Quantitation of type II topoisomerase in oocytes and eggs of Xenopus laevis

We have generated a monoclonal antibody and a polyclonal antiserum specific for Xenopus laevis topoisomerase II. Using quantitative immunoprecipitation and Western blotting techniques, we have determined the content of topoisomerase II in X. laevis oocytes during oogenesis and in unfertilized eggs. An average stage I oocyte contains 6 pg of topoisomerase II. The content of topoisomerase II per oocyte increases throughout oogenesis to 1.5 ng per stage VI oocyte. The topoisomerase II protein in stage VI oocytes is stored in the germinal vesicles. The cellular content of type II topoisomerase increases significantly when stage VI oocytes are hormonally stimulated to mature into unfertilized 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 developing Xenopus oocyte specifies the type of gonadotropin-stimulated steroidogenesis performed by its associated follicle cells

As a response to gonadotropin, amphibian ovarian follicles primarily synthesize and secrete estradiol-17 β (E2) during vitellogenesis and progesterone (P) when fully grown. Stage IV (vitellogenic) and stage VI (full-grown) ovarian follicles from Xenopus laevis, as well as intermediate sizes, were used to explore this change in steroidogenesis. Optimum steroidogenesis occurred in both stage IV and stage VI follicles exposed for 6 h to 20 IU human chorionic gonadotropin/mL. Although the total amounts of steroid found were about the same, the E2/P ratios ranged from 26 to 35 for intact stage IV follicles, but only 0.02–0.03 for intact stage VI follicles. Steroid-producing follicle cells were isolated from stage IV and stage VI follicles by non-enzymatic procedures, were washed and were tested for steroidogenic activity in the absence of oocytes. In both cases, P was the predominant steroid produced (E2/P = 0.004–0.04), so the presence of stage IV, but not stage VI, oocytes appears to be necessary for E2 production as a response to gonadotropin. Octanol had no significant effect on the E2/P ratio of intact stage IV follicles. Dissected oocyte/follicle cell preparations from stage IV follicles were also periodically challenged with gonadotropin over 72 h, during which time most follicle cells detached from the oocyte and formed a monolayer over the bottom of the culture dish. The relatively high E2/P ratios for such preparations showed no significant change when stimulated with gonadotropin at various times over the 72 h, as long as the medium was not replaced. We conclude that the estrogenic effect of stage IV oocytes is most likely mediated by a secretory product rather than by gap junctions or by cell contact. Because the X. laevis oocyte has been shown to be a self-differentiating cell, the steroidogenic shift that occurs in developing ovarian follicles appears to be fundamentally regulated by the growing oocyte as it undergoes a physiological change rather than by different gonadotropins.     

Calcium-induced dehiscence of cortical granules in Xenopus laevis oocytes

Microinjection of 0.1 microgram of Ca++ into Xenopus laevis oocytes induces breakdown of the cortical granules. The cortical granules disappeared in both full grown (Stage VI) and small growing (Stage IV) oocytes. Microinjection of Mg++, K+, or Na+ had no effect on cortical granules in either Stage IV or Stage VI oocytes. Small quantities (0.03 microgram) of Ca++ induced dehiscence of the cortical granules only in proximity to the injection site.     

Changes in Xenopus oocyte nucleus and cytoplasm organization after actin filaments depolymerization by latrunculin

Actin-containing filaments have been visualized inside the Xenopus oocyte nuclei due to combination of fluorescence and transmission electron microscopy. It has been shown that these filaments contact with nucleoli, spherical bodies and nuclear pore complexes. The incubation of oocytes with actin-depolymerizing latrunculin causes membrane vesiculation in the cytoplasm, and disruption of the nucleoplasm and nuclear envelope integrity. We suppose that actin-containing filaments belong to crucial cell components which are involved in coordination of nuclear-cytoplasmic interactions as well as distribution and transport of intranuclear components in growing Xenopus oocytes.     

Segregation of mitochondria in the cytoplasm of Xenopus vitellogenic oocytes

In actively growing vitellogenic oocytes of Xenopus laevis mitochondria segregate into 2 populations. One stays around the nucleus, actively replicates mitochondrial DNA (mtDNA), and builds up most of the stock of the mitochondria in the full-grown oocyte. The other moves toward the vegetal pole and stops replicating mtDNA early in vitellogenesis. Organelles of this population are components of the germ plasm of the cell.     

