Rat eggs normally exhibit a variety of surface phenomena during fertilization

The surface topography of the rat egg was examined during fertilization in vitro and in vivo. Using phase optics, 348 in vitro fertilized and 50 in vivo fertilized eggs were continuously monitored throughout the 7-hour period of sperm incorporation. A myriad of different surface configurations were seen, with each egg exhibiting one or more of the following changes. A small number of eggs (4–6%) formed surface elevations over the sperm head after its detachment from the flagellum, 15–30 min after sperm-egg fusion; 1 to 1.5 hr after fusion, 40–50% of the eggs produced the so-called incorporation cone, a prominent surface elevation over the decondensing sperm nucleus. The vast majority of eggs (74–82%) formed surface elevations over the proximal tip of the flagellum 2–3 hr after sperm-egg fusion. These had no association with the decondensing sperm nucleus. A few eggs (11–12%) exhibited multiple protrusions that were distributed randomly about the egg surface, whereas 14–20% did not manifest any surface elevations and remained spherical throughout the sperm incorporation period. Regardless of the type of surface change, all of the eggs resumed a spherical shape by the time sperm incorporation was complete. These observations are in contrast to the conclusions by previous authors that formation of the so-called incorporation cone over the decondensing sperm nucleus is a ubiquitous event.     

Fertilization cone formation in starfish oocytes: The role of the egg cortex actin microfilaments in sperm incorporation

The process of sperm incorporation into starfish (Asterias amurensis) oocytes was examined by electron and fluorescence microscopy. The fertilization cone began to form at the place where the acrosomal process fused with the egg surface and developed into an inverted conical mass containing a small amount of electron-dense cytoplasm. Microfilaments, which stained with NBD-phallacidin, were detected in the fertilization cone. Microvillar protrusions from the fully grown fertilization cone engulfed the sperm head outside the fertilization membrane. The sperm organelles were incorporated into the egg cortex with the absorption of the protrusions. Cytochalasin B inhibited sperm incorporation, fertilization cone formation, and actin filament organization. It is suggested that the development and reduction of the fertilization cone, which depend on the functioning of microfilaments, are necessary for sperm incorporation in starfish.     

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.     

Morphology of the site of sperm entry on the frog egg.

We located the site of sperm entry on the frog (Rana pipiens) egg using light and scanning electron microscopy. The site changed from a small, microvilli-free structure at 20 min after insemination to a clump of elongated microvilli at 40 min, to a distinct patch of microvilli by 2 hr. The sperm entry site responded differentially to hypertonicity. At 40 min, the site was found in a circular depression which was due to the sperm aster and which expanded to a rigid area in the animal half. We consider how these observations may be related to gray crescent formation.     

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.     

Effects of cytochalasins B and D on the fertilization of zebrafish (Brachydanio) eggs

The effects of selected concentrations of cytochalasins B (1-10 micrograms/ml; CB) and D (10, 50 micrograms/ml; CD) on the morphology and fertilization of zebra danio (Brachydanio) eggs were studied primarily with light and scanning electron microscopy. Eggs pretreated with either CB (10 micrograms/ml) or CD (10, 50 micrograms/ml) prepared in Fish Ringer's solution-0.5% DMSO showed a flattened shape, alterations in the form of surface microplicae and microvilli, and occasional spontaneous exocytosis of cortical granules. All eggs preincubated in either CB or CD were activated upon transfer to tap water, showing cortical granule exocytosis, elevation of the chorion, and formation of a fertilization cone. When eggs were pretreated for 5 minutes with 1-5 micrograms/ml CB or 10 micrograms/ml CD and inseminated, they incorporated the fertilizing sperm and typically developed to the two-cell stage. A single sperm cell attached to and fused with the sperm entry site microvilli but failed to enter the cytoplasm in eggs preincubated with 10 micrograms/ml CB. Eggs that were immersed continuously in either CB (10 micrograms/ml) or CD (50 micrograms/ml) 15 seconds after insemination also failed to incorporate the fertilizing sperm. Treatment of eggs after insemination with CD (10 micrograms/ml), however, did not prevent sperm cell incorporation or fertilization cone formation. Our drug data suggest the presence of actin-containing filaments in the danio egg before and following fertilization. These filaments appear to play a role in maintaining the shape of the egg cell and its surface specializations and in the incorporation of the fertilizing sperm. The fertilization cone appears to form independently of actin polymerization.     

The sperm entry site during fertilization of the zebrafish egg: localization of actin.

