Morphological features of the surface of the sea urchin (Arbacia punctulata) egg: Oolemma-cortical granule association

Scanning microscopy and transmission electron microscopy of sectioned specimens and freeze-fracture replicas revealed the presence of slightly elevated regions, approximately one-fourth to one-half the diameter of microvilli, which were situated along the surface of unfertilized Arbacia eggs. These modifications of the surface of the egg were observed in areas occupied by cortical granules and were greatly reduced in number following the cortical granule reaction. Few such modifications were present in immature and urethane-treated ova, in which cortical granules were located in regions of the egg other than the cortex. Freeze-fracture replicas of unfertilized eggs revealed a significantly higher density of intramembranous particles within the plasmalemma when compared to replicas of the membrane surrounding cortical granules. Areas characteristic of the cortical granule membrane, i.e., sparsely laden with particles, were not observed within the plasmalemma of the fertilized egg. Hence, following its fusion with the egg plasma membrane there is a dramatic reorganization in particle distribution of the membrane derived from cortical granules.     

Unfertilized sea urchin eggs contain a discrete cortical shell of actin that is subdivided into two organizational states

Changes in the distribution and organizational state of actin in the cortex of echinoderm eggs are believed to be important events following fertilization. To examine the initial distribution and form of actin in unfertilized eggs, we have adapted immunogold-labeling procedures for use with eggs of Strongylocentrotus purpuratus. Using these procedures, as well as fluorescence microscopy, we have revealed a discrete 1-micron-thick concentrated shell of actin in the unfertilized egg cortex. This actin is located in the short surface projections of unfertilized eggs and around the cortical granules in a manner that suggests it is associated with the cortical granule surface. The actin in the short surface projections appears to be organized into filaments. However, most if not all of the actin surrounding the cortical granules is organized in a form that does not bind phalloidin, even though it is accessible to actin antibody. The lack of phalloidin binding is consistent with either the presence of nonfilamentous actin associated with the cortical granules or the masking of actin-filament phalloidin-binding sites by some cellular actin-binding component. In addition to the concentrated shell of actin found in the cortex, actin was also found to be concentrated in the nuclei of unfertilized eggs.     

Early Events in Anuran Amphibian Fertilization: An Ultrastructural Study of Changes Occurring in the Course of Monospermic Fertilization and Artificial Activation

In unfertilized frog eggs, the plasma membrane displays an animal vegetal polarity characterized by the presence of short microvilli in the vegetal hemisphere and long microvilli or ridge-like protrusions in the animal hemisphere. The densities of microvilli are similar in the two hemispheres.
The fertilizing sperm always fuses with the animal hemisphere of the egg and induces a wave of exocytosis of cortical granules from its site of penetration. Similar spreading of the cortical reaction is seen on activation by pricking the egg cortex. The integration of the cortical granule membrane with the plasma membrane is rapidly followed by elongation of microvilli, which is progressively realized all over the egg surface from the site of sperm entry or the site of pricking. At this time, the length and shape of the microvilli in the animal and vegetal hemispheres are similar and their densities are the same as in unfertilized eggs.
A "smoothing" wave can be seen on the living egg, 40–60 seconds after pricking, starting around the site of pricking. This wave of microvillar elongation is accompanied by changes in intensity of diffracted light spots observed at the surface of the egg. This pattern might result from rapid and progressive thickening of the cortex that would drive pigment granules into the cytoplasm. The Brownian movement of these granules is thought to be responsible for the observed diffracted light spots.
Electrical stimulus or the ionophore A23187 induced activation reactions similar to those triggered by the sperm or by pricking, except that the cortical reaction began simultaneously in several distinct sites of the cortex.     

