Studies on fertilization in the teleost. III. The relationship between nuclear behavior and the histone H1 kinase activity in anesthetized medaka eggs

To investigate the mechanisms of fertilization in the teleostean egg, the relationship between the nuclear behavior and the activity of histone H1 kinase was examined in medaka, Oryzias latipes, eggs that were anesthetized at sperm penetration. Inseminated in the anesthetized state, most eggs failed to undergo the propagative waves of increase in cytoplasmic Ca²⁺ and exocytosis of cortical alveoli (CABD). The sperm‐penetrated eggs that exhibited no or partial CABD only around the animal pole underwent a transient contraction of the cortical cytoplasm toward the animal pole region and were designated nonactivated eggs. Temporary compaction of the second meiotic metaphase (MII) chromosomes was accompanied by contractile movement of the cortical cytoplasm, but not by completion of the second meiotic division. The activity of histone H1 kinase in nonactivated eggs remained high, although it decreased slightly concurrent with sperm penetration. Cyclin B and cdc2 levels remained unchanged as well. The nonactivated eggs began to transform the penetrated sperm nucleus into metaphase chromosomes in the cortical cytoplasm facing the inner end of micropylar canal within 20 min postinsemination (PI). Two figures of typical metaphase chromosomes were found in the animal pole area at ≤40 min PI. Chromosome condensation in nonactivated eggs was not inhibited by actinomycin D, nor was the high activity of histone H1 kinase reduced. In the presence of cycloheximide or 6‐dimethylaminopurine (6‐DMAP), however, the compact sperm nucleus and the MII chromosomes transformed to interphase nuclei without CABD or extrusion of the polar body, although the activity of histone H1 kinase remained high. These results suggest that in the fish egg, transformation of MII chromosomes to an interphase nucleus may not be caused by loss of MPF activity, but rather than by the loss of activity of a short‐lived protein kinase(s), sensitive to 6‐DMAP that is independent of CABD in the cascade reactions triggered by increased cytoplasmic calcium. Dev. Genet. 25:137–145, 1999. © 1999 Wiley‐Liss, Inc.     

Medaka Oocytes Rotate Within the Ovarian Follicles During Oogenesis

The purpose of the current investigation was to ascertain whether medaka oocytes rotate within the follicle. Isolated medaka follicles were incubated in modified L15 Medium for 3 hr at 26°C. During incubation, movement of oocytes within follicles held on slides under a microscope was recorded by a video cassette recorder. Within the follicle, the surface of which was marked with carbon particles, the movement of the intrafollicular oocyte was traced by dislocation of its attaching and non-attaching filaments on the chorion. Pre-vitellogenic oocytes exhibited rotation around the predetermined animal-vegetal axis, accompanied by rotation at a slightly oblique angle to the axis. The velocity of oocyte rotation was about 40–48 μm hr⁻¹ and was similar among oocytes of different stages between the pre-vitellogenic and early vitellogenic phases of oogenesis. Rotation was inhibited by cytochalasin B treatment. Also, it was not observed in oocytes surrounded only by the granulosa cell layer when the thecal cell layer and the basement membrane were removed from the follicle. In oocytes with a thick chorion, rotation was also inhibited by impaling the oocytes with a glass needle at a right angle to the animal-vegetal axis of the oocyte. These results provide evidence that growing medaka oocytes rotate primarily around their animal-vegetal axis and at a slightly oblique angle to the axis. That the rotation of medaka oocytes may depend upon the movement of the granulosa and the thecal cells within the follicles was discussed.     

Determination of first cleavage plane: the relationships between the orientation of the mitotic apparatus for first cleavage and the position of meiotic division-related structures in starfish eggs

In order to understand when the orientation of the first cleavage plane is fixed along the animal-vegetal axis in starfish eggs, the behavior of the sperm aster was examined by indirect immunofluorescence staining. After duplication, the sperm aster organizes the mitotic apparatus for first cleavage perpendicular to the cleavage plane. The sperm aster located in the egg periphery just after fertilization and moved to the site close to the animal pole rather than the egg center by meiosis II. At early metaphase II, duplication of the sperm aster was detected but the axis of the resultant sperm diaster randomly pointed. Subsequently, its axis had already turned perpendicular to the animal-vegetal axis before pronucleus fusion. These results indicate that the orientation processes of the sperm diaster consist of positioning before its duplication and successive determining its azimuth. Furthermore, the azimuth and position of the mitotic apparatus for first cleavage did not change by shifting or eliminating the meiotic division-related structures such as the germinal vesicle, meiotic spindle, and female pronucleus by micromanipulation. These results show that none of them determines the first cleavage plane. Therefore, we discuss the pointing mechanism of the first cleavage plane without the influence of these meiotic division-related structures.     