Expression of rat mRNA coding for hormone-stimulated adenylate cyclase in Xenopus oocytes

Beta-Adrenergic agonist-stimulated hyperpolarization, whole-cell cAMP accumulation, and activity of isoproterenol-stimulated membrane-bound adenylate cyclase (EC 4.6.1.1) in Xenopus laevis ovarian oocytes are entirely dependent on the presence of nascent follicle cells. A method was developed to remove rapidly and completely all extra-oocyte cell types to yield defolliculated oocytes that exhibited normal viability and resting membrane potentials yet lacked beta-adrenergic receptor (beta AR)-stimulated responses. Purified follicle membranes contained beta AR-stimulated adenylate cyclase activity, whereas oocyte cell membranes did not. Purified oocyte membrane preparations from X. laevis oocytes previously microinjected with C6-2B rat astrocytoma mRNA, and subsequently defolliculated, exhibited novel beta AR and forskolin-stimulated adenylate cyclase activity. These experiments demonstrate that oocytes expressed rat C6-2B mRNA coding for the beta-adrenergic receptor and the components necessary for forskolin-stimulated adenylate cyclase activity.     

Cathepsin D Activity in the Vitellogenesis of Xenopus laevis

An ovarian extract of Xenopus laevis exhibited in SDS-PAGE analyses an activity cleaving vitellogenin to lipovitellins under mildly acidic conditions. This activity was pepstatin-sensitive and inhibited by monospecific anti-rat liver cathepsin D antibody and thus identified as cathepsin D. Immunoblot analysis showed that two proteins of 43 kDa and 36 kDa immunoreacted with the antibody.
Immunocytochemical staining revealed that the enzyme was located in the cortical cytoplasm of stage I and II oocytes and in small yolk platelets and nascent forms of large yolk platelets in the cortical cytoplasm of stage III oocytes. In stage IV and V oocytes, small yolk platelets retained the immuno-staining but large yolk platelets decreased it. No immuno-positive signals were observed in oocytes at stage VI. When examined by immunoelectron microscopy, gold particles indicated that cathepsin D was located on dense lamellar bodies in the cortical cytoplasm of stage I and II oocytes. The particles were located on primordial yolk platelets and on the superficial layer of small yolk platelets in stage III oocytes, while they were sparse or not present at all on large yolk platelets in stage IV and V oocytes. These results indicate that cathepsin D plays a key role in vitellogenesis by cleaving endocytosed vitellogenin to yolk proteins in developing oocytes.     

Differential subcellular sequestration of proapoptotic and antiapoptotic proteins and colocalization of Bcl-x(L) with the germ plasm, in Xenopus laevis oocytes

Apoptosis is an important element of normal embryonic development and gametogenesis in invertebrate and vertebrate species. Although the components of apoptotic machinery are present in Xenopus laevis fully grown stage VI oocytes and eggs, apoptosis in the developing Xenopus ovary is limited to the somatic cells with no indication of apoptosis in the germ cells. Considering the possibility that Xenopus previtellogenic oocytes might lack the components of the apoptotic pathway, we analyzed Xenopus Stage I oocytes for the presence of the proapoptotic factors Bax and tumor suppressor p53, and antiapoptotic factors Bcl-x(L) and mitochondrial heat shock protein 60 (Hsp60). We found that pro- and antiapoptotic proteins are present in Xenopus oocytes but, surprisingly, they are located in distinct subcellular compartments with proapoptotic proteins Bax and p53 being sequestered in the oocyte nucleus and antiapoptotic protein Bcl-x(L) sequestered in the cytoplasm and highly enriched in the METRO region of the mitochondrial cloud, where it colocalized with the germ plasm, and Hsp60 colocalizing with all mitochondria. The absence of apoptosis in Xenopus early oogenesis is maybe due to differential sequestration of pro- and antiapoptotic molecules.     

Interaction between rat brain microtubule associated proteins (MAPs) and free ribosomes from Xenopus oocyte: a possible mechanism for the in ovo distribution of MAPs

The binding of microtubule associated proteins (MAPs) to free 80 S ribosomes isolated from Xenopus laevis oocytes inhibits in vitro tubulin assembly (Jessus et al., 1984). The inhibition of tubulin polymerisation was shown to be dependent upon GTP. The dose of GTP needed to induce 50% of the maximal effect was 0.5 mM. Furthermore, the inhibition is enhanced by pretreatment of the ribosomes with ATP-gamma-S, and partially abolished after phosphatase treatment, which strongly suggests that protein phosphorylation regulated the inhibitory effect. When fluorescent purified MAPs are microinjected into Xenopus laevis oocyte, they cap 1 h later the basal nuclear envelope; in contrast, when the fluorescent MAPs-ribosome complex is injected, the fluorescent MAPs remain in the cytoplasm and never reach the region underlying the nuclear envelope.     