Cortical granules remaining after fertilization in Xenopus laevis

Eggs of Xenopus laevis were examined in an electron microscope at unfertilized egg, 1-cell, 2-cell, 32-cell, and blastula stages. Granules closely resembling cortical granules were observed within the “germinal plasm” as well as in the peripheral cytoplasm of all the eggs examined. A staining method was developed that makes it easier to count cortical granules in thick Epon sections. Light and electron microscope examinations revealed that granules remaining after fertilization possessed morphological characteristics wholly consistent with those of cortical granules of unfertilized eggs. These granules were confirmed to be true cortical granules.     

A marker of animal-vegetal polarity in the egg of the sea urchin Paracentrotus lividus. The pigment band

We have examined the subequatorial accumulation of pigment granules (the so-called 'pigment band') in the egg of the sea urchin Paracentrotus lividus, which constitutes an unambiguous marker of animal-vegetal polarity. Most of the reddish pigment granules are situated at the periphery of the egg. They exhibit occasional saltatory movements and can aggregate into large patches. Pigment granules are retained as a band in the isolated cortex when the egg surface complex is isolated by shearing eggs attached to polylysine-coated surfaces with calcium-free isotonic solutions. Pigment granules remain as the main vesicular component of fertilized egg cortices or of unfertilized egg cortices perfused with calcium to provoke cortical granule exocytosis. They may be anchored to the isolated cortex through associations with the plasma membrane and with an extensive subsurface network of rough endoplasmic reticulum (rough ER). Pigment granules contain antimonate-precipitable calcium and, in this respect and many others, resemble acidic vesicles recently identified in the cortex of unpigmented sea urchin eggs. We discuss the similarities observed between granules and acidic vesicles in various urchin egg species and their possible functions.     

Immunocytochemical evidence suggesting heterogeneity in the population of sea urchin egg cortical granules

Unfertilized eggs of many species of animals contain cortical granules, which are specialized secretory granules that upon fertilization release their contents from the egg. The unfertilized eggs of the sea urchin, Strongylocentrotus purpuratus, contain cortical granules that all display an identical and elaborate internal morphology. It has been assumed that they all contain identical components. In this report we present immunocytochemical data which indicate that the cortical granule population of S. purpuratus eggs is heterogeneous. Two monoclonal antibodies are shown to react to the spiral lamellae region of approximately 20% of the cortical granules, implying that the contents of the reactive granules differ from the contents of the majority of the population. An egg protein of greater than 320 kDa is recognized by the antibody. These antibodies also stain a 130-kDa protein expressed on the surface of primary mesenchyme cells in later development. Both antibodies recognize a post-translational modification of this protein. This suggests that an antigenically similar epitope is present both on the 130-kDa primary mesenchyme cell-specific protein and in the cortical granules. To determine if the primary mesenchyme and cortical granule proteins are related, a fusion protein antibody specific for a region of the 130-kDa protein was used to stain unfertilized eggs. This antibody did not stain cortical granules. Thus, 20% of the cortical granules contain a molecule that has an epitope antigenically similar to the post-translational modification recognized in primary mesenchyme cells by the monoclonal antibodies.     

The ultrastructure of the sea urchin egg cortex isolated before and after fertilization

The three-dimensional organization of cortices isolated from unfertilized and fertilized Strongylocentrotus purpuratus eggs has been examined by several techniques of light and electron microscopy. It has been found that when moderate shear forces are used, the isolated unfertilized egg cortex, in addition to cortical granules, contains acidic vesicles and an elaborate network of rough endoplasmic reticulum. This network provides a physical link between the cell surface and several kinds of cytoplasmic organelles (mitochondria, yolk granules, acidic vesicles) which are retained as part of the isolated cortex when gentle shear forces are applied. Furthermore a good visualization of actin in the cortex is provided: it is present as short filaments and mostly within the stubby microvilli of the egg. Finally, it has been noted that plaques exist on the inside face of the plasma membrane ready to assemble into typical clathrin coats that prefigure the burst of coated vesicle endocytosis that takes place after fertilization. The cortex isolated soon after fertilization is shown to contain coated pits and a scaffolding of filaments (mostly actin) in which many acidic vesicles are embedded.     

