Studies on the formation of germ cells in a compound ascidian Botryllus,primigenus oka

Gametogenesis of a compound ascidian Botryllus primigenus was studied histologically. On either side of the zooid (stage 9), in the gonadal space between the epidermis and the atrial epithelium, either a single testis or a complex of an egg follicle and a testis can be formed. The egg follicle consists of a single ovum (occasionally two ova) and its accessory cells and is connected with the atrial epithelium by the follicle stalk. The egg follicle is always accompanied by the brood pouch, a diverticulum of the atrial cavity. The testis is equipped with a vestigial spermiduct and is attached to the atrial epithelium. Buds of stage 8 comprise, besides the developing testes and, egg follicles, loose aggregations of hemoblasts and oocytes of early developmental stages, which are already accompanied by primary follicular cells. Both the oocytes and the primary follicular cells seem to arise from the hemoblasts. The young oocytes are isolated in the gonadal space of the buds nnd are transferred to buds of the succeeding generations until they finally mature. In the bud of stage 3, a compact mass of cells appears, attaching to tbe inner vesicle on either side of the body. It is derived from the hemoblasts lodged there in the preceding generation and presumably also from the circulating hemoblasts. When the cell mass receives a large oocyte derived from the preceding generation, part of the cell mass differentiates into egg envelopes, forming an egg follicle, and a follicle stalk and the remainder into a testis. When the cell mass receives no oocyte, it differentiate as a whole into a testis. In the egg follicle thus formed the outer and inner follicular cells increase in number by mitotic division. Subsequently, initial test cells are derived from the inner follicle by migration across the developing chorion; then they increas2 in number by mitosis. In the testis, meiosis and spermiogenesis take place.     

In vitro and in vivo maturation of oocytes from gonadotrophin-treated brushtail possums

The time course of nuclear maturation of oocytes was examined in brushtail possums, Trichosurus vulpecula. Oocytes were recovered from ovarian follicles > 2 mm in diameter after pregnant mares' serum gonadotrophin/porcine luteinizing hormone (PMSG/LH) treatment (in vivo matured) or 72 hr after PMSG treatment (in vitro matured). Oocytes recovered from small (< 2 mm) and large (> 2 mm) follicles were also assessed for their ability to mature in vitro. Staining with the DNA-specific dye Hoechst 33342 was used to assess the stage of nuclear development by fluorescence microscopy. The process of nuclear maturation progressed rapidly in vivo, as oocytes collected at 20-27 hr post-LH all had a GV, but by 28-29.5 hr post-LH approximately a third of eggs were MII. By 30-hr post-LH, more than 70% of oocytes had reached MII stage and all ovulated eggs were MII. In vitro, all oocytes were at germinal vesicle stage at the start of culture. After 24 hr of culture, 67% of oocytes had progressed to metaphase I/anaphase I of meiosis. After 36 hr, 25% of oocytes had completed maturation to metaphase II, increasing to 52% after 48 hr. Maturation of oocytes after 48 hr in culture was unaffected by the presence or absence of granulosa cells, PMSG or LH/porcine follicle stimulating hormone (FSH). More oocytes from large follicles (55%) completed maturation by 48 hr than from small follicles (15%). The potential of oocytes to mature after 48 hr in culture was dependent on the follicle harvested having reaching a critical diameter of 1.5 mm.     

