Morphodynamics of the contract plate in the course of oocyte maturation in the scyphozoan <Emphasis Type="Italic">Aurelia aurita</Emphasis> (Cnidaria: Semaeostomae)

The structure forming in the area of contact between the oocyte and the germinal epithelium in the course of oocyte maturation of the scyphozoan Aurelia aurita is termed the contact plate. This study traces the successive stages of contact plate formation in the course of oocyte maturation at the light microscopic and ultrastructural levels. At early stages of oocyte development, the appearance of granules is observed in the peripheral cytoplasm of the oocyte; these granules accumulate at the pole, which retains its connection with the germinal epithelium of the gonads. Two types of these granules are recognized: (1) granules with homogeneous content and (2) granules containing loose shapeless material in the form of thick cords. The transformation of type two granules into larger structures, as well as the consolidation of type one and type two granules at later stages of oocyte development, are probably the processes that lead to the formation of the characteristic structure and contact plate, visible in paraffin and semithin sections. It remains unclear where exactly the contact plate is localized at the moment of fertilization: inside or outside the oocyte. The content of granules and components of the plate specifically bind the antibodies (RA47) against mesoglein, the ZP domain-containing protein of the mesoglea of A. aurita. The contact plate, covering only the anomalous pole of the oocyte but detected by the presence of ZP domain-containing proteins, may prove to be the simplest egg membrane of the Zona Pellucida type.     

Plate in the zone of oocyte and germinal epithelium contact in Scyphomedusa Aurelia aurita binds antibodies to ZP-domain protein mesoglein

The morphological features of oocyte and germinal epithelium (epithelial wall of germinal sinus) contact area in Scyphomedusa Aurelia aurita are described. Growing oocytes were divided into seven stages based on oocyte size. The structure revealed the area of contact between the oocyte and the germinal epithelium called the contact plate. During oocyte growth, single granules are fused into the homogeneous mass area of oocyte contact with epithelium. Plate components bound antibodies to mesoglein. It was assumed that the plate material contained ZP-domain proteins. Electrophoresis and immunoblotting results show that proteins immunologically similar to mesoglein have higher molecular masses, probably due to post-translation modifications, which are common for extracellular proteins. On the other hand, however, gonad proteins may be other representatives of jellyfish ZP-domain proteins. Further experiments should be conducted to clarify which alternative is true.     

Precocious loss of cortical granules during mouse oocyte meiotic maturation and correlation with an egg-induced modification of the zona pellucida

Fertilization results in cortical granule exocytosis, which is thought to be involved in modifications of the zona pellucida that constitute the zona pellucida block to polyspermy. A previous report demonstrated that a decrease in the number of Lens culinaris agglutinin-staining granules, which are likely to be cortical granules, occurred during in vivo mouse oocyte maturation with arrest at metaphase II, as well as the formation of a cortical granule-free domain in the area of the metaphase II spindle (T. Ducibella, E. Anderson, D.F. Albertini, J. Aalberg, and S. Rangarajan, 1988, Dev. Biol. 130, 184-197). We extend these observations by reporting here that germinal vesicle-intact oocytes matured in vitro to metaphase II in either the absence or the presence of serum develop a cortical granule-free domain and have reduced numbers of cortical granules when compared to germinal vesicle-intact oocytes; these changes are similar to those of oocytes matured in vivo. The reduction in the number of cortical granules requires germinal vesicle breakdown, since it is prevented by dibutyryl cAMP, which inhibits germinal vesicle breakdown in vitro. The ability of oocytes to respond to the calcium ionophore A23187 with a reduction in the number of cortical granules is also associated with meiotic maturation and develops between 7 and 12 hr after initiation of maturation. The maturation-associated reduction in the number of cortical granules is likely to represent cortical granule exocytosis, since this reduction is accompanied by the formation of a cortical granule-free domain and a conversion of ZP2 to ZP2f when the oocytes are matured in vitro in serum-free medium; this zona pellucida modification occurs following fertilization and is thought to be due to cortical granule exocytosis. In contrast, the loss of cortical granules and development of the cortical granule-free domain of oocytes matured in vitro in the presence of serum is not accompanied by the modification of ZP2. The inhibitory effect of serum on the ZP2 modification may afford in vivo a physiological mechanism to prevent a precocious modification of the zona pellucida that could result in a premature block to polyspermy and hence inhibit fertilization.     

