Possible involvement of cytoskeletal organelles in blastoderm formation of the silkworm,Bombyx mori

Summary

In this work we have studied the possibility that cytoskeletal systems are involved in energid migration and blastoderm formation of the silkworm, Bombyx mori. The results obtained suggest: (1) energid migration is mainly controlled by microtubules and perhaps secondarily by microfilaments, (2) morphological changes of microprojections covering the egg surface are regulated by microfilaments and (3) the changes of microprojections are independent of energid migration.     

Early embryonic development and diapause stage in the band-legged ground cricket Dianemobius nigrofasciatus

The band-legged ground cricket Dianemobius nigrofasciatus enters diapause at an early embryonic stage when adults are reared under short-day conditions or the eggs are exposed to a low temperature. We examined the morphological features of the embryo during early development and determined the exact stage of entry into diapause. In non-diapause eggs, no periplasmic space was observed in the surface region and a small number of nuclei surrounded by cytoplasm (energids) were found among the yolk granules and lipid droplets 12 h after egg laying (AEL) at 25°C. The energids sparsely but evenly populated the surface region at 40 h AEL, but there were some gaps between these energids. A continuous thin layer of nuclei with cytoplasm had completely covered the egg surface at 56 h AEL, suggesting that the blastoderm is formed between 40 and 56 h AEL. At 72 h AEL, we found a germ band at the posterior pole. Electron microscopy revealed clear cell membranes at 40 h AEL. Staining with rhodamine-dextran dye demonstrated that the cell membrane is formed when the nuclei appear on the egg surface at 12–24 h AEL. These results indicate that cellularization occurs before blastoderm formation. In diapause eggs, neither the embryonic rudiment nor germ band was formed, but a continuous layer of cells covered the egg surface. It is concluded that D. nigrofasciatus enters diapause at the cellular blastoderm.     

The cytaster,a colchicine-sensitive migration organelle of cleavage nuclei in an insect egg

Time-lapse analyses of nuclear multiplication in the eggs of the gall midge Wachtliella persicariae L., documented in film D 1235 (available from the IWF, Göttingen), give evidence of a special migration organelle of cleavage nuclei. Each of these “migration cytasters” represents one greatly enlarged polar cytaster of the mitotic apparatus, which is connected to one nucleus. From the films it can be concluded that the astral rays temporarily adhere to peripheral egg structures and exert tractive forces toward the cytaster center. These forces combine and pull the accompanying daughter nucleus through the ooplasm after each mitosis. This “active” mode of migration, which is accompanied by extensive polarized transport of yolk particles toward the cytaster center, enables the energids (= cleavage nucleus and its associated island of cytoplasm) to move relative to the surrounding ooplasm. In addition, there is a “passive” mode of nuclear migration: The energids are moved by means of plasmic flows, thereby maintaining their position in relation to the surrounding ooplasm. Electron microscopic studies show solitary microtubules running radially toward the cytaster center. As a result of colchicine injection (1) the microtubules disintegrate, (2) the polarized transport of yolk particles cases, (3) the active nuclear migration stops and the nuclei are only passively moved by rhythmic ooplasmic flows. This inhibition of active nuclear migration gives further evidence that microtubules take an essential part in it. Control experiments with lumicolchicine show no effect on nuclear migration. Conversely, under the influence of cytochalasin B active nuclear migration is continued, while the ooplasmic flows are inhibited. Thus the mechanisms of active and passive nuclear migration can work independently of each other. The generation of tractive forces along the astral rays is discussed with respect to current models of spindle function.     

Early embryonic development in the spider Achaearanea tepidariorum: Microinjection verifies that cellularization is complete before the blastoderm stage

The spider Achaearanea tepidariorum is emerging as a non-insect model for studying developmental biology. However, the availability of microinjection into early embryos of this spider has not been reported. We defined the early embryonic stages in A. tepidariorum and applied microinjection to its embryos. During the preblastoderm 16- and 32-nucleus stages, the energids were moving toward the egg periphery. When fluorochrome-conjugated dextran was microinjected into the peripheral region of 16-nucleus stage embryos, it was often incorporated into a single energid and inherited in the progeny without leaking out to surrounding energids. This suggested that 16-nucleus stage embryos consisted of compartments, each containing a single energid. These compartments were considered to be separate cells. Fluorochrome-conjugated dextran could be introduced into single cells of 16- to 128-nucleus stage embryos, allowing us to track cell fate and movement. Injection with mRNA encoding a nuclear localization signal/green fluorescent protein fusion construct demonstrated exogenous expression of the protein in live spider embryos. We propose that use of microinjection will facilitate studies of spider development. Furthermore, these data imply that in contrast to the Drosophila syncytial blastoderm embryo, the cell-based structure of the Achaearanea blastoderm embryo restricts diffusion of cytoplasmic gene products.     

