Changes in mitochondria density during oogenesis of loach]

The growth of loach oocytes is accompanied by an increase in the density of mitochondria. Simultaneously with the increase in density an acceleration of 14C-valine incorporation into mitochondrial proteins takes place. It is assumed that the increase in mitochondria density during oogenesis is due to an increase in the amount of membrane material per unit of mitochondria weight.     

A study of X chromosome regulation during oogenesis in the mouse

Mature oocytes of mammals, in contrast to somatic cells, have two active X chromosomes. This situation might arise through either of two possible mechanisms. The germ line might be differentiated from somatic cells prior to X inactivation. Alternatively, an X chromosome in germ cells would be reactivated after prior inactivation. This paper presents data compatible with reactivation of the X in germ cells. X-linked enzymes were compared in oocytes of XX and XO fetal mice. The activity of G6PD is similar in the two classes of cells at early meiotic stages, but an $\text{XX}\text{XO}$ ratio of 2:1 is approached at later times; this suggests reactivation of the G6PD locus. For HPRT, a 2:1 ratio is observed at all meiotic stages. HPRT shows a large increase in enzyme activity during early meiosis, while G6PD does not. Synthesis of this enzyme at early meiotic stages probably accounts for differences between these data and those obtained for G6PD, and places the time of X reactivation at the entry to meiosis.     

Rebuilding MTOCs upon centriole loss during mouse oogenesis

The vast majority of animal cells contain canonical centrosomes as a main microtubule-organizing center defined by a central pair of centrioles. As a rare and striking exception to this rule, vertebrate oocytes loose their centrioles at an early step of oogenesis. At the end of oogenesis, centrosomes are eventually replaced by numerous acentriolar microtubule-organizing centers (MTOCs) that shape the spindle poles during meiotic divisions. The mechanisms involved in centrosome and acentriolar MTOCs metabolism in oocytes have not been elucidated yet. In addition, little is known about microtubule organization and its impact on intracellular architecture during the oocyte growth phase following centrosome disassembly. We have investigated this question in the mouse by coupling immunofluorescence and live-imaging approaches. We show that growing oocytes contain dispersed pericentriolar material, responsible for microtubule assembly and distribution all over the cell. The gradual enlargement of PCM foci eventually leads in competent oocytes to the formation of big perinuclear MTOCs and to the assembly of large microtubule asters emanating from the close vicinity of the nucleus. Upon meiosis resumption, perinuclear MTOCs spread around the nuclear envelope, which in parallel is remodelled before breaking-down, via a MT- and dynein-dependent mechanism. Only fully competent oocytes are able to perform this dramatic reorganization at NEBD. Therefore, the MTOC-MT reorganization that we describe is one of key feature of mouse oocyte competency.     

X chromosome expression during oogenesis in the mouse.

The activities of glucose-6-phosphate dehydrogenase (G6PD) and lactate dehydrogenase (LDH) have been assayed in mouse oocytes at several stages of follicle development isolated from XX and XO female mice. Throughout the entire growth period the activity of G6PD was proportional to the number of X chromosomes present in the oocyte, whereas no difference in LDH activity was detected between XX and XO oocytes. It is concluded, therefore, that both X chromosomes are functional throughout oogenesis.     

The occurrence of intercellular bridges during oogenesis in the mouse

A fine structural analysis of fetal mouse ovaries reveals the presence of intercellular bridges between developing oocytes. These bridges, which connect two or more oocytes, are most frequently seen prior to the dictyate stage of meiotic prophase. The intercellular connections are limited by a tri-laminar membrane which is continuous with the oocyte plasmalemma. A characteristic feature of all bridges is the presence of an electron-dense material on the cytoplasmic side of the limiting membrane. Since this dense material is a constant and conspicuous component of the entire bridge, identification of these connections is possible in all planes of section. In cross section, the bridges are usually cylindrical, while in longitudinal section, a variety of configurations are observed. Oocytes connected by intercellular bridges exhibit a highly developed Golgi complex which is frequently localized in the region of the cytoplasmic continuities. Vesicular elements, apparently derived from the Golgi, are routinely observed within the boundaries of the bridges. Other cytoplasmic organelles, including rough and smooth endoplasmic reticulum, free ribosomes and mitochondria, are also seen in these bridges. The presence of these vesicles and organelles within intercellular bridges suggests that these connections may provide a means for transfer of organelles and other substances from one oocyte to another. It may be, therefore, that intercellular bridges are important for the nourishment and maturation of certain selected oocytes as well as for the synchronization of meiotic events.     

