Jerzy Klag

Formation of germ-line cysts with a central cytoplasmic core is accompanied by specific orientation of mitotic spindles and partitioning of existing intercellular bridges

Animal germ cells tend to form clonal groups known as clusters or cysts. Germ cells within the cyst (cystocytes) are interconnected by intercellular bridges and thus constitute a syncytium. Our knowledge of the mechanisms that control the formation of germ-cell clusters comes from extensive studies carried on model organisms (Drosophila, Xenopus). Germ-cell clusters have also been described in worms (annelids, flat worms and nematodes), although their architecture differs significantly from that known in arthropods or vertebrates. Their peculiar feature is the presence of a central anucleate cytoplasmic core (cytophore, rachis) around which the cystocytes are clustered. Each cystocyte in such a cluster always has one intercellular bridge connecting it to the central cytoplasmic core. The way that such clusters are formed has remained a riddle for decades. By means of light, fluorescence and electron microscopy, we have analysed the formation and architecture of cystocyte clusters during early stages of spermatogenesis and oogenesis in a few species belonging to clitellate (oligochaetous) annelids. Our data indicate that the appearance of germ cells connected via a central cytophore is accompanied by a specific orientation of the mitotic spindles during cystocyte divisions. Spindle long axes are always oriented tangentially to the surface of the cytophore. In consequence, cystocytes divide perpendicularly to the plane of the existing intercellular bridge. Towards the final stages of cytokinesis, the contractile ring of the cleavage furrow merges with the rim of the intercellular bridge that connects the dividing cystocyte with the cytophore and forces partition of the existing bridge into two new bridges.

Oogenesis in Acerentomon gallicum Jonescu (Protura)

SummaryAt the onset of previtellogenesis, the oocytes of Acerentomon gallicum begin to grow and increase their content of organelles. The nuage material in the oocytes at first increases in amount, then declines gradually to disappear completely from oocytes that have attained 50 μm in diameter. During the growth period, new dictyosomes, mitochondria and ribosomes appear. Numerous vesicles become detached from the cell membrane and subsequently fuse into cisternae, thus forming extensive complexes of the rough endoplasmic reticulum. In oocytes with diameters between 50 and 100 μm the Golgi complexes show a considerable increase in activity, and many lamellar bodies arise from mitochondria that have undergone specific transformation.

Primordial germ cell differentiation in natural and manipulated twin embryos of Thermobia domestica (Insecta: Zygentoma)

Abstract In eggs of many insects there exists a characteristic structure called an oosom that is required for the formation and differentiation of primordial germ cells (PGCs). Thermobia domestica (Packard) belongs to the group of insects in which there are no visible signs of such germ cell determinants and PGCs are formed at the later stages of development. Spontaneous and experimental polyembryony helps to resolve the problem of germ cells determinants existence. The stratification of cytoplasmic inclusions in T. domestica eggs causes the displacement of germ cells determinants. As a result, all twin embryos and some single embryos (experimental polyembryony) have sterile gonads.

Ultrastructure of the Pleuropodium in 8-d-old Embryos of Thermobia domestica (Packard) (Insecta, Zygentoma)

Abstract Pleuropodia of the invaginated type were observed on the first abdominal segment in 8-d-old embryos of Thermobia domestica (Packard). The pleuropodium is formed by a cytoplasmatic internal part and a mushroom-like cavity. The latter is filled with fluid and is composed of a stem protruding through the epidermis and a vesicle-like copula. The arrangement of membrane folds, mitochondria, and lipid drops was observed on electron micrographs (TEM) of pleuropodium cells. The position and structure of these organelles indicates that the cells of this organ perform transport and secretory functions.