An ultrastructural study of oocyte atresia in the starfish Pisaster ochraceus.

The alterations involved in oocyte atresia of the starfish Pisaster ochraceus were investigated using both light and electron microscopy. It was shown that atresia may be defined by three patterns of cell destruction. Initially, the small electron-lucent vesicles produced by the Golgi complex underwent amalgamation into groups. This was followed by loss of vesicle membranes and consequent formation of transparent necrotic zones in the cytoplasm. The second pattern, ultrastructurally comparable with autophagic cell death, was marked by apparent amalgamation of the morphologically similar electron-lucent vesicles into growing vacuoles, giving rise to a multibranched autophagic vacuole. This vacuole engulfed the cytosol granules and ultimately came to occupy the entire space within the oocyte. In addition, the cytosol insulation inside of the 'apoptotic body-like spheres' was regularly observed. Thus, it is supposed that oocyte destruction may occur by a complex mechanism that includes elements of necrosis, autophagic cell death and apoptosis.

PM-2: an ECM epitope necessary for morphogenesis in embryos of the starfish, Pisaster ochraceus.

Anti-PM-2 is a monoclonal antibody that has been developed against the ECM of embryo/larvae of the starfish Pisaster ochraceus. Immunofluorescent staining shows that the PM-2 epitope is present in the cortical granules of unfertilized eggs and is released into the perivitelline space on fertilization. At the blastula stage, staining is very faint and limited to the blastocoel and a few granules within the cells. Strong staining appears in the embryonic/larval body cavity shortly after gastrulation and continues to increase in both the embryonic/larval body cavity and lumen of the gut at least until the bipinnaria stage. The presence of PM-2 in the Golgi apparatus, its susceptibility to enzymes that attack carbohydrates, and inhibition of PM-2 synthesis by tunicamycin, a drug that inhibits the linkage of carbohydrate moieties to protein backbone chains, suggest that the PM-2 epitope is or contains carbohydrate. Western blots of the whole embryo homogenates show bands at molecular weights of 130, 122, 100, 70, and 50 kDa. As embryos grow, two other high molecular weight (greater than 200 kDa) bands also appear. This suggests that the epitope is present on a series of molecules and that some of the lower MW molecules are precursors of the higher MW ones. A single 24-h exposure to the antibody just posthatching appears to inhibit normal mesenchymal migration at the gastrula stage, and if development of these treated embryos/larvae is allowed to continue to the bipinnaria stage, the embryos are stunted and have a smaller oral hood and esophagus. Long-term exposure results in stunted animals with distorted shapes. Such animals develop a very small embryonic/larval body cavity or none at all and differentiation of the larval GI tract fails to occur. The results suggest that molecules exhibiting the PM-2 epitope are necessary for the proper formation of the blastocoel, for mesenchyme cell movement and for proper development of the larvae GI tract.

Lectin histochemistry of the hyaline layer in the asteroid, pisaster ochraceus.

Six different lectins were used to study the carbohydrate nature of the hyaline layer (HL), the external extracellular matrix of the starfish embryo. Thin sections of embryos fixed in the late gastrula stage were incubated with five fluoresceinated lectins: Con A, WGA, RCA, UEA-I, and SBA. All but UEA-I labelled the HL, suggesting that the following sugars are present: mannose and/or glucose, glcNAc and/or Neu5Ac, galactose, and galNAc. The different lectins produced variable degrees of labelling, with WGA, RCA, and SBA producing more intense labelling than Con A. Binding of lectins by the HL was studied at the ultrastructural level by exposing ultrathin sections to the following lectin-gold conjugates: Con A, WGA, PNA, SBA, and LFA. Lectin binding was observed over the various regions of the HL, recognized by Crawford and Abed (J. Morphol. 176:235-246, '86), i.e., the intervillus layer, the supporting layer and the coarse outer meshwork. Local differences in labelling patterns were observed among the various lectins, with SBA labelling all regions intensely, WGA and PNA labelling the supporting layer predominantly, and Con A labelling the HL only lightly. No labelling was observed with LFA. These lectin-labelling patterns in the HL demonstrate the presence of different glycoconjugates in different regions of the HL, suggesting that the layers differ biochemically. The existence of biochemical differences strengthens the idea that each layer may have different functions in the developing starfish embryo.

Changes in the arrangement of the extracellular matrix, larval shape, and mesenchyme cell migration during asteroid larval development.

When fixed in the presence of alcian blue, extracellular matrix (ECM) in the embryonic asteroid blastocoel can be visualized by light and electron microscopy as a fibrous meshwork encrusted with alcianophilic material. In early to mid-gastrulae, the ECM is associated with the basal laminae underlying the ectoderm and endoderm. It also forms a fibrous meshwork between them in the posterior part of the blastocoel. In early larvae, when mesenchyme cells arrive at the esophagus to differentiate into smooth muscle, very little ECM is associated with the stomach region. In contrast, a meshwork of long ECM strands radiates from the esophageal basal lamina which connects to a dense ECM web associated with the inner aspect of the dorsal ectoderm. This dorsal web is associated, in turn, with numerous long ECM strands which run parallel to the stomodeum. The strands located between the esophagus and the ectoderm appear when the mouth and coeloms form and may be responsible for a constriction of the ectoderm that forms in this region. During late gastrula one population of mesenchyme cells becomes associated with the esophageal region and differentiates into muscle. Most of the other mesenchyme cells stop migrating through the esophageal web at this time. Less alcianophilic material is associated with the esophageal basal lamina, and the ECM adjacent to the esophagus in the late gastrula and early bipinnaria larvae. The arrangement of the ECM elements suggests that they could be involved in controlling the migration of mesenchyme cells, particularly those destined for the esophagus.

