ELECTRON MICROSCOPY OF GROWING OOCYTES OF RANA PIPIENS

1. In the cytoplasm of oocytes of stage Y₀, prior to the appearance of yolk, one observes a few scattered profiles of endoplasmic reticulum and numerous filamentous mitochondria, usually distributed at random but sometimes clustered. As the nuclear membrane begins to bulge outward, small granules and short rods appear in the perinuclear cytoplasm and endoplasmic reticulum becomes more prominent throughout the cytoplasm. 2. Coincident with the appearance of the first yolk platelets, which are deposited in a narrow peripheral ring within the endoplasm at stage Y₁, protoplasmic processes, the microvilli, push out all over the surface of the oocyte. At the same time follicle cells pull away but remain attached to the oocyte at some points through finger-like processes which interdigitate with neighboring microvilli. It is estimated that the microvilli increase the absorptive area of the surface to about thirty-five times that of a simple sphere. Just beneath the microvillous layer is the basal protoplasm of the cortex, now containing tiny granules probably synthesized from newly absorbed raw materials. Cortical granules appear and become aligned below the basal layer on the external border of the endoplasm. Both the cortical granules and the yolk platelets measure up to 1 µ in diameter at this stage. 3. By stage Y₃ (yolk filling peripheral three-fourths of cytoplasm), the basal layer of the cortex is folded so that it appears in section as alternating ridges and valleys. The microvilli now extend from the summits of the cortical ridges. Small, ring-shaped granules are abundant in the cortex. Cortical granules have increased to 2 µ in diameter. 4. Yolk platelets continue to be synthesized around the cortical granules and in the subjacent endoplasm. The largest platelets measured in the interior cytoplasm at stage Y₄ (cytoplasm filled with yolk) were 3.7 µ wide by 5.8 µ long. Pigment granules increase in size from 0.15 µ in diameter at stage Y₃ to 0.30 µ in diameter at stage Y₄.     

Oogenesis in the leech Glossiphonia heteroclita (Annelida, Hirudinea, Glossiphoniidae) II. Vitellogenesis, follicle cell structure and egg shell formation

By the end of previtellogenesis, the oocytes of Glossiphonia heteroclita gradually protrude into the ovary cavity. As a result they lose contact with the ovary cord (which begins to degenerate) and float freely within the hemocoelomic fluid. The oocyte's ooplasm is rich in numerous well-developed Golgi complexes showing high secretory activity, normal and transforming mitochondria, cisternae of rER and vast amounts of ribosomes. The transforming mitochondria become small lipid droplets as vitellogenesis progresses. The oolemma forms microvilli, numerous coated pits and vesicles occur at the base of the microvilli, and the first yolk spheres appear in the peripheral ooplasm. A mixed mechanism of vitellogenesis is suggested. The eggs are covered by a thin vitelline envelope with microvilli projecting through it. The envelope is formed by the oocyte. The vitelline envelope is produced by exocytosis of vesicles containing two kinds of material, one of which is electron-dense and seems not to participate in envelope formation. The cortical ooplasm of fully grown oocytes contains many cytoskeletal elements (F-actin) and numerous membrane-bound vesicles filled with stratified content. Those vesicles probably are cortical granules. The follicle cells surrounding growing oocytes have the following features: (1) they do not lie on a basal lamina; (2) their plasma membrane folds deeply, forming invaginations which eventually seem to form channels throughout their cytoplasm; (3) the plasma membrane facing the ovary lumen is lined with a layer of dense material; and (4) the plasma membrane facing the oocyte forms thin projections which intermingle with the oocyte microvilli. In late oogenesis, the follicle cells detach from the oocytes and degenerate in the ovary lumen.     

Isolation of plasma membrane complexes fromXenopus oocytes

Summary A method for the isolation of plasma membrane fractions fromXenopus oocytes has been developed, and the membranes have been characterized biochemically and morphologically. Plasma membrane complexes prepared by this procedure consisted of large sheets of the membrane, with associated vitelline envelope (a nonmembranous meshwork of fibers) and cortical (secretory) granules still attached. The morphology of cell surface microvilli and coated pits was well preserved. Cortical granules were removed by gentle homogenization in a low ionic strength medium, and integral and peripheral membrane proteins were then separated from vitelline envelopes by detergent extraction and phase separation in Triton-X-114. Biochemical characterization of the plasma membrane fractions indicated substantial levels of 5-nucleotidase and alkaline phosphodiesterase activity associated with the oocyte cell surface, with 44–66% recovery of these markers in the final membrane preparations. Lectin blotting and lectin affinity chromatography with Concanavalin A and wheat germ agglutinin were used to characterize the major glycoprotein species associated with the plasma membrane complexes. Plasma membrane fractions prepared by this procedure should be very useful in both biochemical and morphological studies of membrane protein sorting in theXenopus oocyte system.     

