Differential Expression and Functions of Cortical Myosin IIA and IIB Isotypes during Meiotic Maturation, Fertilization, and Mitosis in Mouse Oocytes and Embryos

To explore the role of nonmuscle myosin II isoforms during mouse gametogenesis, fertilization, and early development, localization and microinjection studies were performed using monospecific antibodies to myosin IIA and IIB isotypes. Each myosin II antibody recognizes a 205-kDa protein in oocytes, but not mature sperm. Myosin IIA and IIB demonstrate differential expression during meiotic maturation and following fertilization: only the IIA isoform detects metaphase spindles or accumulates in the mitotic cleavage furrow. In the unfertilized oocyte, both myosin isoforms are polarized in the cortex directly overlying the metaphase-arrested second meiotic spindle. Cortical polarization is altered after spindle disassembly with Colcemid: the scattered meiotic chromosomes initiate myosin IIA and microfilament assemble in the vicinity of each chromosome mass. During sperm incorporation, both myosin II isotypes concentrate in the second polar body cleavage furrow and the sperm incorporation cone. In functional experiments, the microinjection of myosin IIA antibody disrupts meiotic maturation to metaphase II arrest, probably through depletion of spindle-associated myosin IIA protein and antibody binding to chromosome surfaces. Conversely, the microinjection of myosin IIB antibody blocks microfilament-directed chromosome scattering in Colcemid-treated mature oocytes, suggesting a role in mediating chromosome–cortical actomyosin interactions. Neither myosin II antibody, alone or coinjected, blocks second polar body formation, in vitro fertilization, or cytokinesis. Finally, microinjection of a nonphosphorylatable 20-kDa regulatory myosin light chain specifically blocks sperm incorporation cone disassembly and impedes cell cycle progression, suggesting that interference with myosin II phosphorylation influences fertilization. Thus, conventional myosins break cortical symmetry in oocytes by participating in eccentric meiotic spindle positioning, sperm incorporation cone dynamics, and cytokinesis. Although murine sperm do not express myosin II, different myosin II isotypes may have distinct roles during early embryonic development.     

Cortical granule exocytosis in hamster eggs requires microfilaments

Earlier work has demonstrated that hamster eggs that do not release a second polar body after fertilization in vitro lack a block to polyspermy (Stewart-Savage and Bavister, 1987: Gamete Res 18:333–338). Since polar body release requires microfilaments, the involvement of microfilaments in cortical granule exocytosis was examined. When hamster eggs were treated with cytochalsin B (CB) for 1 hr and then coincubated with sperm for 90 min, there was a dose-dependent increase in both the percentage of eggs with more than one sperm penetrating the zona pellucida and the mean number of sperm that penetrated the zona, with a maximum effect at 20 μg CB/ml (100% polypenetration, 3.0 ± 0.3 sperm/egg). Cytochalasin-treated eggs retained 85% of their cortical granules 55 min after insemination, as compared to unfertilized eggs. Longer time periods did not result in any further reduction. As seen with the scanning confocal microscope, an extensive microfilament network was present in the cortex of untreated eggs, with the cortical granules located within this cortical network. The cortical microfilament network was highly reduced in CB-treated eggs. When viewed with the electron microscope, the same number of cortical granules were located next to the plasma membrane in both cytochalasin-treated and untreated, unfertilized eggs. These data indicate that intact microfilaments are required for normal cortical granule exocytosis in the hamster egg, but the role of the microfilaments in exocytosis is unresolved. Mol. Reprod. Dev. 47:334–340, 1997. © 1997 Wiley-Liss, Inc.     

The role of oocyte maturation in the ontogeny of the fertilization site in the hydrozoan Hydractinia echinata

Summary In hydrozoans the sperm will fuse with the egg only at the site of polar body formation. The primary oocyte and maturing oocytes which have produced the first polar body cannot be fertilized even though maturing oocytes which have produced the first polar body attract sperm. These eggs do not acquire the ability to be fertilized until after second polar body formation. If either first or second polar body formation is inhibited or if first and second polar body formation do not take place in close proximity to each other, the fertilization site is not set up. Under normal circumstances the site of polar body formation takes place at the region on the maturing oocyte surface nearest the site where the germinal vesicle resided in the primary oocyte. When maturing oocytes are centrifuged prior to polar body formation, the site of polar body formation is frequently shifted so that it does not correspond to the site where it would be given off under normal circumstances. Under these conditions the shifted site of polar body formation is the only site where the egg can be fertilized, indicating that the fertilization site is selected during oocyte maturation.Oocyte maturation in these hydrozoans is mediated by a hormone released by the somatic cells of gonophores as a consequence of bringing dark adapted gonophores into the light. The hormone acts directly on the oocyte to induce maturation. The oocyte only has to be exposed to the hormone for the first few minutes of the maturation process in order to complete the process of maturation.Dedicated to Professor N.H. Verdonk of the Rijksuniversiteit Utrecht on his 65th birthday     

