Formation of the amphibian grey crescent: Effects of colchicine and cytochalasin B

Summary The effects of colchicine and cytochalasin B on grey crescent formation in frog (Rana pipiens) and toad (Bufo arenarum) eggs were determined. Colchicine prevented the appearance of the grey crescent, but this inhibition was not due to the absence of an aster. Cytochalasin B did not inhibit grey crescent formation, nor did it inhibit certain activation events such as cortical granule breakdown or cortical contraction. Cytochalasin B caused a detachment of the cortex from the cytoplasm and induced the formation of a morphological grey crescent in non-activated eggs. The results suggest that microtubules may play several roles in grey crescent formation and that a change in the attachment of the cortex to the cytoplasm may also be involved.     

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.     

Mitochondrial inhibitor sodium azide inhibits the reorganization of mitochondria‐rich cytoplasm and the establishment of the anteroposterior axis in ascidian embryo

In ascidian eggs, cytoplasmic and cortical reorganization, previously called ooplasmic segregation, occurs in two phases during the first cell cycle. In the second phase of reorganization, the mitochondria‐rich cytoplasm (myoplasm) moves to the future posterior side, concurrent with sperm aster migration along the egg cortex. Although this reorganization is the critical step for establishing the anteroposterior axis, its molecular mechanism is not fully understood. In this study, we showed that low concentrations of the mitochondrial inhibitor sodium azide (NaN₃), which showed the low toxicity in sperm, inhibited the second phase of reorganization without the microtubule depolymerization. In the NaN₃‐treated embryo, the sperm aster was not attracted to the cortex and altered its migration pathway; therefore, the myoplasm remained at the vegetal pole. Consequently, the anteroposterior axis was not established. Another mitochondrial inhibitor, oligomycin, did not affect these processes. These results suggest that NaN₃ inhibits unknown molecules that are important for the second phase of reorganization. Identifying the target molecule of NaN₃ will lead to a molecular understanding of cytoplasmic and cortical reorganization.     

Role of the cytoskeleton in sperm entry during fertilization in the freshwater bivalve Dreissena polymorpha

The present study examined the role of the cytoskeleton in sperm entry and migration through the egg cytoplasm during fertilization in the zebra mussel, Dreissena polymorpha (Bivalvia: Veneroida: Dreissenidae). Fertilization in this freshwater bivalve occurs outside the mantle cavity, permitting detailed observations of fertilization. After its initial binding to the egg surface, the sperm is incorporated in two stages: (1) a gradual incorporation of the sperm nucleus into the egg cortex, followed by (2) a more rapid incorporation of the sperm axoneme, and translocation of the sperm head through the egg cytoplasm. Initial incorporation into the egg cortex was shown to be microfilament dependent. Microfilaments were found in the sperm's preformed acrosomal filament, the microvilli on the egg surface, and in an actin-filled insemination cone surrounding the incorporating sperm. Treatment of eggs with cytochalasin B inhibited sperm entry in a dose- and time-dependent manner. Microtubule polymerization was not necessary for initial sperm entry. Following incorporation of the sperm head, the flagellar axoneme entered the egg cytoplasm and remained active for several minutes. Associated with the incorporated axoneme was a flow of cytoplasmic particles originating near the proximal end of the flagella. Inhibition of microtubule polymerization prevented entry of the sperm axoneme, and the subsequent cytoplasmic current was not observed. After sperm incorporation into the egg cortex, no appreciable microfilaments were associated with the sperm nucleus. A diminutive sperm aster was associated with the sperm nucleus during its decondensation, but no obvious extension toward the female pronucleus was observed. The sperm aster was significantly smaller than the spindle associated with the female pronucleus, suggesting a reduced role for the sperm aster in amphimixis.     