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.     

Microtubules in the cortical region of the egg of Lymnaea during cortical segregation

The cortical region of the 2-cell stage egg of the gastropod Lymnaea palustris was studied by light and electron microscopy. This region includes (1) a vitelline membrane and perivitelline space which contain membrane-limited dense bodies derived from the cell surface, (2) oolemma with surface coat material and microvilli, and (3) a peripheral zone of cytoplasm (0.5-5.0 μm wide) composed of irregular vesicles, electron dense granules, and cytoplasmic microtubules. Microtubules are most abundant in the equatorial region of the egg, where they form arrays that are parallel and oblique to the egg's surface. Microtubular profiles also occur in the cortical region at the animal and vegetal poles of the egg and in the endoplasm. They may play a role in cortical segregation.     

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).     

A CYTOLOGICAL STUDY OF THE RELATION OF THE CORTICAL REACTION TO SUBSEQUENT EVENTS OF FERTILIZATION IN URETHANE-TREATED EGGS OF THE SEA URCHIN, ARBACIA PUNCTULATA

Eggs of the sea urchin, Arbacia punctulata, treated with 3% urethane for 30 sec followed by 0.3% urethane and inseminated are polyspermic and fail to undergo a typical cortical reaction. Upon insemination the vitelline layer of urethane-treated eggs either does not separate or is raised only a short distance from the oolemma. 1–6 min after insemination, almost all of the cortical granules remain intact and are dislodged from the plasmalemma. Later (6 min to the two-cell stage) some cortical granules are released randomly along the surface of the zygote. Not all zygotes show the same degree of cortical granule dehiscence; most of them experience little if any granule release whereas others demonstrate considerably more. The thickness of the hyaline layer appears to be directly related to the number of cortical granules released. Subsequent to pronuclear migration, several male pronuclei become associated with the female pronucleus. Later the male and female pronuclear envelopes contact and the outer and the inner laminae fuse, thereby forming the zygote nucleus. The male pronuclei remaining in the cytoplasm increase in size and progressively migrate to, and fuse with, the zygote nucleus. By 60 min some zygotes appear to contain only one large zygote nucleus which subsequently enters mitosis. Other zygotes possess a number of male pronuclei which remain unfused, and later these pronuclei along with the zygote nucleus undergo mitosis. There does not appear to be a direct relation between the number of cortical granules a zygote possesses and the above mentioned dichotomy.     

Ultrastructural Aspects of Fertilization in Spiralian Eggs

Normally, the eggs of Spisula are monospermic. How polyspermyis prevented in this organism is unclear, particularly whenthe cortex of the fertilized ovum is examined. Using conventionalmicroscopic procedures, little alteration of the surface ofthe egg is observed following insemination; the microvilli,vitelline layer and cortical granules are morphologically unchanged.Investigations employing freeze fracture replication of fertilizedand unfertilized Spisula eggs demonstrate that there is a dichotomywith respect to the distribution of intra membranous particleswithin the plasmalemma of Spisula eggs. There is a structuralreorganization of microvilli and a two-fold increase in particleson the A-face of the plasma membrane along their bases followinginsemination. These transformations in microvillar structureand intramembranous particle number may be involved in establishinga block to polyspermy, however, further evidence is necessaryto demonstrate a cause-effect relation.     

Ultrastructural characteristics of the follicle cell-oocyte interface in the oogenesis of Ceratophrys cranwelli