Dynamics of Mitotic Apparatus Formation and Tubulin Content during Oocyte Maturation in Starfish

To follow the topo-temporal behavior of structures containing tubulin and the change in tubulin content during oocyte maturation, starfish oocytes were extracted with a medium containing detergent so that morphological observation and biochemical analysis could be conducted on the same residual oocyte preparation simultaneously. Before 1-methyladenine (1-MeAde) stimulation, "pre-meiotic asters" were observed on the germinal vesicle at the animal pole. 1-MeAde caused the appearance of distinct asters at the position of the aster precursor. When germinal vesicle breakdown (GVBD) took place, chromosomes were condensed. Chromosome gathering was concurrent with a reduction in the size of nuclear matrix. The mitotic apparatus was first constructed parallel to the cortex and then changed its axis perpendicularly. Fluorescence of tubulin due to indirect immunofluorescence in the cytoplasm other than the mitotic apparatus decreased rapidly along the course of maturation at least up to the first metaphase. Despite these dynamic morphological change, the tubulin content in the whole oocyte and the residual structures, measured by SDS-PAGE and immunostaining, did not show remarkable (statistically significant) changes through the course of maturation, although the content tended to decrease a little before the second polar body formation and to increase thereafter in the latter.     

Centriole behavior during meiosis in oocytes of the sea urchin Hemicentrotus pulcherrimus

Ultrastructural changes in the maturing oocyte of the sea urchin Hemicentrotus pulcherrimus were observed, with special reference to the behavior of centrioles and chromosomes, using oocytes that had spontaneously started the maturation division process in vitro after dissection from ovaries. The proportion of oocytes entering the maturation process differed from batch to batch. In those eggs that accomplished the maturation division, it took ~4.5-5 h from the beginning of germinal vesicle breakdown to the formation of a second polar body. Serial sections revealed that a young oocyte before germinal vesicle breakdown had a pair of centrioles with procentrioles, located between the presumed animal pole and the germinal vesicle and accompanied by amorphous aggregates of moderately dense material and dense granules (granular aggregate). Just before germinal vesicle breakdown, a pair of fully grown centrioles located in the granular aggregate, which is present until this stage and then disappears, had already separated from another pair of centrioles. In meiosis I, each division pole had two centrioles, whereas in meiosis II each had only one. The two centrioles in the secondary oocyte separated into single units and formed the mitotic figure of meiosis II. The first polar body had two centrioles and the second had only one. The two centrioles in the first polar body did not form the mitotic figure nor did they separate at the time of meiosis II. These results indicate that, in sea urchins, duplication of the centrioles does not occur during the two successive meiotic divisions and the egg inherits only one centriole from the primary oocyte, confirming the results previously reported for starfish oocytes.     

Modifications of the mouse zona pellucida during oocyte maturation and egg activation: effects of newborn calf serum and fetuin.

A precocious but limited loss of cortical granules (CG) occurs during mouse oocyte maturation both in vivo and in vitro. Although CG loss during maturation in vivo is not associated with changes in the zona pellucida (ZP), a maturation-associated conversion of ZP2 to ZP2f occurs during oocyte maturation in vitro in serum-free medium. We now demonstrate that a maturation-associated change of ZP3 to ZP3f, as assessed by a reduction in sperm binding, also occurs during maturation in vitro in serum-free medium, and that both newborn calf serum (NCS) and fetuin, each of which inhibits the ZP2 conversion, also inhibit the ZP3 conversion. The concentration-dependence of the NCS- and fetuin-mediated inhibition of the ZP2 conversion, coupled with the concentration of fetuin present in NCS, is consistent with fetuin being the component present in NCS that is primarily responsible for this inhibition. Although NCS can inhibit the ZP modifications that occur during oocyte maturation in vitro, ionophore treatment of eggs, which results in an extensive release of CGs over a short period of time, overcomes the inhibitory effect of NCS on the ZP2 conversion. Results of these studies suggest a potential regulatory function of serum-derived components in the formation of a fertilizable egg.     

