Annual fish oogenesis : I. Differentiation of the mature oocyte and formation of the primary envelope

The chorion surface in the eggs of the annual fishes Cynolebias melanotaenia and C. ladigesi contains an elaborate, three-dimensional species-specific pattern. Two concentric layers form the chorion. The pattern resides in the outer layer, the secondary envelope. It consists of closely packed tubules about 250 Å in diameter. A coat of electron dense “fuzzy” material increases this to 475 Å. The inner layer, the primary envelope, of uniformly low electron density possesses no obvious substructure. Oogenesis is divided into six stages. The oocyte increases in size from 10–20 μm in Stage 1 to 250 μm in Stage 3, 600 μm in Stage 4, and attains maximal size of 900 μm by Stage 6. Massive inclusions of protein and lipid yolk accumulate during Stages 4 and 5. Zone 1, one of the three zones of the primary envelope, first appears late in Stage 2. During Stage 3, Zone 1 is completed and Zone 2 appears between the oocyte surface and Zone 1. The oocyte cytoplasm increases in complexity. Material similar to Zone 1 (light, fibrillar) and Zone 2 (dark, compact) is present in the RER, Golgi, derivative vesicles, and apical pits. Micropyle formation also commences. The oocyte secretes Zone 3 during Stage 4 as thin filaments which consolidate into a highly ordered, transitional structure composed of tangentially oriented bundles of interwoven filaments. These partially fuse during Stage 5 except for fenestrations through which oocyte and follicle cell microvilli pass. Complete fusion during Stage 6 produces a continuous layer. Follicle cells retain an unspecialized structure from Stages 1 through 4. Secondary envelope material accumulates in the RER of the follicle cells during Stage 5. It is secreted and deposited during Stage 6.     

Structural changes in oocyte nucleoli ofXenopus laevis during oogenesis and meiotic maturation

Immunoelectron microscopy with anti-nucleolin defined substructures within the multiple nucleoli of biosynthetically active stage II–III oocytes and within the nucleoli of relatively quiescent stage VI oocytes of Xenopus laevis. Dense fibrillar components (DFCs) of nucleoli from stage II–III oocytes consisted of nucleolonemas that radiated from a continuous DFC sheath surrounding fibrillar centers (FCs). Discernible granular regions (GRs) were absent in these same nucleoli. Conversely, stage VI oocyte nucleoli displayed compacted DFCs and prominent GRs. Immunofluorescence microscopy then tracked fibrillarin, nucleolin, and condensed DNA through oogenesis and into progesterone-induced meiotic maturation and nuclear breakdown. In stage II–III oocyte nucleoli, fibrillarin was enriched near the FC-DFC boundaries, while nucleolin was distributed throughout these same DFCs. Both proteins were enriched within the compacted DFCs of stage VI oocyte nucleoli. Staining with (DAPI) 4′,6-diamidino-2-phenylindole showed condensed DNA within nucleolar FCs of both stage II–III and stage VI oocyte. Upon nuclear breakdown, we found fibrillarin and nucleolin in small particles and in the surrounding cytoplasm. Although we saw no trace of fibrillarin or nucleolin in nuclear remnants prepared just minutes later, DAPI-stained particles remained within these preparations, thus suggesting that FCs were at least slow to disassemble. Received: 18 March 1996 / Accepted: 16 April 1996     

U-cadherin in Xenopus oogenesis and oocyte maturation

U-cadherin is a member of the cadherin family in Xenopus that participates in interblastomere adhesion in the early embryo from the first cleavage onwards. Though a maternal pool of U-cadherin is available in the egg, it is not present on the egg membrane (Angres et al., 1991. Development 111, 829-844). To assess the origin of this unexpected distribution in the egg, the accumulation and localization of the cadherin during oogenesis and oocyte maturation were investigated. We report here that U-cadherin is present in Xenopus oocytes throughout oogenesis. It is localized at the oocyte-follicle cell contacts suggesting that it functions in the adhesion of the two cell types. When oocytes mature and the contacts to the follicle cells break, U-cadherin disappears from the oocyte surface. Evidence for a translocation of U-cadherin from the membrane to the inside of the oocyte was obtained when the fate of membrane-bound U-cadherin, which was labelled on the surface of oocytes prior to maturation, was followed through maturation. The total U-cadherin content of the oocyte increases during maturation. Metabolic labelling experiments indicate that at maturation the translation of U-cadherin is elevated well above the level that one would expect from the general increase in protein synthesis is presumably the main source of the maternal pool of U-cadherin in the egg.     

