The oocytes of many invertebrate and non-mammalian vertebrate species are not only asymmetrical but also polar in the distribution of organelles, localized RNAs and proteins, and the oocyte polarity dictates the patterning of the future embryo. Polarily located within the oocytes of many species is the Balbiani body (Bb), which in Xenopus is known to be associated with the germinal granules responsible for the determination of germ cell fate. In contrast, in mammals, it is widely believed that the patterning of the embryo does not occur before implantation, and that oocytes are non-polar and symmetrical. Although the oocytes of many mammals, including mice and humans, contain Bbs, it remains unknown how and if the presence of Bbs relates to mouse oocyte and egg polarity. Using three-dimensional reconstruction of mouse neonatal oocytes, we showed that mouse early oocytes are both asymmetrical and transiently polar. In addition, the specifics of polarity in mouse oocytes are highly reminiscent of those in Xenopus early oocytes. Based on these findings, we conclude that the polarity of early oocytes imposed by the position of the centrioles at the cytoplasmic bridges is a fundamental and ancestral feature across the animal kingdom.
We describe our analysis of primordial germ cell migration in Drosophila wild-type and mutant embryos using high resolution microscopy and primary culture in vitro. During migratory events the germ cells form transient interactions with each other and surrounding somatic cells. Both in vivo and in vitro they extend pseudopodia and the accompanying changes in the cytoskeleton suggest that actin polymerization drives these movements. These cellular events occur from the end of the blastoderm stage and are regulated by environmental cues. We show that the vital transepithelial migration allowing exit from the gut primordium and passage into the interior of the embryo is facilitated by changes in the structure of this epithelium. Migrating germ cells extend processes in different directions. This phenomenon also occurs in primary culture where the cells move in an unoriented fashion at substratum concentration-dependent rates. In vivo this migration is oriented leading germ cells to the gonadal mesoderm. We suggest that this guidance involves stabilization of states of an intrinsic cellular oscillator resulting in cell polarization and oriented movement.
In insects, the ovarian follicular epithelium morphogenesis has been intensively studied and best characterized in the fruit fly, Drosophila melanogaster. It is well established that initially identical somatic follicular cells (FCs) form a simple epithelium overlying the germline cells, but during oogenesis, they diversify into a number of morphologically distinct subpopulations each responsible for creating specific eggshell structures. In addition, some FC subpopulations (e.g. polar cells) are indispensable in establishing antero-posterior and dorso-ventral ovarian follicle axes and patterning of the developing embryo. The morphological and molecular changes that occur during follicular epithelium morphogenesis in Drosophila are frequently considered as a paradigm of the FC diversification in all flies. However, recent comparative studies indicate that, in dipterans, the functioning of the ovarian follicles is diverse, group-specific and may significantly differ from the Drosophila model system. We discuss the similarities and differences of the ovary structure and follicular epithelium morphogenesis in different dipteran groups and put them into a phylognetic context. We suggest that the migratory activity of the FCs represents an evolutionary novelty that evolved in the ancestors of higher dipterans (Brachycera). Subsequently, during evolution of this subgroup, the number of migrating FC subpopulations has gradually increased from one (in Orthorrhapha) to four (in Cyclorrhapha).
We have developed a simple and reliable method of preserving antigen immunoreactivity with concomitant excellent retention of the cell ultrastructure. Using this method, we have been able to follow the origin and developmental stages of nuage accumulations within the nurse cell/oocyte syncytium in the ovary of the fruit fly, Drosophila melanogaster, at the ultrastructural level. We have found two morphologically and biochemically distinct forms of nuage material in the nurse cell cytoplasm: translocating accumulations of nuage containing the Vasa protein, termed sponge bodies and stationary polymorphic accumulations of nuage enriched in Argonaute and Survival of motor neuron proteins. Immunogold labeling combined with confocal fluorescent and ultrastructural analyses have revealed that the Vasa-containing nuage accumulations remain closely associated with the cisternae of the endoplasmic reticulum throughout their lifetimes. The migration mechanism of the Vasa-positive nuage appears distinct from the microtubule-dependent translocation of oskar ribonucleoprotein complexes. We postulate that these two distinct nuage translocation pathways converge in the formation of the polar granules within the polar/germ plasm of the oocyte posterior pole. We also provide morphological and immunocytochemical evidence that these polymorphic nuage accumulations correspond to the recently described cytoplasmic domains termed U body-P body complexes.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.