Influence of Donor Age on Establishing Well-Differentiated Clonal Cultures from Embryonic Chicken Retinal Pigmented Epithelium: (pigment cell/eye/embryo/cell culture/development).

Retinal pigmented epithelia (RPE) isolated from chicken embryos of various developmental stages were dissociated into single cells, and their ability to re-express defferentiated characteristics in clonal culture was investigated. The lighty pigmented, columnar cells isolated from stage 25 to 29 embryos dissociated more easily than the heavily pigmeted, cuboidal cells from embryos of stages 30 to 34. The yield of RPE cells per embryo increased with donor age, paralleling the growth of the epithelium in vivo. However, the potential these cells to attach, to proliferate, and to form typical, welldifferentiated RPE colonies declined with donor age. Cells from stage 25 embryos developed exclusively into large, typical epithelial colonies which expressed all stages of differentiation from flat, unpigmented cells at the margin to cuboidal, pigmented cells in the centre. At the other end of the spectrum, cells from stage 34 embryos frequently formed small, atypical colonies of unpigmented cells, in addition to typical but relatively small colonies. The plating efficiency (calculated on the basis of pigmented colonies formed within 3 weeks) dropped from more than 2% at stage 25 to 0.01% at stage 34.

Regional Ultrastructural Differences in Basal Laminae Isolated from the Starfish Pisaster ochraceus: (Starfish/embryo/basal lamina/ultrastructure).

The ultrastructure of different regions of the basal laminae isolated from 5-1/2-6 day-old embryos of the starfish, Pisaster ochraceus, has been described after fixation in the presence of anionic dyes. Isolated basal laminae from all regions of the embryo exhibit a lamina lucida and lamina densa. No lamina fibroreticularis is present. Instead, a coarse meshwork of thick densely stained and thinner intermediately stained fibers is embedded in the lamina densa and extends into the blastocoel forming the extracellular matrix. The coarse meshwork associated with the ectodermal basal lamina consists primarily of thick densely stained fibers with a small number of intermediate ones while that associated with the endodermal one contains much less densely stained material. These structures were morphologically identical to those found in control embryos. Examination of different regions of the endodermal basal lamina shows that the amount of dense material varies from region to region. These differences in dense material may reflect biochemical differences, particularly of proteoglycans, which could provide positional information to migrating mesenchyme cells.

A fine structural study of the testicular wall and spermatogenesis in the crinoid, Florometra serratissima (Echinodermata).

The testicular wall and the process of spermatogenesis in the crinoid, Florometra serratissima, has been studied at the fine structural level. The testicular wall is composed of three layers: a perivisceral layer consisting of nerve processes, muscle fibers, and epithelial cells; a haemal sinus containing haemal fluid, collagen-like fibers, and haemocytes; and a germinal layer consisting of germinal and interstitial cells. The germinal layer is elaborated into numerous folds that project into the lumen of the testis and a branch of the haemal channel extends through the core of each fold. Evidence suggesting that nutrients are carried to the testis and germinal cells via the haemal system is presented. Spermatogonia are concentrated around the base of each fold and spermatocytes line the more distal regions. Spermatids occur at the luminal surface of the germinal layer and spermatozoa fill the testicular lumen. Interstitial cells phagocytize spermatozoa and may also transfer nutrients to spermatids. The nucleus of spermatogonia is large and contains one or two nucleoli. The cytoplasm contains numerous organelles, lipid granules, and a distal and proximal centriole, each with a satellite complex. A striated rootlet extends from the distal centriole. During first meiotic prophase, the distal centriole loses its striated rootlet and produces a flagellum, the proximal centriole loses its satellite complex, the nucleolus disappears, and proacrosomal vesicles are synthesized by the Golgi complex. During spermiogenesis, most of the mitochondria appear to fuse to form a single, large mitochondrion, the nuclear chromatin condenses, and superfluous cytoplasm is lost by autophagocytosis. The formation and definitive positioning of the acrosomal vesicle and periacrosomal material at the apex of the nucleus is described in detail.

Coelomic pouch formation in the starfish Pisaster ochraceus (Echinodermata: Asteroidea).

The process of coelomic pouch formation in Pisaster ochraceus was studied with light microscopy, transmission and scanning electron microscopy and time-lapse cinemicrography as well as with the drug cytochalasin B. As in most asteroids, the paired coelomic pouches of Pisaster ochraceus are formed from outpocketing of the archenteron. Arrays of 50 Å microfilaments are found in the presumptive coelomic pouch cells at the apex of the archenteron as well as in the filopodia of the mesenchyme cells. Both cell types undergo active movements throughout the entire process. Treatment of embryos with cytochalasin B (CCB) during coelomic pouch formation results in the loss of cell movements and the regression of the coelomic pouches; this is accompanied by the loss of microfilament arrays in both cell types. Cell movements and microfilament arrays reappear on removal of CCB and coelomic pouch formation resumes. Our evidence suggests that the microfilaments in the presumptive coelomic pouch cells provide the main force for the outpocketing movement. The major role of the microfilament arrays in the filopodia of the mesenchyme cells associated with the coelomic pouches is to determine the definitive shape and location of the pouches.