Polarity and reorganization of the endoplasmic reticulum during fertilization and ooplasmic segregation in the ascidian egg

During the first cell cycle of the ascidian egg, two phases of ooplasmic segregation create distinct cytoplasmic domains that are crucial for later development. We recently defined a domain enriched in ER in the vegetal region of Phallusia mammillata eggs. To explore the possible physiological and developmental function of this ER domain, we here investigate its organization and fate by labeling the ER network in vivo with DiIC16(3), and observing its distribution before and after fertilization in the living egg. In unfertilized eggs, the ER-rich vegetal cortex is overlaid by the ER-poor but mitochondria-rich subcortical myoplasm. Fertilization results in striking rearrangements of the ER network. First, ER accumulates at the vegetal-contraction pole as a thick layer between the plasma membrane and the myoplasm. This accompanies the relocation of the myoplasm toward that region during the first phase of ooplasmic segregation. In other parts of the cytoplasm, ER becomes progressively redistributed into ER-rich and ER- poor microdomains. As the sperm aster grows, ER accumulates in its centrosomal area and along its astral rays. During the second phase of ooplasmic segregation, which takes place once meiosis is completed, the concentrated ER domain at the vegetal-contraction pole moves with the sperm aster and the bulk of the myoplasm toward the future posterior side of the embryo. These results show that after fertilization, ER first accumulates in the vegetal area from which repetitive calcium waves are known to originate (Speksnijder, J. E. 1992. Dev. Biol. 153:259-271). This ER domain subsequently colocalizes with the myoplasm to the presumptive primary muscle cell region.     

Effects of cytoskeletal inhibitors on ooplasmic segregation and microtubule organization during fertilization and early development in the ascidian Molgula occidentalis

The effects of microtubule and microfilament inhibitors on ooplasmic segregation and microtubule organization were examined during fertilization, parthenogenetic activation, and early development in the ascidian Molgula occidentalis. At fertilization the egg cortex contracts as the first phase movement and shortly after mitochondria migrate as the myoplasmic crescent develops in the second phase. The microtubule inhibitors colcemid and nocodazole inhibit the second phase, but not the first phase, of ooplasmic segregation. The microfilament inhibitor cytochalasin E has the reciprocal effect of inhibiting the first, but not the second, phase. It appears that sperm may initially bind at any site on the egg surface and that the contractile activities at the first phase and during polar body formation occur independent of the microtubule system. Since the second phase migration occurs as the sperm astral microtubules assemble and since microtubule, but not microfilament, inhibitors arrest this aspect of ooplasmic segregation, microtubules appear necessary for mitochondrial migration. These results demonstrate that the two phases of ascidian ooplasmic segregation are mediated by different systems, the first by microfilaments and the second by microtubules. The microtubule and microfilament systems appear to operate independent of one another and their combined actions result in the completion of ooplasmic segregation. A model is proposed in which the cortical contraction following fertilization is important not only as the motive force for the first phase movement but also as a method to unite the myoplasm with the entering sperm which can initially bind anywhere on the egg surface. The association between myoplasmic components and the growing sperm aster would ensure that the migration and the spatial distribution of myoplasm in the second phase results in the formation of the myoplasmic crescent.     

Changes in the Distribution of Calcium-Sequestering Membranes during the First Cell Cycle of the Sea Urchin, Lytechinus variegatus

Chlortetracycline (CTC) has been used to study sequential changes in the distribution of calcium-sequestering membranes during the first cell cycle of fertilized sea urchin eggs CTC staining patterns first appear as a diffuse ring around the centered zygote nucleus at the time of syngamy. As development proceeds, the ring becomes brighter and then elongates concurrently with the formation of the streak apparatus. Fluorescence subsequently accumulates in the centrospheres of the developing mitotic apparatus and is present in mitotic asters throughout mitosis. When the mitotic apparatus disappears, the fluorescence associated with each aster condenses into a bright ring surrounding each daughter nucleus. Ultrastructural studies show that CTC-fluorescent areas are rich in membranes while experiments with rhodamine 123, a mitochondrion-specific laser dye, indicate that mitochondria are excluded from areas in which membranes accumulate. Microtubule inhibitors prevent the initial accumulation of fluorescence around the zygote nucleus and arrest the development of existing fluorescence patterns when applied at later stages. In contrast, changes in fluorescence patterns are unaffected by the microfilament inhibitor cytochalasin D. These observations show that calcium-sequestering membranes are associated consecutively with the sperm aster, streak, and mitotic apparatus and that the continual reorganization of these membranes during the first cell cycle depends on the assembly and disassembly of microtubules.     