Fertilization Reaction without Changes in Intracellular Ca2+ in Medaka Eggs—An Experiment with Acetone-Treated Eggs

To investigate whether or not causal relationship exists between the increase in intracellular Ca²⁺ and other cortical reactions at fertilization in the medaka, Oryzias latipes , intracellular Ca²⁺ was determined from luminescence of aequorin previously microinjected into cortical cytoplasm in acetone-treated eggs, when they were inseminated or activated by microinjection of Ca²⁺. Neither an increase in cytoplasmic calcium nor exocytosis of cortical alveoli occurred in eggs treated with acetone, though other events of fertilization i.e. completion of meiosis, fusion of pronuclei, and accumulation of cortical cytoplasm with intact cortical alveoli in the animal pole region were observed in normal time sequence in these eggs. When denuded eggs were treated with acetone, contraction of the egg and slow resumption of meiosis (extrusion of polar body) were observed without insemination. When denuded eggs were inseminated immediately after acetone-treatment, the number of spermatozoa that penetrated into the egg was greater in the animal hemisphere than in the vegetal hemisphere. These results may indicate that acetone inactivates the egg plasma membrane or its adjacent cortical cytoplasm so that it cannot participate in a propagative increase in intracellular Ca²⁺ and exocytosis, while it also induces cytoplasmic activation leading to egg contraction, resumption of meiosis and formation of pronuclei. The present results suggest that sperm penetration, resumption of meiosis and ooplasmic segregation are regulated separately from the release of intracellular Ca²⁺ and exocytosis.     

Analysis of cortical flow models in vivo

Cortical flow, the directed movement of cortical F-actin and cortical organelles, is a basic cellular motility process. Microtubules are thought to somehow direct cortical flow, but whether they do so by stimulating or inhibiting contraction of the cortical actin cytoskeleton is the subject of debate. Treatment of Xenopus oocytes with phorbol 12-myristate 13-acetate (PMA) triggers cortical flow toward the animal pole of the oocyte; this flow is suppressed by microtubules. To determine how this suppression occurs and whether it can control the direction of cortical flow, oocytes were subjected to localized manipulation of either the contractile stimulus (PMA) or microtubules. Localized PMA application resulted in redirection of cortical flow toward the site of application, as judged by movement of cortical pigment granules, cortical F-actin, and cortical myosin-2A. Such redirected flow was accelerated by microtubule depolymerization, showing that the suppression of cortical flow by microtubules is independent of the direction of flow. Direct observation of cortical F-actin by time-lapse confocal analysis in combination with photobleaching showed that cortical flow is driven by contraction of the cortical F-actin network and that microtubules suppress this contraction. The oocyte germinal vesicle serves as a microtubule organizing center in Xenopus oocytes; experimental displacement of the germinal vesicle toward the animal pole resulted in localized flow away from the animal pole. The results show that 1) cortical flow is directed toward areas of localized contraction of the cortical F-actin cytoskeleton; 2) microtubules suppress cortical flow by inhibiting contraction of the cortical F-actin cytoskeleton; and 3) localized, microtubule-dependent suppression of actomyosin-based contraction can control the direction of cortical flow. We discuss these findings in light of current models of cortical flow.     

Oogenesis: From Oogonia to Ovulation in the Flagfish,Jordanella floridae Goode and Bean, 1879 (Teleostei: Cyprinodontidae)

