Ultrastructure of the polygerm ofAgeniaspis fuscicollis Dalm. (Chalcidoidea,Hymenoptera)

Summary The extraembryonic food supply of developingAgeniaspis fuscicollis polygerm from the host haemolymph is mediated by the trophamnion. The nutritive materials are absorbed by micropinocytosis. Besides microvilli and micropinocytotic vesicles, the following organelles appear in the trophamnion: multivesicular bodies, dictyosomes, mitochondria, and microtubules. The multivesicular bodies may be considered as a form of yolk. The storage material of the trophamnion is lipid. Numerous polyribosomes appear in the inner part of the trophamnion indicating intense protein synthesis. Food supply from the trophamnion to the embryo cells also proceeds by micropinocytosis. The polyembryo is surrounded by a cyst made up of host cells. Large numbers of tracheoles supplying the developing parasitic embryos with oxygen are invaginated into the cyst cells. The ultrastructure of theAgeniaspis fuscicollis polygerm shows a close trophic relationship between the polyembryonally developing parasite and its host.This research was supported in part by Nencki Institute of Experimental Biology, Polish Academy of Sciences, Warsaw     

The role of the Golgi complex in the isolation and digestion of organelles

The origin of the membranes and lytic enzymes involved in autophagy has been studied in metamorphosing insect fat body.The Golgi complex has two functions in the organelle destruction which takes place when fat body cells change their activities. (1) It gives rise to envelopes which externalize organelles scheduled for destruction. Microbodies, mitochondria and rough endoplasmic reticulum are sequentially removed from the cytoplasm by investment in isolation membranes. During the isolating phase, isolation membranes have the same osmiophilia as the outer saccular and microvesicular components of the Golgi complex, they do not contain lytic enzymes and they are specific in their adhesion to organelles scheduled for destruction. (2) The Golgi complex gives rise to lytic enzymes. Primary lysosomes which contain acid phosphatase fuse with the isolation bodies formed from invested organelles to become autophagic vacuoles. During this lytic phase, acid phosphatase is present in the inner saccules and microvesicular components of the Golgi complex, in the primary lysosomes seen fusing with isolation bodies and in autophagic vacuoles.     

秀丽白虾卵母细胞不同发育阶段滤泡细胞的超微结构

用透射电镜技术观察了秀丽白虾(Exopalaemon modestus)不同发育阶段卵巢滤泡细胞的超微结构及其与卵母细胞的联系。随着卵母细胞的发育进程,滤泡细胞经历了发育和退化过程。在卵黄大量发生期,卵母细胞被多层滤泡细胞包绕,血窦伸入层间;滤泡细胞内含有丰富的内质网、高尔基体、线粒体、核糖体及原始卵黄颗粒。在卵子成熟期,滤泡细胞由内向外依次解体,血窦萎缩。这些形态变化支持滤泡细胞具有吸收血液营养、合成并向卵母细胞输送原始卵黄物质的功能的观点。与锯缘青蟹、长毛对虾和中华绒螯蟹的滤泡细胞的作用方式稍有不同。     

Immunocytochemical localization of surfactant protein D (SP-D) in type II cells, Clara cells, and alveolar macrophages of rat lung.

We investigated the cellular and subcellular distribution of surfactant protein D (SP-D) by immunogold labeling in lungs of adult rats that had been given bovine serum albumin coupled to 5-nm gold (BSAG) for 2 hr to visualize the endocytotic pathway. Specific gold labeling for SP-D was found in alveolar Type II cells, Clara cells, and alveolar macrophages. In Type II cells abundant labeling was observed in the endoplasmic reticulum, whereas the Golgi complex and multivesicular bodies were labeled to a limited extent only. Lamellar bodies did not seem to contain SP-D. Gold labeling in alveolar macrophages was restricted to structures containing endocytosed BSAG. In Clara cells labeling was found in the endoplasmic reticulum, the Golgi complex, and was most prominent in granules present in the apical domain of the cell. Double labeling experiments with anti-surfactant protein A (SP-A) showed that both SP-A and SP-D were present in the same granules. However, SP-A was distributed throughout the granule contents, whereas SP-D was confined to the periphery of the granule. The Clara cell granules are considered secretory granules and not lysosomes, because they were not labeled for the lysosomal markers cathepsin D and LGP120, and they did not contain endocytosed BSAG.     