RNA synthesis in the ovary and oocytes of the starfish

Qualitative studies on the in vitro uptake and incorporation of tritiated uridine into RNA of the somatic and germinal elements of the starfish ovary were carried out prior to and during hormone-induced oocyte maturation and spawning.Autoradiography of nonhormone-treated ovaries indicated that the outer ovarian wall contained the highest concentration of label, with lesser amounts in the follicle cells and least in the oocytes. Oocytes and follicle cells localized at the periphery of the ovary were labeled first, and both cells became progressively labeled throughout the ovary with time; the label first appeared localized in the nucleolus of the oocyte.Sucrose gradient analysis of the separated cellular components of prelabeled hormone-treated ovaries indicated that RNA synthesis occurred in all segments of the ovary and that the spawned oocyte fraction was the least active. Synthesis of ribosomal RNA was detectable after a lag period of approximately 4 hr. Oocytes incubated in ³H-uridine during and subsequent to 1-methyladenine-induced spawning and maturation synthesized 15–19 S and low molecular weight RNA but not ribosomal RNA. Synthesis of the 15–19 S RNA was inhibited with ethidium bromide and to a limited extent by actinomycin D. Isolated mitochondrial fractions contained most of the labeled 15–19 S RNA. These data suggest the mitochondrial origin of most, if not all, of this intermediate-weight RNA. On the basis of these studies, it appears that starfish oocytes and follicle cells are metabolically active at the transitional period from growth to maturational stages in oocytes. Synthesis of RNA furthermore apparently continues in the cytoplasm subsequent to germinal vesicle breakdown and spawning.     

Regulation of mouse oocyte growth: probable nutritional role for intercellular communication between follicle cells and oocytes in oocyte growth

Intercellular communication, as determined by two different assay procedures, was established in vitro between mouse oocytes free of adhering follicle cells and monolayers of either follicle or 3T3 cells. Both of these cell types are known to be able to form homologous gap junctions, and follicle cells naturally form heterologous gap junctions with oocytes in vivo. Monolayers of L cells that are communication deficient did not establish intercellular communication with oocytes as determined by the two different assays for intercellular communication. The diameter of oocytes cultured for 4 days in medium or on monolayers of L cells decreased markedly, 9.7 and 13.1 micron, respectively. In contrast, oocytes cultured for 4 days on follicle cell monolayers increased on the average about 4.7 micron in diameter. Oocytes cultured for 4 days on monolayers of 3T3 cells decreased slightly in diameter, i.e., 2.1 micron. Results from these experiments support a nutritional role for intercellular communication between follicle cells and oocytes in oocyte growth.     

Possible MIS Production by Follicle Cells in Spontaneous Oocyte Maturation of the Ascidian, Halocynthia roretzi

Outer and inner follicle cell-enclosed oocytes (oocyte complexes) of Halocynthia roretzi underwent germinal vesicle breakdown (GVBD) within 2 hr when transferred from ovaries to normal seawater of pH 8 (NSW). Extrusion of test cells (TC) into the perivitelline space and elevation of the chorion also occurred. This phenomenon was designated as spontaneous oocyte maturation.
Seawater of low pH, protease inhibitors such as leupeptin or soybean trypsin inhibitor (SBTI), and calcium deficiency inhibited the spontaneous maturation only when introduced to the NSW during the first 10 minutes of incubation. GVBD-blocked complexes underwent GVBD after addition of trypsin regardless of pH or the absence of calcium ions. The oocytes from which follicle cells were removed with glycosidase did not undergo GVBD in NSW, but addition of trypsin triggered GVBD in these defolliculated oocytes (TC oocytes). Furthermore, incubation media in which spontaneous maturation had occurred, induced GVBD in the TC oocytes. This GVBD-inducing activity was heat-labile and was inhibited by leupeptin.
These results indicate that in the first step of the spontaneous oocyte maturation, outer and/or inner follicle cells give a signal to the oocyte itself or TC oocyte. This signal is likely to be trypsin-like.     