Cortical granule exocytosis in hamster eggs requires microfilaments

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

Induction of the cortical reaction in isolated sea urchin egg cortices: effects of Ca2+ and ionophore A23187

The cortical reaction in isolated sea urchin (Strongylocentrotus purpuratus) egg cortices has been monitored with phase-contrast video microscopy. It was confirmed that the cortical reaction is induced by exposure to Ca2+. No induction was observed after exposure to the Ca2+-ionophore A23187, although the cortices remain sensitive to a subsequent exposure to Ca2+, and the cortical reaction in unfertilized eggs suspended in cortex isolation medium remains inducible by exposure to A23187. These results imply: (1) that A23187 does not induce the cortical reaction directly; (2) that the release of intracellular Ca2+, through which A23187 induces the cortical reaction, is not from storage sites localized entirely in the cortex; and (3) that intracellular storage sites for the Ca2+ involved in the cortical reaction are also present outside the cortex.     

Ultrastructural study of the mature egg of Tethya citrina sarà and melone (porifera,demospongiae)

Tethya citrina is an oviparous demosponge in which eggs are distributed in clumps within the choanosome. The cytoplasm of the mature egg presents a peripheral cortex consisting of a slightly granular layer sandwiched between two densely granular, vesiculated ones. The cortex probably has a specialized, trophic function. Mesohyl bacteria are phagocyted at the egg surface, included in vacuoles, and transferred across the cortical sheath toward the inner cytoplasm. The region of the egg extending between the cortex and the nucleus shows a lacunary system mostly developed beneath the cortical envelope. The noncortical cytoplasm also contains lipid droplets, dense rodlike bodies, and phagosomelike granules. Most of the latter are probably autophagosomes, forming lacunae and supporting autosynthetic vitellogenesis. Rodlike inclusions are probably proteinaceous; they likely originate within the phagosomes and represent the actual yolk material.     

The cortical actin-membrane cytoskeleton of unfertilized sea urchin eggs: analysis of the spatial organization and relationship of filamentous actin, nonfilamentous actin, and egg spectrin

Whole mounts, cryosections, and isolated cortices of unfertilized sea urchin eggs were probed with fluorescent phalloidin, anti-actin and anti-egg spectrin antibodies to investigate the organizational state of the cortically associated actin-membrane cytoskeleton. Filamentous actin and egg spectrin were localized to the plasma membrane, within microvillar and nonmicrovillar domains. The nonmicrovillar filamentous actin was located immediately subjacent to the microvilli forming an extensive interconnecting network along the inner surface of the plasma membrane. The organization of this filamentous actin network precisely correlated with the positioning of the underlying cortical granules. The cortical cytoplasm did not contain any detectable filamentous actin, but instead contained a sequestered domain of nonfilamentous actin. Spectrin was localized to the cytoplasmic surface of the plasma membrane with concentrated foci co-localized with the filamentous actin present in microvilli. Spectrin was also observed to coat the surfaces of cortical granules as well as other populations of intracellular vesicles. On the basis of light microscopic morphology, intracellular distribution, and co-isolation with the egg cortex, some of these spectrin-coated organelles represent acidic vesicles. Identification of an elaborate organization of inter-related domains of actin (filamentous and nonfilamentous) and spectrin forming the cortical membrane cytoskeleton provides insight into the fundamental mechanisms for early membrane restructuring during embryogenesis. Additionally, the localization of spectrin to the surface of intracellular vesicles is indicative of its newly identified functional roles in membrane trafficking, membrane biogenesis and cellular differentiation.     