In this work we carried out an ultrastructural analysis of the cell interface between oocyte and follicle cells during the oogenesis of the amphibian Ceratophrys cranwelli, which revealed a complex cell-cell interaction. In the early previtellogenic follicles, the plasma membrane of the follicle cells lies in close contact with the plasma membrane of the oocyte, with no interface between them. In the mid-previtellogenic follicles the follicle cells became more active and their cytoplasm has vesicles containing granular material. Their apical surface projects cytoplasmic processes (macrovilli) that contact the oocyte, forming gap junctions. The oocyte surface begins to develop microvilli. At the interface both processes delimit lacunae containing granular material. The oocyte surface has endocytic vesicles that incorporate this material, forming cortical vesicles that are peripherally arranged. In the late previtellogenic follicle the interface contains fibrillar material from which the vitelline envelope will originate. During the vitellogenic period, there is an increase in the number and length of the micro- and macrovilli, which become regularly arranged inside fibrillar tunnels. At this time the oocyte surface exhibits deep crypts where the macrovilli enter, thus increasing the follicle cell-oocyte junctions. In addition, the oocyte displays coated pits and vesicles evidencing an intense endocytic activity. At the interface of the fully grown oocyte the fibrillar network of the vitelline envelope can be seen. The compact zone contains a fibrillar electron-dense material that fills the spaces previously occupied by the now-retracted microvilli. The macrovilli are still in contact with the surface of the oocyte, forming gap junctions.     

Oogenesis of the mayfly Habrophlebia eldae: Synthesis of vitelline and chorionic envelopes

The ultrastructure of developing ovarian follicles inside the panoistic ovarioles of Habrophlebia eldae were examined to observe the events occurring during egg maturation up to the full formation of the chorionic envelopes. The early vitellogenic follicles are coupled by gap junctions and are extensively interlocked with the oocyte plasma membrane via microvilli. With the onset of vitellogenesis, coated pits and coated vesicles are precursors to yolk deposition and are visible at the follicle cell-oocyte interface. Postvitellogenic development entails the deposition of the egg envelopes. The vitelline envelope arises from the coalescence of rectangular plaques whose precursors are visible in Golgi complexes as heterogeneous electron-opaque granules. A chorionic pattern of ridges on the egg surface characterizes the shell of H. eldae. The fully developed chorion shows three distinct regions with differently organized patterns. A fine layer of fibrous material (a secretion of the follicle cells, Ephemeroptera devoid of accessory glands) adheres to the egg chorion and is probably involved in attachment to the substrate.     

Egg-shells in mites

Summary This communication presents results of studies on the formation and structure of the vitelline envelopes in three species of mites: Euryparasitus emarginatus (Gamasida), Erythraeus phalangoides (Actinedida), and Hafenrefferia gilvipes (Oribatida). In E. emarginatus and E. phalangoides, in which the oocytes are not covered with follicular cells, the material of the vitelline envelope appears first in vesicles under the surface of the oocytes prior to secretion by exocytosis. The formed vitelline envelope is built of a homogeneous material which is perforated by numerous channels containing oocyte microvilli. Later, as the microvilli are retracted, the channels disappear. In both of these species the formed vitelline envelope is incomplete and the micropylar orifice occurs as a transitional structure.In H. gilvipes follicular cells encircling the oocyte contain granules filled with material that is subsequently secreted into the perivitelline space forming the vitelline envelope on the oocyte surface. The inner layer of the vitelline envelope is granular, whereas the outer part is more homogeneous. Both lack channels containing microvilli and micropyle.     

Ultrastructural differentiations in the developing follicle cortex of Locusta migratoria,with special reference to vitelline membrane formation

Summary Electron microscopic studies on developing follicles of Locusta migratoria show the vitelline membrane to be composed of two ultrastructurally distinguishable components: The vitelline membrane bodies (VMBs) and, in addition, fine granular material, cementing the VMBs together. VMBs form first in the oocyte-near zone within the oocyte-follicle cell space. Subsequently, the second vitelline membrane substance is secreted between the VMBs through apical protrusions of the follicle cells. The possible origin of the VMBs is discussed.Yolk uptake in Locusta seems to occur predominantly by pinocytosis. During oocyte development the oocyte membrane is enlarged by numerous microvilli and folds. In addition pinocytotic vesicles are pinched off. It is supposed that the latter loose their coat and eventually transform into large proteid yolk spheres.This work was supported by the Volkswagenstiftung, HannoverI wish to thank Prof. Dr. H. Emmerich, Techn. Hochschule Darmstadt, for valuable discussions     

A Rho-signaling pathway mediates cortical granule translocation in the sea urchin oocyte