Oogenesis: From Oogonia to Ovulation in the Flagfish,Jordanella floridae Goode and Bean, 1879 (Teleostei: Cyprinodontidae)

We provide histological details of the development of oocytes in the cyprinodontid flagfish, Jordanella floridae. There are six stages of oogenesis: Oogonial proliferation, chromatin nucleolus, primary growth (previtellogenesis [PG]), secondary growth (vitellogenesis), oocyte maturation and ovulation. The ovarian lamellae are lined by a germinal epithelium composed of epithelial cells and scattered oogonia. During primary growth, the development of cortical alveoli and oil droplets, are initiated simultaneously. During secondary growth, yolk globules coalesce into a fluid mass. The full‐grown oocyte contains a large globule of fluid yolk. The germinal vesicle is at the animal pole, and the cortical alveoli and oil droplets are located at the periphery. The disposition of oil droplets at the vegetal pole of the germinal vesicle during late secondary growth stage is a unique characteristic. The follicular cell layer is composed initially of a single layer of squamous cells during early PG which become columnar during early vitellogenesis. During primary and secondary growth stages, filaments develop among the follicular cells and also around the micropyle. The filaments are seen extending from the zona pellucida after ovulation. During ovulation, a space is evident between the oocyte and the zona pellucida. Asynchronous spawning activity is confirmed by the observation that, after ovulation, the ovarian lamellae contain follicles in both primary and secondary growth stages; in contrast, when the seasonal activity of oogenesis and spawning ends, after ovulation, the ovarian lamellae contain only follicles in the primary growth stage. J. Morphol. 277:1339–1354, 2016. © 2016 Wiley Periodicals, Inc.     

Fetuin inhibits zona pellucida hardening and conversion of ZP2 to ZP2f during spontaneous mouse oocyte maturation in vitro in the absence of serum.

The zona pellucida of mouse oocytes becomes resistant to chymotrypsin digestion, or "hardened", when spontaneous maturation occurs in serum-free medium (De Felici and Siracusa, Gam Res 1982; 6:107). The hardened zona pellucida is refractory to sperm penetration, thus preventing fertilization. Conversion of the zona pellucida glycoprotein ZP2 to ZP2f by a protease from precociously released oocyte cortical granules appears to be a major contributory factor of zona pellucida hardening (Ducibella et al., Dev Biol 1990; 137:46). Fetal bovine serum (FBS) prevents zona hardening and the ZP2 to ZP2f conversion during oocyte maturation in vitro (Downs et al., Gam Res 1986; 15:115; Ducibella et al., Dev Biol 1990; 137:46). This study was conducted to determine whether fetuin, a major glycoprotein constituent of FBS and a protease inhibitor, could prevent zona pellucida hardening during murine oocyte maturation in serum-free medium. Commercially available preparations of fetuin purified by three different methods were all active in inhibiting zona pellucida hardening in a concentration-dependent manner. Further chromatographic purification of one of these preparations indicated that the activity preventing zona pellucida hardening was associated specifically with fetuin. Fetuin also inhibited the conversion of ZP2 to ZP2f in a concentration-dependent manner during oocyte maturation in serum-free medium. Moreover, oocytes that matured in serum-free medium containing fetuin could be fertilized and could undergo preimplantation development to the blastocyst stage. These results indicate that fetuin, a component of FBS, inhibits zona pellucida hardening during oocyte maturation, and suggest that fetuin acts by preventing the proteolytic conversion of ZP2 to ZP2f by precociously released cortical granules.     

Changes in subcellular localization of mtlrRNA outside mitochondria in oogenesis and early embryogenesis of Drosophila melanogaster

Mitochondrial large ribosomal RNA (mtlrRNA) has been identified as a cytoplasmic factor inducing pole cells in ultraviolet (UV)-sterilized Drosophila embryos. In situ hybridization studies have revealed that mtlrRNA is present outside mitochondria localized on the surface of polar granules during the cleavage stage. In the present study, we describe the developmental changes in extramitochondrial mtlrRNA distribution through early embryogenesis using in situ hybridization at the light and electron microscopic level. No mtlrRNA signal was discernible on polar granules in the mature oocyte, unless the oocyte was activated for development. mtlrRNA was localized on the surface of polar granules during a limited period of stages from oocyte activation to pole bud formation and disappeared as soon as being detached from polar granules without entering pole cells. These changes in the temporal and spatial distribution of mtlrRNA outside mitochondria are compatible with the idea that mtlrRNA is required for pole cell formation but not for the differentiation of pole cells as functional germ cells.     

