Vitelline envelope formation during oogenesis in Bufo arenarum.

The formation of vitelline envelope (VE) during the oogenesis of Bufo arenarum (Amphibia Anura) is described. At the stage of early vitellogenesis, the first structures appear: the number of oocyte microvilli increases, and many cross sections of them are observed between the follicle cells and the oocyte. A filamentous material is observed inside the follicle cells and between the follicle cells and the oocyte. Multivesicular bodies are also found in the follicle cells, and in the perivitelline space. The micrographs also suggest the participation of the oocyte in the process of VE formation: large vesicles are present in the cortex of the oocyte, filled with an amorphous material of low and uniform electron density. Some of them are in the process of releasing their content to the perivitelline space. Many vesicles (probably resulting from microvilli fragmentation) are also observed in the perivitelline space. During late vitellogenesis the VE is a continuous structure between the layer of follicle cells and the oocyte. The filamentous material is aggregated in bundles, forming a net, and the spherical components are now either included in the orifices of the net, or free near the oocyte's surface. At the end of oogenesis, when the VE is completely formed, it is difficult to distinguish its components independently. Immunolocalization with antibodies against VE, show a positive reaction in follicle cells and oocytes in previtellogenic and full grown ovarian follicles. This analysis suggests that both the oocyte and the follicle cells are directly involved in the synthesis and secretion of the components of the vitelline envelope in Bufo arenarum.

Vitelline envelope formation during oogenesis in Bufo arenarum

The formation of vitelline envelope (VE) during the oogenesis of Bufo arenarum (Amphibia Anura) is described. At the stage of early vitellogenesis, the first structures appear: the number of oocyte microvilli increases, and many cross sections of them are observed between the follicle cells and the oocyte. A filamentous material is observed inside the follicle cells and between the follicle cells and the oocyte. Multivesicular bodies are also found in the follicle cells, and in the perivitelline space. The micrographs also suggest the participation of the oocyte in the process of VE formation: large vesicles are present in the cortex of the oocyte, filled with an amorphous material of low and uniform electron density. Some of them are in the process of releasing their content to the perivitelline space. Many vesicles (probably resulting from microvilli fragmentation) are also observed in the perivitelline space. During late vitellogenesis the VE is a continuous structure between the layer of follicle cells and the oocyte. The filamentous material is aggregated in bundles, forming a net, and the spherical components are now either included in the orifices of the net, or free near the oocyte's surface. At the end of oogenesis, when the VE is completely formed, it is difficult to distinguish its components independently. Immunolocalization with antibodies against VE, show a positive reaction in follicle cells and oocytes in previtellogenic and full grown ovarian follicles. This analysis suggests that both the oocyte and the follicle cells are directly involved in the synthesis and secretion of the components of the vitelline envelope in Bufo arenarum.

Vitelline envelope formation during oogenesis in Bufo arenarum

The formation of vitelline envelope (VE) during the oogenesis of Bufo arenarum (Amphibia Anura) is described. At the stage of early vitellogenesis, the first structures appear: the number of oocyte microvilli increases, and many cross sections of them are observed between the follicle cells and the oocyte. A filamentous material is observed inside the follicle cells and between the follicle cells and the oocyte. Multivesicular bodies are also found in the follicle cells, and in the perivitelline space. The micrographs also suggest the participation of the oocyte in the process of VE formation: large vesicles are present in the cortex of the oocyte, filled with an amorphous material of low and uniform electron density. Some of them are in the process of releasing their content to the perivitelline space. Many vesicles (probably resulting from microvilli fragmentation) are also observed in the perivitelline space. During late vitellogenesis the VE is a continuous structure between the layer of follicle cells and the oocyte. The filamentous material is aggregated in bundles, forming a net, and the spherical components are now either included in the orifices of the net, or free near the oocytes surface. At the end of oogenesis, when the VE is completely formed, it is difficult to distinguish its components independently. Immunolocalization with antibodies against VE, show a positive reaction in follicle cells and oocytes in previtellogenic and full grown ovarian follicles. This analysis suggests that both the oocyte and the follicle cells are directly involved in the synthesis and secretion of the components of the vitelline envelope in Bufo arenarum.(AU)

Structures in material transference and vitelline envelope formation in Betta splendens follicles.

Structures were found by transmission electron microscopy, they were located within follicular cells and the oocyte, and in the interspace between them in follicles of the teleost fish Betta splendens. Some structures with features characteristic or lamellar bodies were found in small follicles. The possible role of these structures in the formation of the vitelline envelope as well as in the material transference is discussed. Vacuoles, vesticles and particles intensely stained were found in the microvilli and the cortical cytoplasm of the oocyte at the onset of vitellogenesis. These results suggest that different substances present in the cellular components of the follicle might be transferred from cell to cell through the extracellular space and through the prolongations that cross the extracellular space.

Decreased mitochondrial biogenesis in temperature-sensitive cell division cycle mutants of Saccharomyces cerevisiae.

The temperature-sensitive cell division cycle (cdc) G1 mutants cdc28 and cdc35 show decreased mitochondrial volumes with respect to the wild type strain A364A (WT) at the restrictive temperature. Of the three criteria of mitochondrial biogenesis studied, that is, number of mitochondria per cell, relative area of the cell occupied by mitochondria, or relative area of mitochondria occupied by inner membranes, only the second indicator was significantly lower in cdc mutants than in the WT. The mitochondrial inner membranes development did not compensate for the decrease in the organelles volume. Apparently, the reduced mitochondrial biogenesis was not due to the temperature shift because the relative area of the cell occupied by mitochondria was already significantly lower at 25 degrees C in cdc mutants. The specific fluxes of oxygen consumption confirmed that the respiratory capacity of cdc mutants is largely impaired in respect to the WT. Cdc28 and cdc35 mutants of Saccharomyces cerevisiae had been previously shown to exhibit high respiratory quotients (from 3 to 7) in respect to the WT (RQ approximately 1.0), which correlated with carbon and energy uncoupling probably the result of glucose-induced catabolite repression [Aon MA, Mónaco ME, Cortassa S (1995) Exp Cell Res 217, 42-51; Mónaco ME, Valdecantos PA, Aon MA (1995) Exp Cell Res 217, 52-56].