Involvement of the gonadal germinal epithelium during sex reversal and seasonal testicular cycling in the protogynous swamp eel,Synbranchus marmoratus Bloch 1795 (Teleostei,Synbranchidae)

The swamp eel, Synbranchus marmoratus, is a protogynous, diandric species. During sex reversal, the ovarian germinal epithelium, which forms follicles containing an oocyte and encompassing follicle cells during the female portion of the life cycle, produces numerous invaginations, or acini, into the ovarian stroma. Within the acini, the gonia that formerly produced oocytes become spermatogonia, enter meiosis, and produce sperm. The acini are bounded by the basement membrane of the germinal epithelium. Epithelial cells of the female germinal epithelium, which formerly became follicle (granulosa) cells, now become Sertoli cells in the developing testis. Subsequently, lobules and testicular ducts form. The swamp eel testis has a lobular germinal compartment in both primary and secondary males, although the germinal compartment in testes of secondary males resides within the former ovarian lamellae. The germinal compartment, supported by a basement membrane, is composed of Sertoli and germ cells that give rise to sperm. Histological and immunohistochemical techniques were used to describe the five reproductive classes that were observed to occur during the annual reproductive cycle: regressed, early maturation, mid-maturation, late maturation, and regression. These classes are differentiated by the presence of continuous or discontinuous germinal epithelia and by the types of germ cells present. Synbranchus marmoratus has a permanent germinal epithelium. Differences between the germinal compartment of the testes of primary and secondary males were not observed.     

In vitro growth and differentiation of primary follicles isolated from cryopreserved sheep ovarian tissue

Achieving full in vitro growth of oocytes of both domestic animals and humans remains a major challenge. The objective of this study was to examine the in vitro development of primary follicles isolated enzymatically from cryopreserved sheep ovarian tissue. In Experiment 1, isolated primary follicles (mean diameter 60.1+/-0.78microm) were cultured in serum-free medium on fibronectin-coated wells for 42 days. Initially follicular structure was lost as granulosa cells plated down, but by Day 7 two distinct morphologies began to emerge. Nineteen out of 36 oocytes were gradually re-surrounded by granulosa cells, forming follicle-like units (reorganized follicles), and the remaining 17 were not (non-reorganized follicles). On Day 2, there was no difference in diameter of oocytes between reorganized and non-reorganized follicles. The diameter (mean+/-S.E.M.) of oocytes of reorganized follicles increased (P<0.05) from 47.1+/-2.2microm to 65.3+/-2.6microm between Day 2 and Day 42, respectively, but that of oocytes of non-reorganized follicles showed no change. In Experiment 2, oocyte growth and granulosa cell differentiation during long-term culture of primary follicles (>42 days) were examined. Oocytes of reorganized follicles reached a maximum diameter of 75.4+/-2.0microm, a size equivalent to that of oocytes of ovine secondary follicles. Using RT-PCR, mRNA for follicle stimulating hormone receptor was detected in granulosa cells of freshly isolated secondary follicles and of long-term cultured reorganized follicles, but not of non-reorganized follicles. In Experiment 3, we tested if the culture conditions could support further oocyte growth in secondary follicles. The oocytes from enzymatically isolated secondary follicles increased in diameter from 77.7+/-1.6microm to 98.8+/-2.1microm (P<0.05) during 28 days in culture. The changes in oocyte size and in gene expression by granulosa cells support the conclusion that isolated ovine primary follicles developed in vitro to reach the secondary follicle stage.     

The timing of reproductive cell development and movement in Schistosoma mansoni, S. japonicum, and S. haematobium, using techniques of autoradiography and transplantation.

Tritiated thymidine was incorporated into gonial and vitelline cells of male and female Schistosoma mansoni, S. japonicum, and S. haematobium after 2 hr of incubation. Spermatogonial cells developed into labeled mature sperm after 6 days of transplantation in all species. Insemination of females was detected on the same day indicating copulation is frequent. Oogonia labeled in the initial incubation matured into primary oocytes after 7 days of transplantation for S. mansoni and S. haematobium and after 6 days in S. japonicum. Cytoplasmic thymidine label was observed after 2-hr incubations in the primary oocytes of all species. Initial label in the vitellaria was scattered and heavy. After 3 days of transplantation, label was considerably diluted and by day 6 was undetectable in vitelline glands. These times for development and movement of reproductive cells are considered to be standards against which the effects of stressful conditions on the reproductive system can be assessed.     