We provide histological details of the development of oocytes in the cyprinodontid flagfish, Jordanella floridae. There are six stages of oogenesis: Oogonial proliferation, chromatin nucleolus, primary growth (previtellogenesis [PG]), secondary growth (vitellogenesis), oocyte maturation and ovulation. The ovarian lamellae are lined by a germinal epithelium composed of epithelial cells and scattered oogonia. During primary growth, the development of cortical alveoli and oil droplets, are initiated simultaneously. During secondary growth, yolk globules coalesce into a fluid mass. The full‐grown oocyte contains a large globule of fluid yolk. The germinal vesicle is at the animal pole, and the cortical alveoli and oil droplets are located at the periphery. The disposition of oil droplets at the vegetal pole of the germinal vesicle during late secondary growth stage is a unique characteristic. The follicular cell layer is composed initially of a single layer of squamous cells during early PG which become columnar during early vitellogenesis. During primary and secondary growth stages, filaments develop among the follicular cells and also around the micropyle. The filaments are seen extending from the zona pellucida after ovulation. During ovulation, a space is evident between the oocyte and the zona pellucida. Asynchronous spawning activity is confirmed by the observation that, after ovulation, the ovarian lamellae contain follicles in both primary and secondary growth stages; in contrast, when the seasonal activity of oogenesis and spawning ends, after ovulation, the ovarian lamellae contain only follicles in the primary growth stage. J. Morphol. 277:1339–1354, 2016. © 2016 Wiley Periodicals, Inc.     

mRNA localization patterns in zebrafish oocytes

In both invertebrate and vertebrate systems, the localization of maternal mRNAs is a common mechanism used to influence developmental processes, including the establishment of the dorsal/ventral axis, anterior/posterior axis, and the germ line (for review, see Bashirullah et al., 1998. Annu. Rev. Biochem. 67, 335-394). While the existence of localized maternal mRNAs has been reported in the zebrafish, Danio rerio, the precise localization patterns of these molecules during oogenesis has not been determined. In this study, in situ hybridization experiments were performed on zebrafish ovaries and activated eggs to examine different mRNA localization patterns. The results establish that while some maternal mRNAs remain ubiquitously distributed throughout the oocyte, other mRNAs follow specific localization patterns, including localization to the animal pole, localization to the vegetal pole, and cortical localization. The animal/vegetal axis is first apparent in stage II oocytes when the earliest mRNA localization is seen. Unique patterns of localization are seen in mature eggs as well. Some mRNAs maintain their oocyte localization patterns, while others localize upon egg activation (fertilization).     

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.     

Cortical differentiation of the animal pole during maturation division in fertilized eggs of Tubifex (Annelida,Oligochaeta): II. Polar body formation

Changes in the cortical organization at the animal pole are examined by scanning and transmission electron microscopy in the Tubifex egg undergoing second polar body formation. At very early anaphase of the second meiosis, the egg surface overlying the meiotic apparatus is undulated, but its neighboring surface appears to be smooth. Although a microfilamentous cortical layer is found in the smooth area, the cortical layer of the undulating area is thin and devoid of filamentous structures except for its central part where some filaments are observed. This local differentiation takes place normally in colchicine-treated eggs where the meiotic apparatus is destroyed. Along with the progression of the anaphase movement, the egg surface of the undulating area is, first, uplifted into a cone-shaped cytoplasmic bulge (presumptive polar body); then the height and surface area of the bulge gradually increase. The distal surface of the growing bulge appears to be undulated whereas the sides of the bulge are relatively smooth. Transmission electron microscopy reveals that a thick microfilamentous cortical layer is always localized at the proximal region of this bulge; other regions of the bulge are characterized by a thin cortical layer which is devoid of filamentous structure except for the apical portion of the bulge. Microfilaments at the base of the bulge are perpendicular or oblique to the egg surface. The cortical layer of the egg which is continuous to that of the proximal region of the bulge comprises microfilaments running parallel to the surface. The attainment of the bulge to its full size is followed by the development of the cleavage furrow along its base. The cleavage furrow appears to bisect the spindle midway between its poles. In cytochalasin B-treated eggs, where some cortical microfilaments are detected at the animal pole, a cytoplasmic bulge lower in height and wider in the diameter of its base than the normal one forms at the animal pole; however, it is subsequently resorbed into the egg. The formation of a cleavage furrow is not observed in these eggs. The mechanism of the polar body formation is discussed in the light of the present observations.     