Early embryonic development of the mayfly Ephemera japonica McLachlan (Insecta: Ephemeroptera,Ephemeridae)

In the newly laid egg of the mayfly Ephemera japonica, an egg nucleus (oocyte nucleus) at metaphase of the first maturation division is in the polar plasm at the mid-ventral side of the egg, and a male pronucleus lies in the periplasm beneath a micropyle situated just opposite the polar plasm or at the mid-dorsal side of egg. The maturation divisions are typical. An extensive and circuitous migration of the male pronucleus is involved in the fertilization process: it first moves anteriad in the periplasm from beneath the micropyle to the anterior pole of the egg and then turns posteriad in the yolk along the egg's long axis to the site of syngamy, near the center of the egg. Cleavage is superficial. The successive eight cleavages, of which the first five are synchronized, result in the formation of the blastoderm, and about ten primary yolk cells remain behind in the yolk. Even in the newly formed blastoderm, the thick embryonic posterior half and the thin extraembryonic anterior half areas are distinguished: the former cells are concentrated at the posterior pole of the egg to form the germ disc, and the latter cells become more flattened, forming serosa. Time-lapse VTR observations reveal a yolk stream that is in accord with the migration of the male pronucleus in time and direction. The yolk stream is also generated in activated unfertilized eggs, and it is probable that the migration of the male pronucleus in association with the fertilization may be directed by the yolk stream. J. Morphol. 238:327–335, 1998. © 1998 Wiley-Liss, Inc.     

Organization of the cytoskeleton in early Drosophila embryos

The cytoskeleton of early, non-cellularized Drosophila embryos has been examined by indirect immunofluorescence techniques, using whole mounts to visualize the cortical cytoplasm and sections to visualize the interior. Before the completion of outward nuclear migration at nuclear cycle 10, both actin filaments and microtubules are concentrated in a uniform surface layer a few micrometers deep, while a network of microtubules surrounds each of the nuclei in the embryo interior. These two filament-rich regions in the early embryo correspond to special regions of cytoplasm that tend to exclude cytoplasmic particles in light micrographs of histological sections. After the nuclei in the interior migrate to the cell surface and form the syncytial blastoderm, each nucleus is seen to be surrounded by its own domain of filament-rich cytoplasm, into which the cytoskeletal proteins of the original surface layer have presumably been incorporated. At interphase, the microtubules seem to be organized from the centrosome directly above each nucleus, extending to a depth of at least 40 microns throughout the cortical region of cytoplasm (the periplasm). During this stage of the cell cycle, there is also an actin "cap" underlying the plasma membrane immediately above each nucleus. As each nucleus enters mitosis, the centrosome splits and the microtubules are rearranged to form a mitotic spindle. The actin underlying the plasma membrane spreads out, and closely spaced adjacent spindles become separated by transient membrane furrows that are associated with a continuous actin filament-rich layer. Thus, each nucleus in the syncytial blastoderm is surrounded by its own individualized region of the cytoplasm, despite the fact that it shares a single cytoplasmic compartment with thousands of other nuclei.     

Drop out: a third chromosome maternal-effect locus required for formation of the Drosophila cellular blastoderm.

drop out (dop) is a recessive maternal-effect locus identified in a screen for female-sterile mutations in Drosophila polytene region 71C-F. Phenotypic analyses of the dop mutation indicate that the gene is required for proper formation of the cellular blastoderm. In embryos derived from either homozygous or hemizygous dop mothers, cytoplasmic clearing, nuclear migration and division, and pole cell formation appear normal. However, developmental defects are observed prior to and during cellularization of the blastoderm. At the beginning of nuclear cycle 14, the distinct separation of the internal yolk mass and the cortical cytoplasm breaks down. Subsequently, a population of somatic nuclei located at the periphery of the syncytial blastoderm becomes irregularly spaced and nonuniform in their distribution. Despite a somewhat regular formation of the cortical actin network, cellularization in mutant embryos is extremely variable. Such embryos fail to gastrulate normally and produce variable amounts of defective cuticle. Overall, our analyses suggest that the dop gene functions in maintaining the separation of yolk and cortical cytoplasm and in stabilizing the distribution of somatic nuclei in the Drosophila syncytial blastoderm.     

