On fertilization in Chaetopleura apiculata and selected Chitonida

Early events of fertilization are described in Chaetopleura apiculata and other selected Chitonida. C. apiculata egg hulls are elaborated into multi-branched spines with interlocking polygonal bases. Around the perimeter of each base are a series of open pores, ranging in size from 0.1-0.5 microm, which permit sperm direct access to the vitelline layer. In Callochitonidae (Chitonida) even larger pores occur in egg jelly coats, but this is considered to be the plesiomorphic condition, found also in Lepidopleurida such as Deshayesiella curvata. Other Chitonina, such as Rhyssoplax tulipa and Acanthopleura granulata, have a continuous outer dense layer that lacks pores and must be digested by penetrating sperm. Fertilization in Chitonida is unique and involves injection of chromatin into the egg via a narrow tubular nuclear extension that appears to exclude other sperm organelles, including mitochondria, centrioles, and flagellum. New evidence from studies of fertilization in Mopalia muscosa (Chitonida: Acanthochitonina) supports this hypothesis. This type of fertilization implies maternal inheritance of both mitochondria and centrioles, which is highly unusual, because in most animals one sperm centriole assists movements of pronuclei and regulates organization of the mitotic spindle. This mechanism of fertilization is defined by a series of apomorphic characters that unify the order Chitonida.     

When do sperm of the sea urchin,Pseudocentrotus depressus,undergo the acrosome reaction at fertilization?

Jelly coats of the sea urchin, Pseudocentrotus depressus, were stripped off the eggs, and the eggs were “inseminated.” After penetration through the isolated jelly hull, sperm swarmed in the cavity previously occupied by the egg. Electron microscopic examination could not detect any sperm with reacted acrosome. Observation was also made of the sperm penetrating through the intact jelly coat-egg complex. Although a number of sperm were examined in ultrathin sections, only those attached to the vitelline layer had undergone the acrosome reaction; those sperm embedded in jelly but not attached to the vitelline layer had not undergone the acrosome reaction. The sequence of events in fertilization of this species and of other echinoids is discussed.     

Structural features of the abalone egg extracellular matrix and its role in gamete interaction during fertilization

Abalone eggs are surrounded by a complex extracellular coat that contains three distinct elements: the jelly layer, the vitelline envelope, and the egg surface coat. In this study we used light and electron microscopy to describe these three elements in the red abalone (Haliotis rufescens) and ascribe function to each based on their interactions with sperm. The jelly coat is a spongy matrix that lies at the outermost margin of the egg and consists of variably sized fibers. Sperm pass through this layer with their acrosomes intact and then go on to bind to the vitelline envelope. The vitelline envelope is a multilamellar fibrous layer that appears to trigger the acrosome reaction after sperm binding. Next, sperm release lysin from their acrosomal granules, a nonenzymatic protein that dissolves a hole in the vitelline envelope through which the sperm swims. Sperm then contact the egg surface coat, a network of uniformly sized filaments lying directly above the egg plasma membrane. This layer mediates attachment of sperm, via their acrosomal process, to the egg surface. © 1995 Wiley-Liss, Inc.     

Egg hull formation in Callochiton dentatus (Mollusca,Polyplacophora): the contribution of microapocrine secretion

Abstract. Egg hull formation during oogenesis in the chiton Callochiton dentatus does not follow the typical model of merocrine secretion involving Golgi vesicle exocytosis. Instead, microapocrine secretions are primarily responsible for egg hull formation, although merocrine secretions contribute “areolae” and the vitelline layer. Microapocrine secretion mechanisms are poorly understood, involving a different cellular pathway than is typical. Egg hull formation in C. dentatus involves two types of microapocrine secretions released by the oocyte, one of which is described here for the first time. The plesiomorphic jelly-like egg hull of chitons, as exemplified by the eggs of members of the basal order Lepidopleurida and present also in eggs of C. dentatus (Chitonida: Callichitonidae), may have evolved solely as an oocyte secretion, whereas members of some other families in the order Chitonida form their egg hulls with considerable secretory input from the follicle cells as well.     

Acrosome reaction in sperm of the toad,bufo bufo japonicus

The acrosome in the sperm of the toad, Bufo bufo japonicus, consists of a membrane-limited acrosomal cap and a fibrous perforatorium. When sperm are incubated with the oviducal pars recta extract (PRE) for 30–60 min, the outer acrosomal membrane fuses with the overlying plasma membrane at several points with concomitant loss of the contents of the acrosomal cap. The inner acrosomal membrane thus exposed fuses with the plasma membrane at the caudal end of the acrosomal region. This PRE-induced acrosome reaction is completely inhibited by soybean trypsin inhibitor. Sperm found in the innermost jelly layer of inseminated eggs possess an intact acrosome, but those either passing through the vitelline coat or localizing in the perivitelline space are acrosome-reacted in the same manner as when treated with PRE. These observations, combined with recent evidence showing involvement of the pars recta substance in fertilization, indicate that the acrosome reaction occurring in a fertilizing sperm at or near the surface of the vitelline coat is a response to a substance that is derived from the pars recta and deposited in the vitelline coat.     