The sperm entry site (SES) of zebrafish (Brachydanio rerio) eggs was studied before and during fertilization by fluorescence, scanning, and transmission electron microscopy. Rhodamine phalloidin (RhPh), used to detect polymerized filamentous actin, was localized to microvilli of the SES and to cytoplasm subjacent to the plasma membrane in the unfertilized egg. The distribution of RhPh staining at the SES correlated with the ultrastructural localization of a submembranous electrondense layer of cortical cytoplasm approximately 500 nm thick and containing 5- to 6-nm filaments. Actin, therefore, was organized at the SES as a tightly knit meshwork of filaments prior to fertilization. Contact between the fertilizing sperm and the filamentous actin network was observed by 15-20 sec postinsemination or just before the onset of fertilization cone formation. Growing fertilization cones of either artificially activated or inseminated eggs exhibited intense RhPh staining and substantial increase in thickness of the actin meshwork. Collectively, TEM and RhPh fluorescence images of inseminated eggs demonstrated that the submembranous actin became rearranged in fertilization cones to form a thickened meshwork around the sperm nucleus during incorporation. The results reported here suggest that activation of the egg triggers a dramatic polymerization of actin beneath the plasma membrane of the fertilization cone. Furthermore, the actin involved in sperm incorporation is sensitive to the action of cytochalasins.     

A Fine Structural Study of the Fertilization Process of the Jellyfish Cladonema uchidai

This study described the fertilization process of the jellyfish Cladonema uchidai by means of transmission electron microscopy. Female pronucleus was situated in close vicinity to the animal pole of the spawned egg, where the surface of the egg was flat or slightly depressed. Microvilli were observed except on the surface at the animal pole. The egg was entirely covered with a coat composed of fibrous materials. The spermatozoon was of the primitive type, and the proacrosomal vesicles were found immediately beneath the plasma membrane of the antero-lateral region of the sperm head. Within 15 sec after insemination, spermatozoa were incorporated in the egg cytoplasm only at the microvilli-free surface at the animal pole. Neither opening of the proacosomal vesicles nor formation of the acrosomal process was observed. No appreciable changes of cortical cytoplasm could be detected, although the egg became sticky after fertilization. Decondensation of the incorporated sperm nucleus occurred without breakdown of the original nuclear envelope. Within 10 min after insemination, the sperm nucleus still under the process of its decondensation fused with the female pronucleus. These findings were discussed in comparison with the fertilization process of higher metazoans as well as of other cnidarians.     

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.     

CHANGES IN THE SPERMATOZOON DURING FERTILIZATION IN HYDROIDES HEXAGONUS (ANNELIDA) : II. Incorporation with the Egg

This, the last of a series of three papers, deals with the final events which lead to the incorporation of the spermatozoon with the egg. The material used consisted of moderately polyspermic eggs of Hydroides hexagonus, osmium-fixed at various times up to five minutes after insemination. The first direct contact of sperm head with egg proper is by means of the acrosomal tubules. These deeply indent the egg plasma membrane, and consequently at the apex of the sperm head the surfaces of the two gametes become interdigitated. But at first the sperm and egg plasma membranes maintain their identity and a cross-section through the region of interdigitation shows these two membranes as a number of sets of two closely concentric rings. The egg plasma membrane rises to form a cone which starts to project into the hole which the spermatozoon earlier had produced in the vitelline membrane by means of lysis. But the cone does not literally engulf the sperm head. Instead, where they come into contact, sperm plasma membrane and egg plasma membrane fuse to form one continuous membranous sheet. At this juncture the two gametes have in effect become mutually incorporated and have formed a single fertilized cell with one continuous bounding membrane. At this time, at least, the membrane is a mosaic of mostly egg plasma membrane and a patch of sperm plasma membrane. The evidence indicates that the fusion of the two membranes results from vesiculation of the sperm and egg plasma membranes in the region at which they come to adjoin. Once this fusion of membranes is accomplished, the egg cytoplasm intrudes between the now common membrane and the internal sperm structures, such as the nucleus, and even extends into the flagellum; finally these sperm structures come to lie in the main body of the egg. The vesiculation suggested above appears possibly to resemble pinocytosis, with the difference that the vesicles are formed from the plasma membranes of two cells. At no time, however, is the sperm as a whole engulfed and brought to the interior of the egg within a large vesicle.     

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.     

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.     