Chromatin and microtubule morphology during the first cell cycle in bovine zygotes

Chromatin and microtubule configurations during the first cell cycle of bovine zygotes were analyzed by DNA staining and microtubule immunolocalization using an IVM/IVF system and oocytes matured and fertilized in vivo, in order to investigate the origin of the active centrosome and to characterize the nuclear and the cytoplasmic changes following bovine fertilization. Our results suggest that the paternal centrosome is active during early zygotic development, forming a conspicuous sperm aster soon after fertilization. We also report that polyspermy in bovine eggs, leads to the formation of numerous sperm asters with different degrees of association with the chromatin. The maternal structures in both monospermic and polyspermic zygotes can be lost or degenerate. Consequently, these cells may resume the first cell cycle as androgenotes, very often with several types of mitotic activity taking place in different regions of the cell cytoplasm at the same time. As indicated by a comparison of monospermic and polyspermic fertilization rates to rates of development, it is possible that some androgenetic embryos cleave and develop to the blastocyst stage. © 1993 Wiley-Liss, Inc.     

Microtubules in ascidian eggs during meiosis, fertilization, and mitosis

The sequential changes in the distribution of microtubules during germinal vesicle breakdown (GVBD), fertilization, and mitosis were investigated with antitubulin indirect immunofluorescence microscopy in several species of ascidian eggs (Molgula occidentalis, Ciona savignyi, and Halocynthia roretzi). These alterations in microtubule patterns were also correlated with observed cytoplasmic movements. A cytoplasmic latticework of microtubules was observed throughout meiosis. The unfertilized egg of M. occidentalis had a small meiotic spindle with wide poles; the poles became focused after egg activation. The other two species had more typical meiotic spindles before fertilization. At fertilization, a sperm aster first appeared near the cortex close to the vegetal pole. It enlarged into an unusual asymmetric aster associated with the egg cortex. The sperm aster rapidly grew after the formation of the second polar body, and it was displaced as far as the equatorial region, corresponding to the site of the myoplasmic crescent, the posterior half of the egg. The female pronucleus migrated to the male pronucleus at the center of the sperm aster. The microtubule latticework and the sperm aster disappeared towards the end of first interphase with only a small bipolar structure remaining until first mitosis. At mitosis the asters enlarged tremendously, while the mitotic spindle remained remarkably small. The two daughter nuclei remained near the site of cleavage even after division was complete. These results document the changes in microtubule patterns during maturation in Ascidian oocytes, demonstrate that the sperm contributes the active centrosome at fertilization, and reveal the presence of a mitotic apparatus at first division which has an unusually small spindle and huge asters.     

Patterns of microtubule polymerization relating to cortical rotation in Xenopus laevis eggs.

Following fertilization, the Xenopus egg cortex rotates relative to the cytoplasm by 30 degrees about a horizontal axis. The direction of rotation, and as a result the orientation of the embryonic body axes, is normally specified by the position of sperm entry. The mechanism of rotation appears to involve an array of aligned microtubules in the vegetal cortex (Elinson and Rowning, 1988, Devl Biol. 128, 185-197). We performed anti-tubulin immunofluorescence on sections to follow the formation of this array. Microtubules disappear rapidly from the egg following fertilization, and reappear first in the sperm aster. Surprisingly, astral microtubules then extend radially through both the animal and vegetal cytoplasm. The cortical array arises as they reach the vegetal cell surface. The eccentric position of the sperm aster gives asymmetry to the formation of the array and may explain its alignment since microtubules reaching the cortex tend to bend away from the sperm entry side. The radial polymerization of cytoplasmic microtubules is not dependent on the sperm aster or on the female pronucleus: similar but more symmetric patterns arise in artificially activated and enucleate eggs, slightly later than in fertilized eggs. These observations suggest that the cortical microtubule array forms as a result of asymmetric microtubule growth outward from cytoplasm to cortex and, since cortical and cytoplasmic microtubules remain connected throughout the period of the rotation, that the microtubules of the array rotate with the cytoplasm.     

