Filamentous actin organization in the unfertilized sea urchin egg cortex

We have investigated the organization of filamentous actin in the cortex of unfertilized eggs of the sea urchins Strongylocentrotus purpuratus and Lytechinus variegatus. Rhodamine phalloidin and anti-actin immunofluorescent staining of isolated cortices reveal a punctate pattern of fluorescent sources. Comparison of this pattern with SEM images of microvillar morphology and distribution indicates that filamentous actin in the cortex is predominantly localized in the microvilli. Thin-section TEM and quick-freeze deep-etch ultrastructure of isolated cortices demonstrates that this microvillar-associated actin is in a novel organizational state composed of very short filaments arranged in a tight network and that these filament networks form mounds that extend beyond the plane of the plasma membrane. Actin filaments within the networks do not exhibit free ends and make end-on attachments with the membrane only within the region of the evaginating microvilli. Myosin S-1 dissociable crosslinks, 2-3 nm in diameter, are observed between network filaments and between network filaments and the membrane. A second population of long, individual actin filaments is observed in close lateral association with the plasma membrane and frequently complexes with the microvillar actin networks. The filamentous actin of the unfertilized egg cortex may participate in establishing the mechanical properties of the egg surface and may function in nucleating the assembly of cortical actin following fertilization.     

Organization of Actin Filaments in the Axial Rod of Abalone Sperm Revealed by Quick Freeze Technique

An axial rod in abalone ( Haliotis discus ) sperm is a structure composed of a bundle of actin filaments, which elongates anteriorly to form the acrosomal process during the acrosome reaction. The ultrastructure of the actin filament bundle constituting the axial rod was examined using quick freeze technique followed by either freeze-substitution or deep-etch electron microscopy. Thin sections of quick freeze and freeze-substituted sperm revealed that the actin filaments in the axial rod are hexagonally packed in a paracrystalline array through its almost entire length with an average center-to-center spacing of 12 nm. Periodic transverse bands were also observed across the actin filament bundle, which may reflect the cross-bridges interconnecting the adjacent filaments. Quick-freeze deep-etch analysis provided the three-dimensional view of the axial rod. Actin filaments exhibiting 5.5–6 nm spaced striations were observed to run in parallel with each other inside the axial rod. The existence of cross-bridging structures was also displayed between adjacent filaments. These results suggest that the actin filaments in the axial rod are probably held together by regularly spaced cross-bridges to form a well ordered hexagonally packed bundle, and also cross-linked by fibrous structure to the lateral inner acrosomal membrane which closely surrounds the anterior half of the actin filament bundle.     

Ultrastructure of detergent-resistant cytoskeletons in the noncortical domain of sea urchin eggs as revealed by the quick-freeze deep-etch technique.

The ultrastructure of detergent-resistant cytoskeletons in the noncortical cytoplasm of sea urchin eggs was studied by quick-freeze, deep-etch electron microscopy. Two different cytoskeletal organizations were identified in the detergent-treated sea urchin eggs. They were distinguished by the presence or the absence of long actin filaments and probably correspond to the cortex and the noncortical cytoplasm, respectively. The non-cortical cytoplasm was composed of a complex network (designated here as the ground network) of filaments 6 to 13 nm in diameter, that interconnected aggregates of small globular materials, yolk granules and a meshwork of uniform filaments (8-9 nm in diameter). The 6 to 13 nm filaments comprising the ground network were branched and associated with filaments of the same or other sizes, resulting in the formation of an extremely complex network. The meshwork of 8-9 nm filaments was homogeneous in composition and constitutes a novel structure which has not been previously described. The 8-9 nm filaments were connected to one another at their ends, forming a meshwork of polygons. Meshworks, ranging up to 3 microns in diameter, were distributed throughout the non-cortical cytoplasm of the egg. Similar cytoplasmic structures were also observed in fertilized eggs.     