Involvement of Rho family G protein in the cell signaling for sperm incorporation during fertilization of mouse eggs: inhibition by Clostridium difficile toxin B

Sperm-egg interaction was investigated in mouse eggs freed from the zona pellucida and injected with Clostridium difficile toxin B, the inhibitor of Rho family small G proteins. Toxin B reduced in a dose-dependent manner the percentage of eggs associated with sperm fusion on the surface or sperm nucleus decondensation in the ooplasm, examined by injection of a DNA-staining dye into the egg and transfer of the dye to the fused sperm head after recording intracellular Ca(2+) responses for 100 min postinsemination. The mean number of decondensed sperm nuclei per egg was remarkably decreased by approximately 1 microg/ml toxin B in the ooplasm. This was because spermatozoa were arrested at the fusion state without developing to sperm incorporation and tended to lose cytoplasmic continuity to the egg. The fusion-arrested spermatozoa caused transient small Ca(2+) oscillations in most of eggs, while an injected spermatozoon produced repetitive large Ca(2+) spikes unaffected by toxin B. A decrease in the rate of fused spermatozoa and decondensed sperm nuclei was also caused by 20-40 microM cytochalasin D, the inhibitor of actin polymerization. Immunostaining of Rho proteins showed that Rac1 and RhoB are present in the cortical ooplasm, but Cdc42 is absent. Actin filaments in the cortex appeared to be reduced in toxin B-injected eggs. This study suggests that Rho protein(s) regulating actin-based cytoskeletal reorganization is involved in the process leading to sperm incorporation.     

Correlative ultrastructural and electrophysiological studies of sperm-egg interactions of the sea urchin, Lytechinus variegatus

The sequence of ultrastructural events following the onset of the sperm-induced conductance increase in eggs of the sea urchin, Lytechinus variegatus, was investigated. Eggs voltage clamped at -20 mV were fixed 1 to 20 sec after onset of the conductance increase caused by single sperm. Continuity between the plasma membranes of the sperm and egg was first detected 5 sec after onset of the conductance increase. The earliest stages of formation of the fertilization cone coincided with the establishment of continuity of the gamete plasma membranes. At 6 to 8 sec after the initial conductance increase cortical granule dehiscence was first observed in the immediate vicinity where continuity of the gamete plasma membranes had occurred. These observations are consistent with the conclusion that opening of ion channels at fertilization precedes fusion of the sperm and egg plasma membranes, while exocytosis of cortical granules is initiated following fusion of the sperm and egg plasma membranes.     

Sperm-oocyte membrane fusion in the human during monospermic fertilization

Sperm-oocyte membrane fusion has been observed during monospermic fertilization of a human oocyte in vitro. Women were stimulated with both clomiphene citrate and human menopausal gonadotropin and were given human chorionic gonadotropin before a LH-surge. Twelve oocytes, collected at laparoscopy from six women who became pregnant by IVF, were allowed to mature for 7–14 hours in vitro and inseminated with preincubated sperm, fixed between 1–3 hours after insemination, and examined by transmission electron microscopy. Membrane fusion had occurred in one ovum 2 hours after insemination, and the oocyte had resumed maturation and was at anaphase II of meiosis. Cortical granules had been exocytosed, and some of their contents were visible at the surface close to the oolemma all around the oocyte. The sperm that fused with this oocyte was acrosome-reacted and had been partly incorporated into the ooplasm, while the anterior two-thirds of its head was phagocytosed by a tongue of cortical ooplasm. Membrane fusion had occurred between the oolemma and the plasma membrane overlying the postacrosomal segment of the sperm head, posterior to the equatorial vestige. Sperm chromatin had not decondensed, and serial sections revealed a midpiece attached to the basal plate and a tail located deeper in the ooplasm, all devoid of plasma membrane. Supplementary sperm penetrating the inner zona, approaching the perivitelline space, had undergone the acrosome reaction but had a persistent vestige of the equatorial segment of the acrosome with intact plasma membrane. Evidence of sperm chromatin decondensation was seen in other oocytes, 3 hours after insemination, which were at telophase II of meiosis. Eight oocytes penetrated by sperm were monospermic, while four were unfertilized. The general pattern of sperm fusion and incorporation appears to conform to that seen in most other mammals. The study also reveals that sperm have to complete the acrosome reaction before fusing with the egg.     

Human teratoma cells share antigens with mouse teratoma cells.

Cytochalasin B inhibits the penetration of sperm nuclei into Urechis eggs without inhibiting sperm-induced egg activation. The acrosome reaction appears normal, and plasma membranes of the acrosomal tubule and egg become closely apposed. It is uncertain whether or not the drug blocks fusion of these membranes; however, sperm penetration cone formation is inhibited.     

