Microtubule disassembly and inhibition of mitosis by a novel synthetic pharmacophore

Microtubule drugs, which block cell cycle progression through mitosis, have seen widespread use in cancer chemotherapies. Although microtubules are subject to regulation by signal transduction mechanisms, their pharmacological modulation has so far relied on compounds that bind to the tubulin subunit. A new microtubule pharmacophore, diphenyleneiodonium, causing disassembly of the microtubule cytoskeleton is described here. Although this synthetic compound does not affect the assembly state of purified microtubules, it profoundly suppresses microtubule assembly in vivo, causes paclitaxel-stabilized microtubules to cluster around the centrosomes, and selectively disassembles dynamic microtubules. Similar to other microtubule drugs, this new pharmacophore blocks mitotic spindle assembly and mitotic cell division.     

Asters play only a dispensable role in the induction of the cleavage furrow in the blastomeres of early Xenopus embryos

Kuroda et al. (2001) of our laboratory have previously revealed that exposure of early Xenopus embryos to 150 mm urethane results in complete suppression of formation of the asters and the cleavage furrow, as well as significant reduction of the size of the spindle in the blastomeres, allowing only 1 or 2 cycles of mitosis but not cytokinesis. In the course of closer examination of the effect of urethane on the cleavage of blastomeres of early Xenopus embryos, we unexpectedly discovered that exposure of early Xenopus embryos to 75 mm urethane did not prevent cell division at all, though asters were not detected in the blastomeres. Instead, they contained a spindle that appeared rather normal. They also formed the diastema, a thin yolk-free structure, which is considered to play an essential role in the induction of the cleavage furrow. Essentially the same results were obtained in the exposure of embryos to vinblastine, a well-known microtubule inhibitor: exposure of embryos to 20 micro g/mL vinblastine resulted in complete suppression of cleavage of the blastomeres, where formation of both the spindle and asters were perfectly suppressed. By contrast, exposure of embryos to 5 microg/mL vinblastine did not prevent cleavage in the blastomeres though asters were not detected, whereas the rather normal spindle was formed. Thus, there was a close correlation between the formation of the normal spindle, not asters, and that of the cell division furrow and the diastema in the blastomeres of early Xenopus embryos. We suggest that while the spindle plays an essential role, asters are likely to play only a dispensable role in the induction of the cleavage furrow in even very large cells like the blastomeres of early Xenopus embryos.     

Behaviour of centrosomes in early Tubifex embryos: asymmetric segregation and mitotic cycle-dependent duplication

An antibody raised against a highly conserved peptide of -tubulin (Joshi et al. 1992) recognized a 50 kDa polypeptide in centrosomes in Tubifex embryos. Centrosomes labelled with this antibody are found at both poles of the first meiotic spindle and at the inner pole of the second meiotic spindle. At the transition to the second meiosis, there is no change in morphology of the centrosomes which are retained in the egg proper. In contrast, as the second meiosis proceeds from anaphase to telophase, centrosomes labelled with the antibody gradually become smaller, but are still recognized as tiny dots; each egg exhibits no more than one tiny dot. The first cleavage spindles exhibit a centrosome at one pole but not at the other. The spindle pole with a centrosome forms an aster which is inherited by the larger cell, CD, of the two-cell embryo; the centrosome-free spindle pole then becomes anastral and is segregated to a smaller cell AB. Centrosomes are present in the C and D cell lineages but not in the A and B lineages, at least up to the eighth cleavage cycle. During cleavage stages, centrosomes duplicate early in telophase of each mitosis, and their size changes in a cell cycle-specific fashion. Centrosomes which otherwise duplicate asynchronously in separate cells do so synchronously in a common cytoplasm. Centrosome duplication is inhibited by nocodazole but not by cytochalasin D. An examination of embryos treated with cycloheximide or aphidicolin also suggests that centrosome duplication during cleavages requires protein synthesis but no DNA replication per se. These results suggest that the centrosome cycle in Tubifex blastomeres is linked to the mitotic cycle more closely than is that in other animals.     