The coelomic envelope of Xenopus laevis eggs: a quick-freeze, deep-etch analysis

The extracellular matrix of Xenopus laevis oocytes was analyzed before and after meiotic maturation using quick-freeze, deep-etch, rotary-shadow electron microscopy. The perivitelline space (PS) of the meiotically immature oocyte contains a filamentous network which connects microvilli (MV) and follicle cell macrovilli to the folded oocyte surface below. The envelope overlying the PS is composed of bundles of large fibers which course between the tips of the MV. Spaces between these bundles contain smaller fibrils which secure the egg envelope to the microvillar tips. Meiotic maturation is accompanied by flattening of the oocyte plasma membrane, formation of an orderly array of MV, and elevation of the egg envelope. In the coelomic eggs, the reorganized envelope is composed of loosely bundled large fibers which course above the microvillar tips rather than between them. The spaces between these bundles contain small fibers similar to those seen in the meiotically immature oocyte. This reorganized envelope, however, will not bind sperm; further modifications must transpire during passage through the oviduct to render it sperm receptive.     

The sea urchin egg jelly coat is a three-dimensional fibrous network as seen by intermediate voltage electron microscopy and deep etching analysis

The egg jelly (EJ) coat which surrounds the unfertilized sea urchin egg undergoes extensive swelling upon contact with sea water, forming a threedimensional network of interconnected fibers extending nearly 50 μm from the egg surface. Owing to its solubility, this coat has been difficult to visualize by light and electron microscopy. However, Lytechinus pictus EJ coats remain intact, if the fixation medium is maintained at pH 9. The addition of alcian blue during the final dehydration step of sample preparation stains the EJ for visualization of resin embedded eggs by both light and electron microscopy. Stereo pairs taken of thick sections prepared for intermediate voltage electron microscopy (IVEM) produce a threedimensional image of the EJ network, consisting of interconnected fibers decorated along their length by globular jelly components. Using scanning electron microscopy (SEM), we have shown that before swelling, EJ exists in a tightly bound network of jelly fibers, 50–60 nm in diameter. In contrast, swollen EJ consists of a greatly extended network whose fibrous components measure 10 to 30 nm in diameter. High resolution stereo images of hydrated jelly produced by the quick-freeze/deep-etch/rotary-shadowing technique (QF/DE/RS) show nearly identical EJ networks, suggesting that dehydration does not markedly alter the structure of this extracellular matrix. © 1993 Wiley-Liss, Inc.     

Novel surface specialization on a sea anemone egg: “Spires” of actin-filled microvilli

The ultrastructure of the “spiny” surface of Tealia crassicornis eggs is examined in detail by scanning and transmission electron microscopy in order to understand its function. Long microvilli are clustered together in spiral aggregates of 50–75 microvilli called “spires.” There are about 15,000 spires per egg. Dense bundles of microfilaments making up the cores of these microvilli are shown to be composed of actin by staining with the fluorescent dye nitrobenzoxadiazole (NBD)-phallacidin. It is postulated that the bundles of actin and the spires of microvilli are stiff and provide reinforcement to the egg surface. Such postulated properties would provide physical protection for these large eggs which, unlike the eggs of most invertebrates, appear to lack all extracellular investing coats.     

Polarized bundles of actin filaments within microvilli of fertilized sea urchin eggs

We report on the internal ultrastructure of long, finger-like microvilli which cover the surface of the fertilized sea urchin egg. Eggs were attached to polylysine-coated surfaces; their upper portions were sheared away with a stream of buffer which left behind only their plasma membranes and adjacent cytoplasmic structures. Scanning electron microscopy (EM) of such fragments revealed intact thin protoplasmic projections radiating away from the body of the cortex. By transmission EM of cortices similarly prepared on grids, small bundles of microfilaments appear as cores within the thin cytoplasmic projections. These microfilaments are shown to be composed of actin by their ability to interact with muscle heavy meromyosin (HMM). HMM-decorated microfilaments possess repeating arrowheads which uniformly point toward the cell interior. Actin bundles in the microvilli of sea urchin eggs may mediate microvillus support and elongation.     