The effects of pH and weak bases on the in vitro endocytosis of vitellogenin by oocytes of Drosophila melanogaster

Summary The endocytosis of labeled vitellogenin by the developing oocytes of Drosophila melanogaster is pH dependent and inhibited in the presence of primary amines as determined by culturing whole ovaries in vitro. When the pH of the culture medium is adjusted to 6.8 or above, the vitellogenic oocytes sequester labeled vitellogenin synthesized by the follicle cells. The endocytosis of vitellogenin is shown autoradiographically by the accumulation of labeled yolk spheres within the oocytes. When the pH of the medium is reduced to 6.6 or below, the oocytes fail to sequester labeled vitellogenin, as demonstrated by an increase in immunoprecipitable vitellogenin in the culture medium and a concomitant reduction in the number of labeled yolk spheres within the oocytes. Vitellogenin endocytosis is also impaired by the addition of the primary amines methylamine or chloroquine to the culture medium. Monensin, a carboxylic ionophore, is shown to inhibit completely the secretion of labeled vitellogenin from the follicle cells.     

Seasonal histological changes in the gonads of Sebastodes paucispinis ayres,an ovoviviparous teleost (family scorpaenidae)

The elongate paired testes of Sebastodes paucispinis consist of tubules which radiate from a single longitudinal sperm duct and terminate blindly at the periphery of the testis. They are lined by an epithelium consisting of columnar cells with distinct elliptical nuclei. During fall and winter, germ cells migrate inward from the fibrous capsule of the testis and become lodged among the tubule-boundary cells of the seminiferous tubules where they mature into primary spermatogonia. Each of these undergoes several mitotic divisions to produce large cysts of secondary spermatogonia. Subsequent spermatogenic divisions within these cysts produce large sperm-filled cysts which rupture, releasing the spermatozoa into the lumina of the seminiferous tubules. Seasonal cycles of cholesterol and carbohydrate production by the tubule-boundary cells suggest that they perform the same functions as the Leydig cells (androgen production) and Sertoli cells (nutrition) of other vertebrates. The paired fusiform ovaries consist of spongy tissue surrounded by thin-walled muscular ovisacs that converge posteriorly to form a genital duct. The spongy tissue is arranged in transverse lamellae composed of fibrovascular trunks which support epithelial and ovigerous tissue. A series of oocytes (up to 150 μ in diameter) is produced continually from oogonial nests distributed throughout each lamella. Vitellogenesis begins in July and continues throughout the summer. The follicle surrounding the mature oocyte consists of a bilaminar striated vitelline membrane, two epithelial layers (granulosa and theca), and a profuse capillary network. Spermatozoa appear within the ovaries from October to March. Ovulation probably precedes fertilization since spermatozoa were never found within pre-ovulatory or post-ovulatory follicles. The follicular epithelium regresses after ovulation but the capillary beds remain intact, thus providing a mechanism for fetal-maternal exchange of gases and nitrogenous wastes.     

Morphological and histochemical examination of male and female gonads in Homarus gammarus (L. 1758)

The reproductive organs of both male and female European lobsters (Homarus gammarus) are H-shaped gonads that lie dorsal to the gut on the large hepatopancreas. The ovary consists of a pair of tubular, parallel lobules with a connecting bridge. The germarium of the ovary containing oogonia is concentrated in the center of the ovarian lobe. As oogonesis proceeds, the oocytes move to the peripheral regions of the ovary. The follicle cells begin to surround the oocytes in the previtellogenic stage, and the mature oocytes are completely surrounded by the follicle cells. Carbohydrates exist in both early and late vitellogenic oocytes that give PAS positive reaction. However, their rising protein content in late vitellogenic oocytes makes them stain with Bromophenol blue. Testes show convoluted lobules with a germinal epithelium and a central collecting duct, and the paired vasa deferentia have three distinct parts. Spermatophores are nonpedunculate and tubular, which extrude as a continuous column and consist of a sperm mass covered with primary and secondary layers. The primary layer stains with Bromophenol Blue and gives a PAS positive reaction. But the secondary layer only weakly stains with Bromophenol Blue. The histochemical results may indicate that the function of the two layers is different.     

