Vitellogenesis of basal trematode Aspidogaster limacoides(Aspidogastrea: Aspidogastridae)

The vitellogenesis of the trematode Aspidogaster limacoides (Aspidogastrea: Aspidogastridae), a parasite of cyprinid fishes, is described here using transmission electron microscopy. Four different stages of vitellocytes are differentiated: immature vitellocytes, early maturing vitellocytes, advanced maturing vitellocytes and mature vitellocytes. The process follows the same general pattern already described in other free-living neoophorans and parasitic flatworms (i.e. Trematoda, Monogenea and Cestoda): differentiation into mature vitelline cells involves the development of mitochondria, granular endoplasmic reticulum, Golgi complexes, lipid droplets and shell-globules. Mature vitellocytes of A. limacoides are composed of numerous shell-globule clusters, few lipid droplets and glycogen granules. They differ from those of another aspidogastrean Rugogaster hydrolagi in that they possess numerous globules tightly packed and by the presence of only one type of vitelline material. The interstitial tissue of vitelline follicles of A. limacoides contains a peripheral nucleus and long cytoplasmic projections extending between vitelline cells. Since aspidogastreans are considered as an archaic group of parasitic flatworms and thus have a strategic phylogenetic position, future works needs to pay special attention to the ultrastructural and chemical composition of mature vitellocytes within this basal group of trematodes.     

Vitellogenesis of the digenean Plagiorchis elegans (Rudolphi, 1802) (Plagiorchioidea,Plagiorchiidae)

The ultrastructural organization of vitellogenesis of Plagiorchis elegans (Rudolphi, 1802), experimentally obtained from the golden hamster Mesocricetus auratus (Linnaeus, 1758), is described using transmission electron microscopy. This study is the first ultrastructural study of vitellogenesis in a member of the superfamily Plagiorchioidea. The four stages usually observed during vitellogenesis are described: stage I, cytoplasm of the vitellocytes mainly filled with ribosomes and few mitochondria; stage II, beginning of the synthetic activity; stage III, active synthesis of the shell globule clusters; stage IV, vitellocytes are filled with shell globule clusters and contain several lipid droplets, and glycogen granules are grouped around clusters and droplets. Vitellogenesis in P. elegans is compared with that of other Digenea. The differences among P. elegans and previously studied digeneans include, but are not limited to the occurrence of dense coiled endoplasmic reticulum saccules and the concentration of glycogen in the mesenchyme, which may be considered as a fifth stage of maturation of the vitelline glands. This peculiarity was not observed in all trematodes, which clearly indicates differences in the vitellogenesis in various digenean lineages at different stages of maturation of their vitelline cells.     

Ultrastructure of vitellogenesis and vitellocytes in the trypanorhynch cestode Aporhynchus menezesi, a parasite of the velvet belly lanternshark Etmopterus spinax

This is the first TEM examination of vitellogenesis in the cestode Aporhynchus menezesi, a parasite of the velvet belly lanternshark Etmopterus spinax and a member of a little-studied trypanorhynch family, the Aporhynchidae. The synthetic activity of vitellocytes plays two important functions in the developmental biology of cestodes: (1) their shell-globules serve in eggshell formation; and (2) their accumulated reserves of glycogen and lipids represent a food source for the developing embryo. In A. menezesi, vitelline follicles consist of cells at various stages of development, from peripheral, immature cells of the gonial type to mature cells towards the centre of the follicle. These stages are: (I) immature; (II) early differentiation; (III) advanced maturation; and (IV) mature. Gradual changes involved in this process occur within each stage. Vitellogenesis involves: (1) an increase in cell volume; (2) the development of a smooth endoplasmic reticulum and an accelerated formation and accumulation of both unsaturated and saturated lipid droplets, along with their continuous enlargement and fusion; (3) the formation of individual β-glycogen particles and their accumulation in the form of glycogen islands scattered among lipid droplets in the cytoplasm of maturing and mature vitellocytes; (4) the rapid accumulation of large, moderately saturated lipid droplets accompanied by dense accumulations of β-glycogen along with proteinaceous shell-globules or shell-globule clusters in the peripheral layer during the advanced stage of maturation; (5) the development of cisternae of granular endoplasmic reticulum that produce dense, proteinaceous shell-globules; (6) the development of Golgi complexes engaged in the packaging of this material; and (7) the progressive and continuous enlargement of shell-globules into very large clusters in the peripheral layer during the advanced stage of maturation. Vitellogenesis in A. menezesi, only to some extent, resembles that previously described for four other trypanorhynchs. It differs in: (i) the reversed order of secretory activities in the differentiating vitellocytes, namely the accumulation of large lipid droplets accompanied by glycogenesis or β-glycogen formation during early differentiation (stage II), i.e. before the secretory activity, which is predominantly protein synthesis for shell-globule formation (stage III); (ii) the very heavy accumulation of large lipid droplets during the final stage of cytodifferentiation (stage IV); and (iii) the small number of β-glycogen particles present in mature vitellocytes. Ultracytochemical staining with PA-TCH-SP for glycogen proved positive for a small number of β-glycogen particles in differentiating and mature vitellocytes. Hypotheses, concerning the interrelationships of patterns of vitellogenesis, possible modes of egg formation, embryonic development and life-cycles, are commented upon.     