Cellular organization and peritrophic membrane formation in the cardia (Proventriculus) of Drosophila melanogaster

The peritrophic membrane of Drosophila melanogaster consists of four layers, each associated with a specific region of the folded epithelial lining of the cardia. The epithelium is adapted to produce this multilaminar peritrophic membrane by bringing together several regions of foregut and midgut, each characterized by a distinctively differentiated cell type. The very thin, electron-dense inner layer of the peritrophic membrane originates adjacent to the cuticular surface of the stomadeal valve and so appears to require some contribution by the underlying foregut cells. These foregut cells are characterized by dense concentrations of glycogen, extensive arrays of smooth endoplasmic reticulum, and pleated apical plasma membranes. The second and thickest layer of the peritrophic membrane coalesces from amorphous, periodic acid-Schiff-positive material between the microvilli of midgut cells in the neck of the valve. The third layer of the peritrophic membrane is composed of fine electron-dense granules associated with the tall midgut cells of the outer cardia wall. These columnar cells are characterized by cytoplasm filled with extensive rough endoplasmic reticulum and numerous Golgi bodies and by an apical projection filled with secretory vesicles and covered by microvilli. The fourth, outer layer of the peritrophic membrane originates over the brush border of the cuboidal midgut cells, which connect the cardia with the ventriculus.     

Ultrastructure of the epidermis of the lizard (Lacerta vivipara) at the resting stage of the sloughing cycle

The ultrastructure of the epidermis of the lizard ( Lacerta vivipara ) one day after sloughing is described. The non-keratinized layers of the epidermis are essentially similar in structure to those of amphibians and mammals. The cells of the basal layer are not however separated from each other by the large spaces described in the amphibian (Farquhar & Palade, 1965). The middle layers of the epidermis at this stage of the sloughing cycle produce neither the characteristic mucous granules found in amphibians nor the keratohyalin granules of mammals. A small number of granules corresponding in size and location to the "Odland bodies" of both mammalian and amphibian epidermis are, however, present. The intermediate layer cells also contain a number of bodies similar in appearance to those described by Farquhar & Palade as lysosomes in amphibian skin. These structures are both osmium iodide and acid phosphatase positive. Unlike the condition in amphibians and mammals, the cytoplasm of cells in the layer immediately beneath the keratinized strata is honeycombed with small vesicles, and contains large irregular vacuoles of uncertain content. Certain nonkeratinizing elements within the epidermis are tentatively interpreted as nerve terminations. Two morphologically distinct keratinized strata can be distinguished, the inner stratum consisting of flattened cells similar to those of the stratum corneum of mammalian epidermis; individual cell outlines cannot be distinguished in the outer stratum, which has a structure similar to that of avian feather keratin. A shallow surface zone of the outer keratinized stratum has been identified as the Oberhautchen. This consists of longitudinally disposed leaflets or laminae which are responsible for the sculptured pattern of the epidermal surface. The observations reported here provide a basis for analysis of changes occurring at other stages of the sloughing cycle.     

Fine structure of the excretory system of the deep posterior (Ebner's) salivary glands of the human tongue

Human deep posterior lingual glands (von Ebner's glands) are located beneath the circumvallate papillae. They are formed by tubuloalveolar adenomeres, intercalated ducts and excretory ducts coming together in the main excretory duct. The tubuloalveolar cells, pyramid-shaped, show large and dense secretory granules (clear cored) throughout the cytoplasm, rare basal folds and packed cisternae of rough endoplasmic reticulum (RER) at the basal pole. The columnar cells of the intercalated ducts are arranged in a monolayer. They are characterized by dense, clear-core secretory granules (mostly in the apical cytoplasm), a basal nucleus, well-developed RER and Golgi apparatus, and thin filaments distributed in supra- and perinuclear cytoplasm. Striated ducts are absent. Excretory ducts, coming together in the main duct, are lined by a bistratified epithelium. The inner layer consists of columnar cells showing bundles of tonofilaments with scarce secretory activity. The outer layer is composed of basal cells lying on the basal lamina. The main excretory duct, which opens at the bottom of the vallum, shows a stratified epithelium. The outer side is composed of 2-3 layers of malpighian cells lying on the basal lamina. The inner side consists of a single layer of cuboidal-columnar cells with dense apical granules and well-developed organelles synthesizing and condensing secretions. These cells interpolate with goblet cells, rare mitochondria-rich cells, ciliated cells and numerous small globous cells showing a clear matrix and lacking secretory granules. The cilia show a 9 + 2 microtubular structure with basal bodies provided with striated rootlets. Myoepithelial cells surround with their processes the basal portions of the secretory cells and the intercalated ducts. The conclusions concern some comparative aspects and some hypothesis on the functional role of goblet cells, ciliated cells and epithelial cells lining the different ducts, also in relation to the final secretory product.     