Gamete interaction in the white sturgeon Acipenser transmontanus: a morphological and physiological review

Synopsis Sturgeon gametes differ from those of most fish in that the sperm possess acrosomes that undergo exocytosis and filament formation while the eggs possess numerous micropyles. Acipenser transmontanus eggs are encased by multilayered envelopes that consist of outer adhesive jelly coats and three structured layers interior to the jelly. The glycoprotein jelly layer only becomes adhesive upon exposure to freshwater. The layer interior to the jelly, layer 3, is the other carbohydrate-containing component of the egg envelope. This layer consists of a water-insoluble glycoprotein that, upon freshwater exposure, is hydrolyzed by a trypsinlike protease to yield a water-soluble, lower molecular weight carbohydrate-containing component. This component can be identified in the surrounding medium when unfertilized eggs are incubated in freshwater. This egg water component elicits acrosome reactions only in homologous sperm. The A. transmontanus sperm acrosome reaction is a Ca⁺⁺ and/or Mg⁺⁺ dependent event that includes the formation of a 10 μ long fertilization filament. A. transmontanus fertilization can occur at low sperm per egg ratios; however, crossfertilization of A. transmontanus eggs with lake sturgeon, A. fluvescens, sperm results in a very low number of fertilized eggs, even at high sperm per egg ratios. The morphological, physiological, and biochemical phenomenon reviewed in this paper are related to the environment in which they occur. Also, the possible role of the acrosome and the presence of numerous micropyles are discussed.     

皱纹盘鲍受精过程的电镜观察

本文用透射电镜观察了皱纹盘鲍的受精过程。鲍卵子的胶膜使精子活化,并诱发了顶体反应,卵黄膜使顶体反应达到高潮。精子入卵后,卵发生皮层反应并形成受精膜开 减数分裂。此外,还观察到鲍的多精入卵现象。     

Involvement of an acrosin-like enzyme in the acrosome reaction of sea urchin sperm

Extracts of the jelly coat of eggs of several marine invertebrates are known to induce in homologous sperm morphological changes known as the acrosome reaction. When sperm of the sea urchin Strongylocentrotus purpuratus are treated with low concentrations (0.2 μg fucose/ml) of egg jelly coat or 30 mM CaCl₂ in artificial seawater the acrosome reaction does not occur. However, either of these treatments causes the exposure of an acrosin-like enzyme to exogenous substrate and inhibitors. Subsequent addition of jelly coat to 3.7 μg fucose/ml to sperm in this “initial stage” induces the acrosome reaction (as judged by the appearance of an acrosomal filament). This concentration is also effective for untreated sperm. If inhibitors of the enzyme (diisopropylphosphofluoridate or phenylmethanesulfonyl fluoride) are added to sperm in the initial stage, no acrosomal filaments are observed when the high concentration of jelly coat is added. Whether other morphological changes occur in these sperm has not been examined. If phenylmethanesulfonyl fluoride is added 4 sec after the jelly coat, the acrosomal filaments are observed, but the sperm still fail to fertilize eggs. These results suggest a dual role for the acrosin-like enzyme(s), first in the mechanism of the acrosomal filament formation and then in a subsequent event in the fertilization process.     

THE SURFACE EVENTS AT FERTILIZATION OF THE SEA URCHIN EGG I. EVENTS ON THE SURFACE OF THE VITELLINE COAT1

Sperm-egg interaction during normal fertilization in the sea urchins, Strongylocentrotus intermedius and Hemicentrotus pulcherrimus, was studied by scanning and transmission electron microscopy. Several seconds after insemination, acrosome-reacted spermatozoa were found attached to the surface of the vitelline coat on each egg. Soon, several bulges of the vitelline coat appeared surrounding the fertilizing spermatozoon. These bulges then spread over the surface increasing in number, while they became fewer and disappeared around the sperm head. Thin sections of the bulging areas revealed discharging cortical granules. As the bulging vitelline coat was elevated, the sperm head was incorporated into the perivitelline space, passing through a small hole in the coat that resulted from penetration of the sperm acrosomal process immediately before fusion of the gametes. When the spermatozoon disappeared beneath the fertilization membrane, a hole was left in the membrane and the cortical reaction had finished on the other hemispheric surface. Mechanical removal of the membrane at that time exposed a spermatozoon protruding perpendicularly from the egg plasma membrane surface. The anterior tip of the sperm head was smoothly connected with the egg surface, and neither microvillous projections nor cytoplasmic covering of the egg cytoplasm could be found around the spermatozoon.     