Activated bovine cytoplasts prepared by demecolcine-induced enucleation support development of nuclear transfer embryos in vitro

Demecolcine-induced enucleation (IE) of mouse oocytes has been shown to improve development to term of cloned mice. In this study, we characterized the kinetics and morphological progression of bovine oocytes subjected to IE, and evaluated their ability to support embryo development to the blastocyst stage after nuclear transfer (NT). In vitro matured bovine oocytes were parthenogenetically activated and subsequently exposed to demecolcine at various times post-activation. Onset and duration of demecolcine treatment significantly altered activation and IE frequencies, which varied from 7.1% to 100% and 33.3% to 91.7%, respectively, at 5 hr post-activation. A significant decrease in IE frequencies was observed at 17 hr post-activation (3.4%-46.1%), possibly due to reincorporation of chromosomes into the oocyte after incomplete second polar body (PB) extrusion. Oocytes were reconstructed by NT before (treatment 1) or after (treatment 2) activation and demecolcine treatment, and cultured in vitro. Cleavage (48.1%-54.2%) and blastocyst rates (15.7%-19%) were equivalent for the two treatments, as well as the total cell number in NT blastocysts. Furthermore, most of the blastocysts were completely diploid (treatment 2) or heteroploid but with a majority of diploid nuclei (treatment 1). Our results demonstrate that the IE method can be successfully used to produce enucleated bovine cytoplasts that are competent to support development to the blastocyst stage after NT. This technically simple approach may provide a more efficient method to enhance the success rate of NT procedures. Further studies are needed to improve the in vitro development efficiency and to expand our understanding of the mechanism(s) involved in demecolcine-induced enucleation.     

Cell cultures derived from early zebrafish embryos differentiate in vitro into neurons and astrocytes

The zebrafish is a polular nonmammalian model for studies of neural development. We have derived cell cultures, initiated from blastula-stage zebrafish embryos, that differentiate in vitro into neurons and astrocytes. Cultures were initiated in basal nutrient medium supplemented with bovine insulin, trout serum, trout embryo extract and fetal bovine serum. After two weeks in culture the cells exhibited extensive neurite outgrowth and possessed elevated levels of acetylcholinesterase enzyme activity. Ultrastructural analysis revealed that the neurites possessed microtubules, synaptic vessicles and areas exhibiting growth cone morphology. The cultures expressed proteins recognized by antibodies to the neuronal and astrocyte-specific markers, neurofilament and glial fibrillary acidic protein (GFAP). Poly-D-lysine substrate stimulated neurite outgrowth in the cultures and inhibited the growth of nonneuronal cells. Medium conditioned by the buffalo rat liver line, BRL, promoted the growth and survival of the cells in culture. Mitotically active cells were identified in cultures that had undergone extensive differentiation. The embryo cell cultures provide an in vitro system for investigations of biochemical parameters influencing zebrafish neuronal cell growth and differentiation.     

Developmental potential of isolated blastomeres from early murine embryos

Experiments were designed to evaluate the effect of blastomere separation on blastocoele formation and development of viable fetuses. Two-cell and four-cell murine embryos were dissociated into individual blastomeres and cultured to the blastocyst stage. For embryos of both stages, zona removal and blastomere separation reduced (P<0.05) the number of viable embryos at the onset of culture and reduced (P<0.01) the frequency of continuation of development of blastomeres to the blastocyst stage. Attempts to repeatedly split two-cell stage embryos decreased in vitro development to blastocysts. The number of cells in two-cell embryos that were cultured to blastocyst was not different for control (64.8 +/- 11.5) or for two-cell embryos cultured without the zona pellucida (60.9 +/- 10.1) but was reduced (P<0.01) for one-half embryos that were cultured to blastocysts (35.6 +/- 10.6). The cell number of blastocysts obtained from dissociated four-cell (1/4) embryos (17.4 +/- 1.4) was similarly reduced (P<0.01). In vivo development was assessed after cultured embryos were transferred to the uteri of day 3 pseudopregnant females. Zona free intact embryos (2/36, 6%) and zona free half embryos (7/36; 19%) developed less frequently (P<0.05) than intact controls (45/100). Noncultured morula briefly exposed to pronase to thin the zona had similar impaired development. Embryos with thinned zona or no zona developed less frequently (21/82, 2/72 respectively, P<0.05) than nonpronase-treated controls (50/83).     