Cortical granules are secretory vesicles of the egg that play a fundamental role in preventing polyspermy at fertilization. In the sea urchin egg, they localize directly beneath the plasma membrane forming a compact monolayer and, upon fertilization, undergo a Ca(2+)-dependent exocytosis. Cortical granules form during early oogenesis and, during maturation, translocate from the cytosol to the oocyte cortex in a microfilament-mediated process. We tested the hypothesis that these cortical granule dynamics were regulated by Rho, a GTPase of the Ras superfamily. We observed that Rho is synthesized early in oogenesis, mainly in a soluble form. At the end of maturation, however, Rho associates with cortical granules. Inhibition of Rho with the C3 transferase from C. botulinum blocks cortical granule translocation and microfilaments undergo a significant disorganization. A similar effect is observed by GGTI-286, a geranylgeranyl transferase inhibitor, suggesting that the association of Rho with the cortical granules is indispensable for its function. In contrast, the anchorage of the cortical granules in the cortex, as well as their fusion at fertilization, are Rho-independent processes. We conclude that Rho association with the cortical granules is a critical regulatory step in their translocation to the egg cortex.     

Reorganization of the Endoplasmic Reticulum during Meiotic Maturation of the Mouse Oocyte

The endoplasmic reticulum (ER) of live metaphase II mouse eggs and prophase I-arrested oocytes was compared using the fluorescent, lipophilic dicarbocyanine dye, DiI. DiI, dissolved in soybean oil, was microinjected into oocytes and eggs; the dye diffused throughout the cytoplasm to label the ER, which was imaged by confocal microscopy. The mature egg had a fine reticular network of ER throughout the cell and numerous dense accumulations of membrane in the cortex. These ER accumulations, 1-2 μm in diameter, were generally absent deeper in the cytoplasm. A similar staining pattern was observed when the eggs were fixed within 1 min of injection, providing evidence that the cortical accumulations of membrane are part of a continuous ER membrane system, since membrane trafficking could not occur in a fixed egg. Cortical ER accumulations were localized to the same region of the egg as the cortical granules and were not observed in the cortical granule-free region adjacent to the meiotic spindle. In contrast, ER accumulations were rarely found in the cortex of the immature, prophase I-arrested oocyte, but larger and less well-defined membrane clusters were found throughout the deeper cytoplasm of the oocyte. The appearance of ER clusters in the egg cortex following oocyte maturation correlates with an increased ability of the mature egg to release calcium at fertilization. Since the ER is a calcium store, structural reorganization of the ER may be necessary to permit the large release of calcium and resulting cortical granule exocytosis at fertilization.     

PROTEIN UPTAKE IN THE OOCYTES OF THE CECROPIA MOTH

The formation of yolk spheres in the oocyte of the cecropia moth, Hyalophora cecropia (L.), is known immunologically to result largely from uptake of a sex-limited blood protein. Recent electron microscope analyses of insect and other animal oocytes have demonstrated fine structural configurations consistent with uptake of proteins by pinocytosis. An electron microscope analysis of the cecropia ovary confirms the presence of similar structural modifications. With the exception of two apparently amorphous layers, the basement lamella on the outer surface of the follicular epithelium and the vitelline membrane on the inner, there is free access of blood to the oocyte surface between follicle cells. Dense material is found in the interfollicular cell space and adsorbed to the outer surface of the much folded oocyte membrane. Pits in the oocyte membrane and vesicles immediately under it are lined with the same dense material not unlike the yolk spheres in appearance. Introduction of ferritin into the blood of a developing cecropia moth and its localization adsorbed to the surface of the oocyte, and within the vesicles and yolk spheres of the oocyte cortex, is experimental evidence that the structural modifications of the oocyte cortex represent stages in the pinocytosis of blood proteins which arrive at the oocyte surface largely by an intercellular route. Small tubules attached to the yolk spheres are provisionally interpreted as a manifestation of oocyte-synthesized protein being contributed to the yolk spheres.     

Ultrastructural changes during fertilization envelope assembly in Lytechinus pictus eggs revealed by quick-freeze,deep-etch electron microscopy

Morphological features of fertilization envelope assembly in egges from the sea urchin Lytechinus pictus were examind in platinum replicas of samples quick-frozen, deep-etched, and rotary-shadowed at various times after insemination. Unfertilized eggs are surrounded by the vitelline layer, a glycocalyx, which faith-fully follows the contours of the microvillus-studded egg surface. The vitelline layer is secured to the plasma membrane below via a series of short projections called vitelline posts. The vitelline matrix itself is an elaborate meshwork of uniformly sized filaments, which are decorated in places with globular particles. At fertilization, the vitelline layer elevates off the egg surface and by 1 min after insemination appears as a thin, airy network of fibers. In contrast to Strongylocentrotus purpuratus, impressions of the underlying microvilli are not retained in this species. The vitelline template appears to become filled in by the deposition of amorphous secretory material between 1 and 5 min after fertilization. This smooth, amorphous layer is then coated with a thin sheet of paracrystalline material. Paracrystalline coating is incomplete at 5 min, but by 20 min after insemination the coat is complete, consisting of ordered parallel rows of roset-telike particles.     