Axis establishment and microtubule-mediated waves prior to first cleavage in Beroe ovata

The single axis (oral-aboral) and two planes of symmetry of the ctenophore Beroe ovata become established with respect to the position of zygote nucleus formation and the orientation of first cleavage. Bisection of Beroe eggs at different times revealed that differences in egg organisation are established in relation to the presumptive oral-aboral axis before first cleavage. Lateral fragments produced after but not before the time of first mitosis developed into larvae lacking comb-plates on one side. Time-lapse video demonstrated that waves of cytoplasmic reorganisation spread through the layer of peripheral cytoplasm (ectoplasm) of the egg during the 80 minute period between pronuclear fusion and first cleavage, along the future oral-aboral axis. These waves are manifest as the progressive displacement and dispersal of plaques of accumulated organelles around supernumerary sperm nuclei, and a series of surface movements. Their timing and direction of propagation suggest they may be involved in establishing cytoplasmic differences with respect to the embryonic axis.Inhibitor experiments suggested that the observed cytoplasmic reorganisation involves microtubules. Nocodazole and taxol, which prevent microtubule turnover,blocked plaque dispersal and reduced surface movements.The microfilament-disrupting drug cytochalasin B did not prevent plaque dispersal but induced abnormal surface contractions. We examined changes in microtubule organisation using immunofluorescence on eggs fixed at different times and in live eggs following injection of rhodamine-tubulin. Giant microtubule asters become associated with each male pronucleus after the end of meiosis. Following pronuclear fusion they disappear successively, those nearest the zygote nucleus shrinking first, to establish gradients of aster size within single eggs. Regional differences in microtubule behaviour around the time of mitosis were revealed by brief taxol treatment, which induced the formation of small microtubule asters in the region of the nucleus or spindle during both first and second cell cycles. The observed wave of change may thus reflect the local appearance and spreading of mitotic activity as the zygote nucleus approaches mitosis.     

Centrosomal function assessment in human sperm using heterologous ICSI with rabbit eggs: a new male factor infertility assay

Sperm centrosomal function was assessed by immunocytochemical analysis after the injection of human sperm into mature rabbit eggs. Three hours after intracytoplasmic sperm injection (ICSI), an astral microtubule array from the base of the human sperm was observed in the rabbit eggs. This sperm aster expanded in the egg cytoplasm, concomitant with pronuclear formation, and a dense microtubule array was organized at the time of pronuclear centration. Using fertile donor sperm, the sperm aster formation rate at 3 hr after ICSI was 35.0 +/- 1.5%. Using sperm from infertile patients, the average aster formation rate was lower (25.4 +/- 14.8%, P<0.05). Among infertile cases, there was no correlation between sperm aster formation rates and conventional parameters of semen analysis. However, the sperm aster formation rate correlated with the embryonic cleavage rate following human in vitro fertilization (IVF). These data suggest that this assay reflects sperm function during embryonic development after sperm entry and that reproductive success during the first cell cycle requires a functional sperm centrosome. Furthermore, sperm centrosomal function cannot be predicted from conventional parameters of semen analysis. We propose that insufficient centrosomal function could be the cause of certain cases of idiopathic infertility. These assays may lead to the discovery of new types of infertility, which have previously been treated as "unexplained infertility," and may also lead to the treatment of infertility incurable even by ICSI. Consequently, an accurate and relevant assay to help assure couples of the success of fertilization is warranted, perhaps prior to ICSI therapy.     