Motility and centrosomal organization during sea urchin and mouse fertilization

Motility and the behavior and inheritance of centrosomes are investigated during mouse and sea urchin fertilization. Sperm incorporation in sea urchins requires microfilament activity in both sperm and eggs as tested with Latrunculin A, a novel inhibitor of microfilament assembly. In contrast the mouse spermhead is incorporated in the presence of microfilament inhibitors indicating an absence of microfilament activity at this stage. Pronuclear apposition is arrested by microfilament inhibitors in fertilized mouse oocytes. The migrations of the sperm and egg nuclei during sea urchin fertilization are dependent on microtubules organized into a radial monastral array, the sperm aster. Microtubule activity is also required during pronuclear apposition in the mouse egg, but they are organized by numerous egg cytoplasmic sites. By the use of an autoimmune antibody to centrosomal material, centrosomes are detected in sea urchin sperm but not in unfertilized eggs. The sea urchin centrosome expands and duplicates during first interphase and condenses to form the mitotic poles during division. Remarkably mouse sperm do not appear to have the centrosomal antigen and instead centrosomes are found in the unfertilized oocyte. These results indicate that both microfilaments and microtubules are required for the successful completion of fertilization in both sea urchins and mice, but at different stages. Furthermore they demonstrate that centrosomes are contributed by the sperm during sea urchin fertilization, but they might be maternally inherited in mammals.     

Translation of incenp during oocyte maturation is required for embryonic development in Xenopus laevis

The chromosome passenger complex (CPC) consists of Aurora-B kinase and several other subunits. One of these, incenp, binds Aurora-B and regulates its kinase activity. During Xenopus oocyte maturation, incenp accumulates through translation, contributing to aurora-b activation. A previous study has demonstrated that inhibition of incenp translation during oocyte maturation diminishes aurora-b activation but does not interfere with oocyte maturation, characterized by normal maturation-specific cyclin-b phosphorylation, degradation, and resynthesis. Here we have extended these findings, showing that inhibition of incenp translation during oocyte maturation did not interfere with meiosis I or II, as indicated by the normal emission of the first polar body and metaphase II arrest, followed by the successful emission of the second polar body upon parthenogenetic egg activation. Most importantly, however, when transferred to host frogs and subsequently ovulated, the incenp-deficient eggs were fertilized but failed to undergo mitotic cleavage. Thus, translation of incenp during oocyte maturation appears to be part of oocyte cytoplasmic maturation, preparing the egg for the rapid mitosis following fertilization.     

Latrunculin inhibits the microfilament-mediated processes during fertilization, cleavage and early development in sea urchins and mice

Latrunculin A, a marine toxin from a Red Sea sponge, is a potent inhibitor of the microfilament-mediated processes of fertilization and early development in sea urchins and in mice. Sperm from sea urchins, but not those from Limulus or mice, were affected by latrunculin, and fertilization in both sea urchins and in mice was arrested but at different stages. Sea urchin sperm treated with 2.6 microM latrunculin are unable to assemble acrosomal processes and their ability to fertilize eggs is impaired. The unwinding of the Limulus sperm acrosomal process occurs in the presence of latrunculin. Treated mouse sperm are able to fertilize mouse oocytes in vitro, suggesting that microfilaments may not be required in this mammalian sperm. In sea urchin eggs, sperm incorporation, microvillar elongation and cytokinesis are inhibited. Microtubule-mediated motility occurs normally. 20 nM latrunculin prevents the morphogenetic movements during gastrulation. It reduces the viscosity of actin gels from sea urchin egg homogenates. In unfertilized mouse oocytes, it prevents the colcemid-induced dispersion of the meiotic chromosomes; accumulations of cortical actin are noted adjacent to the scattered chromosomes. Sperm incorporation during mouse fertilization in vitro is unaffected suggesting that sperm entry may occur independent of microfilament activity in mammals. However, the apposition of the pronuclei at the center of the egg cytoplasm does not occur, providing evidence that cytoplasmic microfilaments may be required for the motions leading to pronuclear union during mouse fertilization. It inhibits the second polar body formation and cytokinesis. These results indicate that latrunculin is a potent inhibitor of microfilament-mediated processes in sperm, eggs and embryos, and that it may prove to be a powerful new drug for exploring the cellular behavior of microfilaments in the maintenance of cell shape and during motility.     