Cytoskeletal filaments in embryonic chick myocardial cells as revealed by the quick-freeze deep-etch method combined with immunocytochemistry

Summary The three-dimensional organization of cytoskeletal filaments associated with the myofibrils and sarcolemma of the myocardial cells of early chick embryos was studied by the rapid-freeze deep-etch method combined with immunocytochemistry. In the endoplasmic region of saponin-treated myocardial cells, 12–14 nm filaments formed a loose network surrounding nascent myofibrils. These 12–14 nm filaments attached to the myofibrils and some of them converged into Z disc regions. In the non-junctional cytocortical region thinner 8–11 nm filaments composed a dense network just beneath the sarcolemma. In myofibril terminating regions at the sarcolemma, i.e., the fascia adherens, 3–5 nm cross-bridges were observed among the thin filaments. In Triton-permeabilized and myosin subfragment 1 (S1)-treated samples, subsarcolemmal 8–11 nm filaments proved to be S1-decorated actin filaments under which there was a loose network of S1-undecorated filaments. Subsarcolemmal S1-decorated actin filaments had mixed polarity and attached to the sarcolemma at one end. A loose network of S1-undecorated filaments among myofibrils in the endoplasmic region was revealed to consist of desmin-containing intermediate filaments after immuno-gold staining for desmin. These networks connecting myofibrils with sarcolemma were assumed to play an important role in integrating and transmitting the contractile force of individual myofibrils within early embryonic myocardial cells.     

Ultrastructural Basis of the Tension Increase in Sea-Urchin Eggs Prior to Cytokinesis

Cortices of sea-urchin eggs were studied by electron microscopy to identify the structure responsible for the rise in tension at the egg surface prior to cleavage. During anaphase the tension increased and fine filaments of 70–90 Å in diameter appeared in the cell cortex forming a thin mesh-work beneath the cell membrane. The meshwork spread all around the egg cortex without reference to the mitotic axis and the number of filaments seemed to increase up to telophase. Immediately before appearance of the cleavage furrow, the meshwork in the anticipated furrow region became dense. As the furrow appeared the tension began to decrease and the meshwork disappeared. In the progressing furrow region fine filaments of the same size as that of the meshwork-filament were oriented in a bundle to form a contractile ring. Treatment with cytochalasin B suppressed both the tension increase and the formation of the filamentous meshwork. These results suggest that the component filament of the meshwork is an actin microfilament, and that the tension increase at anaphase is due to formation of a meshwork of actin microfilaments from which a contractile ring is subsequently derived at late telophase.     

Cortical differentiation of the animal pole during maturation division in fertilized eggs of Tubifex (Annelida,Oligochaeta): II. Polar body formation

Changes in the cortical organization at the animal pole are examined by scanning and transmission electron microscopy in the Tubifex egg undergoing second polar body formation. At very early anaphase of the second meiosis, the egg surface overlying the meiotic apparatus is undulated, but its neighboring surface appears to be smooth. Although a microfilamentous cortical layer is found in the smooth area, the cortical layer of the undulating area is thin and devoid of filamentous structures except for its central part where some filaments are observed. This local differentiation takes place normally in colchicine-treated eggs where the meiotic apparatus is destroyed. Along with the progression of the anaphase movement, the egg surface of the undulating area is, first, uplifted into a cone-shaped cytoplasmic bulge (presumptive polar body); then the height and surface area of the bulge gradually increase. The distal surface of the growing bulge appears to be undulated whereas the sides of the bulge are relatively smooth. Transmission electron microscopy reveals that a thick microfilamentous cortical layer is always localized at the proximal region of this bulge; other regions of the bulge are characterized by a thin cortical layer which is devoid of filamentous structure except for the apical portion of the bulge. Microfilaments at the base of the bulge are perpendicular or oblique to the egg surface. The cortical layer of the egg which is continuous to that of the proximal region of the bulge comprises microfilaments running parallel to the surface. The attainment of the bulge to its full size is followed by the development of the cleavage furrow along its base. The cleavage furrow appears to bisect the spindle midway between its poles. In cytochalasin B-treated eggs, where some cortical microfilaments are detected at the animal pole, a cytoplasmic bulge lower in height and wider in the diameter of its base than the normal one forms at the animal pole; however, it is subsequently resorbed into the egg. The formation of a cleavage furrow is not observed in these eggs. The mechanism of the polar body formation is discussed in the light of the present observations.     