Microtubule assembly is required for the formation of the pronuclei,nuclear lamin acquisition,and DNA synthesis during mouse,but not sea urchin,fertillization

Microtubule assembly is required for the formation of the male and female pronuclei during mouse, but not sea urchin, fertilization. In mouse oocytes, 50 μM colcemid prevents the decondensation of the maternal meiotic chromosomes and of the incorporated sperm nucleus during in vitro fertilization. Nuclear lamins do not associate with either of the parental chromatin sets although peripherin, the PI nuclear peripheral antigen, appears on both. DN A synthesis docs not occur in these fertilized, colcemid-arrested oocytes. This effect is limited to the first hours after ovulation, since colcemid added 4–6 hours later no longer prevents pronuclear development, lamin acquisition, or DNA synthesis. Neither microtubule stabilization with 10 μM taxol nor microfilament inhibition with 10 μM cytochalasin D or 2.2 μg/ml lalrunculin A prevent these pronuclear events; these drugs will inhibit the apposition of the pronuclei at the egg center. In sea urchin eggs, colcemid or griseofulvin treatment doe? not result in the same effect and the male pronucleus forms with the attendant accumulation of the nuclear lamins. The differences in the requirement for microtubule assembly during pronucleus formation may be related to the cell cycle: In mice the sperm enters a meiotic cytoplasm, whereas in sea urchin eggs it enters an interphase cytoplasm. Refertilization of mitotic sea urchin eggs was performed to test the possibility that this phenomenon is related to whether the sperm enters a meiotic/mitotic cytoplasm or one at interphase; during refertilization at first mitosis, the incorporated sperm nucleus is unable to decondense and acquire lamins. These results indicate a requirement for microtubule assembly for the progression from meiosis to first interphase during mouse fertilization and suggest that the cytoskeleton is required for changes in nuclear architecture necessary during fertilization and the cell cycle.     

Anti-tubulin immunofluorescence microscopy of microtubules present during the pronuclear movements of sea urchin fertilization

Anti-tubulin immunofluorescence microscopy is used here to demonstrate the configurations of the microtubule-containing structures which participate in the pronuclear movements of sea urchin fertilization. This technique shows that the egg is devoid of microtubules until after the fertilizing sperm is fully incorporated. All the microtubules which appear during the course of fertilization are organized around the base of the sperm head and the sperm aster thus formed behaves in a way that could account for the characteristic motions of the male and female pronuclei as documented by time-lapse video microscopy. Extension of astral microtubules appears to be responsible for the slow (ca. 2.5 μm min^?1) movement of the sperm aster into the cytoplasm of the egg; the rapid (ca. 15 μm min^?1) migration of the female pronucleus to the sperm aster seems to depend on connection of the female pronucleus to microtubules of the sperm aster. Continued extension of astral microtubules after the pronuclei are brought into conjunction can account for the centripetal motion of the paired (or fused) pronuclei and for the positioning of the zygote nucleus in the center of the egg. The behavior of astral microtubules during these motions suggests that they are capable of transmitting both pushing and pulling forces. All the pronuclear movements, and the assembly of detectable microtubules, are sensitive to the microtubule inhibitors griseofulvin and colchicine. Because of this sensitivity, and since all the observable microtubules within the egg during fertilization arise at the sperm aster, it is concluded that the pronuclear movements of fertilization result from the actions of the sperm aster. The pronuclear movements of sea urchin fertilization represent a simple but striking example of microtubule-mediated motility.     

Organization and regulation of cortical microtubules during the first cell cycle of Xenopus eggs.