Histochemical studies on the yolk-nucleus in fish oogenesis

Summary A histochemical study of the oogenesis of two species of fresh water fishes, Channa maruleus and Heteropneustes fossilis, was undertaken to reveal the origin, structure, histochemical nature, and function of the so-called yolk-nucleus. The basophilic substance of the yolk-nucleus, which is situated in the juxta-nuclear cytoplasm, gradually accumulates adjacent to the nuclear membrane. It is a homogeneous, spherical mass. In Channa, some basophilic, dense bodies develop in the yolk-nucleus. Histochemical tests show that the yolk-nucleus and dense bodies are rich in RNA and proteins. Mitochondria of lipoprotein composition and lipid inclusions, composed of unsaturated phospholipids, appear in association with the yolk-nucleus. Throughout previtellogenesis, the yolk-nucleus continues to proliferate its basophilic, RNA-containing substance and other inclusions. Finally it disintegrates while lying in the peripheral cytoplasm of the larger oocytes which show the synthesis of yolk bodies. During yolk formation, lipid inclusions and mitochondria start disappearing from view but the RNA-containing substance, originated from the yolk-nucleus of previtellogenesis, continues to persist among the growing yolk bodies. The latter arise de novo from the ground cytoplasm, under the influence of the RNA-containing substance, mitochondria and lipid inclusions of previtellogenesis.This work was carried out in the Department of Zoology, University of Gorakhpur, Gorakhpur, India.Population Council Post-Doctoral Fellow.     

Studies on the ichthyo-fauna in Plover Cove Reservoir, Hong Kong: I. Sequence of fish population changes

Gill-net surveys were made weekly from May 1971 to April 1974 in Plover Cove Reservoir, Hong Kong and the results analysed to determine the fish species composition in the reservoir, the seasonal fluctuation of catches and the length frequency distribution of some major species.
Over 20 species were represented in the fish fauna including almost all the naturally occurring species as well as the stocked species. Of the twenty species, some were collected regularly in gill-net samples while others occurred rarely. Sarotherodon (Tilapia) mossam-bicus (Peters) was the dominant species and contributed the main bulk of the catch. This species also showed distinct age groups in the reservoir and modal changes occurred seasonally. Thus, among the fish species studied only S. mossambicus showed a steady and progressive increase in abundance in the reservoir and the full development of this fish population with its wide range of feeding habits should be beneficial.     

Studies on protein synthesis during sea urchin oogenesis. I. Synthesis of histone F2b

Basic proteins were extracted from sea urchin oocytes previously incubated with 3H-lysine and then were analyzed by electrophoresis. A very radioactive band, which showed the same mobility as histone F2b, was analyzed for its amino acid composition. The results show an identity between this protein and histones F2b. In addition, an improved method of isolating large amounts of sea urchin oocytes is described.     

Dynamics of the oocyte cortical cytoskeleton during oogenesis in Rhodnius prolixus

The oocyte cortex undergoes dramatic changes during oogenesis in Rhodnius prolixus. Despite numerous studies examining oogenesis in the telotrophic ovariole, none has investigated the ultrastructural details of the oocyte cortex, in particular, the lateral cortical cytoskeleton. Indirect immunofluorescent staining of sections, rhodamine phalloidin staining of whole mounts and scanning and transmission EM of permeabilized and unpermeabilized preparations revealed the dynamic changes of the oocyte cortex from early previtellogenesis through to late vitellogenesis. During early previtellogenesis, oocytes 50-150 mum in length have a smooth oolemma, with no discernible cortical cytoskeleton. During mid to late previtellogenesis (oocytes 150-350 mum in length) a tightly woven network of microfilaments and microtubules forms, excluding mitochondria and Golgi complexes from the lateral cortex. At the onset of vitellogenesis, the follicuiar epithelium becomes patent, and there is an increase in microvilli covering the lateral oocyte surface. The microfilament cores form a discrete pattern that corresponds to the imprint of the follicle cells on the oocyte surface. While the lateral microfilament cytoskeleton becomes more elaborate, the lateral microtubule cytoskeleton diminishes, remaining sparse throughout vitellogenesis. The oocyte cortical cytoskeleton undergoes dramatic changes during oogenesis. These cortical dynamics are intricately related to the cellular and molecular processes that occur during oogenesis.     

Studies of oogenesis in Urechis caupo. I. Method for separating different size classes of oocytes

The immature oocytes of the echiuroid worm Urechis caupo develop while suspended as single cells in the coelomic fluid, free of any associated nurse or follicle cells. In any one female, size classes can be found ranging from 8 to 130 μm in diameter. A method is described for obtaining four to five relatively uniform size fractions by centrifuging the mixed oocyte population through a discontinuous Ficoll gradient and collecting the different size oocytes which accumulate at each step of the gradient. Phagocytosis of oocytes in vivo is also discussed.     