High doses of medroxyprogesterone as the cause of disappearance of adherence of the zona pellucida to an oocyte

The zona pellucida (ZP) is an external glycoprotein membrane of oocytes of mammals and embryos in the early stage of their development. ZP first appears in growing ovarian follicles as an extracellular substance between the oocyte and granular cells. The zona pellucid markedly affects the development and maturation of the oocyte. The morphology of the ZP-oocyte complex allows a more precise determination of the oocyte maturity. According to numerous experimental studies, ZP is essential for preimplantation embryonic development of humans and other mammals. It prevents dispersion of blastomeres and enhances their mutual interactions. ZP is a dynamic structure responsible for the provision of nutrients to early forms of oocytes in mammals. The aim of the present study was untrastructural evaluation of the ZP-oocyte contact during inhibited ovulation. Female white rats (Wistar strain) received a suspension of medroxyprogesterone acetate (MPA) in incremental intramuscular bolus doses of 3.7 mg (therapeutic dose), 7.4 mg and 11.1 mg. The animals were decapitated 5 days after the administration of MPA. Ovarian sections were evaluated under a transmission electron microscope (TEM) Zeiss EM 900. Morphometric analysis of ZP was conducted using the cell imaging system by Olympus. In females exposed to therapeutic doses of MPA, ZP showed the structure of granular-fibrous reticulum of a medium electron density with single cytoplasmic processes originating from the surrounding structures. The oocyte cell membrane generated single, delicate processes directed toward ZP. Microvilli of the oocyte were short and thin. In the group receiving 7.4 mg of MPA, ZP had the structure of a delicate, loose granular-fibrous reticulum, and the oocyte cell membrane generated single microvilli directed toward ZP. In both those groups, the close ZP-oocyte contact was observed. Otherwise, in the group exposed to the highest MPA doses (11.1 mg), thicker and more numerous oocyte microvilli were found, which did not penetrate ZP matrix. They were dense, irregularly separated contour, forming a barrier between ZP and oocyte. The present findings are likely to suggest that MPA has inhibiting effects on the synthesis of binding proteins and causes the loss of the oocyte contact with ZP.     

Nuclear requirement of post-maturational cortical differentiation of amphibian oocytes: effects of cycloheximide.

Cycloheximide induced a complex series of alterations in the cortical cytoplasm of amphibian (Rana pipiens) oocytes undergoing steroid induced nuclear and cytoplasmic maturation in vitro. The morphological changes were described and the role of nuclear-cytoplasmic interactions in the induction of these changes was investigated in intact, enucleated and enucleated-reinjected oocytes. Three stages of cortical changes were ascertained on the basis of: localized alterations at the animal pole, redistribution of pigment and localized contractility (furrow formation) primarily along the animal:vegetal pole axis. The extent and type of cortical alterations varied depending upon the time at which oocytes were examined following hormonal stimulation and cycloheximide treatment. Cycloheximide did not produce cortical alterations in non-hormone treated oocytes nor in steroid treated oocytes until after germinal vesicle breakdown. Nuclear and cytoplasmic maturation and the appearance of cortical alterations were all inhibited when cycloheximide was added to oocytes at the time of steroid treatment. Cycloheximide induction of cortical alterations occurred only after the inhibitor was no longer effective in preventing germinal vesicle breakdown. Enucleated oocytes underwent cytoplasmic maturation in response to the steroid but exhibited no cortical alterations following the delayed addition of cycloheximide. Simultaneous administration of cycloheximide and steroid to enucleated oocytes inhibited cytoplasmic maturation and all observable cortical alterations. Reinjection of nuclear material into enucleated oocytes restored the ability of cycloheximide to induce cortical alterations following steroid induction of cytoplasmic maturation. Without steroid treatment, such reinjected oocytes did not exhibit cortical changes in response to cycloheximide. The data demonstrate that the nucleus is required for and contains a factor(s) which controls the cycloheximide response and post-maturation differentiation of the oocyte. The maturational changes in the cortical cytoplasm appear to be dependent on the intermixing of the germinal vesicle nucleoplasm materials with mature cytoplasm following germinal vesicle breakdown. The results further suggest that the cortical effects of cycloheximide are dependent upon the initiation of protein synthesis during this period of oocyte development. The significance of these observations and experimental studies are discussed in relation to current understanding of the molecular mechanisms controlling meiosis induction and the composition of the germinal vesicle.     