Electron microscope study of vitellogenesis in Glaridacris catostomi (Cestoidea: Caryophyllidea)

Swiderski Z. and Mackiewicz J. S. 1976. Electron microscope study of vitellogenesis in Glaridacris catostomi (Cestoidea: Caryophyllidea). International Journal for Parasitology6: 61–73. Mature vitelline follicles consist of cells in various stages of development, progressing from immature cells of gonial type near the periphery to mature ones toward the centre. Maturation, completed before the cell leaves the follicle, is characterized by: increase in cell volume; increase in nuclear surface area restoring the N/C ratio; nucleolar transformation; extensive development of large parallel cisternae of granular endoplasmic reticulum, the shell-protein producing units; development of Golgi complexes engaged in shell globule formation; formation and storage of glycogen in the cytoplasm; simultaneous, independent formation and storage of intranuclear glycogen; progressive increase in the number and size of shell globule clusters; and disintegration of endoplasmic reticulum, degenerative changes, and accumulation of glycogen and shell globule clusters within the cytoplasm associated with a massive accumulation of glycogen in the nucleus. The functional significance of the large amount of nuclear and cytoplasmic glycogen and numerous shell globule clusters is analyzed. Vitellogenesis in G. catostomi is compared with that in other cestodes and trematodes. Some conclusions, concerning the interrelationship between the vitellogenesis pattern and the type of embryogenesis following it, are drawn and discussed.     

Ultrastructural study of vitellogenesis and oogenesis of Metadena depressa (Stossich, 1883) Linton, 1910 (Digenea,Cryptogonimidae), intestinal parasite of Dentex dentex (Pisces,Teleostei)

The ultrastructural organization of the female reproductive system of Metadena depressa, digenean intestinal parasite of Sparidae (Dentex dentex), was investigated by electron microscopy. The vitellogenesis is divided into four stages: stage I, vitellocytes have a cytoplasm mainly filled with ribosomes and few mitochondria; stage II, beginning of the synthetic activity; stage III, active shell globule clusters synthesis; stage IV, mature vitellocytes are filled with shell globule clusters and generally contain several large lipid droplets. Glycogen granules are grouped at the periphery of the cell. The three stages of the oogenesis process take place in the ovary: stage I, oogonia are undifferentiated small cells located at the periphery of the organ; stage II, primary oocytes possess a higher nucleo-cytoplasmic ratio and a nucleus with a nucleolus and synaptonemal complexes indicating the zygotene-pachytene stage of the first meiotic division; stage III, mature oocytes are located in the proximal region of the organ and possess a cytoplasmic chromatoid body and cortical granules in a monolayer close to the periphery of the cell.     

Vitellocytes and vitellogenesis in cestodes in relation to embryonic development, egg production and life cycle