怀头鲇胚胎发育过程卵膜形态结构变化及对孵化影响

采用扫描电镜和光学解剖镜,对黑龙江水域怀头鲇(Silirus soldatovi)成熟卵膜层次构造和受精卵胚胎发育过程中卵膜形态结构变化进行观察,并比较未脱黏和人工脱黏卵受精卵膜的表面超微结构变化.结果显示,受精卵膜的胶膜表面由一层薄而致密的物质组成,上有微孔构造.未脱黏受精卵膜表面胶膜光滑致密,多孔隙,内有小梁相连,随胚胎发育逐渐膨胀、展开、变薄,破膜期自然脱落.人工脱黏几乎全部脱去鱼卵的胶膜层,从而使卵失去黏性.脱去胶膜层的受精卵膜表面由不规则的颗粒状结构紧密嵌合而成,表面粗糙,胚胎发育过程中颗粒形状变化不大,但颗粒层逐渐变薄而且疏松,直至胚胎破膜而出:胚胎发育后期颗粒层有过早脱落和破洞出现.同时对活体鱼卵进行连续比较观察,讨论了卵膜结构及动态变化与孵化效果的关系.     

SEM observation of the External Yolk Syncytial Layer in Blastopore Closure of the Medaka, Oryzias latipes

The embryonic surface of the teleost, Oryzias latipes , was observed by scanning electron microscopy (SEM) to examine the last phase of epiboly or blastopore closure. The surface of the external yolk syncytial layer (E–YSL), a surface cytoplasmic layer encompassing the yolk sphere situated beyond the blastoderm, was highly undulated with surface folds of random orientation throughout most of epiboly (st. 14–20). Scattered microvilli were observed on the surface of the margin of the yolk plug in st. 18–20. The microvilli, 1 to 6 μm in length, were projected in a bunch at the end of blastopore closure (st. 20–21). The appearance of these microvilli in the last phase of epiboly is discussed with respect to the mechanism of epiboly.     

The structure of the chorion and associated surface filaments in Oryzias--evidence for the presence of extracellular tubules

The structure of the chorion with its associated surface filaments has been examined in Oryzias latipes using several techniques, including scanning and transmission electron microscopy, enzymatic digestion, and sodium dodecylsulfate-polyacrylamide gel electrophoresis. The chorion of the recently fertilized egg was found to be organized into three zones: an outer, fuzzy electron-lucent zone that was continuous over the surface of filaments, a middle, homogeneous electron-dense zone, and an inner zone of ten to 12 horizontal, fibrous lamellae. Two topographically distinct types of filaments were found on the chorionic surface: nonattaching and attaching. Nonattaching filaments showed a regular spatial distribution over the chorion with an interfilament distance of about 60-70 microns. Attaching filaments originated from a localized portion of the chorion and united with those of neighboring eggs to anchor the egg cluster to the gonoduct of the female. Both nonattaching and attaching filaments were morphologically regionalized into basal and distal segments. Internally, nonattaching and attaching filaments were constructed of unbranched, packed tubules with an average outside diameter of approximately 19.5 and 18.8 nm, respectively. Using the attaching filament for further study, it was determined by rotational analysis (Markham et al., '63) that the wall of each tubule was a cylinder composed of 14 globular subunits. Two structural types of attaching filaments were identified. The type I attaching filament was similar in internal organization to the nonattaching filament and consisted of only tubules. The type II attaching filament, however, showed a highly osmiophilic, electron-dense bar surrounded by packed tubules. Tubules of attaching filaments of the adult were resistant to the action of Triton X-100 and colchicine, but sensitive to a 0.1% protease solution. However, colchicine-treated ovary tissue showed an absence and pattern of disorganization of tubules at the periphery of developing filaments. Solubilized attaching filament samples electrophoresed on 7.5% polyacrylamide-SDS gels were resolved into a pair of Coomassie-blue-positive bands that comigrated with purified porcine brain tubulin. The apparent molecular weight of the attaching filament polypeptide was determined to be approximately 55,000 daltons. These data suggest that the extracellular, tubular components of attaching filaments (as well as nonattaching filaments) are proteinaceous and show properties similar to those of cytoplasmic microtubules. Tubular precursor material was electron-dense and appeared to originate in the cisternae of the rough endoplasmic reticulum of ovarian foll     