Integration of sperm and egg plasma membrane components at fertilization

Studies examining the integration of the sperm and egg plasma membranes, subsequent to gamete fusion in the surf clam, Spisula solidissima, were carried out employing the concanavalin A-horseradish peroxidase-diaminobenzidine procedure (Con A-HRP-DAB). When unfertilized Spisula eggs were incubated in Con A, either prior to or after aldehyde fixation and reacted with HRP-DAB, enzymatic precipitate was found associated with the vitelline layer and plasmalemma. The plasma membranes of sperm treated in a similar manner failed to stain. The plasma membranes of fertilized eggs reacted with Con A-HRP-DAB and examined by 1 min postinsemination were associated uniformly with enzymatic precipitate except at sites of sperm incorporation. These portions of unstained plasma membrane were derived from the spermatozoon and delimited the contents of the fertilization cone. From 2 to 4 min postinsemination, HRP-DAB reaction product became associated with the plasma membrane delimiting the fertilization cone. By 4 min postinsemination no difference in staining of the plasma membranes derived from the egg or the sperm (plasmalemma delimiting the fertilization cone) was detected. Evidence is presented suggesting that the acquisition of HRP-DAB reaction product by the former sperm plasmalemma is due to the movement of Con A binding sites from the egg plasma membrane.     

Studies in Fertilization of Fokienia

Material of Fokienia hodginsii was collected in 1964 from Fengyangshan (alt. 1000–1400 M) in Lungchuan county, Chekiang province. This paper deals with the fertilization in Fokienia. It includs the structure of male and female gametes as wed1 as the process of fusion of their nuclei and cytoplasm respectively. The division of the spermatogenous cell of Fokienia occurred by the end of June (1964) and two sperms similar in shape and size were formed when pollen tube reached the top of archegonia. Two equalsperms look like two hemispherical bodies conjoined togather. The sperm possesses cell wall and is about 65 μ in diameter. Its nucleus is rather large and about 45–50 μ in diameter. There is a nucleolus in the nucleus. Outside the nucleus the dense cytoplasm forms the deep colored zone, some 10 μ in thickness. This zone is separated from the nucleus by a narrow perinuclear zone, and from the plasmalemma by a marginal zone. The perinuclear zone is about 2 μ thick, and the mariginal zone is from 3 to 4 μ thick. Both zones have transparent cytoplasm. When the archegonium is formed, the central cell has a small nucleus which is located below the neck ceils. At the middle of June (1964), the central cell divides to form the ventral nucleus and the egg nucleus. The egg nucleus sites primarily at the upper part of archegoninm and has only one nucleolus. Then the egg nucleus increases gradually in sim and moves to the central part of the archegoninm. In mature archegonium there are usually 4–5, rarely 6–7 nucleoli in the egg nucleus, each of them is about 15 μ in diameter. The egg cell in Fokienia hodginsii is about 500 in length. The female nucleus is larger than the male one. After egg cell matures, its cytoplasm increases gradually, while the central vacuole decreases gradually and almost disappears completely after fertilization. It is interesting to note that there are 1–2 dense cytoplasm masses at the upper or lower part of egg nucleus. The shape of the mass is similar to that of the egg nucleus but no membrane is formed. These cytoplasm masses are about 50–70 μ in diameter in some cases. The fertilization of Fokienia took place at the end of June when the growing tip of pollen tube had reached the top of the archegoninm. Then the neck cells become disorganized and degenerated. It is possible that all the cytoplasmic contents of pollen tubes are released into the archegoninm. Before fertilization, the cytoplasm around the sperms and sterile cell and tube nucleus are in front of these two sperms. Then the sperms separate from each other and come down into the cytoplasm of the egg. When the mede nucleus contacts with the egg nucleus, both become flattened along their contact surface. Then the nuclear membranes of both sperm and egg nuclei become ultimately disintegrated. Thus the fusion process is complete. However, it is nia, though the opposite is the case in an exceptional example. When the sperm nucleus passes into the cytoplasm of egg cell, its cytopasm is released inside the archegonium along with it. During the course of fusion of the male and female nuclei, tile fertilized nucleus is surrounded by both female and male cytoplasm. Thus the male cytoplasm along with the peripheral cytoplasm of the egg cell invests the two nuclei lying in contact and forms a dense neocytoplasm. When the zygote divides, the neoeytoplasm is full of the starch grains and a dense cytoplasm sheath is formed. After fertilization, the fused nucleus moves toward the base of the egg cell. It seems that the movement of the fused nucleus is not a simple mechanical movement but turned over repeatedly toward the base of the arehegonium. Sometimes the position of the sperm and egg nuclei makes a turn of 180. At the same time the track of the fertilized egg nucleus with vacuoles in the archegonium may be traced. After zygote moves into basal part of the archegonium, first intranuclear mitosis occurs. The nuclear envelop of zygote disappears gradually at the telophase of the first mitosis. Then division of the free nuclei of proembryo follows. From fertilization to the stage of proembryo formation, the second sperm may sometimes enter into the cytoplasm of the egg cell. Mitosis of the second sperm nucleus may take place in the upper part of the archegonium. In addition, there are often several supernmnerary nuclei (as many as 7–8 in number) in the same egg cell. These nuclei are also surrounded by dense cytoplasm. They may persist for some time and be recognizable at somewhat later stages of the proembryo or even after the elongated suspensors are formed. In some cases, there are some cell groups above the upper tier of proembryo. These cell groups are also surrounded by dense cytoplasm. Either the supernumerary nuclei or cells are surrounded by the dense cytoplasm. Probably they are derived from the mitosis or amitosis of the second sperm. Investigations on submicroscopic structures of sperm and egg in relation to the fertilization of Cupressaceae have been carried out extensively during the last decade. The fate of male cytoplasm has been debated for a long time and this problem attracted attention again in the nineteen seventies. At last the concept of neocytoplasm has been established soundly based upon the information from observation of electron microphotographs. The neocytoplasm is also visible under the light microscope though the components are not recognizable. The sperms of Fokienia are similar to those of Cupressus funebris, Juniperus communis, Sabina virginiana, Tetraclinis articulata, Chamaecyparis pisifera as well as the genus Thujopsis and others. Two sperms are all effective in fertilization and this is the common phenomenon of the family Gupressaceae.     