Vitellocytes have two important functions in cestode embryogenesis: (1) formation of hard egg-shell (e.g. Pseudophyllidea) or a delicate capsule (e.g. Cyclophyllidea), and (2) supplying nutritive reserves for the developing embryos. During evolution any of these two functions can be reduced or intensified in different taxa depending on the type of their embryonic development, degree of ovoviviparity and life cycles. Within the Cestoda, there are three monozoic taxa with only one set of genital organs: Amphilinidea, Gyrocotylidea and Caryophyllidea. In these monozoic taxa and some polyzoic groups with well developed vitellaria (e.g. Pseudophyllidea, Trypanorhyncha) a single oocyte [=germocyte] and a large number of vitellocytes (up to 30) are enclosed within a thick, hardened egg-shell, forming a type of eggs typical for the basic pattern of Neodermata. Only one type of egg-shell enclosures, the so-called 'heterogeneous shell-globule vesicle' is common for the above mentioned cestode taxa. Each membrane-bounded vesicle of mature vitellocytes contains numerous electron-dense shell globules embedded in a translucent matrix. In free-living Neoophora and Monogenea there are two types of vesicles with dense granules; the second is considered to be proteinaceous reserve material. Within the Cestoda, the numbers of vitellocytes per germocyte are reduced in those taxa forming eggs of the 'Cyclophyllidean-type' (e.g. Cyclophyllidea, Tetraphyllidea, Pseudophyllidea). This is particularly evident in Cyclophyllidea; for example, in vitellocytes of Hymenolepis diminuta (Hymenolepididae) there are numerous vitelline granules of homogeneously electron-dense material; in Catenotaenia pusilla (Catenotaeniidae) there are three large, homogenous vitelline vesicles, while in Inermicapsifer madagascariensis (Anoplocephalidae) there is only one large vitelline vesicle, containing homogeneously electron-dense material, which occupies most of the vitelline cell volume. In this respect the Tetraphyllidea and Proteocephalidea, in forming eggs that lack a hard egg-shell, hold an intermediate position. A comparison of interrelationships which exist among types of vitellocytes, vitellogenesis, types of embryonic development, ovoviviparity and life cycles indicates parallelisms and analogies in adaptation to the parasitic way of life in different groups of cestodes. Knowledge on cestode vitellogenesis may also have an important applied aspect. Vitellocytes, due to their high metabolic rate, represent a very sensitive target for analysing effect of anthelminthic drugs upon the egg formation (ovicidal effects); rapid degeneration of vitellocytes is usually accompanied by a cessation of egg production.     

东方杯叶吸虫卵黄腺和卵巢的超微结构研究

本文应用透射电镜观察了东方杯叶吸虫卵黄腺和卵巢的超微结构,并与体外培养成虫进行比较。根据形态特征和内含物的存在情况,将卵黄细胞和卵母细胞的发育均分为不同时期,详细描述了各期的形态特征,探讨了卵黄球和皮质颗粒等内含物的生理功能。体外培养成虫成熟卵黄细胞中有散在的卵黄物质,成熟卵母细胞中线粒体囊泡化,这些可作为体外培养的评价指标。     

Morphological and histochemical observations on the vitelline cells of developing and adult Paramphistomum cervi (Trematoda: Digenea)

In 6 week-old Paramphistomum cervi, vitelline cells appear in the form of a few scattered cells, present below the body wall which divide mitotically to form vitelline follicles in 8 week-old worms. Small shell globules appear first in 10 week-old worms, the number and size of which continue to increase till the worm becomes adult. In the latter the vitelline follicles contain stem cells, immature, maturing and mature vitelline cells, which differ due to the distribution of shell globules as well as their histochemical nature. The shell globules are keratin in nature. The vitelline cells showed activities of various phosphatases but did not show the presence of any of the dehydrogenases studied.     

Ultrastructure of the vitelline follicles of Gorgoderina vitelliloba (Trematoda: Gorgoderidae)

An electron microscope study of the vitelline follicles of Gorgoderina vitelliloba indicates that they contain vitelline cells in various stages of development. Juvenile cells are small and characterised by a little cytoplasm. During differentiation a large amount of granular endoplasmic reticulum develops. In more mature cells, indistinct Golgi complexes give rise to globules of shell protein which migrate to form clusters at the periphery of the cell. Further maturation results in the appearance of large lipid bodies in the vitelline cell cytoplasm.Developing vitelline cells are ensheathed by nurse cell cytoplasm containing numerous small vacuoles which appear to be derived from smooth endoplasmic reticulum. It is suggested that nurse cells may have a role in selection and transport of nutrient material for vitelline cells and that they manufacture precursors of lipid which is subsequently stored as a food reserve in mature vitelline cells. Possible transport sites between parenchymal cells and nurse cells were identified.     