The cortical contraction related to the ooplasmic segregation inCiona intestinalis eggs

Summary The egg cytoplasm of ascidian,Ciona intestinalis, segregates towards both the animal and vegetal poles within a few minutes of fertilization or parthenogetic activation with ionophore A23187. A constriction appears first on the egg surface near the animal pole and then moves to the vegetal pole. Carmine granules and spermatozoa attached to the egg surface move towards the vegetal pole with the movement of the constriction. Microvilli, which are distributed uniformly in unfertilized egg, disappear on the animal side of the constriction and became more dense on the vegetal side of the constriction. Transmission electron microscopy revealed that sub-cortical cytoplasm, containing numerous mitochondria and sub-cortical granules, moves towards the vegetal pole with the movement of the constriction and then concentrates into a cytoplasmic cap at the vegetal pole. An electron-dense layer appears in the cortex of the cap. The ooplasmic segregation and the cortical contraction were inhibited by cytochalasin B and induced by ionophore A23187. These observations suggest that ooplasmic segregation is caused by the cortical contraction which is characterised by a surface constriction and by the formation of an electron-dense layer.     

Dynamic organization of cortical actin filaments during the ooplasmic segregation of ascidian Ciona eggs

Spatial reorganization of cytoplasm in zygotic cells is critically important for establishing the body plans of many animal species. In ascidian zygotes, maternal determinants (mRNAs) are first transported to the vegetal pole a few minutes after fertilization and then to the future posterior side of the zygotes in a later phase of cytoplasmic reorganization, before the first cell division. Here, by using a novel fluorescence polarization microscope that reports the position and the orientation of fluorescently labeled proteins in living cells, we mapped the local alignments and the time-dependent changes of cortical actin networks in Ciona eggs. The initial cytoplasmic reorganization started with the contraction of vegetal hemisphere approximately 20 s after the fertilization-induced [Ca²⁺] increase. Timing of the vegetal contraction was consistent with the emergence of highly aligned actin filaments at the cell cortex of the vegetal hemisphere, which ran perpendicular to the animal–vegetal axis. We propose that the cytoplasmic reorganization is initiated by the local contraction of laterally aligned cortical actomyosin in the vegetal hemisphere, which in turn generates the directional movement of cytoplasm within the whole egg.     

Site of sperm entry and a cortical contraction associated with egg activation in the frog Rana pipens

The region of the frog egg that is receptive to fertilization was determined. As an approximation to the site of sperm entry, the start of the male pronuclear penetration path within the egg was made visible externally by bleaching fixed eggs. A bleached egg had a pigment accumulation on its surface corresponding to the start of the penetration path. The accumulation characteristically changed shape with cortical movements prior to first cleavage, and most accumulations (path starts) were within 60° of the animal pole.Localized inseminations and an analysis of the distribution of failures of fertilization at the egg plasma membrane demonstrated that few if any sperm entered the vegetal region of the egg. Localized inseminations, however, demonstrated that sperm entered between 60° from the animal pole and the animal-vegetal margin.Although sperm entry occurred throughout the animal region, most penetration paths started within 60° of the animal pole. To account for this, the sperm nucleus must move towards the animal pole prior to starting the penetration path. This movement appeared to be due to a contraction of the cortex towards the animal pole that occurred 3–4 min after activation of the egg.     

Establishment of animal-vegetal polarity during maturation in ascidian oocytes

Mature ascidian oocytes are arrested in metaphase of meiosis I (Met I) and display a pronounced animal-vegetal polarity: a small meiotic spindle lies beneath the animal pole, and two adjacent cortical and subcortical domains respectively rich in cortical endoplasmic reticulum and postplasmic/PEM RNAs (cER/mRNA domain) and mitochondria (myoplasm domain) line the equatorial and vegetal regions. Symmetry-breaking events triggered by the fertilizing sperm remodel this primary animal-vegetal (a-v) axis to establish the embryonic (D-V, A-P) axes. To understand how this radial a-v polarity of eggs is established, we have analyzed the distribution of mitochondria, mRNAs, microtubules and chromosomes in pre-vitellogenic, vitellogenic and post-vitellogenic Germinal Vesicle (GV) stage oocytes and in spontaneously maturing oocytes of the ascidian Ciona intestinalis. We show that myoplasm and postplasmic/PEM RNAs move into the oocyte periphery at the end of oogenesis and that polarization along the a-v axis occurs after maturation in several steps which take 3-4 h to be completed. First, the Germinal Vesicle breaks down, and a meiotic spindle forms in the center of the oocyte. Second, the meiotic spindle moves in an apparently random direction towards the cortex. Third, when the microtubular spindle and chromosomes arrive and rotate in the cortex (defining the animal pole), the subcortical myoplasm domain and cortical postplasmic/PEM RNAs are excluded from the animal pole region, thus concentrating in the vegetal hemisphere. The actin cytoskeleton is required for migration of the spindle and subsequent polarization, whereas these events occur normally in the absence of microtubules. Our observations set the stage for understanding the mechanisms governing primary axis establishment and meiotic maturation in ascidians.     