Fertilization and the cytoskeleton in the mouse

The behaviour and roles of the microtubule network and the microfilaments following fertilization in the mouse oocyte are described. The microtubule network is organized by multiple microtubule organizing centres (MTOCs) and these play a major role in establishing spindle structure and pronuclear movement following fertilization; in contrast to sea urchin and frog eggs, the sperm centriole plays little part in organization of the post-fertilization spindle. The microfilaments are required for spindle rotation, polar body formation, certain changes in the egg cortex, and also for pronuclear movement. Influences of the chromosomes on microtubule and microfilament organisation are also discussed.     

Surface ultrastructure of paddlefish eggs before and after fertilization

The surface ultrastructure of eggs of the paddlefish Polyodon spathula was investigated by scanning electron microscopy. Mature eggs of paddlefish possess four to 12 micropyles in the animal polar region. There are sperm entry sites in the egg surface under the micropyles which consist of tufts of microvilli. Five to nine sperm entry sites were observed on mature eggs. Probably, the number of sperm entry sites corresponds to the number of micropyles. In a few eggs, 1 min after fertilization the ball-like enlarged top of a cytoplasmic process (probably a full-grown fertilization cone) had reached the external aperture or the canal of several micropyles. In other micropyles of the same egg, a few smaller cytoplasmic processes or flocculent material were found in the micropylar canal. With one exception, no sperm tails were found there. The formation of the full-grown cytoplasmic process is possibly initiated before the cortical reaction has started in an area of the animal hemisphere. Three, 10 and 20 min after fertilization, the uneven surface of the cortical cytoplasm in the animal polar region rose gently where microvilli were much less than the in other area and together with a secondary polar body at the latter stage. Taken together, paddlefish eggs may have sperm entry sites corresponding to the number of micropyles and respond to the stimulus of fertilization by forming a few cytoplasmic processes–fertilization cones (larger and smaller). Sperm penetration into the egg may be achieved at an earlier stage of fertilization (sperm-egg contact), as inferred from the fact that a secondary polar body was formed at the 20-min stage irrespective of the exceptional finding of the sperm tail.     

Effects of motility inhibitors during sea urchin fertilization : Microfilament inhibitors prevent sperm incorporation and restructuring of fertilized egg cortex, whereas microtubule inhibitors prevent pronuclear migrations

The sensitivity of specific stages of fertilization to microfilament inhibitors (cytochalasins B (CB), D (CD), and E (CE) and phalloidin) and to inhibitors of microtubule assembly (colcemid (CMD), colchicine (CLC), griseofulvin (GSF), maytansine (MAY), nocodazole (NCD), podophyllotoxin (PDP), and vinblastine (VB)) was investigated using differential interference contrast, time-lapse video microscopy of the sea urchin Lytechinus variegatus. Cytochalasins (CDCE>CB) will prevent sperm incorporation if added prior to or simultaneous with insemination. Sperm-egg fusion and the cortical reaction appear normal, but then the subsequent elevation of the fertilization coat lifts and eventually detaches the ‘fertilizing’ sperm from the egg plasma membrane. When the cytochalasins are added after fusion, the forming fertilization cone is rapidly resorbed, and the lateral displacement of the sperm along the egg cortex is terminated; the pronuclear migrations and mitoses occur normally though cytokinesis is never observed. Cytochalasin treatment before or within 2 min of insemination results in the development of aberrant egg cortices, whereas cytochalasin treatments after 2 min post-fusion have little effect. Phalloidin results in large and long-lasting fertilization cones and a retardation of the rate of sperm incorporation. Eggs exposed to any of the microtubule inhibitors 15 min prior to insemination will incorporate the spermatozoon, though the formation of the sperm aster and the accompanying pronuclear migrations are prevented. Interestingly, the final stage of sperm incorporation involving a lateral displacement of the sperm along the egg cortex is greater (27.1 vs 12.4 μm in controls) and faster (5.4 vs 3.5 μm/min in controls) in microtubule-inhibited eggs. GSF and VB, which readily permeate fertilized eggs, will prevent the formation of the sperm aster if added 3 min after sperm-egg fusion, they will prevent the migration of the female pronucleus if added 5 or 7 min after sperm-egg fusion, pronuclear centration if added 10 min post-fusion, and syngamy if added 12 min post-fusion. CLC- or CMD- treated eggs will develop normally if these drugs are photochemically inactivated with 366 nm light within 4 min post-fusion, arguing that sperm incorporation is completely independent of assembling microtubules. These results indicate that microfilament inhibitors will prevent sperm incorporation and the restructuring of the fertilized egg cortex, and that microtubule inhibitors will prevent the formation and functioning of the sperm aster during the pronuclear migrations; an interplay between cortical microfilaments and cytoplasmic microtubules appears required for the successful completion of fertilization.     