Isolation of protoplasts from somatic embryos of carrot

Protoplasts were isolated enzymatically from synchronously induced globular somatic embryos from a carrot suspension culture. Among the macerating enzymes tested, Driselase was the most effective for release of protoplasts from embryos. A higher medium osmolarity was required for the isolation of protoplasts from embryos than from undifferentiated cells. Protoplasts from embryos were smaller than protoplasts from undifferentiated cells. On step gradients of Ficoll, protoplasts from embryos gave one major band. Protoplasts from undifferentiated cells gave two major bands, one lighter and the other heavier than the protoplasts from embryos.     

Dynamic Organization of Microtubules and Microfilaments during Cell Cycle Progression in Higher Plant Cells

Abstract: The cytoskeleton, which mainly consists of microtubules (MTs) and actin microfilaments (MFs), plays various significant roles that are indispensable for eukaryotic viability, including determination of cell shape, cell movement, nuclear division, and cytokinesis. In animal cells, MFs appear to be of more importance than MTs, except for spindle formation in nuclear division. In contrast, higher plants have a rigid cell wall around their cells, and have thus evolved elegant systems of MTs to control the direction of cellulose microfibrils (CMFs) deposited in the cell wall, and to divide centrifugally in a physically limited space. Dynamic changes in MTs during cell cycle progression in higher plant cells have been observed over several decades, including cortical MTs (CMTs) during interphase, preprophase bands (PPBs) from late G₂ phase to prophase, spindles from prometaphase to anaphase, and phragmoplasts at telophase. The MFs also show some changes not as obvious as MT dynamics. However, questions regarding the process of formation of these arrays, and the precise mechanisms by which they fulfill their roles, remain unsolved. In this article, we present an outline of the changes in the cytoskeleton based on our studies with highly-synchronized tobacco BY-2 cells. Some candidate molecules that could play roles in cytoskeletal dynamics are discussed. We also hope to draw attention to recent attempts at visualization of cytoskeletons with molecular techniques, and to some examples of genetic approaches in this field.     

Synchronization of cell division in eight-cell bovine embryos produced in vitro: Effects of nocodazole

Current methods of arresting and synchronizing cell division have not been very successful and have had few applications in embryo studies. Our objective was to determine the reliability of a metaphase arrest agent, nocodazole, for halting and synchronizing blastomere division in cleavage-stage bovine embryos, and to verify its reversibility and toxicity in vitro. Eight-cell-stage embryos obtained at 58 hr postinsemination were treated with varying concentrations of nocodazole for 12 hr. Treated embryos were assessed for cleavage arrest, chromatin morphology, DNA synthesis, and histone H1 and myelin basic protein (MBP) kinase activity, and were scored for blastocyst formation and hatching rate. They were subsequently fixed to count the number of nuclei. Complete arrest of cell division was observed at concentrations of 0.4 μg ml⁻¹ and above. Removal from nocodazole treatment led to immediate release from cleavage arrest, and was followed by synchronized mitosis, histone H1 kinase deactivation, and reentry into interphase within 3–5 hr. DNA synthesis was reinitiated at 6 hr after release. Although cell numbers and hatching rate decreased, the proportion of embryos reaching blastocyst stage was not significantly affected in nocodazole-treated embryos. It is concluded that nocodazole is a suitable choice for the cell-cycle synchronization of donor embryos for use in studies on the interactions between nucleus and cytoplasm during early embryogenesis. © 1996 Wiley-Liss, Inc.     

Culture of cells from zebrafish (Brachydanio rerio) blastula-stage embryos

The zebrafish has become a popular model for studies of vertebrate development and toxicology. However,in vitro approaches utilizing this organism have not been fully exploited due to the absence of suitable cell culture systems. Previously, we developed methods for the culture of cells derived from zebrafish blastula-stage embryos. One of these cultures, ZEM-2, was derived in a complex medium containing trout embryo extract, trout serum and medium conditioned by buffalo rat liver cells. In this study we describe a zebrafish embryo cell line, ZEM-2A, derived from ZEM-2 following selection for growth in a simplified medium. Optimal growth of ZEM-2A cells is attained in nutrient medium supplemented with 5% fetal bovine serum.     