Scanning electron microscope studies of sperm incorporation into the zebrafish (Brachydanio) egg

Morphological studies on the gametes and entry of the spermatozoan into the egg of the zebra danio, Brachydanio rerio, were conducted primarily with scanning electron microscopy. The spermatozoan showed a spherical head, which lacked an acrosome, a midpiece containing several mitochondria, and a flagellum. Observations of the unfertilized egg confirmed and extended prior studies showing a distinct cluster of microvilli on the plasma membrane, identified as the sperm entry site, beneath the inner micropylar aperture (Hart and Donovan, '83). The fertilizing spermatozoan attached to the sperm entry site within 5 seconds of the mixing of a gamete suspension. Binding to the egg microvilli appeared restricted to the equatorial surface of the spermatozoan. Fusion between the plasma membranes of the interacting gametes was followed by the formation of a distinct, nipple-shaped fertilization cone. The sperm head was partially incorporated into the fertilization cone cytoplasm by 60 seconds postinsemination. The incorporation of the entire sperm head, midpiece, and a portion of the flagellum occurred between 1 and 2 minutes. During this time, the fertilization cone shortened and was transformed into a massive, blister-like cytoplasmic swelling. Concurrently, upward movements of the ooplasm resulted in the gradual disappearance of the original depression in the egg surface containing the sperm entry site. The second polar body, fully developed by 10 minutes postinsemination, formed approximately 10-15 microns from the site of sperm penetration. Development of the fertilization cone, formation of the second polar body and exocytosis of cortical granules at the sperm entry site readily occurred in parthenogenetically activated eggs, indicating that these surface rearrangements do not require sperm binding and/or fusion.     

Mammalian sperm-egg fusion: the rat egg has complementary sites for a sperm protein that mediates gamete fusion.

Rat epididymal protein DE is localized on the fusogenic region of the acrosome-reacted spermatozoa and has a potential role in sperm-egg fusion. We investigated the presence of DE binding sites on the egg surface by co-incubating zona-free eggs and capacitated sperm in different concentrations of pure DE. Results indicate that DE produced a concentration-dependent decrease in egg penetration by sperm (fusion), with almost complete inhibition at 200 micrograms/ml. This inhibition was not due to an effect of DE on initial sperm binding to the egg membrane, since the presence of this protein did not affect the percentage of oocytes with bound sperm nor the number of bound sperm per egg. Those sperm that failed to penetrate the egg in the presence of DE became able to do so after transfer of the eggs to protein- and sperm-free medium, indicating a role for DE in an event subsequent to binding and leading to fusion. Indirect immunofluorescence using a polyclonal antibody against DE revealed a patchy labeling over the entire egg surface, with the exception of the area overlying the second metaphase spindle. This conclusion was supported by the disappearance of the DE-negative area on the fertilized egg. Zona-free eggs, incubated with DE at 4 degrees C or fixed before exposure to DE, displayed a uniform staining, suggesting that the patchy labeling resulted from aggregation of DE binding sites by the purified protein. The aggregation of these egg components may represent a necessary step of the fusion process. To our knowledge, this is the first study reporting the existence and localization of complementary sites to a specific sperm protein on the plasma membrane of the mammalian egg.