Physiological polyspermy: Selection of a sperm nucleus for the development of diploid genomes in amphibians

The union between a sperm and an egg nucleus in egg fertilization is necessary to mix genetic materials to create a new diploid genome for the next generation. In most animals, only one sperm is incorporated into the egg (monospermy), but several animals exhibit physiological polyspermy in which several sperms enter the egg during normal fertilization. However, only one sperm nucleus forms the zygote nucleus with the egg nucleus, even in a polyspermic egg. The cellular and molecular mechanisms involved in the selection of sperm nuclei in the egg cytoplasm have been well investigated in urodele amphibians. The principal sperm nucleus develops a larger sperm aster and contacts the egg nucleus to form a zygote nucleus, whereas other accessory sperm nuclei are unable to approach the egg nucleus. The diploid zygote nucleus induces cleavage and participates in embryonic development, whereas the accessory sperm nuclei undergo pyknosis and degenerate. We propose several models to account for the mechanisms of the selection of one sperm nucleus and the degeneration of accessory sperm nuclei. The roles of physiological polyspermy in animal reproduction are discussed by comparison with other polyspermic species.     

A model for sperm-egg binding and fusion based on ADAMs and integrins

Once a sperm meets an egg, several events must occur in order for fertilization to proceed. Sperm must bind to the zona pellucida, undergo the acrosome reaction, penetrate the zona pellucida and then bind to and fuse with the egg plasma membrane. Shortly thereafter, the egg must be activated for zygotic development. This review focuses on mammalian sperm-egg plasma membrane binding and fusion, and in particular on the roles of two families of cell-adhesion molecules, ADAMs and integrins, in this important union.     

Mechanism of Ca2+ release at fertilization in mammals.

At fertilization in mammals the sperm triggers a series of oscillations in intracellular Ca2+ within the egg. These Ca2+ oscillations activate the development of the egg into an embryo. It is not known how the sperm triggers these Ca2+ oscillations. There are currently three different theories for Ca2+ signaling in eggs at fertilization. One idea is that the sperm acts as a conduit for Ca2+ entry into the egg after membrane fusion. Another idea is that the sperm acts upon plasma membrane receptors to stimulate a phospholipase C (PLC) within the egg which generates inositol 1,4, 5-trisphosphate (InsP(3)). We present a third idea that the sperm causes Ca2+ release by introducing a soluble protein factor into the egg after gamete membrane fusion. In mammals this sperm factor is also referred to as an oscillogen because, after microinjection, the factor causes sustained Ca2+ oscillations in eggs. Our recent data in sea urchin egg homogenates and intact eggs suggests that this sperm factor has phospholipase C activity that leads to the generation of InsP(3). We then present a new version of the soluble sperm factor theory of signaling at fertilization. J. Exp. Zool. (Mol. Dev. Evol.) 285:267-275, 1999.     

Egg-jelly structure promotes efficiency of internal fertilization in the newt, Cynops pyrrhogaster

Egg-jelly is composed of a network of fibrous components and contains substances regulating the sperm-egg interaction. Many studies on the latter have been conducted, whereas the role of the egg-jelly structure in fertilization has not yet been fully assessed. In this study, we examined the fertilization efficiency in the presence and absence of the structure around the egg of the newt, Cynops pyrrhogaster, using a gelatin gel system. Although de-jellied eggs of C. pyrrhogaster can be fertilized with an adequate number of sperm, the fertilization rate was dramatically increased through the use of the gelatin gel. Sperm showed forward motility with straight morphology in the gel, whereas they swam in circles in solution. This result indicates that the gel structure is significant for sperm guidance to the egg surface, and its presence raises the fertilization efficiency in C. pyrrhogaster. When sperm were entangled in the gel structure, they were immediately folded and never showed any forward motility. Sperm with zigzag morphology were observed in the gelatin gel as well as in the egg-jelly, indicating the elimination of sperm by the gel structure. The effect of sperm elimination on successful fertilization was estimated using gelatin gels of different thickness. Though the variation did not affect the fertilization rate, the rate of normal development gradually increased in the thicker gels. This result indicates that sperm elimination in egg-jelly can function in the fertilization system. The roles of sperm guidance and sperm elimination under the physiological condition of internal fertilization of the newt are discussed.     