不同群系小鼠胚胎玻璃化冷冻保存技术的研究

利用 EFS40 ,二步法对近交系 C5 7BL/6、DBA/2和远交群 ICR小鼠囊胚玻璃化冷冻保存 ,并对冷冻后胚胎体内、外发育效果进行比较。结果表明 ,相同条件下鲜胚经培养 ,近交系 C5 7BL /6小鼠的囊胚发育率 ( 93% )与 ICR( 1 0 0 % )相比差异不显著 ( P>0 .0 5 ) ;而两近交系的囊胚孵化率明显低于 ICR( P<0 .0 1 )。 C5 7BL/6、DBA/2小鼠囊胚冷冻后发育率 ( 93% ,96% )和孵化率 ( 5 2 % ,46% )与各自对照组 ( 1 0 0 % ,1 0 0 %和 61 % ,62 % )相比均无显著差异 ( P>0 .0 5 ) ;并且与 ICR冷冻组发育率和孵化率 ( 94% ,5 3% )之间也无显著差异 ( P>0 .0 5 )。两近交系冻胚移植妊娠与各自对照组和 ICR冷冻组比较均无显著差异 ( P>0 .0 5 )。C5 7BL/6胚胎移植产仔率 ( 35 % )与对照组 ( 5 1 % )之间差异显著 ( P<0 .0 1 ) ,而 DBA/2胚胎移植产仔率 ( 4 7% )与对照组和 ICR冷冻组 ( 39% ,5 8% )相比差异不显著 ( P>0 .0 5 )。     

Incidence of chromosomal anomalies in early bovine embryos derived from in vitro fertilization

The incidence of chromosomal anomalies in early bovine embryos derived from follicular oocytes fertilized in vitro using sperm separated by Percoll density gradient centrifugation was investigated. Overall, chromosomal anomalies were observed in 13.7% (138/1005) of embryos. There were 14 haploids (1.4%), 2 hypodiploids (0.2%), 6 hyperdiploids (0.6%), 101 triploids (10.0%), 12 tetraploids (1.2%), 2 diploid/triploid mosaics (0.2%), and 1 diploid/tetraploid mosaic (0.1%). The frequency of triploidy was caused mainly by polyspermy. There was a significant difference in the frequency of embryos with abnormal chromosomes between the two bulls used (P < 0.005), but Percoll centrifugation did not affect the observed incidence of anomalies. The frequency of chromosomal anomalies in embryos at each stage increased with delay or arrest of development. These results suggest that the incidence of chromosomal anomalies depended on the conditions of in vitro fertilization and the arrest of development.     

Isolation and culture of single cells from carrot embryos

Callus and secondary cell cultures originating from embryos are known to have a higher morphogenetic capacity in comparison to others of different origin. A method for isolating embryonic cells in order to establish primary cell cultures has been developed. Carrot embryos were digested with different cell-separating enzymes and after 24 h post-digestion in 0.6 M mannitol they were sheared by using a hypodermic syringe. The resulting cell suspension consisted of morphologically-intact cells. In the procedure to macerate embryos into single cells it was found that embryos were surrounded by a cuticle. Carrot embryo cells when cultured divided and gave rise to callus and to proembryos.     

Regulation of interkinetic nuclear migration by cell cycle-coupled active and passive mechanisms in the developing brain

A hallmark of neurogenesis in the vertebrate brain is the apical-basal nuclear oscillation in polarized neural progenitor cells. Known as interkinetic nuclear migration (INM), these movements are synchronized with the cell cycle such that nuclei move basally during G1-phase and apically during G2-phase. However, it is unknown how the direction of movement and the cell cycle are tightly coupled. Here, we show that INM proceeds through the cell cycle-dependent linkage of cell-autonomous and non-autonomous mechanisms. During S to G2 progression, the microtubule-associated protein Tpx2 redistributes from the nucleus to the apical process, and promotes nuclear migration during G2-phase by altering microtubule organization. Thus, Tpx2 links cell-cycle progression and autonomous apical nuclear migration. In contrast, in vivo observations of implanted microbeads, acute S-phase arrest of surrounding cells and computational modelling suggest that the basal migration of G1-phase nuclei depends on a displacement effect by G2-phase nuclei migrating apically. Our model for INM explains how the dynamics of neural progenitors harmonize their extensive proliferation with the epithelial architecture in the developing brain.     