Vitellogenin Incorporation into Oocytes of Rainbow Trout, Oncorhynchus mykiss, in Vitro: Effect of Hormones on Denuded Oocytes

An in vitro culture procedure to measure vitellogenin (VTG) incorporation into oocytes without follicle cell layers was developed using oocytes of the rainbow trout, Oncorhynchus mykiss . Oocytes incorporated VTG specifically and linearly for up to 24 hr. The maximum incorporation observed was 314 μg/24 hr/oocyte, using vitellogenic (3.6 mm diameter) oocytes.
The effect of hormones was examined by adding insulin, growth hormone, prolactin, gonadotropins (GTH-I, GTH-II), thyroid hormones, testosterone, estradiol-17β, or 17α, 20β-dihydroxy-4-pregnen-3-one to the medium. The results indicated that insulin and thyroxine stimulated uptake of VTG by 13% and 12%, respectively. Insulin specifically stimulated VTG incorporation and did not cause any change in background uptake of insulin. The lack of an effect of gonadotropins hormones on denuded oocytes suggests that the previously observed stimulation of VTG incorporation into follicle cell-enclosed oocytes in vivo and in vitro by GTH-I is most likely mediated by the somatic cells of the ovarian follicle.     

STEROID INHIBITION OF PROTEIN INCORPORATION BY ISOLATED AMPHIBIAN OOCYTES

The relationship between blood protein (vitellogenin) incorporation and nuclear maturation was studied in individual amphibian oocytes after in vitro exposure to desoxycorticosterone acetate (DOCA). Isolated Rana pipiens oocytes were incubated in vitro with radioactively labeled oocyte yolk precursor ([³H]vitellogenin) obtained from estrogenized Xenopus laevis. Incorporation of labeled vitellogenin into the oocytes continued over a 24-h period. Oocytes simultaneously exposed to DOCA and to labeled vitellogenin exhibited both inhibition of vitellogenin incorporation and stimulation of nuclear maturation and cortical changes. Inhibition of vitellogenin incorporation was observed after approximately 9 h of incubation and was correlated with the time of nuclear breakdown. Preincubation of oocytes in steroid for 9 h essentially terminated vitellogenin incorporation. Incorporation of vitellogenin occurred after removal of follicle cells from the oocyte by a short treatment with EDTA. These results demonstrate the macromolecular vitellogenin transport system remains operative in oocytes which can undergo nuclear maturation and that the steroid DOCA can affect its function. Evidence suggests that the mechanism of steroid inhibition is in part the result of inhibition of the micropinocytotic process in the oocyte cortex.     

Prepubertal goat oocytes from large follicles result in similar blastocyst production and embryo ploidy than those from adult goats

Developmental competence of oocytes from prepubertal females is lower than those from adult females. Oocyte development competence is positively related to follicular diameter. Most of the follicles of prepubertal goat ovaries are smaller than 3 mm. The aim of this study was to compare oocytes of two follicle sizes (< 3 mm and ≥ 3 mm) from prepubertal goats with oocytes from adult goats in relation to their in vitro production and quality of blastocysts. Oocytes from prepubertal goats were obtained from slaughterhouse ovaries and selected according to the follicle diameter whereas oocytes from adult goats were recovered in vivo by LOPU technique without prior selection of follicle size. COCs were IVM for 27 h, IVF at the conventional conditions with fresh semen and presumptive zygotes were cultured in SOF medium for 8 days. Blastocysts obtained were vitrified and after warming their blastocoele re-expansion and the ploidy by FISH technique were assessed. We found significant differences between blastocysts yield of oocytes recovered from follicles smaller than 3 mm of prepubertal goats compared to those from adult goats (5.45% vs 20. 83%, respectively) however, these differences disappear if oocytes were recovered form large follicles (18.07%). A total of 28 blastocysts were analysed and 96.43% showed mixoploidy. Age did not affect the number of embryos with abnormal ploidy or blastocyst re-expansion after warming. Furthermore, the percentage of diploid blastomeres per embryo was similar in the 3 groups studied, adult, prepubertal from follicles ≥ 3 mm and < 3 mm (68.6%, 80.8% and 73.6%, respectively). In conclusion, IVP of blastocysts coming from follicles larger than 3 mm of goats 45 days old were not different to the blastocysts produced from adult goats, both in terms of quantity and quality.     