The function of the nuclear envelope in nuclear protein accumulation

The mechanism by which proteins accumulate in the cell nucleus is not yet known. Two alternative mechanisms are discussed here: (a) selective unidirectional entry of karyophilic proteins through the nuclear pores, and (b) free diffusion of all proteins through the nuclear pores and specific binding of nuclear proteins to nondiffusible components of the nucleoplasm. We present experiments designed to distinguish between these alternatives. After mechanical injury of the Xenopus oocyte nuclear envelope, nuclear proteins were detected in the cytoplasm by immunohistochemical methods. In a second approach, nuclei from X. borealis oocytes were isolated under oil, the nuclear envelopes were removed, and the pure nucleoplasm was injected into the vegetal pole of X. laevis oocytes. With immunohistochemical methods, it was found that each of five nuclear proteins rapidly diffuses out of the injected nucleoplasm into the surrounding cytoplasm. The subsequent transport and accumulation in the intact host nucleus could be shown for the nuclear protein N1 with the aid of a species-specific mAb that reacts only with X. borealis N1. Purified and iodinated nucleoplasmin was injected into the cytoplasm of Xenopus oocytes and its uptake into the nucleus was studied by biochemical methods.     

RNA 3' cleavage and polyadenylation in oocytes and unfertilized eggs of Xenopus laevis

Xenopus laevis histone H4 and H1 genes were transcribed in vitro to generate artificial precursor mRNAs (pre-mRNAs). These pre-mRNAs were microinjected into oocytes, matured oocytes, and unfertilized eggs of Xenopus laevis and their 3' cleavage and polyadenylation were investigated. In the oocyte nucleus both H4 and H1 pre-mRNAs were 3' cleaved but were not detectably polyadenylated. In the oocyte cytoplasm there was neither 3' cleavage nor polyadenylation of these histone pre-mRNAs. When injected into either matured oocytes or unfertilized eggs, the pre-mRNAs underwent 3' cleavage but this was inefficient when compared to the oocyte nucleus. In addition approximately 50% of the remaining uncleaved pre-mRNA was subject to a polyadenylation activity which added A tails of approximately 70 A residues. In contrast, artificial mouse beta-globin pre-mRNAs were not detectably 3' cleaved or polyadenylated in either microinjected oocytes or unfertilized eggs.     

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.     

Oogenesis in Xenopus laevis (Daudin). I. Stages of oocyte development in laboratory maintained animals

Oogenesis in the anuran Xenopus laevis can be divided into six stages based on the anatomy of the developing oocyte. Stage I consists of small (50 to 100 μ) colorless oocytes whose cytoplasm is transparent. Their large nuclei and mitochondrial masses are clearly visible in the intact oocyte. Stage II oocytes range up to 450 μ in diameter, and appear white and opaque. Stage I and II are both previtellogenic. Pigment synthesis and yolk accumulation (vitellogenesis) begins during Stage III. Vitellogenesis continues through Stage IV (600 to 1000 μ), the oocytes grow rapidly, and the animal and vegetal hemispheres become differentiated. By Stage V (1000 to 1200 μ) the oocytes have nearly reached their maximum size and yolk accumulation gradually ceases. Stage VI oocytes are characterized by the appearance of an essentially unpigmented equatorial band. They range in size from 1200 to 1300 μ, are postivtellogenic and ready for ovulation. These stages of oocyte development have been correlated with physiological and biochemical data related to oogenesis in Xenopus.     

Myelin-like structures as a possible source of the smooth endoplasmic reticulum in early amphibian oocytes

A comparative study of amphibian oocyte ultrastructural organization has shown a significant accumulation of elements of the smooth endoplasmic reticulum in the oocyte cytoplasm at the third stage of development. The analysis of oocytes of two frog species, Xenopus laevis and Rana temporaria, at the first and second stages of their development enabled us to recognize in the cytoplasm of the oocyte some myelin-like structures (MLs) made of 30-40 densely packaged membranous layers and shaped as dense bodies. MLs are also present in the adjacent follicular cells and in the intercellular space. In the oocyte cytoplasm these structures are located near the nuclear envelope and other intracellular organelles. At the third stage of oogenesis, which is characterized by a high functional activity of the cells, MLs are seen to unwrap sequentially into double-layer membranes similar to the smooth endoplasmic reticulum cisternae. Intermediate steps of this process being also observed. It is supposed that MLs may play the role of membrane stocks to be used eventually for the formation of nascent endoplasmic membranes in the amphibian oocytes.     