Human retinal development: ultrastructure of the inner retinal layers

Studies of the developing human retina from 6.5 to 18 weeks' gestational age (16–156 mm) by light and electron microscopy are concerned with the morphogenesis of neuroblast cells, plexiform layers, and inner limiting membrane. The transient layer of Chievitz is formed posteriorly by 20 mm (7 weeks), inner plexiform by 48 mm (9 weeks), outer plexiform layer by 83 mm (12 weeks), identifiable cones by 83 mm, and rods by 120 mm (15 weeks). Mitotic activity continues posteriorly until 120 mm and was seen in inner layers of the retina until 103 mm (13 weeks). Outer neuroblastic differentiation is marked by diversification from a uniform cell population to one containing at least three cell types differing in their nuclear shape, chromatin pattern, and cytoplasmic characteristics. Differentiating ganglion cells accumulate polysomes, rough endoplasmic reticulum, Golgi complexes, microtubules, and dense bodies. Müller cell bodies in ganglion and inner nuclear layers extend processes between ganglion cells, and radial fibers, containing extensive smooth endoplasmic reticulum, to the vitreal surface. Synapses appear in the inner and outer plexiform layers by 83 mm (12 weeks), and by 120 mm (15 weeks) demonstrate a variety of conventional and ribbon forms similar to those found in the adult. Synaptogenesis therefore begins considerably before the development of photoreceptor outer segments.     

Fine Structure of Gametogony and Oocyst Formation in Sarcocystis sp. in Cell Culture

Fine structure of gametocytes and oocyst formation of Sarcocystis sp. from Quiscalus quiscula Linnaeus grown in cultured embryonic bovine kidney cells was studied. Microgametocytes measured up to ～5 μm diameter. During nuclear division of the microgametocyte, dense plaques were found adjacent to the nucleus just beneath the pellicle; occasionally microtubules were present within these plaques. These microtubules subsequently formed 2 basal bodies with a bundle of 4 microtubules between them. Microgametocytes also contained numerous mitochondria, micropores, granules, vacuoles, and free ribosomes. Each microgamete was covered by a single membrane and consisted of 2 basal bodies, 2 flagella, a bundle of 4 microtubules, a perforatorium, a mitochondrion, and a long dense nucleus which extended anteriorly and posteriorly beyond the mitochondrion. The bundle of 4 microtubules is thought to be the rudiment of a 3rd flagellum. Macrogametes were covered by a double membrane pellicle, and contained a large nucleus (～2.5 μm), vacuoles, and a dilated nuclear envelope connected with the rough endoplasmic reticulum (ER). In young macrogametes (～4 μm), the ER was arranged in concentric rows in the cortical region, and several sizes of dense granules were found in the cytoplasm. However, in later stages (～8 μm) the ER was irregularly arranged and was dilated with numerous cisternae; only large dark granules remained and a few scattered polysaccharide granules were found. No Golgi apparatus or micropores were observed. After the disappearance of dark granules 5 concentric membranes appeared. Four of these fused to form an oocyst wall composed of a dense outer layer (～66 nm thick) and a thin inner layer (～7 nm). The 5th or innermost membrane surrounded the cytoplasmic mass which was covered by a 2-layered pellicle and contained a nucleus, small amounts of ER, large vacuoles, and mitochondria. The sexual stages described greatly resemble those of Eimeria and Toxoplasma.     

Fine Structure of Zygotes and Oocysts of Eimeria nieschulzi*

SYNOPSIS. Mature macrogamonts were present in the small intestine of rats 5.5 to 7.5 days postinoculation with Eimeria nieschulzi oocysts; oocysts were present at 6 to 7.5 days. Types I and II wall-forming bodies in macrogamonts began to undergo ultrastructural changes within zygotes to form the outer and inner layers of the oocyst wall. Before and during oocyst wall formation a total of 5 membranes (M1–5) were formed at or near the surface of the zygote. The outer and inner oocyst wall layers formed between M2 and M3, and M4 and M5, respectively. The mature oocyst was loosely surrounded by M1 and M2, had an electron-dense outer layer, 100–275 nm thick, and an electron-lucent inner layer, 160–180 nm thick. It also contained an electron-lucent line consisting of M3 and M4 interposed between the outer and inner layers of the oocyst wall. The micropyle, measuring 935 × 47 nm, was located in the outer layer of the oocyst wall and consisted of 10–14 alternating layers of electron-dense and lucent material. The sporont of mature oocysts was covered by M5, immediately beneath which were M6 and M7. The sporont contained a nucleus and nucleolus, lipid and amylopectin bodies, mitochondria, ribosomes, as well as smooth and rough endoplasmic reticulum. Canaliculi, Golgi complexes, and types I and II wall-forming bodies were absent.