Stepwise transformation of the vitelline envelope of Xenopus eggs at activation: a quick-freeze, deep-etch analysis

The extracellular matrix of Xenopus laevis eggs was analyzed at fixed intervals after prick-activation using quick-freeze, deep-etch, rotary-shadow electron microscopy. This technique revealed that the modifications of the matrix seen at fertilization do not occur simultaneously, but that instead there is an orderly progression of alterations at activation. The first modification, conversion of the vitelline envelope (VE) to the altered vitelline envelope (VE), occurs within 2 to 3 min after activation. Intermediate stages of the VE to VE transformation can be visualized traveling around the egg in a wave-like fashion. Upon completion of the wave, the loosely woven outer surface of the VE, believed to be the prefertilization layer, remains unaltered. Subsequent formation of the fertilization (F) layer at this VE-jelly interface occurs between 4 and 8 min postactivation. Finally, between 10 and 15 min postactivation, the smooth (S) layer forms on the tips of the microvilli and surrounds the entire egg.     

Surface activity at the egg plasma membrane during sperm incorporation and its cytochalasin B sensitivity: Scanning electron microscopy and time-lapse video microscopy during fertilization of the sea urchin Lytechinus variegatus

Sperm incorporation and the formation of the fertilization cone with its associated microvilli were investigated by scanning electron microscopy of eggs denuded of their vitelline layers with dithiothreitol or stripped of their elevating fertilization coats by physical methods. The activity of the elongating microvilli which appear to engulf the entering spermatozoon was recorded in living untreated eggs with time-lapse video microscopy. Following the acrosome reaction, the elongated acrosomal process connects the sperm head to the egg surface. About 15 microvilli adjacent to the attached sperm elongate at a rate of 2.6 μm/min and appear to engulf the sperm head, midpiece, and sperm tail. These elongate microvilli swell to form the fertilization cone (average height, 6.7 ± 2.0 μm) and are resorbed as the sperm tail enters the egg cytoplasm 10 min after insemination. Cytochalasin B, an inhibitor of microfilament motility, completely inhibits the observed egg plasma membrane surface activity in both control and denuded eggs. These results argue for a role of the microfilaments found in the egg cortex and microvilli as necessary for the engulfment of the sperm during incorporation and indicate that cytochalasin interferes with the fertilization process at this site.     

Fine Structure of the Oocyst Wall of Eimeria nieschulzi

SYNOPSIS. Oocysts of Eimeria nieschulzi from the laboratory rat, Rattus, norvegicus , were studied by scanning and transmission electron microscopy. Oocysts had a rough outer wall with apparent random depressions. The oocyst wall is composed of 2 layers: an osmiophilic outer layer consisting of a rough external and smooth internal surface, and a relatively thick, electron-lucent inner layer. The outer layer is composed of a dense, coarsely granular matrix. The inner layer consists of homogeneous fine granular material interspersed with coarse osmiophilic granules and contains one closely applied membrane on the outermost surface. Several raised lenticular areas are seen on the coarse outer surface of the inner layer. These layers are 102 (75–128) and 176 (135–204) nm thick, respectively.
The sporocyst wall is thin, consisting of 3 to 4 unit membranes, and measures 27 (18–34) nm thick.     