Anti-tubulin antibodies and confocal immunofluorescence microscopy were used to examine the organization and regulation of cytoplasmic and cortical microtubules during the first cell cycle of fertilized Xenopus eggs. Appearance of microtubules in the egg cortex temporally coincided with the outgrowth of the sperm aster. Microtubules of the sperm aster first reached the animal cortex at 0.25, (times normalized to first cleavage), forming a radially organized array of cortical microtubules. A disordered network of microtubules was apparent in the vegetal cortex as early as 0.35. Cortical microtubule networks of both animal and vegetal hemispheres were reorganized at times corresponding to the cortical rotation responsible for specification of the dorsal-ventral (D-V) axis. Optical sections suggest that the cortical microtubules are continuous with the microtubules of the sperm aster in fertilized eggs, or an extensive activation aster in activated eggs. Neither assembly and organization, nor disassembly of the cortical microtubules coincided with MPF activation during mitosis. However, cycloheximide or 6-dimethylaminopurine, which arrest fertilized eggs at interphase, blocked cortical microtubule disassembly. Injection of p13, a protein that specifically inhibits MPF activation, delayed or inhibited cortical microtubule breakdown. In contrast, eggs injected with cyc delta 90, a truncated cyclin that arrest eggs in M-phase, showed normal microtubule disassembly. Finally, injection of partially purified MPF into cycloheximide-arrested eggs induced cortical microtubule breakdown. These results suggest that, despite a lack of temporal coincidence, breakdown of the cortical microtubules is dependent on the activation of MPF.     

Cytoskeletal organization in the oocyte,zygote, and early cleaving embryo of the stripe-faced dunnart (Sminthopsis macroura)

Ovulation occurs in Sminthopsis macroura approximately 160 hr after administration of 1.3 IU PMSG, and yields significantly more oocytes than does spontaneous ovulation (P = 0.001). Germinal vesicle (GV)-stage oocytes have a thin cortical rim of microfilaments, which is disrupted by exposure to cytochalasin D. After GV breakdown, the first meiotic spindle forms subcortically and parallel to the oolemma. It rotates during anaphase and telophase to extrude the first polar body. This rotation is associated with a local cortical concentration of microfilaments, which is extruded in the first polar body. The second meiotic spindle is orthogonal to the surface, and extrusion of the second polar body is not associated with obvious local changes in cortical actin, resulting in a polar body containing little polymerized actin. The sites of second polar body emission and sperm entry are always in the half of the oocyte opposite the concentrating yolk mass, and are within 60° of each other in most oocytes. During the concentration and eccentric movement of the yolk, microfilaments condense around it. During yolk expulsion, these microfilaments become continuous with those located subcortically. During early cleavage, the cytocortex of the zygote, but not of the extruded yolk mass, stains heavily for polymerised actin. Multiple sites of pericentriolar material are detectable in the cytoplasm of some secondary unfertilized oocytes which, in the presence of taxol, generate large cytasters and pseudospindle structures. After fertilization, a large aster is formed in association with the sperm entry point and serves as the center of an extensive cytoplasmic network of microtubules which surrounds but does not enter the yolk mass. Taxol treatment generates small cytasters within this meshwork and promotes selective stabilization of some periyolk microtubules opposite to the sperm aster. © 1995 Wiley-Liss, Inc.     

Fertilization of porcine oocytes following intracytoplasmic spermatozoon or isolated sperm head injection

We demonstrated normal fertilization processes (as determined by pronuclear formation, pronuclear apposition and syngamy) in porcine oocytes either following intracytoplasmic spermatozoon (ICSI) or isolated sperm head injection. Microtubule organization and chromatin configuration were investigated in these oocytes during the first cell cycle. Following ICSI, the microtubular aster was organized from the neck of the spermatozoon and filled the whole cytoplasm. These male-derived microtubules appear to move both pronuclei to the center of oocytes. These cytoskeletal changes are analogous to those seen following conventional fertilization. In contrast, following isolated sperm head injection, the sperm aster was not seen. Instead, the microtubule matrix was organized from the cortex and then filled the whole cytoplasm in all cases in normally fertilized oocytes following injection (n = 35). This organization is similar to what has been shown in the parthenogenetically activated oocytes. Chromosome analysis revealed that the oocytes injected with isolated sperm heads were fertilized normally. At 7 days following injection, the incidence of blastocoele formation following ICSI (38%) and isolated sperm head injection (22%) was higher than that following sham injection (2%). These results suggested that successful fertilization and preimplantation development occurred in porcine oocytes following either ICSI or isolated sperm head injection. Our results also indicated that fertilization processes can occur by self-assembled microtubules within cytoplasm in the absence of a sperm centrosome. Mol. Reprod. Dev. 51:436–444, 1998. © 1998 Wiley-Liss, Inc.     