Sea urchin egg hyaline layer: evidence for the localization of hyalin on the unfertilized egg surface

The sea urchin embryo hyaline layer is an extracellular investment which develops within 20 min postinsemination of Strongylocentrotus purpuratus eggs and contains a single calcium-precipitable subunit termed hyalin. Other ultrastructural and biochemical studies have suggested that hyalin is localized in the cortical granules. We have examined the hypothesis that hyalin is a cell surface protein of the unfertilized egg using vectorial lactoperoxidase-catalyzed radioiodination. Extracts of labeled unfertilized eggs contained several labeled proteins, one of which was electrophoretically indistinguishable from authentic hyalin isolated by each of three different procedures. Pronase digestion of labeled unfertilized eggs removed 75% of the label, but the labeled hyalin-like molecule was still present in whole cell extracts. Upon insemination, pronase-digested, labeled eggs formed an apparently normal hyaline layer and whole cell extracts contained the labeled hyalin-like molecule. Denuded, labeled eggs were inseminated and the hyaline layer was selectively solubilized in calcium- and magnesium-free artificial seawater. Labeled hyalin was purified from this crude hyalin preparation to constant specific radioactivity and apparent homogeneity as shown by gel electrophoresis. These data strongly suggest that hyalin or a precursor is a cell surface protein of the unfertilized sea urchin egg.     

Accumulation of fluorescently labeled actin in the cortical layer in sea urchin eggs after fertilization

Actin from sea urchin eggs was fluorescently labeled with fluorescein isothiocyanate (FITC), N-(7-dimethylamino-4-methylcoumarinyl)-maleimide (DACM), or 5-iodoacetamidofluorescein (IAF) and microinjected into sea urchin eggs and oocytes. It distributed evenly in the cytoplasm of unfertilized eggs. Upon fertilization, actin accumulated first around the sperm binding site and, soon afterwards, in the fertilization cone. The accumulation propagated all over the cortex after a latent period of 10-20 sec. In the case of Clypeaster japonicus eggs, propagation of the accumulation coincided with a shape change in the egg, suggesting that the accumulated actin in the cortex generates forces. FITC-actin was incorporated into microvilli and retained in the cortex after cleavage. On the other hand, DACM- or IAF-actin was not incorporated into microvilli and was dispersed from the cortex by cleavage. These differences may be attributable to differences in the properties of the actins labeled at different sites. After photobleaching by laser light irradiation, FITC- or IAF-actin redistributed in the cortex of fertilized egg as quickly as it did before fertilization. When an unfertilized egg was injected with both actin and a calcium buffer (intracellular free Ca2+ concentration 9 microM), the actin accumulation was similar to that during fertilization but without the latent period. This suggests that the accumulation depended on the increase in the intracellular free Ca2+ concentration. When the unfertilized egg was injected with 0.2 M EGTA after injection of labeled actin and then inseminated, it accumulated only in the protrusion of cytoplasm where the sperm had entered, and fertilization was not completed. In immature oocytes, the accumulation was observed in the cortical region, including the huge protrusion of the cytoplasm where the sperm had entered. These results suggest that actin accumulation in the sperm binding site plays an important role in the sperm reception mechanism of the egg.     

Filipin/sterol complexes in fertilized and unfertilized sea urchin egg membranes

Sea urchin (Arbacia punctulata) eggs and zygotes were treated with filipin in an effort to examine changes in membrane sterols at fertilization. The plasma membrane of treated unfertilized eggs possessed numerous filipin/sterol complexes, while fewer complexes were associated with membranes delimiting cortical granules, demonstrating that the plasmalemma is relatively rich in β-hydroxysterols in comparison to cortical granule membrane. Following fusion with the plasmalemma, membrane formerly delimiting cortical granules underwent a dramatic alteration in sterol composition, as indicated by a rapid increase in the number of filipin/sterol complexes. In contrast, portions of the zygote plasma membrane, derived from the plasmalemma of the unfertilized egg, displayed little or no change in filipin/sterol composition. Other than regions of the plasma membrane engaged in endocytosis, the plasmalemma of the zygote possessed a homogeneous distribution of filipin/sterol complexes and appeared similar to that of the unfertilized egg. These results demonstrate that following its fusion with the egg plasmalemma, membranes, formerly delimiting cortical granules, undergo a dramatic alteration in sterol composition. Changes in the localization of filipin/sterol complexes are discussed in reference to alterations in egg plasmalemmal function at fertilization.     