Biosynthesis of the sperm receptor during oogenesis in the mouse

During their growth phase, mouse oocytes synthesize and secrete three different glycoproteins, called ZP1, 2 and 3, that constitute the extracellular coat, or zona pellucida, of the oocyte. One of these glycoproteins, ZP3, exhibits properties expected for a sperm receptor. We have now used rabbit antisera that recognize ZP3 to immunoprecipitate [35S]methionine-labeled, intracellular precursors of this glycoprotein from growing oocytes cultured in vitro in the presence or absence of tunicamycin, a drug that prevents addition of N-linked oligosaccharides to nascent polypeptide chains. Electrophoretic analyses of these immunoprecipitates, as well as of immunoprecipitates digested with endo-beta-N-acetylglucosaminidase H (Endo H), indicate that ZP3 is synthesized as a 44,000 mol. wt. polypeptide chain to which either three or four high-mannose-type oligosaccharides are added, resulting in 53,000 and 56,000 mol. wt. ZP3 precursors, respectively. The latter species are converted to mature ZP3 (mol. wt. approximately 80,000) by processing of the high-mannose-type oligosaccharides (Endo H-sensitive) to complex-type oligosaccharides (Endo H-insensitive) prior to ZP3 secretion. The evidence presented reveals that the extreme heterogeneity of mature ZP3, with respect to both mol. wt. and isoelectric point, is partly a consequence of the N-linked oligosaccharides and not the polypeptide chain itself.     

Confocal microscopy analysis of the activity of mitochondria contained within the 'mitochondrial cloud' during oogenesis in Xenopus laevis.

We have used ratiometric confocal microscopy and three fluorescence techniques to study the distribution and activity of mitochondria in frog oocytes during the early stages of oogenesis. Mitochondria in frog oocytes during oogenesis were characterised by a high ratio in the 'mitochondrial cloud' and perinuclear region and a low ratio in mitochondria freely dispersed within the cytoplasm. We tested whether the high ratio visualised by the three techniques represented mitochondrial membrane potential by perturbing the mitochondrial membrane potential. Carbonyl cyanide p-(trifluoromethyl)phenylhydrazone (FCCP) caused the immediate destruction of the membrane potential, and consequent loss of fluorescence from the membrane-potential-sensitive confocal channel. In contrast, nigericin caused an increase in membrane potential represented by a steady increase in fluorescence ratio. These data demonstrate that mitochondrial activity can be measured during oogenesis in frog oocytes, and suggest that the mitochondrial cloud and perinuclear regions are characterised by highly active mitochondria.     

Cytoskeleton organization during oogenesis, fertilization and preimplantation development of the mouse

The organization and role of the cytoskeletal networks (mainly microtubules and microfilaments) during oogenesis, fertilization and preimplantation development of the mouse are described given the importance of cell-cell interactions and of the subcellular organization in events leading to the formation of the first two lineages of the mouse embryo.     

Notch pathway regulates female germ cell meiosis progression and early oogenesis events in fetal mouse

A critical process of early oogenesis is the entry of mitotic oogonia into meiosis, a cell cycle switch regulated by a complex gene regulatory network. Although Notch pathway is involved in numerous important aspects of oogenesis in invertebrate species, whether it plays roles in early oogenesis events in mammals is unknown. Therefore, the rationale of the present study was to investigate the roles of Notch signaling in crucial processes of early oogenesis, such as meiosis entry and early oocyte growth. Notch receptors and ligands were localized in mouse embryonic female gonads and 2 Notch inhibitors, namely DAPT and L-685,458, were used to attenuate its signaling in an in vitro culture system of ovarian tissues from 12.5 days post coitum (dpc) fetus. The results demonstrated that the expression of Stra8, a master gene for germ cell meiosis, and its stimulation by retinoic acid (RA) were reduced after suppression of Notch signaling, and the other meiotic genes, Dazl, Dmc1, and Rec8, were abolished or markedly decreased. Furthermore, RNAi of Notch1 also markedly inhibited the expression of Stra8 and SCP3 in cultured female germ cells. The increased methylation status of CpG islands within the Stra8 promoter of the oocytes was observed in the presence of DAPT, indicating that Notch signaling is probably necessary for maintaining the epigenetic state of this gene in a way suitable for RA stimulation. Furthermore, in the presence of Notch inhibitors, progression of oocytes through meiosis I was markedly delayed. At later culture periods, the rate of oocyte growth was decreased, which impaired subsequent primordial follicle assembly in cultured ovarian tissues. Taken together, these results suggested new roles of the Notch signaling pathway in female germ cell meiosis progression and early oogenesis events in mammals.     

