the capacity of cells to be driven into mitosis by caffeine addition, for the ability of cells to progress to mitosis with detached kinetochores, and for centrosome/spindle pole replication.     

Studies on the Endoplasmic Reticulum : IV. Its Form and Distribution during Mitosis in Cells of Onion Root Tip

Cells of onion and garlic root tips were examined under the electron and phase contrast microscopes after fixation in KMnO₄. Special attention was focused on the distribution and behavior of the endoplasmic reticulum (ER) during the several phases of mitosis. Slender profiles, recognized as sections through thin lamellar units of the ER (most prominent in KMnO₄-fixed material), are distributed more or less uniformly in the cytoplasm of interphase cells and show occasional continuity with the nuclear envelope. In late prophase the nuclear envelope breaks down and its remnants plus cytoplasmic elements of the ER, which are morphologically identical, surround the spindle in a zone from which mitochondria, etc., are excluded. During metaphase these ER elements persist and concentrate as two separate systems in the polar caps or zones of the spindle. At about this same time they begin to proliferate and to invade the ends of the spindle. The invading lamellar units form drape-like partitions between the anaphase chromosomes. In late anaphase, their advancing margins reach the middle zone of the spindle and begin to fray out. Finally, in telophase, while elements of the ER in the poles of the spindle coalesce around the chromosomes to form the new envelope, the advancing edges of those in the middle zone reticulate at the level of the equator to form a close lattice of tubular elements. Within this, which is identified as the phragmoplast, the earliest signs of the cell plate appear in the form of small vesicles. These subsequently grow and fuse to complete the separation of the two protoplasts. Other morphological units apparently participating in mitosis are described. Speculation is provided on the equal division or not of the nuclear envelope and the contribution the envelope fragments make to the ER of the new cell.     

Mitotic dynamics of micronuclei induced by amiprophos-methyl and prospects for chromosome-mediated gene transfer in plants

Summary Mitotic dynamics and the kinetics of mass induction of micronuclei after treatment of Nicotiana plumbaginifolia cell suspensions with the spindle toxin amiprophos-methyl (APM) are reported. The addition of APM to suspension cells resulted in the accumulation of a large number of metaphases. The course of mitosis was strikingly different from normal. Metaphase chromosomes showed neither centromere division nor separation of chromatids. Single chromosomes and groups of 2 or more chromosomes were scattered over the cytoplasm. After 5–6 h of APM treatment, chromosomes decondensed and formed micronuclei. When treatment duration was increased, the frequency of cells with micronuclei as well as those showing lobed micronuclei increased. Similarly, with an increase in APM concentration the frequency of cells with micronuclei increased. After removal of APM, chromosome grouping disappeared, cells showing lobed micronuclei further increased and mitoses with doubled chromosome numbers appeared in the next cell division. Cytological observations and DNA measurements revealed that several sub-diploid micronuclei containing 1 or a few chromosomes can be obtained, and that flow cytometry can detect and sort out these micronuclei. The applications of micronuclei for genetic manipulation of specific chromosomes and gene mapping are indicated.     

The GTP-binding protein G(ialpha) translocates to kinetochores and regulates the M-G(1) cell cycle transition of Swiss 3T3 cells

The receptor-generated signals that are responsible for driving the cell cycle are incompletely characterised in mammalian cells. It is clear, however, that the cellular messenger systems that stimulate DNA synthesis and mitosis are separable. These are interwoven with biochemical checkpoints that ensure that processes, such as chromosomal replication and microtubule attachment to duplicated chromosomes, are complete before the following phase of the cell cycle is initiated. In some cells, activation of DNA synthesis by factors such as LPA and serum has been shown to require the GTP-binding protein G(i). We have found that G(i) plays an additional role in mitosis activated by both 7-transmembrane receptors and tyrosine kinase receptors, and that this involves the translocation of the alpha-subunit of G(i) (G(ialpha)) to the nucleus. Here we show by confocal microscopy that G(ialpha)migrates to the nucleus near the onset of mitosis in serum-activated Swiss 3T3 cells and binds to the kinetochore region of replicated chromosomes. Inhibition of G(i) function with pertussis toxin had no effect on the induction of DNA synthesis by serum, but cell proliferation was inhibited. Flow cytometric analysis showed that this resulted from retardation of the transition through mitosis and into G(1). Additionally, pertussis toxin impaired the activity of p34(cdc2), a cyclin-dependent kinase involved in the transition from M-phase to G(1), but not the S-phase cyclin, cyclin E. These data show that the G-protein G(i) has a key role in the regulation of mitosis in fibroblasts.     