Biochemical research on oogenesis. The storage particles of the teleost fish Tinca tinca

Oocytes ofTinca tinca and other Teleosts accumulate small and large molecules of RNA in noncoordinate fashion. Previtellogenic oocytes synthesize far less 28 S and 18 S RNA than tRNA and 5 S RNA, so that the latter molecules make up 50 to 90% of total RNA in these cells. As inXenopus laevis, tRNA and 5 S RNA made in excess by small oocytes ofT. tinca are stored in two kinds of nucleoprotein particles, sedimenting at 7 S and 42 S. In this paper we describe the biochemical and physical properties of the storage particles ofT. tinca. The 7 S particles are made up of one 5 S RNA and one 32,000 M_r protein (c). The molecular weight of this protein is lower by 8,000 than itsX. laevis counterpart. In contrast, the 42 S particles have the same size and composition inT. tinca andX. laevis. The 42 S particles of both species are made up of four subunits, each of which contains three molecules of tRNA, one molecule of 5 S RNA, two molecules of a 50,000-M_r protein (a), and one molecule of a 40,000-M_r protein (b). We present evidence showing that in the 42 S particles protein a is associated with tRNA, whereas protein b is associated with 5 S RNA, and suggesting that protein c is a cleavage product of protein b.     

Morphological changes of the nucleolus during oogenesis in oviparous teleost fish, Barbus barbus (L.)

In fishes, like in amphibians, it is well established that variations in rRNA activity occur during oogenesis. Contrary to amphibians, however, little is known about the ultrastructural changes of the nucleolus during fish oogenesis. Evolution of the nucleolus has been followed during oogenesis in the teleost fish Barbus barbus (L.) using light and transmission electron microscopies. We show that the behaviour of the nucleolus during B. barbus oogenesis resembles that reported in amphibians but also presents several peculiarities. The most striking feature is the marked vacuolization of nucleoli occurs at the beginning of the growth during previtellogenesis. The results obtained by means of the in situ terminal deoxynucleotidyl transferase-immunogold method for detecting DNA seem further to indicate that the chromatin cap becomes integrated into developing nucleoli during previtellogenesis and then segregate at the periphery of nucleoli at the end of glycoproteinic vitellogenesis. Our study also shows that the nucleoli of germ cells, like that of follicle cells, are devoid of fibrillar centre but comprise a fibrillar and a granular component whatever the oogenetic stage. Ultrastructural detection of DNA and nucleolar proteins (AgNOR proteins, fibrillarin, and pp135) supports further the view that the Barbus nucleolus is a bipartite structure.     

Annual fish oogenesis : II. Formation of the secondary egg envelope

Elaborate surface ornamentation of the secondary egg envelope of the annual fishes, Cynolebias melanotaenia and C. ladigesi, is comprised of 250-Å components which are synthesized in the follicle cells during Stage 5 and are secreted during Stage 6. Tubules, due to their structure and electron density, act as naturally occurring tracers which can be used to localize their site of synthesis and path of intracellular transport. At Stage 5, follicle cells acquire the morphological features of a protein synthesizing-secreting cell. Appearance of a well-developed granular endoplasmic reticulum coincides with the initial appearance of tubular material. Tubular precursors first appear in the cisternae of the RER. These regions become dilated and seem to bud off to form vesicles. Vesicle enlargement occurs through continued synthesis or by fusion with other vesicles. Vesicles contain partially assembled tubules in a loose aggregation of disks and short rods. The limiting membrane of vesicles, even up to half the size of the nucleus, is uniformly studded with ribosomes. Late in Stage 5, the contents of the vesicles coalesce into compact granules in which 250-Å tubules have assembled. During Stage 6, shortly before fusing with the plasma membrane, the RER-derived vesicles appear to shed their ribosomes. Upon fusion, the vesicle discharges a discrete granule. The RER-derived vesicles transport tubular components directly from the site of synthesis to the exterior of the cell. Morphological evidence indicates that the pathway of intracellular transport and secretion bypasses the Golgi complex. Hexagonal close packing of the follicle cells seems to determine the spatial distribution of pattern in the secondary envelope. Generation of elaborate structures within the overall pattern results from the morphogenetic activity of individual cells. On the basis of structure, the secondary envelope constitutes a chorionic respiratory system similar to insect eggs. It probably functions as a “plastron” or physical gill.     

Studies of oogenesis in the rotifer,Asplanchna

Summary Oocyte development in Asplanchna brightwelli was studied by observation through the transparent body wall of living females and by electron microscopy. During oogenesis, which requires four to six hours, the oocyte increases in volume approximately 1000-fold. Most of its cytoplasm appears to be derived from the vitellarium by direct flow through the cytoplasmic bridge. This flow is rapid enough to be easily observed in the living female at low magnifications. Ribosomes, mitochondria, cortical granules, and lipid droplets were observed in the bridge area in electron micrographs.RNA synthesis during oogenesis was studied by means of autoradiography. Very little synthesis could be demonstrated in oocyte nuclei at any period of oogenesis, whereas the vitellarium nuclei show active incorporation of ³H-uridine throughout the reproductive life of the adult female. Most of this RNA is subsequently transferred to developing oocytes.This research was supported by USPHS Grant GM 121183 to Dr. C. W. Birky, Jr.