The female gonad in two species of Microplana (Platyhelminthes,Tricladida, Rhynchodemidae): Ultrastructural and cytochemical investigations

The female gonad of the land planarians Microplana scharffi and Microplana terrestris consists of two small germaria located ventrally in the anterior third of the body and of two ventro‐lateral rows of oblong vitelline follicles distributed between the intestinal pouches. Both these structures are enveloped by a tunica composed of an outer extracellular lamina and an inner sheath of accessory cells. Oocyte maturation is characterized by the appearance of chromatoid bodies and the development of endoplasmic reticulum and Golgi complexes. These organelles appear to be correlated with the production of egg granules with a fenestrated/granular content of medium electron density, about 4–5 μm in diameter, which remain dispersed in the ooplasm of mature oocytes. On the basis of cytochemical tests showing their glycoprotein composition, and their localization in mature oocytes, these egg granules have been interpreted as yolk. In the vitelline follicles, vitellocytes show the typical features of secretory cells with well‐developed rough endoplasmic reticulum and Golgi complexes involved in the production of eggshell globules and yolk. The eggshell globules, which appear to arise from repeated coalescences of two types of Golgi‐derived vesicles, contain polyphenols and, when completely mature, they measure about 1–1,2 μm in diameter and show a meandering/concentric content pattern as is typical of the situation observed in most Proseriata and Tricladida. Mature vitellocytes also contain a large amount of glycogen and lipids as further reserve material. On the basis of the ultrastructural features of the female gonad and in relation to the current literature the two species of rhynchodemids investigated appear to be closely related to the freshwater planarians belonging to the family Dugesiidae. J. Morphol. 2009. © 2009 Wiley‐Liss, Inc.     

Ultrastructural and cytochemical aspects of the female gonad of Geoplana burmeisteri (Platyhelminthes, Tricladida, Terricola)

The ultrastructure of the female gonad of the land planarian Geoplana burmeisteri was investigated by means of electron microscopy and cytochemical techniques. It consists of two small germaria located ventral to the intestine and of two irregular, lateral rows of vitelline follicles, both enveloped by a tunica composed of an extracellular lamina and an inner sheath of accessory cells. Accessory cell projections completely surround developing oocytes and vitellocytes. The main feature of oocyte maturation is the appearance of chromatoid bodies and the development of the rough endoplasmic reticulum (RER) and Golgi complexes. These organelles appear to be correlated with the production of egg inclusions of medium electron density, about 1.5-1.8 microm in diameter, which remain scattered in the ooplasm of mature oocytes. On the basis of cytochemical tests demonstrating their glycoprotein composition, these inclusions were interpreted as residual yolk globules. Vitellocytes are typical secretory cells with well-developed RER and Golgi complexes that are mainly involved in the production of yolk globules and eggshell globules, respectively. Eggshell globules appear to arise from repeated coalescence of small Golgi-derived vesicles and, at an intermediate stage of maturation, show a multigranular pattern. Later, after vesicle fusion, they reach a diameter of 1.3-1.6 microm when completely mature and show a meandering/concentric pattern, as is typical of the situation seen in most Proseriata and Tricladida. The content of yolk globules is completely digested by pronase, while the content of eggshell globules is unaffected. Mature vitellocytes contain, in addition, a large quantity of glycogen and lipid droplets as further reserve material. On the basis of the ultrastructural characteristics of the female gonad described above and in relation to the current literature, we conclude that G. burmeisteri appears to be more closely related to the freshwater triclads, in particular to members of the Dugesiidae, than to the marine triclads.     

Ultrastructural and cytochemical aspects of the germarium and the vitellarium in Syndesmis patagonica (Platyhelminthes,Rhabdocoela, Umagillidae)

The cytoarchitecture of the female gonad of the endosymbiont umagillid Syndesmis patagonica has been investigated using electron microscopy and cytochemical techniques. The female gonad consists of paired germaria and vitellaria located behind the pharynx in the mid‐posterior region of the body. Both the germaria and the vitellaria are enveloped by an outer extracellular lamina and an inner sheath of accessory cells which contribute to the extracellular lamina. Oocyte maturation occurs completely during the prophase of the first meiotic division. Oocyte differentiation is characterized by the appearance of chromatoid bodies and the development of endoplasmic reticulum and Golgi complexes. These organelles appear to be involved in the production of round granules, about 2–2.5 μm in diameter, with a homogeneous electron‐dense core surrounded by a granular component and a translucent halo delimited by a membrane. These egg granules migrate to the periphery of mature oocytes, are positive to the cytochemical test for polyphenol detection, are unaffected by protease and have been interpreted as eggshell granules. The mature oocytes also contain a small number of yolk granules, lipid droplets, and glycogen particles scattered throughout the ooplasm. The vitellaria are branched organs composed of vitelline follicles with vitellocytes at different stages of maturation. Developing vitellocytes contain well‐developed rough endoplasmic reticulum and small Golgi complexes involved in the production of eggshell and yolk globules. Eggshell globules are round, measure 4–5 μm in diameter, and have a mosaic‐like patterned content which contains polyphenols. The yolk globules, 2–3 μm in diameter, show a homogeneous protein content of medium electron density, devoid of polyphenols, and completely digested by protease. The mature vitellocytes also contain glycogen as further reserve material. The presence of polyphenolic eggshell granules in the oocytes and of polyphenolic eggshell globules with a mosaic‐like pattern in the vitellocytes have been considered apomorphic features of the Rhabdocoela + Prolecithophora. J. Morphol. 275:703–719, 2014. © 2014 Wiley Periodicals, Inc.     