Ultrastructure of Male Gametophyte in Wheat II. Formation and Development of Sperm Cell

Ultrastructural events in wheat sperm cell development were examined from the division of generative cell stage to the maturation of sperm cell in pollen grains. The results are smnmarized as follows: 1. The generative cell in forming microspore by mitosis goes through a series of changes including tile displacement and transformation. It finally becomes a spindle-shaped cell getting ready for another mitosis. The generative cell at this stage is naked. it is only surrounded by both membranes of its own and vegetative cell Most part of the generative cell is occupied by the conspicuous elliptical nucleus with highly condensed chromatin. With the exception of ribosomes, the organelles in the thin layer of generativc cell cytoplasm are obviously fewer and smaller than those in the vegetative cytoplasm. The mierotubules may also be seen in the cytoplasm of spindle-shaped generative cell parallel to the long axis of the cell. There is no amyloplast in generative cell. 2. When the generative cell has moved to the position close to the vegetative nucleus again, it begins to divide. The formation of sperm cells as the result of mitosis of generative cell, and the development of sperm cell involves the following main changes. The shape of the sperm cell tranforms from spherical to elliptical, finally it forms an elongated cell with a tail-like structure. At the sametime, the distribution of cytoplasm gradually concentrated at one end of the sperm cell to form the cytoplasmic extension, so that the so called "tail" of the sperm cell is formed. There are more organelles, especially the mitochondria, assembling in this part. The sperm cell just formed after mitosis is naked and the enclosed plasma membrane is discontinuous. The sperm cell membrane is enclosed by vegetative cell membrane, and the double membranes may be completed at a later stage. It is considered that the period which follows is very short, the deposition of wall material, the callose, occurs to fill up continuously the space between two membranes, but soon after this period the cell wall becomes discontinuous and the wall material is obviously decreased. The significance of the position of the generative cell before its mitosis and the morphological changes during the development of the sperm cell are discussed in this paper.     

Radiosensitivity of early and late M-phase HeLa cells isolated by a combination of fluorescent ubiquitination-based cell cycle indicator (Fucci) and mitotic shake-off

The mitotic shake-off method revealed the remarkable variation of radiosensitivity of HeLa cells during the cell cycle: M phase shows the greatest radiosensitivity and late S phase the greatest radioresistance. This method harvests all M-phase cells with a round shape, making it impossible to further subdivide M-phase cells. Recently, the fluorescent ubiquitination-based cell cycle indicator (Fucci) was developed; this system basically causes cells in G(1) to emit red fluorescence and other cells to emit green fluorescence. Because the green fluorescence rapidly disappears at late M phase, two-dimensional flow cytometry analysis can usually detect a green(high)/red(low) fraction including S-, G(2)- and early M-phase cells but not a transitional fraction between green(high)/red(low) and green(low)/red(low) including late M-phase cells. However, combining the shake-off method concentrated the transitional fraction, which enabled us to separate early and late M-phase cells without using any drugs. Here we demonstrate for the first time that cells in early M phase are more radiosensitive than those in late M phase, implying that early M phase is the most radiosensitive sub-phase during the cell cycle.     

The induction of DNA synthesis in the chick red cell nucleus in heterokaryons during the first cell cycle after fusion with HeLa cells.