Programmed Endocytosis During Epiboly of Fundulus heteroclitus

A major question in the analysis of teleost epiboly is the fateof the yolk cytoplasmic layer. It diminishes during epibolyand eventually disappears at the completion of epiboly. Thispaper is concerned with the fate of the surface of the yolkcytoplasmic layer during epiboly. When gastrulae during epibolyare bathed in lucifer yellow (CH) and then observed with fluorescentmicroscopy or bathed in ferritin and then fixed and observedwith TEM, a thin circumferential ring of endocytic vesiclesis observed, confined to the external yolk syncytial layer justperipheral to the advancing margin of the blastoderm. Even thoughthe entire egg is immersed in the marker, endocytosis is confinedto this limited region. More precisely, this endocytosis occursonly within the region of the external yolk syncytial layer,where the surface is most folded. The endocytic vesicles thusformed move downward and settle on the surface of the membraneseparating the yolk from the cytoplasm in the yolk syncytiallayer. They do not join the surface of the internal yolk syncytiallayer; hence they do not contribute to its expansion. Priorto the onset of epiboly there is no such endocytosis at thesurface of the egg. Since this endocytosis occurs only duringepiboly and only at the surface of the external yolk syncytiallayer just peripheral to the advancing margin of the blastoderm,and in the absence of large molecules in the medium, we concludethat it is programmed. We, therefore, present this as a caseof programmed internalization of cell surface serving as themorphogenetic mechanism responsible for the disappearance ofthe surface of the yolk cytoplasmic layer during gastrulationof the teleost Fundulus heteroclitus     

Blastoderm formation in artificially activated eggs of Pimpla turionellae (Hym.).

Unlaid, explanted eggs of Pimpla turionellae can be activated by mechanical deformation. Time-lapse films of cleavage and blastoderm formation in such eggs show that in some of them the normal central flow of ooplasm, which transports the energids, is reduced or absent. Instead, a peripheral syncytial ring moves along the antero-posterior egg axis and distributes nuclei within the periplasm.     

Early embryonic development,including germ-disk stage,in the theridiid spider Achaearanea japonica (Bös. et Str.)

Early embryonic development, from the first cleavage to the germ-disk stage, in the theridiid spider Achaearanea japonica was examined by light and electron microscopy. The eggs are syncytial during the first four cleavages, and then invaginations of cell membranes fuse to generate the blastomeres at the sixteen-nucleus stage. The cleavage pattern is a modified type of total cleavage. It appears that radial bundles of microtubules that radiate from the perinuclear cytoplasm may participate in the migration of cleavage nuclei for the formation of the blastoderm. The large yolk granules are sequestered by cell membranes from the blastomeres or blastoderm cells into the interior of the embryo together with various organelles and glycogen granules. Most of the blastoderm cells converge in the upper hemisphere to form the germ disk, whereas a few cells remain in the lower hemisphere. The embryo at the germ-disk stage contains many spherical germ-disk cells. Almost no large yolk granules are found in these cells, but the flat remaining cells each contain several large yolk granules. These remaining cells may preserve a flat shape to cover the surface of the embryo that does not include the germ disk. © 1995 Wiley-Liss, Inc.     

Early development of the kelp fly,Coelopa frigida (Diptera). II. Morphology of cleavage and blastoderm formation

Cleavage and blastoderm formation in Coelopa frigida are extremely rapid developmental processes. In short (6–7 minutes) successive cell cycles, nuclei multiply and spread out through the egg. The movement seems to be aided by endoplasmic vesicles and cisternae which are in direct contact with the nuclear membrane. The first cells to separate from the egg plasmodium in early superficial cleavage stages are the pole cells. Precursor material from multivesicular bodies forms the pole cell membranes. The primary nuclei from the posterior pole region are removed from the blastoderm by the pole cell segregation. Blastoderm nuclei from the regions adjacent to the posterior pole migrate into the residual periplasm after pole cell segregation has been completed and constitute the blastoderm nuclei in that region of the egg. Nucleoli are not revealed during internal cleavage. They appear in pole cells shortly after their segregation. The generation time of the blastoderm nuclei increases after the twelfth cleavage. Concurrently, nucleoli form in the blastoderm nuclei and permanent cell membranes separate individual blastoderm cells. After blastoderm cells have been separated from each other, they remain in contact with the interior yolk sac by means of cytoplasmic canals. This contact is maintained at least during the early phases of blastokinesis. Observations on nuclear migration and rapid membrane formation are discussed as examples of protein assembly from subunits as an alternative to de novo protein synthesis in early stages of development.     