The Interactions of Sea Urchin Gametes During Fertilization

The interactions between sea urchin spermatozoa and ova duringfertilization usually exhibit a high degree of species specificity.Under natural conditions and reasonable gamete concentrations,most interspecific inseminations fail to yield zygotes. Macromoleculeson the external surfaces of the apposing gametes must surelybe responsible for successful gamete recognition, adhesion andfusion. Species specific recognition between surface componentsof sperm and egg could occur during at least three events comprisingthe fertilization process. The first event is the interactionof the sperm plasma membrane with the egg jelly coat. This inducesthe sperm acrosome reaction resulting in the exocytosis of the"bindin" -containing acrosome granule and also the extrusionof the acrosome process from the anterior tip of the sperm.The second event is the adhesion of the bindin-coated acrosomeprocess to glycoprotein "bindin receptors" on the external surfaceof the egg vitelline layer. The third event is the penetrationof the vitelline layer and the fusion of sperm and egg plasmamembranes. With the isolations of the component of egg jellywhich induces the acrosome reaction, sperm bindin from the acrosomevesicle and the egg surface bindin receptor from the vitellinelayer, there is hope of discovering the molecular basis of thismost interesting intercellular interaction which results inthe activation of embryonic development.     

Helper Function of Follicle Cells in Sperm-Egg Interactions of the Ascidian, Ciona intestinalis

Studies were made on the involvement in sperm-egg interactions of follicle cells of Ciona intestinalis , which are tall, vacuolated cells attached to the outer surface of the egg vitelline coat. The basal surface of the follicle cells is polygonal. The borders between cells could easily be observed by the binding of fluorescent SBA (soy bean agglutinin), a lectin recognizing N-acetylgalactosamine (GaINAc) residues. At fertilization many spermatozoa aggregate along these polygonal borders of cells on the vitelline coat, through which they entered the perivitelline space. The removal of follicle cells was sometimes associated with loss of SBA-binding sites, and in such cases the sperm did not show a hexagonal pattern of aggregation, but became dispersed all over the vitelline coat. Removal of the follicle sometimes delayed fertilization. Examination of sections of gametes stained with DAPI, a fluorescent dye staining DNA, showed that removal of the follicle reduced the number of spermatozoa bound to the vitelline coat and, more especially, the number of spermatozoa penetrating through the vitelline coat. The blockage of GalNAc residues on the vitelline coat with SBA did not appreciably affect the time course of fertilization or the number of sperm associated with eggs. These findings are discussed in relation to the role of follicle cells in facilitating sperm aggregation on the vitelline coat and their penetration through it.     

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.     

The role of jelly coats in sperm-egg encounters, fertilization success, and selection on egg size in broadcast spawners

Sperm limitation may be an important selective force influencing gamete traits such as egg size. The relatively inexpensive extracellular structures surrounding many marine invertebrate eggs might serve to enhance collision rates without the added cost of increasing the egg cell. However, despite decades of research, the effects of extracellular structures on fertilization have not been conclusively documented. Here, using the sea urchin Lytechinus variegatus, we remove jelly coats from eggs, and we quantify sperm collisions to eggs with jelly coats, eggs without jelly coats, and inert plastic beads. We also quantify fertilization success in both egg treatment groups. We find that sperm-egg collision rates increase as a function of sperm concentration and target size and that sperm are not chemotactically attracted to eggs nor to jelly coats in this species. In fertilization assays, the presence of the jelly coat is correlated with a significant but smaller-than-expected improvement in fertilization success. A pair of optimality models predict that, despite the large difference in the energetic value of egg contents and jelly material, the presence of the jelly coat does not diminish selection for larger egg cell size when sperm are limiting.     

Cross fertilization between sea urchin eggs and oyster spermatozoa

Interphylum crossing was examined between sea urchin eggs (Temnopleurus hardwicki) and oyster sperm (Crassostrea gigas). The eggs could receive the spermatozoa with or without cortical change. The fertilized eggs that elevated the fertilization envelope began their embryogenesis. Electron microscopy revealed that oyster spermatozoa underwent acrosome reaction on the sea urchin vitelline coat, and their acrosomal membrane fused with the egg plasma membrane after the appearance of an intricate membranous structure in the boundary between the acrosomal process and the egg cytoplasm. Oyster spermatozoa penetrated sometimes into sea urchin eggs without stimulating cortical granule discharge and consequently without fertilization envelope formation. The organelles derived from oyster spermatozoa seemed to be functionally inactive in the eggs whose cortex remained unchanged.     