Distribution of the Germinal Vesicle Material during Progesterone-Induced Oocyte Maturation in Xenopus and in Cynops

The distribution of the germinal vesicle material in the oocyte during progesterone-induced maturation was studied in Xenopus and in Cynops. In both species, two distinctive masses of yolkfree cytoplasm appear in specific areas of the oocyte and at definite stages of maturation. One, the primary cytoplasmic mass, is formed at the basal side of the germinal vesicle during early maturation and is very RNA-rich. In Xenopus , a large part of the primary cytoplasmic mass persists as a mass during maturation and ends up as a thin disk at the boundary between the animal and the vegetal hemisphere in the mature oocyte. In Cynops , a rod-like primary cytoplasmic mass extends near to the equatorial zone and becomes indistinct in the mature oocyte. The other, the secondary cytoplasmic mass, is formed at or prior to germinal vesicle breakdown in areas around the germinal vesicle and is also RNA-rich. The secondary cytoplasmic mass is dispersed and constitutes the RNA-rich animal hemisphere cytoplasm in the mature oocyte. Observed results suggest that the primary and the secondary cytoplasmic mass contain different germinal vesicle materials.     

FORMATION AND BEHAVIOR OF PINOSOMES IN THE SEA URCHIN OOCYTE DURING OOGENESIS

Formation and behavior of the pinosomes at the surface of the oocyte during oogenesis in the 4 species of sea urchins, Anthocidaris crassispina, Temnopleurus toreumaticus, Mespilia globulus and Pseudocentrotus depressus, were studied. The plasma membrane of the oocyte is almost smooth at the early stage of oogenesis, although a small number of cytoplasmic processes appear on it, facing the germinal epithelium. At the beginning of vitellogenetic stage many processes appear on the whole surface of the oocyte. Near the base of the fully grown process, the pinosome designated as the α-pinosome is formed. The α-pinosome may play a part in maturation of the yolk granule. The processes shorten as a whole at the time of the breakdown of the germinal vesicle. Formation of the pinosome designated as the β-pinosome begins just before vitellogenetic stage and continues during this stage. The β-pinosome may be directly concerned with the formation of cortical granules.     

Cytochemical demonstration of modification of carbohydrates in the mouse zona pellucida during folliculogenesis

In the present study, lectin-gold cytochemistry and antibodies against ZP2 and ZP3 glycoproteins were used to investigate the oligosaccharide content of mouse ovarian zona pellucida (ZP) during follicular development. The entire thickness of the ZP and several organelles of the oocyte (cortical granules, Golgi apparatus, and vesicular aggregates) were reactive to RCA-I, DSA, AAA, WGA, MAA, and LFA throughout follicular development. HPA labeling was not detected at the earliest stages of follicular folliculogenesis. HPA reactivity was first observed in the ZP, Golgi apparatus, and the vesicles of oocytes at the trilaminar primary follicle stage. HPA labeling in the ZP was always restricted to the inner region of the zona matrix. After neuraminidase treatment, HPA reacted with the entire ZP in ovarian follicles at different stages of development. Immunolabeling with specific antibodies showed that, although ZP2 and ZP3 glycoproteins were uniformly distributed in the zona matrix of ovarian oocytes, there was a progressive increase in thickness of the ZP in parallel with the proliferation of follicular cells. ZP3 glycoprotein was also localized to the Golgi apparatus and vesicular aggregate. The present results suggest: (1) a difference in composition of carbohydrate content between the inner and outer region of the fully developed ZP generated probably by a modification in the biosynthetic pathway of oligosaccharides in the oocyte during folliculogenesis, (2) that newly synthesized ZP glycoproteins displace previously synthesized ZP components in a direction toward the follicular cells and, therefore, no redistribution of the ZP matrix occurs during folliculogenesis, and (3) that the vesicular aggregates in the ooplasm constitute an intermediate step in the secretory pathway of ZP glycoproteins. Accepted: 10 January 2000     

Maturation conditions and boar affect timing of cortical reaction in porcine oocytes

The cortical reaction induces changes at the egg's Zona pellucida (ZP), perivitelline space and/or oolemma level, blocking polyspermic fertilization. We studied the timing of sperm penetration and cortical reaction in pig oocytes matured under different conditions and inseminated with different boars. Immature (germinal vesicle stage) and in vitro matured (IVM) (metaphase II stage) oocytes were inseminated and results assessed at different hours post insemination. Penetrability and polyspermy rates increased with gamete coincubation time and were higher in IVM oocytes. A strong boar effect was observed in IVF results. Cortical reaction (assessed as area occupied by cortical granules) and galactose-β(1-3)-Nacetylgalactosamine residues on ZP (area labeled by peanut agglutinin lectin, PNA) were assessed in IVM and in vivo matured (IVV) oocytes at different hours post insemination. After maturation, IVM and IVV oocytes displayed similar area occupied by cortical granules and it decreased in fertilized oocytes compared to unfertilized ones. Cortical reaction was influenced by boar and was faster in polyspermic than in monospermic oocytes, and in IVM than in IVV oocytes. The outer ZP of inseminated oocytes appeared stained by PNA and the labeled area increased along with gamete coculture time. This labeling was also observed after insemination of isolated ZP, indicating that this modification in ZP carbohydrates is not induced by cortical reaction. The steady and maintained cortical reaction observed at 4 to 5 h post insemination in IVV monospermic oocytes might reflect the physiological time course of this important event in pigs. Both maturation conditions and boar affect cortical granules release.     