Intracellular sperm/egg interactions in Drosophila: a three-dimensional structural analysis of a paternal product in the developing egg

During fertilization in Drosophila, a single 1.75 mm long sperm enters the egg through the anterior end. Using a sperm-specific monoclonal antibody and indirect immunofluorescence of whole fixed eggs and embryos, intracellular interactions between the sperm and egg are examined as they occur inside the fertilized egg. The sperm nucleus remains attached to the axoneme throughout the entire process of fertilization including the stages of pronuclear maturation, pronuclear fusion and karyogamy indicating an intracellular function for the sperm during these stages. Optical sections and three-dimensional reconstructions of whole mount specimens reveal that a stereotypically folded structure forms during fertilization strongly suggesting that this structure positions the male pronucleus in the proper region of the egg in anticipation of pronuclear fusion. This, and the appearance of regional structural changes in the sperm upon entry suggests that sperm are localized via specific interactions with the maternal cytoplasm. Following fertilization and during the ensuing cleavage divisions, the sperm remains intact and localized at the anterior end of the egg. During cellular blastoderm formation the sperm tail is sequestered into the anterior yolk area where it continues to persist well into embryonic development. This structural analysis identifies intracellular sperm/egg interactions as an important aspect of fertilization, and provides a unique model system for the study of sperm/egg interactions not presently available in other systems.     

Characterization of a sperm factor for egg activation at fertilization of the newt Cynops pyrrhogaster

Eggs of the newt, Cynops pyrrhogaster, arrested at the second meiotic metaphase are activated by sperm at fertilization and then complete meiosis to initiate development. We highly purified a sperm factor for egg activation from a sperm extract with several chromatographies. The purified fraction containing only a 45 kDa protein induced egg activation accompanied by an intracellular Ca2+ increase when injected into unfertilized eggs. Although injection of mouse phospholipase C (PLC) zeta-mRNA caused a Ca2+ increase and egg activation, partial amino acid sequences of the 45 kDa protein were homologous to those of Xenopus citrate synthase, but not to PLCs. An anti-porcine citrate synthase antibody recognized the 45 kDa protein both in the purified fraction and in the sperm extract. Treatment with the anti-citrate synthase antibody reduced the egg-activation activity in the sperm extract. Injection of porcine citrate synthase or mRNA of Xenopus citrate synthase induced a Ca2+ increase and caused egg activation. A large amount of the 45 kDa protein was localized in two lines elongated from the neck to the middle piece of sperm. These results indicate that the 45 kDa protein is a major component of the sperm factor for egg activation at newt fertilization.     

Profile of a mammalian sperm receptor

Complementary molecules on the surface of eggs and sperm are responsible for species-specific interactions between gametes during fertilization in both plants and animals. In this essay, several aspects of current research on the mouse egg receptor for sperm, a zona pellucida glycoprotein called ZP3, are addressed. These include the structure, synthesis, and functions of the sperm receptor during oogenesis and fertilization in mice. Several conclusions are drawn from available information. These include (I) ZP3 is a member of a unique class of glycoproteins found exclusively in the extracellular coat (zona pellucida) of mammalian eggs. (II) ZP3 gene expression is an example of oocyte-specific and, therefore, sex-specific gene expression during mammalian development. (III) ZP3 is a structural glycoprotein involved in assembly of the egg extracellular coat during mammalian oogenesis. (IV) ZP3 is a sperm receptor involved in carbohydrate-mediated gamete recognition and adhesion during mammalian fertilization. (V) ZP3 is an inducer of sperm exocytosis (acrosome reaction) during mammalian fertilization. (VI) ZP3 participates in the secondary block to polyspermy following fertilization in mammals. (VII) The extracellular coat of other mammalian eggs contains a glycoprotein that is functionally analogous to mouse ZP3. The unique nature, highly restricted expression, and multiple roles of ZP3 during mammalian development make this glycoprotein a particularly attractive subject for investigation at both the cellular and molecular levels.     