Signaling pathway from [Ca2+]i transients to ooplasmic segregation involves small GTPase rho in the ascidian egg

Intracellular Ca2+ transients occur at fertilization in the eggs of all animal species and are thought to be critical for the initiation of several events in egg activation. The rho family of small GTPases are known to organize and maintain the actin filament-dependent cytoskeleton, and rho is involved in the control mechanism of cytokinesis. In the ascidian Ciona savignyi, the first step of ooplasmic segregation observed just after fertilization is cortical contraction with egg deformation, mediated by the cortical actin filaments. C3 exoenzyme, a rho-specific inhibitor, did not affect the pattern of [Ca2+]i transients in the ascidian egg, but inhibited ooplasmic segregation and cytokinesis at the first cleavage. Injection of inositol 1,4,5-trisphosphate or treatment of Ca2+ ionophore induced deformation of the egg and extrusion of the first polar body, but these phenomena did not occur in the C3 exoenzyme-injected egg. These results suggest that rho proteins are involved in egg deformation, ooplasmic segregation and cytokinesis downstream of the [Ca2+]i transients.     

Response of the cortex to the mitotic apparatus during polar body formation in the starfish oocyte of Asterina pectinifera

In order to understand the mechanism of unequal division, polar body formation was investigated using the oocytes of the starfish, Asterina pectinifera. Cortical actin filaments were quantitatively measured after staining the maturing oocytes with fluorescently labeled phalloidin using a computer and image-processing software. Before polar body formation, at first the actin filaments at the animal pole decreased and subsequently the animal pole bulged. On the other hand, actin filaments surrounding the animal pole increased gradually and made a cleavage furrow around the animal pole as the bulge grew. Then the furrow ingressed and finally a polar body formed. When the surface force was calculated according to the cell shape, the surface force decreased at the animal pole but the force at the contractile ring increased. When by micromanipulation the mitotic apparatus was detached and translocated to the cortex other than the animal pole, polar body formation occurred all over the cortex of the oocyte, which indicates that the response of the whole cortex to the mitotic apparatus is equal. These results indicate that the decrease in the actin filaments and surface force near the centrosome of the mitotic apparatus as well as the increase in the actin filaments and surface force at some distance of the centrosome is important for cytokinesis.     

Cortical differentiation of the animal pole during maturation division in fertilized eggs of Tubifex (Annelida,Oligochaeta): I. Meiotic apparatus formation

The fine structure of the animal pole cortex is examined in the fertilized Tubifex egg undergoing the formation of the second meiotic apparatus (MA). The fully formed MA which orients its axis at right angles to the surface is found at the animal pole about 40 min after formation of the first polar body. It is composed of a spindle and asters at its poles; a centriole is found in the inner aster, but not in the peripheral aster adjacent to the surface. During the formation of the MA, the animal pole surface is lined with a 0.15-μm-thick, electron-dense cortical layer, which is rich in microfilaments. The arrangement of the filaments in the layer changes from a parallel array to a meshwork with progressive formation of the MA. Microtubules of the peripheral aster terminate in the cortical layer. When a jet stream of glycerol/dimethyl sulfoxide solution is applied to an egg fragment glued on a polylysine-coated coverslip, an egg cortex-MA complex is isolated on the coverslip; the MA appears to be tethered to the egg surface by the structural connection between the filamentous cortical layer and microtubules of the peripheral aster. Cytochalasin B (50 μg/ml), when administrated at early phase of the MA formation, does not show any effect on the structure of the cortical layer and the MA; however, if eggs shortly before the termination of the first polar body formation are immersed in the same test solution, the cortical layer of the animal pole becomes thinner, and the filamentous material is not observed in it. Furthermore, in these eggs, the peripheral aster and the spindle are not structurally discernible because of the suppression of microtubule assembly, whereas microtubules on kinetochores and in the inner aster are normally developed. These results are discussed in relation to the role of the animal pole cortex in fixing of the MA to the egg surface and in forming of the MA.     