不同发育时期哲罗鱼卵黄的超微结构

应用透射电镜观察了不同发育时期哲罗鱼(Hucho taimen)卵黄的超微结构.根据哲罗鱼卵黄物质在卵母细胞中的加工合成、积累以及卵母细胞中参与卵黄颗粒形成的细胞器的变化,可将该鱼卵黄发生分为4个特征时期,即卵黄发生前期、卵黄泡期、卵黄积累期和卵黄积累完成期.卵黄发生前期是指卵母细胞发育过程中的卵黄物质开始积累前的时期,此时期核仁不断分裂,出现线粒体云和早期的滤泡细胞层、基层和鞘细胞层;卵黄泡期特点主要是细胞器不断变化产生卵黄泡和皮层泡;卵黄积累期的滤泡膜由内向外依次为放射带、颗粒细胞层、基层和鞘细胞层,此时外源性卵黄前体物质不断经过血液汇集于鞘细胞层,后经微胞饮作用穿过胶原纤维组成的基层,经过多泡体作用转运至颗粒细胞内,在细胞内经过加工和修饰形成小的卵黄蛋白颗粒,卵黄蛋白颗粒经微胞饮穿过放射带进入卵母细胞边缘形成的空泡中,不断积累形成卵黄球;进入卵黄积累完成期,卵黄球体积变大,向细胞中心聚集,填满大部分卵母细胞,卵黄积累完毕.     

Fasciola hepatica: A light and electron autoradiographic study of shell-protein and glycogen synthesis by vitelline follicles in tissue slices

The incorporation of tritiated amino acids and monosaccharides by the vitelline cells of F. hepatica slices maintained in vitro was studied by light and electron microscope autoradiography.A “pulse-chase” labeling technique was used with tritiated tyrosine, phenylalanine, leucine, and methionine, of which H³-tyrosine was the most readily incorporated into shell-protein globules of immature vitelline cells. The mechanism of protein synthesis appeared to resemble the GER-Golgi mediated mechanism of vertebrates. Young vitelline cells were the most active in protein synthesis, and they matured considerably during the 60 min chase period. Maturing cells, which were carrying out glycogenesis, incorporated no amino acids.An “accumulation” labeling technique was used with H³-galactose and H³-glucose. Both monosaccharides were readily incorporated into glycogen by vitelline cells which had reached the stage of glycogenesis, but mature cells, which were already packed with glycogen, incorporated little monosaccharide. Labeling appeared in the nurse cells of follicles containing many mature vitelline cells. No evidence was found for the involvement of any cell organelle in glycogenesis, but preformed glycogen may have acted as a “template” for further synthesis.     

Ultrastructural studies on the reproductive system of Gyrocotylidea and Amphilinidea (Cestoda)

Summary The vitellaria, vitellocyte development and vitelloduct of Gyrocotyle urna are described at the ultrastructural level. Vitellar follicles are surrounded by an extracellular lamina; vitellocytes and the periphery of the follicles are enclosed by a cytoplasmic sheath. Immature vitellocytes are spherical and show a high nucleus-to-plasma ratio. During maturation of vitellocytes their cytoplasmic content increases and numerous dictyosomes, endoplasmic reticulum, egg-shell granules and lipid droplets are formed. Lipid droplets and egg-shell granules fill most of the volume of mature vitellocytes. The vitelloduct is ciliated and shows intraepithelial nuclei and intraluminal folds. No cell borders have been found within the vitelloduct. Vitellogenesis and the vitelloduct morphology of Gyrocotyle are compared with those of other parasitic Plathelminthes.Abbreviations I immature vitellocyte - II maturing vitellocyte - III mature vitellocyte - Az cytoplasmic sheath surrounding the vitellocytes and the follicle - bb basal body - ci cilia of the vitelloduct - ld lipid droplet - mi mitochondrium - nu nucleus - rer rough endoplasmic reticulum - sg egg-shell granulum - ve vesicles     

Oöcyte resorption during ovarian development in the blowfly Lucilia cuprina

Nulliparous females of a normal anautogenous strain of Lucilia cuprina mature all of their primary oöcytes after feeding ad lib on sheep's liver. Females fed measured inadequate amounts of protein-rich materia either fail to mature any oöcytes or mature less than their full complement. These mature oöcytes are smaller than in ad lib fed females. In females maturing no oöcytes, ovarian development ceases with all oöcytes in a pre-vitellogenic or early vitellogenic stage. When females mature only some of their oöcytes, the remainder are resorbed in early vitellogenesis. Few females mature less than 100 oöcytes, if they mature any at all.     