Ultrastructural study of the mature egg of Tethya citrina sarà and melone (porifera,demospongiae)

Tethya citrina is an oviparous demosponge in which eggs are distributed in clumps within the choanosome. The cytoplasm of the mature egg presents a peripheral cortex consisting of a slightly granular layer sandwiched between two densely granular, vesiculated ones. The cortex probably has a specialized, trophic function. Mesohyl bacteria are phagocyted at the egg surface, included in vacuoles, and transferred across the cortical sheath toward the inner cytoplasm. The region of the egg extending between the cortex and the nucleus shows a lacunary system mostly developed beneath the cortical envelope. The noncortical cytoplasm also contains lipid droplets, dense rodlike bodies, and phagosomelike granules. Most of the latter are probably autophagosomes, forming lacunae and supporting autosynthetic vitellogenesis. Rodlike inclusions are probably proteinaceous; they likely originate within the phagosomes and represent the actual yolk material.     

Influence of centriole behavior on the first spindle formation in zygotes of the brown alga Fucus distichus (Fucales, Phaeophyceae)

The influence of centrioles, derived from the sperm flagellar basal bodies, and the centrosomal material (MTOCs) on spindle formation in the brown alga Fucus distichus (oogamous) was studied by immunofluorescence microscopy using anti-centrin and anti-beta-tubulin antibodies. In contrast to a bipolar spindle, which is formed after normal fertilization, a multipolar spindle was formed in polyspermic zygote. The number of mitotic poles in polyspermic zygotes was double the number of sperm involved in fertilization. As an anti-centrin staining spot (centrioles) was located at these poles, the multipolar spindles in polyspermic zygotes were produced by the supplementary centrioles. When anucleate egg fragments were fertilized, chromosome condensation and mitosis did not occur in the sperm nucleus. Two anti-centrin staining spots could be detected, microtubules (MTs) radiated from nearby, but the mitotic spindle was never produced. When a single sperm fertilized multinucleate eggs (polygyny), abnormal spindles were also observed. In addition to two mitotic poles containing anti-centrin staining spots, extra mitotic poles without anti-centrin staining spots were also formed, and as a result multipolar spindles were formed. When karyogamy was blocked with colchicine, it became clear that the egg nucleus proceeded independently into mitosis accompanying chromosome condensation. A monoastral spindle could be frequently observed, and in rare cases a barrel-shaped spindle was formed. However, when a sperm nucleus was located near an egg nucleus, the two anti-centrin staining spots shifted to the egg nucleus from the sperm nucleus. In this case, a normal spindle was formed, the egg chromosomes arranged at the equator, and the associated MTs elongated from one pole of the egg spindle toward the sperm chromosomes which were scattered. From these results, it became clear that paternal centrioles derived from the sperm have a crucial role in spindle formation in the brown algae, such as they do during animal fertilization. However, paternal centrioles were not adequate for the functional centrosome during spindle formation. We speculated that centrosomal materials from the egg cytoplasm aggregate around the sperm centrioles and are needed for centrosomal activation.     

Differential distribution of poly(A)-containing RNA in the embryonic cells of Oncopeltus fasciatus: Analysis by in situ hybridization with a [3H]poly(U) probe