Ultrastructural changes during nuclear maturation in Bufo arenarum oocytes.

During progesterone-induced nuclear maturation the oocytes of Bufo arenarum undergo a series of nuclear and cytoplasmic changes. The breakdown of heterocellular communications between the follicular cell projections and the oocyte microvilli, and the consequent enlargement of the perivitelline space, were observed at the animal pole. The more evident cytoplasmic feature during nuclear maturation comprised the gathering of glycogen granules in clusters, some phagocytosed by empty vesicles. With respect to the location of these vesicles, some were observed in close proximity to the oolemma and others were freely suspended in the perivitelline space, extruded from the oocyte. Other visible events were the disruption of the annulate lamellae, the formation of an elaborate cortical endoplasmic reticulum and the rearrangement of the cortical granules in a monolayer immediately beneath the oolemma together with aggregates of endoplasmic reticulum cisternae. Our results show that during nuclear maturation the nuclear oocyte changes include a flattening of the spherical oocyte nucleus, its migration towards the surface of the animal pole, the disappearance of the nucleoli and the dissolution of the nuclear envelope.     

Surface alterations of the bovine oocyte and its investments during and after maturation and fertilization in vitro

Surface characteristics of the bovine oocyte and its investments before, during, and after maturation, and fertilization in vitro were evaluated by scanning electron microscopy (SEM). Oocyte diameters were also measured during SEM analysis of the oocyte. The cumulus cells manifested a compact structure with minimal intercellular spaces among them in the immature oocytes. These became fully expanded with increased intercellular spaces after maturation in vitro, but contracted again after fertilization. The zona pellucida (ZP) showed a fibrous, open mesh-like structure in the maturing and matured oocytes. The size and number of meshes on the ZP decreased dramatically after fertilization. The vitelline surface of immature oocytes was characterized by distribution of tongue-shaped protrusions (TSPs) varying in density. After 10 and 22 hr of maturation incubation, oocyte surface microvilli (MV) increased to become the predominant surface structure, and TSPs decreased substantially. The vitelline surface of fertilized oocytes (at 6 and 20 hr) was similar to that of the matured oocytes, but unfertilized oocytes had less dense MV than did fertilized oocytes (at 20 hr). The diameter of the oocytes decreased from 99 to 80 μm during maturation and increased to 106 μm after insemination (P < 0.05). Membrane maturation was characterized by surface changes from a TSP-predominant pattern to a MV-predominant pattern. Thus, the bovine oocyte maturation process was found to involve the expansion of cumulus cells and the maturation of the ZP, which changes dramatically upon fertilization. Also, volumetric changes occurred in ooplasm processed for SEM following oocyte maturation and insemination. © 1994 Wiley-Liss, Inc.     

The mitochondrial cloud of Xenopus oocytes: the source of germinal granule material

The mitochondrial cloud is a prominent mass in the cytoplasm of previtellogenic oocytes of Xenopus laevis. It is shown here that the cloud contains both mitochondria and electron-dense granulofibrillar material (GFM). Using a combination of light microscopical, fluorescence, time-lapse filming, and electron microscopical techniques, the ontogeny of these components is reported and their fate is studied. It was found that the cloud is stationary in previtellogenic stages and fragments into islands of mitochondria and GFM during stage II (using the staging system of J. N. Dumont [1972) J. Morphol. 136, 153-180). These islands become localized in the peripheral cytoplasm at one pole of the stage III oocyte. By studying successive stages, GFM was followed through oogenesis and it was found localized only at the vegetal pole of stage IV and V oocytes. Furthermore, it was found that it bears a striking resemblance in position, appearance, and associations with mitochondria to the "germinal granules" of unfertilized eggs. Germinal granules have been shown by others to become incorporated into germ-line cells. It is concluded that the GFM is the precursor of this material and that the mitochondrial cloud is the site of its accumulation and localization in the previtellogenic oocyte.