Histological changes during ovarian maturation in the tarnished plant bug,Lygus lineolaris (Palisot de beauvois) (Hemiptera : Miridae)

Histological changes during the first gonotropic cycle in the telotrophic ovarioles of Lygus lineolaris (Hemiptera : Miridae) were studied by light and transmission electron microscopy. Each oocyte goes through a gonotrophic cycle that lasts for ca 7 days during which time 3 distinct stages are observed: previtellogenic, vitellogenic and choriogenic. In the previtellogenic stage, oocytes descend into the vitellarium and increase in size, while maintaining contact with the trophic core by means of nutritive cords. During vitellogenesis, ovarioles are characterized by the development of intercellular spaces in the follicular epithelium and numerous microvilli on the oocyte surface. Yolk granules are incorporated by pinocytosis and the granules coalesce, resulting in large yolk droplets. The trophic core supplies ribosomes, mitochondria and lipid to the oocytes, and its morphology remains unchanged throughout the gonotropic cycle. Vitellogenesis ends with the formation of vitelline membrane on the oocyte surface. During choriogenesis, an egg shell consisting of an exo- and endochorion is formed on the surface of the vitelline membrane. With the completion of choriogenesis, the mature oocyte is ready to be ovulated. During the gonotropic cycle, the oocyte increases in size 10–12-fold, while the germarium remains unchanged in size.     

Development and roles of vitelline cells in eggshell formation in Fasciola gigantica

Summary

In Fasciola gigantica, vitelline cells are the major contributors to the formation of the eggshell. The vitelline cells develop in vitelline follicles that are located in the posterior third of the adult parasite's body, in the areas lateral to the uterus and the testis. Mature vitelline cells are released and transported to the Mehlis' gland-ootype complex via a series of vitelline ducts. Based on ultrastructural features, the developing vitelline cells are classified into four stages: stem cell, protein-synthetic, carbohydrate-synthetic and mature cell stages. At the protein-synthetic stage, the eggshell globules are formed, whereas during the carbohydrate-synthetic stage glycogen particles and glycan vesicles are synthesized. The mature vitelline cells are detached from the nurse cells, and pass successively into the intrafollicular, interfollicular, longitudinal and transverse vitelline ducts, to be stored in the vitelline reservoir before being transported to the ootype via the median vitelline duct. At the same time, ova are transported from the ovary through the oviduct into the ootype lumen where each becomes surrounded by a number of vitelline cells. Vitelline cells secrete eggshell globules to surround a group of vitelline cells and an ovum in the ootype lumen, and these globules coalesce into the definitive eggshell. In the middle part of the uterus fertilization occurs, after which the eggshell is completely formed. Within the egg proper, vitelline cells break down, releasing glycogen and other products to nourish the developing embryo.     

Electrotonic junctions in cecropia moth ovaries.

The steady-state potential of the oocyte, resistance between the ooplasm and the medium, and electronic coupling between oocytes in adjacent follicles were examined in vitellogenic ovarioles of Hyalophora cecropia. The steady-state potential had a constant value of ?40 mV throughout the 100-fold volume increase accompanying yolk deposition, while membrane resistance decreased gradually with increasing size. Resistance rose steeply with the onset of chorion deposition, but did not detectably change with either nurse cell collapse or termination of vitellogenesis. Nonrectified electrical coupling was found between oocytes in adjacent follicles, and fluorescein ions injected into the ooplasm moved readily from follicle to follicle. Large surface area and low membrane resistance made coupling difficult to detect electrically between more mature oocytes, but interfollicular fluorescein migration was found to persist until the end of vitellogenesis. Migration of fluorescein from the oocyte to the follicular epithelium could also be visualized and fingers of ooplasm that cross the vitelline envelope and terminate in dome-shaped attachments to the epithelial cells were implicated in this transfer. The termination of interfollicular coupling coincided with the termination of epithelial-oocyte coupling, and is proposed to result from thickening of the vitelline envelope and withdrawal of the ooplasmic processes.