Expression of creatine kinase isoenzyme during oogenesis and embryogenesis in the mouse

Creatine kinase activity was discovered in the growing mouse oocyte and in the preimplantation embryo. Changes in the enzyme activity during the growth and maturation of the egg and during the development of the embryo up to the blastocyst stage were determined. Close similarity of the protein to the brain-type isoenzyme of creatine kinase was established immunochemically. The kinetic parameters of the brain-type isoenzyme (M. R. Iyengar, C. E. Fluellen, and C. W. L. Iyengar, 1982, J. Muscle Cell Motil. 3, 231–246) and the pattern of development-associated changes in activity suggest a possible role for creatine kinase in maintaining the reported high ATP/ADP ratio (L. Ginsberg and N. Hillman, 1975, J. Reprod. Fertil. 43, 83–90), which is essential for the biosynthetic activities of the embryo.     

The fine structure of mitochondria and the mitochondrial cloud during oogenesis on the sea anemone Actinia

The appearance and arrangement of the mitochondria during all stages of oocyte growth in the sea anemone Actinia fragacea (Cnidaria: Anthozoa) have been examined by electron microscopy. In small oocytes, the mitochondria are generally squat, with a dense matrix and numerous cristae, although a proportion may show an unusual arrangement of prismatic cristae. During early oogenesis, the mitochondria tend to be arranged in aggregates rather than randomly scattered, and may be associated with nuage material. With the onset of vitellogenesis, a large mitochondrial aggregate forms next to the nucleus. During early vitellogenesis this aggregate enlarges and comes to resemble the mitochondrial clouds found in some amphibian oocytes. Within the cloud, many mitochondria appear to be highly elongate and irregular in shape. The cloud begins to fragment and disperse midway through vitellogenesis at about the time when cortical granules appear. In fully grown oocytes, some mitochondria may have a much less dense matrix and fewer cristae than the remainder, which may be related to their state of activity.     

A homeo-box-containing gene expressed during oogenesis in Xenopus

We report the isolation of a second Xenopus gene containing a homeo domain homologous to those of Drosophila. Out of 60 amino acids, 59 are conserved with Antennapedia, and 54 with a previously isolated frog gene. The predicted carboxy-terminus of this homeotic-like protein is 21 amino acids downstream from the conserved domain, ending with six glutamic acids in a row. The main interest of this gene lies in the fact that it is abundantly transcribed in large Xenopus oocytes, where it might be translated into proteins potentially involved in the early determination of embryonic cell types.     

Stereological studies of mitochondria during the implantation of mouse blastocytes

The following stereological parameters of mitochondria were compared in trophoblast of 5 and 6 day blastocysts: volume density of inner membrane (Vim), outer membrane (Vom), matrix (Vmat), outer compartment (Voc), surface density of outer membrane (Som) and inner membrane (Sim). They were the basis to calculate the partition coefficient of matrix (Emm) and the partition coefficient of outer compartment (Eocm). On 6 day after fertilization we found statistically significant volume increase of Vim, Voc, Sim, Som, Eocm and volume decrease of Vom, Vmat and Emm. Mitochondria visual evaluation and stereological analysis made for both groups allow to classify them to metabolic transitional state.     

Proteomic analysis and functional characterization of mouse brain mitochondria during aging reveal alterations in energy metabolism

Mitochondria are the main cellular source of reactive oxygen species and are recognized as key players in several age‐associated disorders and neurodegeneration. Their dysfunction has also been linked to cellular aging. Additionally, mechanisms leading to the preservation of mitochondrial function promote longevity. In this study we investigated the proteomic and functional alterations in brain mitochondria isolated from mature (5 months old), old (12 months old), and aged (24 months old) mice as determinants of normal “healthy” aging. Here the global changes concomitant with aging in the mitochondrial proteome of mouse brain analyzed by quantitative mass‐spectrometry based super‐SILAC identified differentially expressed proteins involved in several metabolic pathways including glycolysis, the tricarboxylic acid cycle, and oxidative phosphorylation. Despite these changes, the bioenergetic function of these mitochondria was preserved. Overall, this data indicates that proteomic changes during aging may compensate for functional defects aiding in preservation of mitochondrial function. The mass spectrometry proteomics data have been deposited to the ProteomeXchange Consortium with the data set identifier PXD001370 ( http://proteomecentral.proteomexchange.org/dataset/PXD001370 ).