Effect of follicle cells on the acrosome reaction, fertilization, and developmental competence of bovine oocytes matured in vitro

The role of follicle cells in the acrosome reaction of frozen-thawed bovine spermatozoa, in vitro fertilization, cleavage, and development in vitro was investigated. Cumulus-oocyte complexes were cocultured and matured in vitro with additional granulosa cells for 24 hr. Immediately before in vitro insemination, the oocytes were divided into three types with different follicle cells: denuded and corona- and cumulus-enclosed oocytes. The proportion of live, acrosome-reacted spermatozoa significantly increased at 3 and 6 hr after insemination in all types of oocytes. However, the mean proportion of live, acrosome-reacted spermatozoa that inseminated cumulus-enclosed oocytes at 6 hr after insemination was significantly higher than that of spermatozoa inseminating denuded oocytes (18.3% and 13.3%, respectively). The frequency of in vitro fertilization was significantly higher for cumulus-enclosed oocytes (65.4%) than for denuded and corona-enclosed oocytes (30.8% and 39.4%, respectively). Cumulus-enclosed oocytes when cocultured with oviduct epithelial cells also had significantly higher rates of cleavage (two- to eight-cell, 59.8%; eight-cell, 22.4%) and blastocyst formation (7.7%) than denuded and corona-enclosed oocytes. No eight-cell embryos or more advanced stages of embryonic development were observed in either denuded or corona-enclosed oocytes without the coculture. The present results indicate that cumulus cells at fertilization play an important role in inducing the acrosome reaction and promoting a high fertilization rate, cleavage, and development into blastocysts in vitro.     

Brief report: Synthesis of ribonucleic acid in oocytes collected from squirrel monkeys and humans following chorionic gonadotropin administration

The time between administration of human chorionic gonadotropin (hCG) and follicle aspiration was analyzed for alterations in [³H]uridine incorporation [as an indicator of relative synthesis of ribonucleic acid (RNA)] of oocytes from squirrel monkeys and humans. There was a significant decline in both the uptake and incorporation of [³H]uridine in squirrel monkey oocytes by 36 hr following hCG administration to the animals, as compared with 16 hr after hCG. Similarly, RNA synthesis diminished in oocytes collected 35 hr after hCG in humans, as compared with 12 hr after hCG. This reduction in RNA synthesis of maturing oocytes is similar to that of other mammalian species. This provides evidence for an increased interval between hCG administration and follicle aspiration in order to recover mature oocytes for in vitro fertilization studies.     

Changes in the protein components of vitelline envelope during oogenesis of a tubiculous polychaete,Schizobranchia insignis

In sabellid polychaetes the vitelline envelopes, in which microvilli with glycocalyx structures at the tips are invested, change in structure during oogenesis. Vitelline envelopes isolated from Schizobranchia oocytes 25–100 μ m and 160–185 μ m in diameter, were analyzed in protein components by iodination, electrophoresis, Western blotting and radioactive labeling technique. The observations demonstrate that the membrane proteins of the vitelline envelopes are not consistent but variable in components during oogenesis. Most of these proteins, particularly the high molecular weight proteins, are PAS-positive glycoproteins, which may have specific carbohydrate residues binding to wheat germ agglutinin. The proteins could be labeled with [³H]valine within 36 h by incubating the whole oocytes in sea water to a high level, indicating that the proteins are actively synthesized by the growing oocytes. Synthetic rates of the proteins differ from each other at one stage and are higher in the small than in the large oocytes in general, suggesting that the membrane proteins are involved in the function of the vitelline envelopes during oogenesis.     