The relations of the plasma membrane,vitelline membrane,and jelly in the egg of Nereis limbata

1. The problem of the relation of the plasma membrane to the extraneous coats and cortex of the Nereis egg is discussed in the light of the observations of Lillie, Chambers, and Novikoff. 2. Evidence obtained from experiments with the centrifuge, and by treating eggs with alkaline sodium chloride, indicates that the plasma membrane of the unfertilized egg is external to the jelly precursor granules of the cortex. 3. Experiments with alkaline sodium chloride indicate that the perivitelline space of the fertilized egg is extraovular after jelly extrusion is complete. 4. The cortical behavior (membrane elevation) of the Nereis egg in alkaline sodium chloride and the cortical response (jelly extrusion) following activation of the egg in normal fertilization or parthenogenesis are attributed largely to the properties of the jelly, and presumably, to its reactions with calcium and hydroxyl ions.     

Fertilization alters the orientation of pigment granule saltations in Arbacia eggs.

Unfertilized eggs of the sea urchin Arbacia punctulata contain pigment granules distributed throughout their cytoplasm. During the first 15 minutes after fertilization, these vesicles move out to the cortex where they become firmly anchored. We have used time-lapse video differential interference microscopy to analyze the motility of these organelles in unfertilized and fertilized Arbacia eggs. Pigment granules exhibit saltatory movement in both unfertilized and fertilized eggs. Quantitation of vesicle saltations before and after fertilization demonstrates that while there is no significant difference in the speed or path-length of vesicle movement, there is a dramatic change in the orientation of these saltations. Saltations in the unfertilized egg are very non-radial and are as likely to be directed toward the cortex as away. In contrast, saltations in the fertilized egg are more radially oriented and more likely to be cortically directed. This transition must reflect underlying changes in the cellular structures necessary for pigment granule saltations. The change in the orientation of pigment granule saltations following fertilization requires both a transient increase in the cytoplasmic concentration of Ca2+ and an elevation of cytoplasmic pH. Similarly, the ability of pigment granules to adhere to the cortex requires both the transient elevation of cytoplasmic Ca2+ and the alkalinization of the cytoplasm. As the reorganization of cortical actin at fertilization is regulated by these ionic fluxes, and both movement and adhesion are sensitive to cytochalasins, we hypothesize that the alterations in directed motility and adhesion reflect underlying changes in the actin cytoskeleton.     

Immunocytochemical localization of the 35-kDa sea urchin egg trypsin-like protease and its effects upon the egg surface

Trypsin-like protease in sea urchin eggs is thought to reside in cortical granules since it is secreted at fertilization and has been isolated with cortical granule fractions from unfertilized eggs. A 35-kDa serine protease has been purified from Strongylocentrotus purpuratus eggs by soybean trypsin inhibitor-affinity chromatography. For this report the protease was localized by immunocytochemistry before and after fertilization, and its potential biological activity was examined by application of the isolated enzyme to the unfertilized egg surface. The protease was localized on sections by immunofluorescence and immunoelectron microscopy, and was found to reside in the spiral lamellae of S. purpuratus cortical granules and in the electron-dense stellate core of Arbacia punctulata granules. At fertilization the enzyme is secreted into the perivitelline space and accumulates only very briefly between the hyaline layer and the nascent fertilization envelope. Shortly thereafter the enzyme is lost from the perivitelline space and immunological reactivity is no longer associated with the egg surface. The 35-kDa cortical granule protease has vitelline delaminase activity but does not appear to destroy vitelline envelope sperm receptors as judged by the fertility of protease-treated eggs.     