Glycobiology of fertilization in the pig

By adopting internal fertilization, the meeting of both gametes - the sperm and the egg - and thus the highly coordinated sequence of interactions leading to fertilization, occur in the female reproductive tract. In mammals, the oviduct has been shown to translate the requirements of the female, coordinating sperm activation (capacitation) and sperm transport with the arrival of the ovulated egg. A hierarchy of carbohydrate-based interactions accompanies these events ranging from the binding of uncapacitated sperm to the oviductal epithelium (establishment of the female sperm reservoir), to the primary and secondary binding processes contributing to gamete recognition and sperm penetration of the oocyte zona pellucida. The current perspective will focus on the carbohydrate-recognition systems in the binding events during fertilization in the pig. The roles of the major carbohydrate-binding proteins, the spermadhesins and the acrosomal serine proteinase, pro/acrosin are discussed under consideration of recent structural data. The glycans and the glycoproteins of the porcine oviduct with a focus on the candidate sperm receptors as well as the zona pellucida N-glycans of prepuberal pigs have been characterized by a mass spectrometric approach. Furthermore, some preliminary data supporting the hypothesis that the zona pellucida has to undergo a maturation process during oocyte development are presented.     

Glycosidases,proteases and ascidian fertilization

Spermatozoa should bind to and then penetrate the vitelline coat for fertilization in ascidians and many other animals. There is substantial evidence that the binding of ascidian sperm is mediated by a sperm glycosidase and complementary saccharide chains of glycoproteins in the vitelline coat. Involvement of a sperm proteasome in the binding is also suggested. For the penetration, sperm proteases such as chymotrypsin-like enzyme, acrosin, spermosin and proteasome are suggested to play essential roles. Sperm glycosidase, that is translocated from the tip of sperm head to the surface overlying the mitochondrion, anchors the mitochondrion at the outer surface of vitelline coat. Therefore it assists sperm to penetrate the vitelline coat and traverse the perivitelline space. For fusion with egg plasma membrane, sperm metalloendoprotease seems to be involved. Egg glycosidases and proteases serve for some steps after fertilization, such as the prevention of polyspermy, expansion of perivitelline space and regulation of cell cycle.     

Zona pellucida glycoproteins

All mammalian eggs are surrounded by a relatively thick extracellular coat, the zona pellucida, that plays vital roles during oogenesis, fertilization, and preimplantation development. The mouse zona pellucida consists of three glycoproteins that are synthesized solely by growing oocytes and assemble into long fibrils that constitute a matrix. Zona pellucida glycoproteins are responsible for species-restricted binding of sperm to unfertilized eggs, inducing sperm to undergo acrosomal exocytosis, and preventing sperm from binding to fertilized eggs. Many features of mammalian and non-mammalian egg coat polypeptides have been conserved during several hundred million years of evolution.     

Gamete membrane microdomains and their associated molecules in fertilization signaling

Fertilization is the fundamental system of biological reproduction in many organisms, including animals, plants, and algae. A growing body of knowledge has emerged to explain how fertilization and activation of development are accomplished. Studies on the molecular mechanisms of fertilization are in progress for a wide variety of multicellular organisms. In this review, we summarize recent findings and debates about the long-standing questions concerning fertilization: how egg and sperm become competent for their interaction with each other, how the binding and fusion of these gamete cells are made possible, and how the fertilized eggs initiate development to a newborn. We will focus on the structure and function of the membrane microdomains (MDs) of egg and sperm that may serve as a platform or signaling center for the aforementioned cellular functions. In particular, we provide evidence that MDs of eggs from the African clawed frog, Xenopus laevis, play a pivotal role in receiving extracellular signals from fertilizing sperm and then transmitting them to the egg cytoplasm, where the tyrosine kinase Src is present and responsible for the subsequent signaling events collectively called egg activation. The presence of a new signaling axis involving uroplakin III, an MD-associated transmembrane protein, and Src in this system will be highlighted and discussed.     

黑节草双受精过程及胚胎发育的研究

黑节草从传粉到受精约需１３０ｄ,精子在花粉管中形成,胚囊发育属蓼型胚囊,因反足细胞较早退化,故受精前胚囊多只由卵器和中央细胞组成。精卵核融合时,精核染色质进入卵核后凝集成颗粒状,并在原位与卵核的染色质融合,雌、雄性核仁一直维持至合子的第一次分裂期前。双受精作用正常,属于有丝分裂前配子融合类型,初生胚乳核发生２－３次分裂后逐渐退化消失,胚的发育局限于球形胚阶段。     

The Ca2+ increase by the sperm factor in physiologically polyspermic newt fertilization: its signaling mechanism in egg cytoplasm and the species-specificity