ELECTRON MICROSCOPY AND ELECTRON PROBE ANALYSIS OF MITOCHONDRIAL CATION ACCUMULATION IN SMOOTH MUSCLE

The contractile responses to barium and the ultrastructure and ionic composition of mitochondria were studied in vascular smooth muscle. In normal rabbit portal anterior mesenteric vein (PAMV) and main pulmonary artery (MPA) smooth muscle mitochondria were frequently associated with the surface vesicles. The average distance between the outer mitochondrial and inner surface vesicle membrane was 4–5 nm. Ba contractures of MPA were tonic and of PAMV were phasic. Incubation of MPA and PAMV with Ba resulted in the accumulation of mitochondrial granules, followed in the MPA by massive mitochondrial swelling. Oligomycin and anoxia inhibited the appearance of mitochondrial electron-opaque granules and prevented the Ba-induced mitochondrial swelling in the MPA. Electron probe analysis of mitochondria in PAMV incubated with Ba and containing granules showed characteristic Ba signals over the mitochondria. Electron probe X-ray microanalysis also showed a highly significant (P < 0.001) correlation of P with mitochondrial Ba, in an estimated elemental ratio of approximately 3 Ba/4 P. Mitochondrial granules were still prominent after block staining of the osmium-fixed, Ba-loaded PAMV, but electron probe microanalysis showed no Ba, but only U, emissions. Tissues incubated with strontium had electron-opaque mitochondrial granules and deposits in the sarcoplasmic reticulum. X-ray microanalysis of mitochondria containing granules showed the presence of characteristic Sr and Ca emissions. The presence of Sr was similarly verified in the sarcoplasmic reticulum. These findings indicate the energy dependent uptake of divalent cations, in association with phosphate, by mitochondria in vascular smooth muscle in situ and the possibility that mitochondria may contribute to the regulation of intracellular divalent cation levels in smooth muscle.     

THE ISOLATION OF A MAJOR STRUCTURAL ELEMENT OF THE SEA URCHIN FERTILIZATION MEMBRANE

Procedures for isolating the contents of the cortical granules from the ova of the sea urchin, Strongylocentrotus purpuratus, are reported. Dithiothreitol is used to remove the vitelline coat; the "demembranated" eggs are then subsequently activated with butyric acid. By means of these procedures, the hyaline protein and crystalline or paracrystalline material have been isolated from the cortical granules. The crystalline material consists of sheets of cylinders or tubules 150–200 A in diameter. This material is believed to be a major structural element of the fertilization membrane which, in the absence of the vitelline coat, does not form.     

Polyspermic fertilization of sea urchin eggs treated with protease inhibitors: Localization of sperm receptor sites at the egg surface

The normal elevation of the fertilization membrane and the establishment of the block to polyspermy are retarded in Arbacia punctulata eggs by specific protease inhibitors, soybean trypsin inhibitor (SBTI), leupeptin, and antipain. Ultrastructural observations show that the vitelline layer remains attached to the plasma membrane of fertilized SBTI treated eggs at numerous sites (cortical projections). Quantitive morphometric analysis indicates that the vitelline layer elevates from about 65% of the surface of SBTI treated eggs during the first 3 min post insemination. However, the vulnerability of SBTI treated eggs to refertilization (polyspermy) only declined during the subsequent gradual detachment of the vitelline layer from the cortical projections over the next 15 min. Antipain and leupeptin (10^?5 to 10^?3M) also promoted polyspermy in Arbacia eggs by a process of refertilization extending for a 10- to 15-min period after the initial monospermic insemination. Normal cleavage and development was obtained when eggs were placed in leupeptin and antipain (10^?3M) after the fertilization membrane had elevated. The data indicate that the normal secretory function (or functions) of the cortical granule protease in establishing the block to polyspermy is retarded by these protease inhibitors, and that the vitelline layer is transformed into a mechanical barrier to prevent penetration by supernumerary sperm during its detachment from the plasma membrane of the egg. Furthermore, the vitelline layer in unfertilized eggs appears to be a mosaic structure, with sperm receptor sites localized in regions of the egg's surface, which give rise to cortical projections in the presence of SBTI.     

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.