Determinants of Early Amphibian Development

The animal-vegetal organization of the amphibian egg may originatefrom the axis of organelles and cytoskeletal elements establishedin the oocyte as it divides from the oogonium. Along this axis,cytoplasmic materials are localized during oogenesis: yolk platelets,for example, are translocated toward the vegetal pole, increasingtheir amount and size in that region. In the first cell cycleafter fertilization, the egg cortex rotates 30° relativeto the cytoplasmic core, modifying animal-vegetal organization.The direction of this rotation, biased by the point of spermentry, defines the site of development of anatomical structuresof the dorsal midline of the embryo. As its immediate effect,rotation activates the cytoplasm of a subregion of the vegetalhemisphere, causing cells cleaved from this subregion to bemore effective than other vegetal parts in inducing marginalzone cells to initiate gastrulation movements. The most stronglyinduced part of the marginal zone begins gastrulation first(the dorsal lip of the blastopore) and proceeds through a seriesof cell interactions leading to its determination as the anteriordorsal mesoderm of the embryo. If these cell movements are inhibitedin the gastrula stage, or if vegetal induction is inhibitedin the blastula stage, or if cortical rotation is inhibitedin the first cell cycle after fertilization, the embryo alwaysfails to develop dorsal structures of the anterior end of itsbody axis; the more inhibition, the more posterior is the levelof truncation, until a radial ventralized embryo develops, derivedfrom the animal-vegetal organization of the oocyte.     

Fertilization and early development in Beroe ovata

Fertilization in the clear egg (1 mm in diameter) of the ctenophore Beroe ovata and, in particular, the positioning and movements of pronuclei, and their relationship to the larval oral-aboral axis have been observed. Fertilization can take place anywhere on the egg surface. The sperm pronucleus remains at its entry site and becomes surrounded by a specialized zone (30–50 μm in diameter) beneath the surface referred to as the sperm pronuclear zone or SPZ and devoid of large cortical granules. Polyspermy has been observed to be frequent; each pronucleus is surrounded by its own SPZ. Only the egg pronucleus migrates with a continuous velocity (averaging 18 μm/min) and moves beneath the surface directly toward the immobile sperm pronucleus. In polyspermic eggs, the egg pronucleus can probe several SPZ, each containing a single sperm nucleus, before it finally enters one SPZ and fuses with the chosen sperm pronucleus. These migrations of the egg pronucleus occur over several millimeters and take hours, but the mechanism underlying the motion or how the egg pronucleus decides which SPZ to enter is not yet known. Under our experimental conditions the mitotic apparatus and the first cleavage plane which defines the oral-aboral axis of the larva (see Reverberi (1971). “Experimental Embryology of Marine and Fresh-Water Invertebrates.” North-Holland, Amsterdam. for review) pass through the point of sperm entry. During fertilization and cleavage, movements of a cortical autofluorescent material are clearly seen. This material is segregated into micromeres as cleavage progresses.     

Sperm incorporation,the pronuclear migrations,and their relation to the establishment of the first embryonic axis: Time-lapse video microscopy of the movements during fertilization of the sea urchin Lytechinus variegatus

The movements during fertilization have been investigated with differential interference optics and recorded by time-lapse video microscopy of the clear egg of the sea urchin Lytechinus variegatus. Sperm-egg binding occurs rapidly, and following a time when the sperm gyrates on the egg surface, gamete fusion occurs. A rapid cortical contraction radiates from the fusion site and is succeeded by the elevation of the fertilization coat. Sperm incorporation occurs in two stages: the fertilization cone enlarges around and above the erect and immotile sperm and then the sperm head, midpiece, and tail are displaced along the subsurface region of the egg at an average rate of 3.5 μm/min. The formation of the sperm aster moves the male pronucleus from the subsurface region of the egg toward the egg center at a rate of 4.9 μm/min. When the rays of the radial sperm aster appear to contact the female pronucleus, the female pronucleus migrates at a rate of 14.6 μm/min to the center of the sperm aster. The now adjacent pronuclei are moved to the egg center by the continuing enlargement of the sperm aster at a rate of 2.6 μm/min. Syngamy is usually preceded by the disassembly of the sperm aster. The centripetal migration of the pronuclei appears involved in the establishment of the first embryonic axis; cleavage occurs within 8° of the direction of this centering motion.