ULTRASTRUCTURAL STUDY ON THE ATTACHING FILAMENTS AND VILLI OF THE OOCYTE OF ORYZIAS LATIPES DURING OOGENESIS

The formation of the attaching filaments and villi on the surface of the oocyte of Oryzias latipes were studied electron-microscopically. The oocyte at the early stage has almost smooth surface with a few tufts of microvilli. Some parts of the surface of the oocyte are in contact with the follicle cell, and these parts subsequently become protrusions. As maturation proceeds, a mass of fine granules appears in the space between the protrusion and the follicle cell. Similar granules begin to appear also in the space between the microvilli. These granules later become the outer layer of the chorion. The protrusions are reduced in height, and consequently become almost flat. At the same time, there appears some amorphous material of high electron density on the above-mentioned granules on the flat part. A bundle of parallel microtubules is formed in the material. The tubule is 180–200 A in diameter, and its wall consists of 12 or 13 subunits. The bundle increases in volume, and becomes the attaching filament or villus.     

ELECTRON MICROSCOPIC STUDIES ON THE BEHAVIOR OF GLYCOGEN PARTICLES DURING OOGENESIS IN THE SEA URCHIN

The behavior of glycogen particles during oogenesis in the sea urchin was studied by electron microscopy. Before the beginning of oogenesis the nurse cells include many glycogen particles, which are spherical or multiangular in shape and about 600 A in diameter, lying within the vesicle of the large granules and also in the cytoplasm among the granules. There are few glycogen particles in the spaces among the oocytes and the nurse cells. At the early stage of oogenesis the limiting membrane of the large granule breaks locally and the glycogen particles in the vesicle are dispersed into the cytoplasm. The plasma membrane of the nurse cell also breaks in places and glycogen particles are spread throughout the intercellular space. At the beginning of vitellogenesis, β-pinosomes begin to be formed at the periphery of the oocyte; these take in glycogen particles from the outside which are progressively broken into smaller units.     

SPERMIOGENESIS IN BARNACLES WITH SPECIAL REFERENCE TO ORGANIZATION OF THE ACCESSORY BODY*

Ultrastructural changes during spermiogenesis in the barnacles, Balanus amphitrite albicostatus, Balanus tintinnabulum rosa, Balanus trigonus and Tetraclita squamosa japonica, and organization of the sperm with special reference to the accessory body were studied. The Golgi complex organizes both the acrosome and the accessory body at different stages during spermiogenesis; the former is formed at the mid-spermatid stage and the latter is formed at the late spermatid stage. The arrangement of the components in the mature filiform sperm is quite unique, with the acrosome, the basal body just behind the acrosome, the axial filament parallel to a long nucleus, and a slender long mitochondrion behind the nucleus. The sperm in the anterior and posterior half of the ejaculatory duct differ from each other in form in that the sperm in the anterior duct are not equipped with the accessory body and the sperm in the posterior duct are. The accessory body can be artificially broken down by some treatments (1 M urea, alkaline sea water: pH 9.0-9.7, low ionic concentration of sea water). The loss of the accessory body from the sperm is assumed to be related to the ferti-lizability of the sperm.     

FORMATION AND BEHAVIOR OF PINOSOMES IN THE SEA URCHIN OOCYTE DURING OOGENESIS

Formation and behavior of the pinosomes at the surface of the oocyte during oogenesis in the 4 species of sea urchins, Anthocidaris crassispina, Temnopleurus toreumaticus, Mespilia globulus and Pseudocentrotus depressus, were studied. The plasma membrane of the oocyte is almost smooth at the early stage of oogenesis, although a small number of cytoplasmic processes appear on it, facing the germinal epithelium. At the beginning of vitellogenetic stage many processes appear on the whole surface of the oocyte. Near the base of the fully grown process, the pinosome designated as the α-pinosome is formed. The α-pinosome may play a part in maturation of the yolk granule. The processes shorten as a whole at the time of the breakdown of the germinal vesicle. Formation of the pinosome designated as the β-pinosome begins just before vitellogenetic stage and continues during this stage. The β-pinosome may be directly concerned with the formation of cortical granules.     

Lactate Dependent Protein Synthesis in Round Spermatids from Rat Testes

Lactate (20 mM) markedly increased protein labeling of round spermatids (steps 1–8) from rat testes. The stimulatory effect of lactate on protein labeling was also observed to some degree in spermatocytes and late spermatids (steps 13–16), but not in Leydig cells and 7 day-old testis cell suspznsions. In the lactate-treated spermatids, 51 % of the labeled proteins was found in the water-soluble fraction (the 105,000 × g 1 hr supernatant), whereas only 21%, in the control cells. The labeled proteins did not break down for at least 90 minutes in the presence of lactate. Actinomycin D (20 μg/ml) had no effect on [³H]leucine incorporation into the water-soluble proteins of spermatids, while labeling of the water-insoluble proteins (the 105,000 × g 1 hr pellet) was decreased by 23%.
These findings suggest that the round spermatids might be the most susceptible for the lactate-induced stimulation of protein synthesis among various types of testicular cells, and that lactate increases the synthesis of water-soluble proteins which may be regulated in the translational level of protein synthesis.