The ascidian egg envelope in fertilization: structural and molecular features

In this report, unpublished and recent findings concerning the structure and function of the ascidian egg coat are compiled in context with fertilization. In the initial stage of ascidian fertilization, sperm interact with a complex egg investment that consists of a layer of follicle cells attached to an acellular vitelline coat. Increasing evidence exists that ascidian sperm are activated at their encounter with the follicle cells. The molecular basis of sperm-follicle cell interactions is discussed in context with sperm binding, membrane proteins and sperm bound glycosidase. The model that suggests a block to polyspermy established by glycosidase released from the follicle cells on fertilization is evaluated and compared with assured facts. Although a number of questions remain to be answered, our recent findings that a cloned beta-hexosaminidase from P. mammillata binds exclusively to the follicle cells of unfertilized but not fertilized eggs, indicates that the follicle cells participate in the block to polyspermy. A dual function, mediating sperm activation and a block to polyspermy attributes to the ascidian follicle cells a key position in fertilization.     

Ultrastructural aspects of the surface coatings of eggs and larvae of the starfish,Pisaster ochraceus,revealed by alcian blue

Eggs of the asteroid Pisaster ochraceus demonstrate cortical granules, a thick vitelline membrane, and a poorly stained jelly coat similar to that seen on the eggs of other echinoderms. When fixed in the presence of alcian blue the jelly coat is seen to be made up of three regions, an inner layer consisting of a meshwork of fibres, a middle layer of thicker fibres, and a dense outer layer. At fertilization the cortical granules release their contents into the potential space between the vitelline layers and a low fertilization membrane consisting of the vitelline layer and a dense component of the corticle granule is formed. Initially the remaining contents of the corticle granules form an amorphous hyaline layer that fills the space between the plasma membrane and the fertilization membrane. At hatching a distinct hyaline layer is present. It persists at least to the bipinnaria stage and consists of four distinct layers. A similar layer is also located over much of the early embryonic endoderm but is lost from the regions involved in the formation of the mesenchyme cells, coelom, and mouth just before these events take place. Numerous large clear vesicles are located in the apex of all cells associated with a hyaline layer. Where the hyaline layer is lacking, only scattered vesicles are present suggesting that the vesicles may be involved in maintenance of the layer. Attempts to identify elements of the hyaline layer by immunofluorescence demonstrated that it appears to bind both antisera and control sera in a nonspecific manner.     

Ascidian sperm lysin system

Fertilization is a precisely controlled process involving many gamete molecules in sperm binding to and penetration through the extracellular matrix of the egg. After sperm bind to the extracellular matrix (vitelline coat), they undergo the acrosome reaction which exposes and partially releases a lytic agent called "lysin" to digest the vitelline coat for the sperm penetration. The vitelline coat sperm lysin is generally a protease in deuterostomes. The molecular mechanism of the actual degradation of the vitelline coat, however, remains poorly understood. In order to understand the lysin system, we have been studying the fertilization mechanism in ascidians (Urochordata) because we can obtain large quantities of gametes which are readily fertilized in the laboratory. Whereas ascidians are hermaphrodites, which release sperm and eggs simultaneously, many ascidians, including Halocynthia roretzi, are strictly self-sterile. Therefore, after sperm recognize the vitelline coat as nonself, the sperm lysin system is thought to be activated. We revealed that two sperm trypsin-like proteases, acrosin and spermosin, the latter of which is a novel sperm protease with thrombin-like substrate specificity, are essential for fertilization in H. roretzi. These molecules contain motifs involved in binding to the vitelline coat. We found that the proteasome rather than trypsin-like proteases has a direct lytic activity toward the vitelline coat. The target for the ascidian lysin was found to be a 70-kDa vitelline coat component called HrVC70, which is made up of 12 EGF-like repeats. In addition to the proteasome system, the ubiquitination system toward the HrVC70 was found to be necessary for ascidian fertilization. In this review, I describe recent progress on the structures and roles in fertilization of the two trypsin-like proteases, acrosin and spermosin, and also on the novel extracellular ubiquitin-proteasome system, which plays an essential role in the degradation of the ascidian vitelline coat.     