Sex ratio of early embryos fertilized in vitro with spermatozoa separated by percoll

Early bovine embryos were obtained by in vitro fertilization and sexing carried out by chromosome analysis. Separation of bovine X- and Y-bearing spermatozoa was performed using Percoll density gradient centrifugation and the enrichment of X-sperm proportion was investigated. Through treatment with vinblastin sulfate and podophyllotoxin, 880 (48.6%) of 1812 embryos at two- to seven-cell stages at 48 to 53 h after sperm-egg incubation produced metaphase spreads, and 399 (45.3%) of these were successfully sexed; the sexable rate reaching 53.4% for four-cell embryos. Sexing rates for embryos from the original sperm of two bulls were 69.6% (32/46) in Bull A and 54.2% (58/107) in Bull B. Embryos fertilized in vitro with sperm sedimented at the bottom of sperm centrifuged under conditions (I) 50 to 85% of Percoll, 15 °C; (II) 30 to 80%, 10 °C; (III) 30 to 80% 20 °C; (IV) 30 to 90%, 20 °C, gave rise to male sex ratios of (I) 58.3% in Bull A and 53.5% in Bull B, (II) 65.9% in Bull A, (III) 49.3% in Bull B and (IV)_66.7% in Bull B. In conclusion, Percoll density gradient centrifugation under these four conditions was unsuccessful in separating X- and Y-bearing bull spermatozoa.     

Dynamic Organization of Plant Microtubules at the Three Distinct Transition Points During the Cell Cycle Progression of Synchronized Tobacco BY-2 Cells

Dynamic changes of microtubule (MT) configuration have been examined during the cell cycle progression in tobacco BY-2 cells, which have been highly synchronized by aphidicolin treatment. Although it has been shown previously that four cell cycle stages display characteristic features of MTs (Hasezawa et al., 1991), distinct changes of MT configuration were observed at the interfaces of G₂/M, M/G₁ and G₁/S, and the frequency of appearance of such distinct structures were quantitatively examined. Among others, it is the first observation that at M/G₁ disintegrating phragmoplasts coexisted with short MTs in the perinuclear envelopes, but the MTs disappeared in the later stage, when cortical MTs were organizing. Thus it is supposed that cortical MTs originate from the transiently observed short MTs in the perinuclear region. This observation offered also an experimental system to analyze the molecular changes of MTs at the three interfaces during cell cycle progression in plant cells, as the mass culture of tobacco BY-2 cells is readily available.     

Development of reconstituted embryos derived from transgenic embryonic stem cell nuclei

This study was carried out to transform embryonic stem (ES) cells and to produce the reconstituted embryos derived from transgenic ES cell nuclei. Then, in vitro/vivo developmental potency of transgenic ES cells were compared to that of control ES cells (non-transgenic ES cells) in the reconstituted embryos. Unfertilized B6D2F1 ooplasm at metaphase II (M II) and two kinds of ES cell lines, 129SV and transgenic (tg) 129SV transformed by EGFP gene, were used as nuclear recipients and nuclear donors, respectively. The M II chromosome-spindle complex was aspirated into the pipette with a minimal volume of ooplasm. After enucleation, the ES cell nuclei was injected into the enucleated ooplasm directly. Then, reconstituted embryos were activated in SrCl2, and they were cultured in HTF medium. There was no difference of developmental rate between reconstituted embryos derived from the control (non-transgenic) and the tg ES cells. From this result, we indicated that transgenic ES cells might not change the property of peculiarity of the ES cell by gene transfer. The expression of GFP gene in the embryos was observed by fluorescence microscope at the 4-cell and more stage. As comparison with development of the embryos derived from the control and tg ES cells, the difference of the development could not be confirmed between the two cell groups. When the reconstituted embryos derived from the control and tg ES cells were transferred into oviduct or uterus of pseudopregnant females, fetuses were observed 13.5 days post coitum. However, in all fetuses, developmental arrest and regression were seen 19.5 days post coitum.     

Primary cell culture from embryos of the Japanese scallop Mizuchopecten yessoensis (Bivalvia)

Primary cell cultures obtained from embryos of Mizuchopecten yessoensis (Bivalvia) survived for four months. Although the number of cells progressively decreased during the cultivation, mitotic cells were observed both at the first stages and at the end. A possibility of growing marine invertebrates cells in long term primary culture is discussed.