The regional distribution of poly(A)⁺ RNA was examined in the embryonic cells of the milkweed bug, Oncopeltus fasciatus, by in situ hybridization of histological sections with a [³H]poly(U) probe. As shown by a number of control experiments, this probe interacts specifically with poly(A) sequences preserved in the sections. Using this method, it was shown that labeling of periplasmic and vitellophage nuclei increases markedly early during syncytial blastoderm formation. At this time, label also increases in the vitellophage cytoplasm but not in the cytoplasm surrounding the blastodermal nuclei. Labeling continues to increase in the blastodermal nuclei during cellularization and germ band differentiation without a concomitant accumulation in the blastodermal cell cytoplasm. At the time of germ band invagination, the region of the most intense subcellular labeing shifts from the nucleus to the cytoplasm of the invaginated cells. This shift is not evident in the blastodermal cells which remain at the surface of the egg to become the serosa. In the serosa and the vitellophage energids, labeling then decreases as histogenesis proceeds. Significant labeling of the nuclei and cytoplasm of the invaginated germ band cells continues through germ layer formation. It is concluded that poly(A)⁺ RNA, probably synthesized de novo following oviposition, is subject to differential intracellular distribution in three types of Oncopeltus embryonic cells which may reflect cell-specific patterns of mRNA or poly(A) metabolism.     

Studies on the yolk granules of the silkworm,Bombyx mori L.: The morphology of diapause and non-diapause eggs during early developmental stages

Summary The morphological features during development of diapause and non-diapause eggs of the silkworm,Bombyx mori, were investigated by means of light and electron microscopy, with special reference to eggs up to 24 h after oviposition.The blastoderm and yolk cells began to be formed about 6 and 24 h after oviposition, respectively, in both the diapause and non-diapause eggs, indicating that the diapause and non-diapause eggs develop at similar rates at least until 24 h after oviposition.Specific changes in the distribution of yolk granules were observed during early development of the diapause egg. Its yolk granules gradually aggregated into clusters from the periphery toward the inside of the egg during the period of blastoderm formation. Aggregation of yolk granules was most noticeable about 12 h after oviposition and then they dispersed again before yolk cell formation. On the other hand, yolk granules of the non-diapause eggs remained dispersed during development.     

Regional Morphological and Cytochemical Differentiation in the Fertilized Egg of Discoglossus pictus (Anura)

A vertical column of cytoplasm poor in yolk (CPY) is located in the centre of the animal region of the unfertilised and fertilised egg of Discoglossus pictus. At the base of this column is found a central region of CPY designated as "clear cytoplasm". Cytochemical methods show that the CPY in this whole region is rich in glycogen and RNA.
By 60 min post opposition (p.o.) the pigmented cortical layer starts moving towards the future ventral side. It attains its definitive position by 90 min p.o. when the grey crescent, visible from 75 min p.o. onwards, achieves its maximal extension on the future dorsal side. The cytoplasmic column is now tilted towards the future ventral side. It progressively loses its direct contact with the cell membrane and disappears.
From 90 min p.o. onwards, the "clear cytoplasm" is found progressively closer to the dorsal grey crescent cortex. When the first cleavage furrow appears at 135 min p.o., the "clear cytoplasm" is situated very near the dorsal cortex and even extends somewhat below the equator. In places a relatively thin layer of cytoplasm containing medium-sized and a few large yolk granules intervenes between the grey crescent cortex and the "clear cytoplasm".
These displacements suggest that sperm entry evokes a dorsally directed cytoplasmic movement in the animal half of the egg which, among other things, may facilitate an interaction between the vegetative yolk and the grey crescent cortex, or may directly influence the dorso-ventral polarisation of the vegetative yolk.     

Pattern formation fails after blastoderm formation by rapid cell cycles in an artificially activated insect egg

Oocytes explanted from adult ovaries of the arrhenotokous Hymenopteron Pimpla turionellae remain in an inactive state, because development has not been initiated by mechanical deformation during natural oviposition. However, they could be induced to enter development by injecting cleavage energids into the posterior pole. After lag phases of up to 32 h, the implanted nuclei initiated a normal cleavage process, except that the polarity of its progress was reversed. In other oocytes, the injected energids congregated in a ring-shaped region at the egg surface to form a superficial nuclear front, which slowly advanced towards the anterior egg pole, thereby successively stimulating portions of the quiescent ooplasm to take part in development. Up to 41 rapid cell cycles started from that front, each of them with an anaphase wave running backwards into the region already peripherally occupied by nuclei. Thus, the blastoderm was formed extremely metachronously and by rapid obviously biphasic cell cycles, which never occur at the egg surface during normal cleavage. A germ band, however, was only formed under the following conditions: (1) that cleavage did not follow the nuclear front mode, and (2) that ooplasm from the donor's posterior pole was co-injected with the graft nuclei. We conclude that embryonic differentiation requires some of the events which had been omitted in eggs where development failed, especially the exponential increase of the cell cycle length, and the activity of some posterior factor(s) during egg activation.     