Studies on the interactions of sperm with the surface of the sea urchin egg

We have examined the relationship between sperm adhesion and fertilization in the cross species insemination of Arbacia punctulata eggs by Strongylocentrotus purpuratus sperm. As previously reported (Kinsey et al., 1980) the addition of S. purpuratus egg jelly results in induction of the acrosome reaction in sperm and significant numbers of S. purpuratus sperm adhere to A. punctulata eggs. However, in the absence of S. purpuratus egg jelly, S. purpuratus sperm fail to bind to A. punctulata eggs. Although at least 200 S. purpuratus sperm bind to an A. punctulata egg in the presence of S. purpuratus jelly, less than 8% of the eggs are fertilized. The adhesion of S. purpuratus sperm meets the same functional criteria as homologous A. punctulata sperm-egg adhesion. Electron microscopy shows that S. purpuratus sperm that have undergone the acrosome reaction adhere to A. punctulata eggs by their bindin-coated acrosomal process in a manner that is morphologically identical to that observed with homologous A. punctulata sperm. We have also compared the ability of S. purpuratus and A. punctulata sperm to fuse and fertilize with A. punctulata eggs after removal of the vitelline layer. Using high levels of sperm of either species, heterologous as well as homologous fertilization is readily detectable. Under these conditions, where stable binding is not demonstrable, there is no difference in the ability of S. purpuratus and A. punctulata sperm to fertilize A. punctulata eggs. These observations suggest that the failure of S. purpuratus sperm to fertilize A. punctulata eggs under normal conditions may be due to their inability to penetrate the vitelline layer so that they can fuse with the egg plasma membrane. In relation to the possible mechanism of vitelline layer penetration, we have also investigated the mode of action of chymostatin, an inhibitor of chymotrypsin that has been reported to inhibit fertilization of sea urchin eggs (Hoshi et al., 1979). Our findings suggest that the fertilization inhibitory activity of chymostatin is not related to its antichymotrypsin activity. Rather, it appears that this inhibition is due to the induction of an abnormal acrosome reaction in sperm that precludes formation of the acrosome process.     

Xenopus laevis egg jelly contains small proteins that are essential to fertilization.

The eggs of Xenopus laevis are surrounded by investment layers of egg jelly that interact with the sperm immediately prior to fertilization. Components of these egg jelly layers are necessary for the fertilization of the egg by incoming sperm. Eggs which are stripped of their jelly layers are refractile to fertilization by sperm, but the addition of solubilized jelly promotes fertilization. We have shown previously that the egg jelly layers are composed of a fibrous network of glycoconjugates which loosely hold smaller diffusible components. Extracts of these diffusible components were prepared by incubation of freshly ovulated eggs in high-salt buffers for 12 h at 4 degrees C. This diffusible component extract, when incubated with sperm, promoted the sperm's ability to fertilize dejellied eggs in a dose-dependent manner. In contrast, the high-molecular-weight "structural" glycoconjugates of jelly that remain after extraction of the diffusible components did not increase fertilization efficiency of dejellied eggs nor did nonspecific proteins, carbohydrate polymers, or organic polymers. The diffusible components, analyzed by SDS-PAGE, consisted of a mixture of proteins from 4 to 180 kDa. The protein responsible for fertilization rescue appeared to be <50 kDa and appeared to self-aggregate or to bind to larger proteins. This protein component was required during sperm binding to the egg, its action required an intact egg vitelline envelope, and its action was independent of large soluble polymers such as Ficoll.     

Egg jelly of the newt, Cynops pyrrhogaster contains a factor essential for sperm binding to the vitelline envelope

The acrosome reaction of newt sperm is induced at the surface of egg jelly and the acrosome-reacted sperm acquire the ability to bind to the vitelline envelope. However, because the substance that induces the acrosome reaction has not been identified, the mechanism by which the acrosome-reacted sperm bind to the vitelline envelope remains unclear. We found here that a Dolichos biforus agglutinin (DBA) specifically mimicked the acrosome reaction immediately upon its addition in the presence of milimolar level Ca(2+). Fluorescein isothiocyanate-labeled DBA bound specifically to the acrosomal cap of the intact sperm in the presence of a Ca(2+)-chelating agent, EDTA, suggesting that binding of DBA to the native receptor for the egg jelly substance on the acrosomal region took the place of the egg jelly substance-induced acrosome reaction. In contrast, the sperm that had been acrosome reacted by DBA treatment did not bind to the vitelline envelope of the egg whose jelly layers were removed. Subsequent addition of jelly extract caused the sperm binding to vitelline envelope, indicating that the egg jelly of the newt contains substances that are involved in not only inducing the acrosome reaction but also binding to the vitelline envelope. This is the first demonstration of the involvement of egg jelly substance in the binding of acrosome-reacted sperm to the vitelline envelope.