Sperm Chromatin-Induced Ectopic Polar Body Extrusion in Mouse Eggs after ICSI and Delayed Egg Activation

Meiotic chromosomes in an oocyte are not only a maternal genome carrier but also provide a positional signal to induce cortical polarization and define asymmetric meiotic division of the oocyte, resulting in polar body extrusion and haploidization of the maternal genome. The meiotic chromosomes play dual function in determination of meiosis: 1) organizing a bipolar spindle formation and 2) inducing cortical polarization and assembly of a distinct cortical cytoskeleton structure in the overlying cortex for polar body extrusion. At fertilization, a sperm brings exogenous paternal chromatin into the egg, which induces ectopic cortical polarization at the sperm entry site and leads to a cone formation, known as fertilization cone. Here we show that the sperm chromatin-induced fertilization cone formation is an abortive polar body extrusion due to lack of spindle induction by the sperm chromatin during fertilization. If experimentally manipulating the fertilization process to allow sperm chromatin to induce both cortical polarization and spindle formation, the fertilization cone can be converted into polar body extrusion. This suggests that sperm chromatin is also able to induce polar body extrusion, like its maternal counterpart. The usually observed cone formation instead of ectopic polar body extrusion induced by sperm chromatin during fertilization is due to special sperm chromatin compaction which restrains it from rapid spindle induction and therefore provides a protective mechanism to prevent a possible paternal genome loss during ectopic polar body extrusion.     

Morphological changes in the oocyte and its surrounding vestments during in vivo fertilization in the dasyurid marsupial Sminthopsis crassicaudata

This light and transmission electron microscopical study shows that the first polar body is given off before ovulation and that part of its cell membrane and that of the surrounding oocyte have long microvilli at the time of its ejection. Several layers of cumulus cells initially surround the secondary oocyte and first polar body, but the ovulated oocytes in the oviducts in the process of being fertilized do not have cumulus cells around them. Partly expelled second polar bodies occur in the oviduct; they are elongated structures that lack organelles and have electron-dense nuclei. A small fertilization cone appears to form around the sperm tail at the time of sperm entry into the egg and an incorporation cone develops around the sperm head in the egg cytoplasm. In three fertilized eggs a small hole was seen in the zona, which was presumably formed by the spermatozoon during penetration. Cortical granules, present in ovarian oocytes, are not seen in fertilized tubal or uterine eggs; release of their contents probably reduces the chances of polyspermy, although at least one polyspermic fertilized egg was seen and several other fertilized eggs had spermatozoa within the zona pellucida. In the zygote the pronuclei come to lie close together, but there was no evidence of fusion. A "yolk mass," which becomes eccentric before ovulation, is extruded by the time the two-cell embryos are formed, but many vacuoles remain in the non-yolky pole of the egg. A shell membrane of variable thickness is present around all uterine eggs but its origin remains undetermined.     