Ooplasmic segregation and morphological axis formation in the polychaete Nereis virens embryo

Ooplasmic segregation is of great importance in the development of Annelida. The mechanisms of this process are very diverse in different groups of polychaetes, oligochaetes, and leeches (Fernandez et al., 1998). Ooplasmic segregation in Nereis virens is connected with the first meiotic spindle formation and animal-vegetative axis appearance. Spherical polyaxial symmetry of the oocyte transforms into radial stratified symmetry in the course of ooplasmic segregation. There are two main steps of ooplasmic segregation in Nereis virens. The first step begins after the cortical reaction when the central clear cytoplasm reaches the surface of the oocyte. The movement of the cytoplasm is sensitive to nocodazole, colchicine, and cytochalasin B and appears to be mediated by microtubules and, partly, by microfilaments. The second step is not sensitive to the microtubule inhibitors and is mediated mainly by actin filaments. Ooplasmic segregation in Nereis virens may be considered as a primitive form of ooplasmic segregation in Annelida.     

Phases of cytoplasmic and cortical reorganizations of the ascidian zygote between fertilization and first division.

Many eggs undergo reorganizations that localize determinants specifying the developmental axes and the differentiation of various cell types. In ascidians, fertilization triggers spectacular reorganizations that result in the formation and localization of distinct cytoplasmic domains that are inherited by early blastomeres that develop autonomously. By applying various imaging techniques to the transparent eggs of Phallusia mammillata, we now define 9 events and phases in the reorganization of the surface, cortex and the cytoplasm between fertilization and first cleavage. We show that two of the domains that preexist in the egg (the ER-rich cortical domain and the mitochondria-rich subcortical myoplasm) are localized successively by a microfilament-driven cortical contraction, a microtubule-driven migration and rotation of the sperm aster with respect to the cortex, and finally, a novel microfilament-dependant relaxation of the vegetal cortex. The phases of reorganization we have observed can best be explained in terms of cell cycle-regulated phases of coupling, uncoupling and recoupling of the motions of cortical and subcortical layers (ER-rich cortical domain and mitochondria-rich domain) with respect to the surface of the zygote. At the end of the meiotic cell cycle we can distinguish up to 5 cortical and cytoplasmic domains (including two novel ones; the vegetal body and a yolk-rich domain) layered against the vegetal cortex. We have also analyzed how the myoplasm is partitioned into distinct blastomeres at the 32-cell stage and the effects on development of the ablation of precisely located small fragments. On the basis of our observations and of the ablation/ transplantation experiments done in the zygotes of Phallusia and several other ascidians, we suggest that the determinants for unequal cleavage, gastrulation and for the differentiation of muscle and endoderm cells may reside in 4 distinct cortical and cytoplasmic domains localized in the egg between fertilization and cleavage.     

Ooplasmic segregation and axis formation in the polychaeteNereis virens embryo

Ooplasmic segregation is of great importance in the development of Annelida. The mechanisms of this process are very diverse in different groups of polychaetes, oligochaetes, and leeches (Fernandezet al., 1998). Ooplasmic segregation inNereis virens is connected with the first meiotic spindle formation and animal-vegetative axis appearance. Spherical polyaxial symmetry of the oocyte transforms into radial stratified symmetry in the course of ooplasmic segregation. There are two main steps of ooplasmic segregation inNereis virens. The first step begins after the cortical reaction when the central clear cytoplasm reaches the surface of the oocyte. The movement of the cytoplasm is sensitive to nocodazole, colchicine, and cytochalasin B and appears to be mediated by microtubules and, partly, by microfilaments. The second step is not sensitive to the microtubule inhibitors and is mediated mainly by actin filaments. Ooplasmic segregation inNereis virens may be considered as a primitive form of ooplasmic segregation in Annelida.