Synthesis and function of the fibrous layers covering the eggs of Siphlonurus lacustris (Ephemeroptera, Siphlonuridae)

Ultrastructural analysis (transmission and electron scanning microscopy) of the eggs of the mayfly Siphlonurus lacustris (Eaton) showed that they are wrapped in a thick coat composed of a network of tightly entwined filaments. Groups of twisted filaments form slightly uplifted buttons that are scattered on the coat surface. After experimentally induced egg deposition, egg–water interaction promotes marked cohesion of the eggs and their firm adhesion to the substrate. Egg masses include numerous gametes; the covering of those located close to the substrate greatly extends to anchor the whole mass. Eggs removed from the coat reveal a slightly punctuated smooth chorion and tagenoform micropyles (three to five). The coat increases egg size by about 20%. The lack of female reproductive accessory glands in Ephemeroptera transfers the synthesis of the adhesive coats to the follicle cells, which are typically competent for insect egg shell deposition (vitelline envelope and chorionic layers). This covering results from electron‐dense granules that give rise to filaments progressively organized to form superimposed layers variously orientated around the egg. In addition to egg adhesion to the substrate, a trophic function and protection from shear stress are postulated for this covering.     

Scanning Electron microscopic Study on the Early Development of Silkworm Eggs (Bombyx mori L.)

Morphological changes of the surface of eggs of the silkworm Bombyx mori L. were studied during early developmental stages by scanning electron microscopy. The egg surface was covered with numerous microvilli at least until 4 h after oviposition. At 6 h the microvilli were replaced by ruffle-like microprojections. This suggests that developmental changes of the surface structure may occur without direct influence of cleavage nuclei. Immediately before blastoderm cell formation, microvilli reappeared in the presumptive groove area. The ruffles seen on the apical portion of newly-formed blastoderm cells gradually became flattened, while microvilli developed on the lateral side of the cells. The mode of blastoderm cell formation is different from the typical one seen in most species of insects.     

Wave of cortical actin polymerization in the sea urchin egg

The distribution of actin filaments in the cortical layer of sea urchin eggs during fertilization has been investigated by light microscopy using fluorescently labeled phallotoxins. The cortical layer of both whole eggs and cortices isolated on a glass surface was examined. In cortices of unfertilized eggs, numerous fluorescent spots were seen, which may correspond to short actin filament cores in microvilli. After insemination, one of the sperm-attaching points on the egg surface first became strongly fluorescent. This fluorescence grew around the point of sperm penetration with the growth of the fertilization cone. Then, the cortical layer of the egg around the fertilization cone became strongly fluorescent and the fluorescence propagated in a wavelike manner over the entire cortex. The mechanism of the propagation of actin polymerization is discussed.     

Extracellular coats on the surface of Strongylocentrotus purpuratus eggs: stereo electron microscopy of quick-frozen and deep-etched specimens

Summary Sea urchin (Strongylocentrotus purpuratus) eggs were fixed, quick-frozen, deep-etched, and rotary-replicated, and the three-dimensional structure of the external surface of the egg visualized using stereo electron microscopy. The cell surface is coated with three layers of filaments: the sheetlike vitelline layer adhering closely to the plasma membrane, a second layer of oblique fibrils extending from microvillar tips to the vitelline layer below, and a third, outermost layer of horizontal filaments coursing in bundles over the microvillar tips. After fertilization, the newly elevated vitelline envelope is transformed into a three-layered structure, the central layer being a tightly knit network of fine filaments decorated on each side with a loose network of thicker fibrils. Subsequently, the envelope becomes coated with paracrystalline protein released from the cortical granules, and microvillar casts are reshaped into angular, jagged peaks having two to five sides. The final structure of the fertilization envelope consists of a thick central layer of compact fibrillar material that is coated on each side with thin plates of paracrystalline protein.