Surface activity at the egg plasma membrane during sperm incorporation and its cytochalasin B sensitivity: Scanning electron microscopy and time-lapse video microscopy during fertilization of the sea urchin Lytechinus variegatus

Sperm incorporation and the formation of the fertilization cone with its associated microvilli were investigated by scanning electron microscopy of eggs denuded of their vitelline layers with dithiothreitol or stripped of their elevating fertilization coats by physical methods. The activity of the elongating microvilli which appear to engulf the entering spermatozoon was recorded in living untreated eggs with time-lapse video microscopy. Following the acrosome reaction, the elongated acrosomal process connects the sperm head to the egg surface. About 15 microvilli adjacent to the attached sperm elongate at a rate of 2.6 μm/min and appear to engulf the sperm head, midpiece, and sperm tail. These elongate microvilli swell to form the fertilization cone (average height, 6.7 ± 2.0 μm) and are resorbed as the sperm tail enters the egg cytoplasm 10 min after insemination. Cytochalasin B, an inhibitor of microfilament motility, completely inhibits the observed egg plasma membrane surface activity in both control and denuded eggs. These results argue for a role of the microfilaments found in the egg cortex and microvilli as necessary for the engulfment of the sperm during incorporation and indicate that cytochalasin interferes with the fertilization process at this site.     

Role of MAP kinase and myosin light chain kinase in chromosome-induced development of mouse egg polarity

During maturation, the mouse oocyte is transformed into a highly polarized egg, characterized by an actin cap and cortical granule-free domain (CGFD) overlying the meiotic spindle that is in close proximity to the cortex. The presence of spindle/chromosomes or microinjected sperm chromatin in the cortical region initiates this cortical reorganization, but the pathway is unknown. We report that cortical reorganization induced by microinjected sperm chromatin is blocked by inhibitors of microfilament assembly or disassembly. Active mitogen-activated protein kinase (MAPK), which becomes enriched in the region of sperm chromatin, is required for cortical reorganization, because microinjected sperm chromatin fails to induce cortical reorganization in Mos-/- eggs, which lack MAPK activity. Last, myosin light chain kinase (MLCK), which can be directly phosphorylated and activated by MAPK, appears involved, because the MLCK inhibitors ML-7 and Peptide 18 prevent sperm chromatin-induced cortical reorganization. These results provide new insights into how cortical reorganization occurs independently of extracellular signals to generate egg polarity.     

Small GTPase RhoA is required for ooplasmic segregation and spindle rotation, but not for spindle organization and chromosome separation during mouse oocyte maturation, fertilization, and early cleavage

RhoA, a small GTPase, plays versatile roles in many aspects of cell function such as stress fiber formation, cytokinesis, and cell polarization. In this study, we investigated the subcellular localization of RhoA and its possible roles during oocyte maturation and fertilization. RhoA was localized in the cytoplasm of eggs from the germinal vesicle (GV) stage to 2-cell stage, especially concentrating in the midbody of telophase spindle when oocyte extruded PB1 and PB2. The RhoA kinases (ROCKs) specific inhibitor Y-27632 blocked GV breakdown (GVBD) and first polar body extrusion, but did not affect apparatus formation and anaphase/telophase I entry. Anti-RhoA antibody microinjection into the oocytes showed similar results. RhoA inhibitor caused abnormal organization of microfilaments, failure of spindle rotation, PB2 extrusion as well as cleavage furrow formation, while sister chromatid separation was not affected. Microinjection of RhoA antibody also blocked PB2 emission. Our findings indicate that RhoA, by regulating microfilament organization, regulates several important events including GVBD, polar body emission, spindle rotation, and cleavage.     

Distribution and role of microfilaments during early events of sheep fertilization

The distribution of actin was studied during early events of sheep fertilization by fluorescence microscopy after staining with 7-nitrobenz-2-oxal-1.3 diazole (NBD)-phallacidin and anti-actin antibody and by electron microscopy after heavy meromyosin labelling. Unfertilized and fertilized eggs exhibited a continuous band of fluorescence with both NBD-phallacidin and anti-actin antibody. Unlike in mice, no high concentration of actin overlying the spindle was detected in ovulated sheep oocytes. At the site of sperm head incorporation, the fertilization cone developed above the decondensing male chromatin and was underlined by a submembranous area rich in microfilaments. A similar actin network was observed in the cortex of the second polar body. Cytochalasin D was used to investigate the role of actin during the fertilization process. This drug did not prevent sperm fusion and incorporation but inhibited polar body abstriction and fertilization cone development and retarded sperm tail incorporation. Moreover, in the presence of the drug, the anchorage of the metaphase II spindle at the surface of the egg was destroyed. The role of microfilaments in these early events is discussed.     