Fine structural investigation of the insemination response in Urechis caupo.

Electron microscopy of Urechis eggs revealed no changes in the egg cortex or investing layers until 4 min after insemination at 172C. From 4 min to about 30 min after insemination the surface coat gradually elevates, widening the perivitelline space. During this period, microvilli separate from the tightly woven layer of the surface coat, fibrogranular aggregates resembling surface coat material appear in the perivitelline space, and some cortical granules are extruded from the egg cortex into cytoplasmic processes. There is no statistically significant decrease in the number of cortical granules remaining in the egg surface during the first 95 min after insemination; many cortical granules persist in postgastrulae. Most of the cortical granules remain in fertilized eggs after removal of the surface coat with glucose-EGTA. We found no morphological correlates of the polyspermy block which is established within 1 min of insemination (Paul, 1975).     

Changes in intracellular acidic compartments in sea urchin eggs after activation

Acridine orange (AO) was used as a vital probe for looking at acidic intracellular compartments in sea urchin eggs. This weak base is concentrated by acidic compartments, shifting its fluorescence from green to red due to the formation of dye aggregates. Fertilization or parthenogenetic activation with ionophore A23187 resulted in the appearance of orange fluorescent granules of sizes ranging from 1 to 2 microns at the cortical region of the egg. In one species of sea urchin (Lytechinus pictus), these granules migrate inward before cell division and associate with the forming mitotic apparatus. Treatments that discharge the transmembrane pH gradient (NH4Cl, nigericin, monensin, and acidic external pH) eliminate the orange fluorescence, indicating they are acidic compartments. Spectrofluorimetric measurements showed a decrease in monomer fluorescence accompanying egg activation which is reversible by similar treatments as seen with the fluorescence microscopic observations. Stratified eggs which were subsequently fertilized had acidic granules concentrated at the centripetal pole. This allowed the electron microscopic identification of the granules and showed they are present in the unfertilized egg, although not able to concentrate the AO. Activation of eggs in the absence of Na+ prevented the cytoplasmic alkalinization and also inhibited the appearance of acidic granules. The results indicate that the internal pH rises after egg activation triggers the acidification of these granules. Their possible functions, as in intracellular pH regulation, are discussed.     

Effects of A23187 upon cortical granule exocytosis in eggs of Brachydanio

Summary The effects of the divalent ionophore A23187 upon unfertilized eggs of the freshwater teleost fish, Brachydanio rerio, have been examined by light, scanning (SEM) and transmission (TEM) electron microscopy. Treatment of eggs with micromolar amounts (1 M, 10 M) of A23187 triggers cortical granule exocytosis and elevation of the chorion. However, the exocytosis of cortical granules in ionophore-activated eggs is explosive and occurs more rapidly than in eggs naturally activated in conditioned tap water. Eggs treated with A23187 in a medium lacking extra-cellular calcium also show cortical granule exocytosis, suggesting strongly that egg activation in Brachydanio results from release of calcium primarily from intracellular stores; however, there is a distinct delay in the onset of cortical granule breakdown. Unfertilized eggs exposed to A23187 for 1–5 min show noticeable disturbances in cell surface topography, including loss of microplicae and the appearance of prominent membrane-limited blebs.To determine if cortical granule exocytosis is self-propagating once initiated, A23187 was applied to a localized portion of the unfertilized egg surface, using either a G-50 sephadex gel bead or a 1 mm glass capillary tube. Eggs placed in continuous contact for 15 min with a bead coated with 10 M A23187 show neither exocytosis of cortical granules nor elevation of the chorion. All eggs exhibit exocytosis when positioned against a glass rod coated with 1 M A23187. The cortical granule breakdown is partial and restricted to less than 50% of the egg surface in most cells. The complete exocytosis of cortical granules in the zebra danio egg appears to require the stimulation and release of calcium from multiple sites over the cortex.