Asymmetrically distributed ecdysteroid-related antigens in follicles and young embryos of Drosophila melanogaster

Summary We have produced monoclonal and polyclonal antibodies against an antigen that is asymmetrically distributed in mature oocytes of Drosophila melanogaster. During late oogenesis and early embryogenesis the antigen undergoes dramatic changes in its cellular localization: until about 2.5 h before completion of oogenesis it is homogeneously distributed in the cytoplasm, then it becomes localized in granules that are more numerous in posterior than in anterior peripheral positions of the ooplasm. The germ plasm is void of the antigen. Shortly after egg deposition the antigen is released from the granules and forms a shallow temporary gradient in the egg. Later during embryogenesis the antigen is associated with the yolk-containing cytoplasm. At the syncytial blastoderm stage it is also detected in the peripheral nuclei. Preliminary evidence suggests that the antigen is an ecdysteroid-related molecule. Five different anti-ecdysone antisera were found to bind to the same antigen or to an antigen with the same localization as our monoclonal antibody. In pattern mutants affecting anteroposterior polarity, the described asymmetrical distribution of the antigen is abnormal. In the mutant BicD, for example, which leads to the formation of two abdomina of opposite polarity, the antigen-containing granules are distributed homogeneously in mature oocytes.     

The cytoskeletal involvement in cellularization of theDrosophila melanogaster embryo

Summary The distribution and arrangement of cytoskeletal components in the early embryo ofDrosophila melanogaster were examined by thin-section electron microscopy to elucidate their involvement in the formation of the cellular blastoderm, a process called cellularization. During the final nuclear division in the cortex of the syncytial blastoderm bundles of astral microtubules were closely associated with the surface plasma membrane along the midline where a new gutter was initiated. Thus the new gutter together with the pre-formed ones compartmentalized the embryo surface to reflect underlying individual daughter nuclei. Subsequently such gutters became deeper by further invagination of the plasma membrane between adjacent nuclei to form so-called cleavage furrows. Nuclei simultaneously elongated in the direction perpendicular to the embryo surface and numerous microtubules from the centrosomes ran longitudinally between the nucleus and the cleavage furrow. Microtubules often appeared to be in close association with the nuclear envelope and the cleavage furrow membrane. The plasma membrane at the advancing tip of the furrow was always undercoated with an electron-dense layer, which could be shown to be mainly composed of 5–6 nm microfilaments. These microfilaments were decorated with H-meromyosin to be identified as actin filaments. As cleavage proceeded, each nucleus with its perikaryon became demarcated by the furrow membrane, which then extended laterally to constrict the cytoplasmic connection between each newly forming cell and the central yolk region. The cytoplasmic strand thus formed possessed a prominent circular bundle of microfilaments which were also decorated with H-meromyosin and bidirectionally arranged, similar in structure to the contractile ring in cytokinesis. These observations strongly suggest that both microtubules and actin filaments play a crucial role in cellularization ofDrosophila embryos.     

All meiotic chromosomes and both centrosomes at spindle pole in the zygotes discarded as two polar bodies in clam Corbicula leana: unusual polar body formation observed by antitubulin immunofluorescence

To understand the unusual polar body formation in the androgenetic clam, Corbicula leana, whole-mount eggs stained with monoclonal antibodies against α-tubulin, γ-tubulin, and 4’-6’-diamidino-2-phenylindole were examined. The meiotic spindle was located at the peripheral region of the egg at metaphase I, and its axis was parallel to the egg surface. After segregation of chromosomes at anaphase I, cytoplasmic bulges formed at both meiotic spindle pole sites. Centrosomes were located at the apical portion of the each bulge. From the apical portion of the bulge a bundle of astral microtubules radiated toward the bulge base in late anaphase resembling a half spindle. Maternal chromosomes and both centrosomes were all distributed in two ”first polar bodies” and were eventually discarded. After the polar body formation only one male pronucleus existed in the egg cytoplasm. The present study showed that the anaphase microtubules originating from a single aster can induce the polar body formation without overlapping of microtubules from the opposing aster. Received: 29 September 1999 / Accepted: 24 November 1999