Studies on fertilization in the teleost. I. Dynamic responses of fertilized medaka eggs

In order to understand the mechanisms of fertilization in the teleost, the movements of the egg cortex, cytoplasmic inclusions and pronuclei were observed in detail in fertilized medaka Oryzias latipes eggs. The first cortical contraction occurred toward the animal pole region following the onset of exocytosis of cortical alveoli. The cortical contraction caused movement of oil droplets toward the animal pole where the germinal vesicle had broken down during oocyte maturation. The movement of oil droplets toward the animal pole region was frequently twisted in the right or left direction. The direction of the twisting movement has been correlated with the unilateral bending of non-attaching filaments on the chorion. The female pronucleus, which approached the male pronucleus from the vicinity of the second polar body, took a course to the right, left or straight along the s-p axis connecting the male pronucleus and the second polar body. The course of approach by the female pronucleus correlated with the bending direction of the non-attaching filaments that had been determined by rotation of the oocyte around the animal–vegetal axis during oogenesis. The first cleavage furrow also very frequently coincided with the axis. These observations suggest that dynamic responses of medaka eggs from fertilization to the first cleavage reflect the architecture dynamically constructed during oogenesis.     

Automictic parthenogenesis of a geographically parthenogenetic mayfly,Ephoron shigae (Insecta: Ephemeroptera,Polymitarcyidae)

In the geographically parthenogenetic mayfly, Ephoron shigae, egg maturation and counts of chromosome number of unfertilized, parthenogenetic eggs were studied, in comparison with fertilized eggs from a bisexual population. The primary oocyte becomes mature through two successive maturation divisions. The first maturation division (meiotic division) takes place in the primary oocyte to produce a secondary oocyte and a first polar body. The second maturation division soon occurs in the secondary oocyte, in which the nucleus is divided into a mature egg nucleus (female pronucleus) and second polar body nuclei. The first polar body, in some cases, was successively divided into two polar bodies; in other instances, it was not divided. After the successive maturation division, the egg nucleus and the sister second polar body nucleus drew near to fuse into the zygote nucleus. The chromosome number was doubled in the zygote, and this conjugation initiates subsequent embryonic development. This suggests that, in E. shigae, the process of parthenogenetic recovery of diploidy is the automictic type categorized as the ‘terminal fusion’ pattern. © 2009 The Linnean Society of London, Biological Journal of the Linnean Society, 2010, 99 , 335–343.     

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.     

Sperm Incorporation Independent of Fertilization Cone Formation in the Danio Egg

The responses of the egg to insemination in a modified Fish Ringer's solution (FRS) were examined in eggs of the zebrafish ( Brachydanio rerio ) primarily by scanning electron microscopy. FRS is a physiological saline which temporarily inhibits parthenogenetic activation of the egg for 5–8 min. Spermatozoa were collected in a small volume of water and pipetted over eggs in FRS. Eggs inseminated in FRS typically incorporated the fertilizing sperm within 3–4 min. Inseminated cells showed an absence of a fertilization cone and no cortical granule exocytosis. The deep conical depression in the egg surface beneath the micropyle remained unaltered. Control eggs inseminated in tank water developed a large fertilization cone during sperm incorporation. Occasionally, eggs inseminated in water were observed to incorporate the entire sperm head prior to egg activation. Our results corroborate earlier findings showing that in the zebrafish, cortical granule exocytosis, fertilization cone formation and elevation of the sperm entry site are not triggered by the fertilizing sperm in experimental conditions (18, 19). Furthermore, sperm incorporation requires neither egg activation nor formation of a fertilization cone in this fish.     

Oocyte Maturation and Furrow Formation in an Unfertilized Egg by Fusion with a Fertilized Egg or Blastomeres in the Ascidian, Ascidia sydneiensis divisa

A technique for fusing an ascidian egg with blastomeres using a chemical fusiogen was established and then used to identify cytoplasmic factors that regulate the process of oocyte maturation in ascidian eggs. Unfertilized eggs fused with fertilized eggs or blastomeres in hypotonic artificial sea water containing 20% polyvinyl alcohol within 10 min. After fusion polar bodies were extruded from the unfertilized portion of the fused eggs. Furrows were formed not only in the fertilized portion but also in the unfertilized portion in the fused eggs. No polar body extrusion and furrow formation occur in either portion of fused unfertilized eggs. These results suggest that fertilized eggs and blastomeres contain a factor that induces oocyte maturation. Polar body extrusion and furrow formation were not suppressed in the fertilized portion of fused eggs, suggesting that unfertilized eggs do not contain a factor that inhibits oocyte maturation.