The newt, Cynops pyrrhogaster, exhibits physiological polyspermic fertilization, in which several sperm enter an egg before egg activation. An intracellular Ca(2+) increase occurs as a Ca(2+) wave at each sperm entry site in the polyspermic egg. Some Ca(2+) waves are preceded by a transient spike-like Ca(2+) increase, probably caused by a tryptic protease in the sperm acrosome at the contact of sperm on the egg surface. The following Ca(2+) wave was induced by a sperm factor derived from sperm cytoplasm after sperm-egg membrane fusion. The Ca(2+) increase in the isolated, cell-free cytoplasm indicates that the endoplasmic reticulum is the major Ca(2+) store for the Ca(2+) wave. We previously demonstrated that citrate synthase in the sperm cytoplasm is a major sperm factor for egg activation in newt fertilization. In the present study, we found that the activation by the sperm factor as well as by fertilizing sperm was prevented by an inhibitor of citrate synthase, palmitoyl CoA, and that an injection of acetyl-CoA or oxaloacetate caused egg activation, indicating that the citrate synthase activity is necessary for egg activation at fertilization. In the frog, Xenopus laevis, which exhibits monospermic fertilization, we were unable to activate the eggs with either the homologous sperm extract or the Cynops sperm extract, indicating that Xenopus sperm lack the sperm factor for egg activation and that their eggs are insensitive to the newt sperm factor. The mechanism of egg activation in the monospermy of frog eggs is quite different from that in the physiological polyspermy of newt eggs.     

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 surface proteins are incorporated into the egg membrane and cytoplasm after fertilization

Using an antibody to sperm surface proteins, we have investigated the fate of the sperm membrane after fertilization. By immunofluorescence, two distinct loci of sperm surface proteins were found in the embryo: a large, restricted domain on the embryo surface and a smaller locus that apparently had moved from the point of sperm entry into the egg cytoplasm. The surface domain was initially over the fertilization cone and slowly disappeared, so that by 2 hr after fertilization it was no longer seen. The small internal locus of staining remained intact throughout the one-cell stage. When fluorescein isothiocyanate (FITC)-labeled sperm were used to fertilize eggs, the FITC-patch in the eggs was at a site distinct from either locus of sperm surface proteins. Thus, while most sperm surface proteins are incorporated into the egg surface at the site of fertilization and then slowly disappear, other sperm surface components are internalized to be retained for longer times. The differential handling of these sperm cytoplasmic components by the embryo raises the possibility that some of the sperm components may play a role in later embryonic events.     

Sperm cell architecture, insemination, and fertilization in the model fern, Ceratopteris richardii

Motile sperm cells of land plants are released directly into the environment and encounter numerous constraints on their way to the egg. Sperm cell organization, shape, size, and plasticity are crucial to the processes associated with fertilization. We conducted an ultrastructural investigation to detail insemination (sperm release, swimming and movement within the archegonium) and fertilization in the model fern Ceratopteris richardii. Gametophytes were grown from spores using sterile culture techniques and flooded in water when sexually mature. Materials were examined at different stages post-flooding. During insemination in C. richardii, the sperm cytoskeleton and flagella rearrange, and the coils of the cell extend while entering the neck canal. In this nearly linear configuration, the dense ridge, a densely compacted band of filaments presumed to be actin, expands to surround the leading edge of the sperm cell. This ridge fuses with the receptive site on the female gamete and is the sperm component that initiates contact with the egg nuclear envelope. All cellular components, except plastids, enter the egg cytoplasm. Sperm mitochondria are distinguishable from those of the egg because they are encased by two or three additional membranes and are sequestered from the zygote cytoplasm. During karyogamy, the sperm components, including the microtubule cytoskeleton (spline) and flagella, maintain their spatial integrity. Microtubules play key roles not only in sperm cell structure but also in facilitating karyogamy in this fern. After karyogamy is completed, microtubule arrays of the sperm cell and the components of the locomotory apparatus are disassembled. We provide the first demonstration of the likely involvement of sperm actin in egg penetration in land plants and new insights into the fate of paternal organelles. This study points to the roles sperm cell structure and dynamics play in the intricate processes of insemination and fertilization in land plants.     

Scanning electron-microscopical and other observations of sperm fertilization reactions in Limulus polyphemus L. (Merostomata: Xiphosura).