Nuclear and cytoplasmic organization in Xenopus oocytes after disruption of actin filaments by latrunculin

Actin-containing filaments have been visualized inside Xenopus oocyte nuclei by a combination of fluorescence and transmission electron microscopy. It was shown that these filaments contact nucleoli, spherical bodies, and nuclear pore complexes. The incubation of oocytes with actin-depolymerizing agent, latrunculin, caused membrane vesiculation in cytoplasm and the disruption of nucleoplasm and the integrity of the nuclear envelope. We suggest that actin-containing filaments are important cell components involved in the regulation of nucleus-cytoplasm interactions, as well as of cellular transport of components during the growth of Xenopus oocytes.     

Localization and Characterization of Lectins in Yolk Platelets of Xenopus Oocytes

The localization and characteristics of yolk platelet lectins (YLs) in Xenopus laevis oocytes were studied with antiserum against cortical granule lectins (CGLs) as a probe. In oocytes at stages I, II and III-IV, specific, immunofluorescent staining for the lectins was observed on the cortical cytoplasm extending about 2, 4 and 20 μm, respectively, from the egg surface. In stage III-IV oocytes, the superficial layer of the yolk platelets was also stained. The cortical cytoplasm included cortical granules, coated pits, coated vesicles, multivesicular bodies and primordial yolk platelets. The YLs were incorporated into the oocytes by endocytosis as demonstrated using gold-labeled YLs. On PAGE, native YLs gave two bands of CGL-like proteins and proteins that appeared as a single diffuse band. The YLs and the CGLs shared antigenicity and hemagglutination activity specific to D-galactoside residues. However, the proteins of the diffuse band had little or no activity for either hemagglutination or jelly-precipitation, suggesting that they were monomers with a single reactive site. These results indicate that the YLs are supplied to the oocytes, presumably from extracellular sources, polymerized to CGL-like molecules in the cortical cytoplasm and accumulated in the superficial layer of the yolk platelets.     

Oocyte maturation and activation in the common frog and the clawed toad under the action of divalent cations]

Maturation of Rana temporaria and Xenopus laevis oocytes was induced by solutions containing Mn2+ and Co2+ ions. Completion of oocyte maturation was estimated by the following criteria: (1) appearance of the maturation promoting factor (MPF) in the oocyte cytoplasm and (2) oocyte capacity to activation and formation of male pronuclei from the injected sperm nuclei. X. laevis oocytes matured under the effect of Co2+ ions were shown to contain MPF. Oocytes of both species matured under the effect of either ions could not be activated by pricking with a needle and injected sperm nuclei didn't transform into pronuclei. R. temporaria oocytes matured under the effect of ions in late spring, when natural spawning takes place, showed spontaneous activation.     

Talin and vinculin in the oocytes, eggs, and early embryos of Xenopus laevis: a developmentally regulated change in distribution

We have investigated the expression and distribution of talin and vinculin in the oocytes, eggs, and embryos of Xenopus laevis. Antibodies to the previously characterized avian proteins stain several different Xenopus cell types identically by immunofluorescence: adhesion plaques of cultured kidney (A6) cells, the cell peripheries of oviduct cells, and the postsynaptic neuromuscular junctions of tadpole tail muscle fibers. These antibodies also identify cognate proteins of the appropriate sizes on immunoblots of A6 cell and oviduct lysates. Using these antibodies on ovarian tissue, we find talin to be highly localized at the cortices of oocytes and vinculin to be in the oocyte cytoplasm and absent from the oocyte cortex. In the cells of the ovarian layers that surround the oocytes, talin and vinculin can be detected as soluble and cytoskeletal components. Vinculin is first detectable as a cytoskeletal component in eggs, appearing some time during or between oocyte maturation and oviposition. During early embryo development, talin and vinculin are colocalized in the cortex of cleavage furrows and blastomeres. Thus, Xenopus oocytes and eggs display different distributions of talin and vinculin. The change from unlinked localization to colocalization appears to be developmentally regulated, occurring during the transition from oocyte to egg.