Effect of follicle diameter on oocyte apoptosis, embryo development and chromosomal ploidy in prepubertal goats

The aim of this study was to assess the following parameters in prepubertal goat oocytes of different follicle diameter (≥3 mm, <3 mm, control): oocyte diameter, early (Annexin-V) and late (TUNEL) apoptosis, embryo development and chromosomal ploidy of these blastocysts using Fluorescence In Situ Hybridization (FISH). Before in vitro maturation, oocytes were measured and stained with Annexin-V or TUNEL. The rest of the oocytes were matured, fertilized, and cultured in vitro for 8 days. Oocytes from follicles of ≥3 mm showed greater mean oocyte diameter (128.27 ± 7.20 μm vs. 125.35 ± 7.59 μm), higher percentages of TUNEL positive (42.86 vs. 24.23%), higher cleavage (47.85 ± 3.98 vs. 23.07 ± 2.44 %) and blastocyst rates (19.77 ± 3.04 vs. 4.11 ± 1.10 %) than oocytes from follicles of <3 mm.. Blastocyst mean cell numbers did not show differences between follicular groups (123.83 ± 49.62 vs. 104.29 ± 36.09 for follicles of ≥3 mm and <3 mm, respectively). A total of 54 blastocysts with 7084 nuclei were hybridized with specific probes to chromosomes X and Y. Ninety-eight percent (98%) of the embryos presented at least one cell carrying an abnormal number of chromosomes, but 78% of them presented less than 25% of chromosomal abnormal cells. No differences in the percentage of blastocysts with abnormal ploidy were found in embryos produced from oocytes of different follicle diameter.     

A variant of the pyroantimonate technique suitable for localization of calcium in ovarian tissue.

Osmium-pyroantimonate solutions for the precipitation of cations are unsuitable for use with delicate mammalian oocytes. A variant of the pyroantimonate technique employing a mixture of pyroantimonate and glutaraldehyde has been found to give successful and repeatable results if a fixation time of 4 hr is used. Calcium-containing antimonate precipitates were localized principally in nuclei, smooth endoplasmic reticulum, Golgi apparatus, mitochondria, and cytoplasmic processes of both oocytes and follicle cells, and along the plasma membrane in small oocytes. Deposits were also concentrated around the periphery of lipid droplets in the follicle cells. The presence of calcium in the precipitates was confirmed by x-ray microprobe analysis.     

Polysaccharide Complexes in Full-Grown Oocytes of the Newt, Pleurodeles, and Changes in their Distribution During Progesterone-Induced Maturation

Immature full-grown oocytes of Pleurodeles waltlii contain large amounts of small electron-dense polysaccharidic granules. These granules lack a limiting membrane, and have a dense but heterogeneous matrix and an apparent diameter of 24–36 nm. Their structure, organization and distribution strongly suggest that they are glycogen granules. On the other hand, mature oocytes both after oviposition or 22–24 hr after in vitro progesterone stimulation contain no polysaccharide granules or complexes. During the first 9–10 hr after hormonal stimulation, granules were abundant and present both individually and as large strands occupying most of the space between the organelles. Granules were frequently found packed together and arranged in regularly arrayed stacks within large subcortical ant cortical vacuoles. Between 4 and 6 hr after progesterone addition, oocytes released the contents of vacuoles to the outside. Between about 11 and 14 hr after progesterone addition, oocytes still contained large amounts of polysaccharide complexes, but the vacuoles were empty. From about 15 hr after progesterone treatment until the end of maturation, the complexes progressively disappeared from the cytoplasm, coincident with the detachment of the follicle cell layer from the oocytes and a reduction in the number and size of microvilli.