Sperm fertilization reactions of Limulus polyphemus were examined by scanning electron and/or light microscopy. The following were considered: sperm motility, attachment of sperm to egg, acrosome reaction, and penetration of the acrosomal filament. The spermatozoa after semination are non-motile and become active only in close proximity to a defined region surrounding the egg. Egg materials diffusing into this region induce sperm motility and stimulate large numbers of spermatozoa to move towards the egg surface. Each sperm initially attaches by the apical tip and undergoes the acrosome reaction which causes a more permanent secondary attachment by the adhesion of acrosomal contents to the egg surface. The acrosome reaction also initiates the penetration of the acrosomal filament through the egg envelope, an event occurring in 70-80% of the attached spermatozoa (about 10(6). Shortly after this penetration, a secondary reaction occurs which involves a spiralling of the flagellum and an incorporation into the sperm body of the flagellar fibrous components, which then become closely apposed to the sperm nucleus. These sperm fertilization reactions were performed or initiated with 0-34 M CaCl2 in whole eggs, egg sections, excised egg envelopes and/or the outer basement lamina of the egg envelope. The Limulus fertilization system is very valuable since sperm reactions can be examined biochemically, which may lead to a better understanding of the chemical mechanisms involved in sperm-egg interactions in all animal species.     

An intermediate state of fertilization involved in internalization of sperm components

The pathway of sperm entry during sea urchin fertilization was analyzed by using sperm covalently labeled with fluorescent and radioactive tracers. Sperm that have been covalently labeled on their surfaces with fluorescein isothiocyanate (FITC) or a radioactive congener, diiodofluorescein isothiocyanate (¹²⁵IFC), transfer labeled components to the egg that persist throughout early development. In order to study the transfer of sperm components and their fate after fertilization, cytochalasin B-dependent inhibition of fertilization, previously shown to permit the cortical reaction of sea urchin eggs but block sperm pronuclear incorporation, was investigated. Under certain conditions cytochalasin B or D (CB or CD) results in about half of the activated eggs having both the sperm nucleus and the fluorescently labeled sperm components arrested apparently at the level of the egg plasma membrane. This arrest of internalization was reversed by removal of CB or CD, and the sperm derivatives entered the egg. When sperm were labeled noncovalently with ethidium bromide or rhodamine 123, fluorescence was transferred to the egg in the cytochalasin-inhibited state in a fashion similar to that found in normal fertilization; in both cases the sperm fluorescence disappeared within a few minutes of fertilization, due to the repartitioning of the noncovalent dyes into the egg cytoplasm. It is concluded that cytochalasin arrests fertilization at an intermediate step in which the sperm has fused with the egg to achieve cytoplasmic continuity, but in which the subsequent internalization of sperm components is inhibited. After removal of cytochalasins the fluorescent sperm components move from the egg surface to an internal site, a process that can be monitored by time-lapse video microscopy with an image intensifier to permit extended observations of sperm fluorescence. The cytoplasmic location of labeled sperm components was substantiated by autoradiography of early embryos fertilized with ¹²⁵IFC-labeled sperm; transfer of sperm components to an internal site was seen after fertilization of either sea urchin or mouse eggs. Taken together, the data suggest that the fate of the labeled sperm surface components, as well as that of the sperm nucleus, is to be transferred to the egg cytoplasm, and that this transfer is mediated by the actin-dependent cytoskeleton of the egg.     

Female‐induced remote regulation of sperm physiology may provide opportunities for gamete‐level mate choice

In sedentary externally fertilizing species, direct interactions between mating partners are limited and prefertilization communication between sexes occurs largely at the gamete level. Certain combinations of eggs and sperm often have higher fertilization success than others, which may be contingent on egg‐derived chemical factors that preferentially attract sperm from compatible males. Here, we examine the mechanisms underlying such effects in the marine mussel Mytilus galloprovincialis, where differential sperm attraction has recently been shown to be associated with variation in offspring viability. Specifically, we focus on the sperm surface glycans, an individually unique layer of carbohydrates that moderate self‐recognition and other cellular‐level interactions. In many species egg‐derived factors trigger remarkable changes in the sperm's glycan layer, physiology, and swimming behavior, and thus potentially moderate mate choice at the gamete level. Here, we show that sperm glycan modifications and the strength of acrosome reaction are both dependent on specific male–female interactions (male–female combination). We also find associations between female‐induced sperm glycan changes and the Ca²⁺ influx into sperm–‐a key regulator of fertilization processes from sperm capacitation to gamete fusion. Together, our results suggest that female‐induced remote regulation of sperm physiology may constitute a novel mechanism of gamete‐level mate choice.     

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.