Induction of DNA synthesis in embryonic chick red cells has been examined during the first and second cell cycles after fusion with HeLa cells synchronized in different parts of G1 and S-phase. The data indicate that: (i) the younger the embryonic blood the more rapidly the red cells are induced into DNA synthesis; (ii) the greater the ratio of HeLa to chick nuclei in the heterokaryon, the more rapidly the induction occurs; (iii) DNA synthesis in the chick nucleus can continue after the HeLa nucleus has left S-phase and entered either G2 or mitosis; (iv) the induction potential of late S-phase HeLa is somewhat lower than that of early or mid S-phase cells; (v) less than 10% of the chick DNA is replicated during the first cycle after fusion and only a small proportion (15%) of the chick nuclei approach the 4C value of DNA during the second cycle after fusion; (vi) the newly synthesized DNA is associated either with the condensed regions of the nucleus or with the boundaries between condensed and non-condensed regions; (vii) the chick chromosomes at the first and second mitosis after fusion are in the form of PCC prematurely condensed chromosomes); they are never fully replicated and are often fragmentary; (viii) DNA synthesis in the chick nuclei is accompanied by an influx of protein (both G1 and S-phase protein) from the HeLa component of the heterokaryon.     

Nuclear responses to MPF activation and inactivation in Xenopus oocytes and early embryos

The cell cycle of most organisms is highlighted by characteristic changes in the appearance and activity of the nucleus. Structural changes in the nucleus are particularly evident when a cell begins to divide. At this time, the nuclear envelope is disassembled, the chromatin condenses into metaphase chromosomes, and the chromosomes associate with a newly formed spindle. Upon completion of cell division the nuclear envelope reassembles around the chromosomes as they form telophase nuclei, and subsequently interphase nuclei, in the daughter cells. The cytoplasmic control of nuclear behavior has been the theme of Yoshio Masui's research for much of his career. His pioneering demonstration that the cytoplasm of maturing amphibian oocytes causes the resumption of the meiotic cell cycle when it is injected into an immature oocyte provided unequivocal evidence that a cytoplasmic factor could initiate the transition from interphase to metaphase (M-phase) in intact cells. As described in several reviews in this and the previous issue of Biology of the Cell (see Beckhelling and Ford; Duesbery and Vande Woude; Maller), Masui initially called this activity maturation promoting factor (MPF), but when it was realized that it was a ubiquitous regulator of both mitotic and meiotic cell cycles, MPF came to stand for M-phase promoting factor. Biochemical evidence indicates that MPF activity is composed of a mitotic B-type cyclins and cyclin-dependent kinase 1. The increase in the protein kinase activity of cdk1 initiates the changes in the nucleus associated with oocyte maturation and with the entry into mitosis. This article will attempt to provide a brief summary of the responses of the nucleus to the activation of MPF. In addition, the effect of MPF inactivation on nuclear envelope assembly at the end of mitosis will be discussed. This article is written as a tribute to Yoshio Masui on his retirement from the University of Toronto, and as an expression of gratitude for his guidance while I was a student in his laboratory. I have felt very privileged to have known him as a mentor and a friend.     

Gene silencing of CENP-E by small interfering RNA in HeLa cells leads to missegregation of chromosomes after a mitotic delay

Centromeric protein-E (CENP-E) is a kinesin-like motor protein required for chromosome congression at prometaphase. Functional perturbation of CENP-E by various methods results in a consistent phenotype, i.e., unaligned chromosomes during mitosis. One unresolved question from previous studies is whether cells complete mitosis or sustain mitotic arrest in the presence of unaligned chromosomes. Using RNA interference and video-microscopy, we analyzed the dynamic process of mitotic progression of HeLa(H2B)-GFP cells lacking CENP-E. Our results demonstrate that these cells initiated anaphase after a delayed mitotic progression due to the presence of unaligned chromosomes. In some dividing cells, unaligned chromosomes are present during anaphase, causing nondisjunction of some sister chromatids producing aneuploid daughter cells. Unlike in Xenopus extract, the loss of CENP-E in HeLa cells does not impair gross checkpoint activation because cells were arrested in mitosis in response to microtubule-interfering agents. However, the lack of CENP-E at kinetochores reduced the hyperphosphorylation of BubR1 checkpoint protein during mitosis, which may explain the loss of sensitivity of a cell to a few unaligned chromosomes in the absence of CENP-E. We also found that presynchronization with nocodazole sensitizes cells to the depletion of CENP-E, leading to more unaligned chromosomes, longer arrest, and cell death.