Vitellogenin transport and yolk formation in the quail ovary

Morphological and biochemical investigations were made on the yolk formation in ovaries of the quail Coturnix japonica. Morphologically, two ways of nutrient uptake were observed in follicles. In small oocytes of white follicles, vitellogenin (VTG) was taken up through fluid-phase endocytosis which was assisted by follicular lining bodies. The lining bodies were produced in follicle cells. They adhered to the lateral cell membrane, moved along the membrane in the direction of the enclosed oocyte and were posted to the tips of the microvilli. These tips, now with lining bodies, were pinched off from the main cell body, engulfed by indented cell membranes of the oocyte, and transported to yolk spheres. In large oocytes of yellow follicles, VTG and very-low-density lipoproteins (VLDL) were taken up through receptor-mediated endocytosis. The VTG and VLDL particles diffused through the huge interspaces between follicle cells, and once in oocytes were transported to yolk spheres via coated vesicles. Immunohistochemistry showed that the VTG resides on or near the surface of the follicle cell membrane at the zona radiata whereas the cathepsin D resides at or near the oocytic cell membranes. Tubular and round vesicles in the cortical cytoplasm of oocytes were also stained with both antisera, suggesting that these vesicles are the sites where the VTG is enzymatically processed by cathepsin D. Upon analysis by SDS-PAGE, a profile similar to that of yolk-granule proteins was produced by incubating VTG with a quail cathepsin D of 40 kD.     

Cytochemical studies of developmental stages during oogenesis in Culex pipiens molestus (Forsk?l). I. Lipids and carbohydrates

Lipids and carbohydrates were studied in the polytrophic ovaries of Culex pipiens molestus during oogenesis. The cytoplasm of both the oocyte and the nurse cells contains lipid structures at all stages of development--granules in the early stages and spheres in the later stages. Intranuclear lipid bodies can be demonstrated in the oocyte and in the nurse cells. After leaving the nucleus, lipids are deposited in the peripheral cytoplasm. From the third to the seventh adult phase, lipid granules are concentrated in the area of the nurse cell and oocyte junction, indicating that lipids originate in the nurse cells and are transported from these to the oocyte. The follicular epithelial cells provide the oocyte with lipid material for fatty yolk synthesis and formation of the egg envelopes. Lipids are distributed similarly to the Golgi apparatus, indicating that there is a relationship between this organelle and fat formation. In the early stages, the cytoplasm of the oocyte, the nurse cells and the follicular epithelium contains glycogen granules. In the later stages these cells also contain mucopolysaccharides. The mucopolysaccharide yolk spheres are enclosed in vacuoles, while the chorion is composed of acid mucopolysaccharides. The follicular epithelium and vitelline membrane are of a mucopolysaccharide nature. A topographical relationship exists between the Golgi apparatus and the glycogen granules, indicating that this organelle also plays a role in glycogen synthesis.     

Cytochemical studies of oocyte development in Sarcophaga lineatocollis Macq. (Muscidae: Diptera)

The ovary of Sarcophaga lineatocollis is a typical polytrophic ovary. Each of its 25-30 ovarioles is composed of a small terminal filament, a small germarium and a vitellarium consisting of the egg follicle. The tunica propria is a noncellular, PAS-positive membrane. The ovarian follicle contains fifteen trophocytes and one oocyte. RNA is synthesized with the aid of the nuclei in the trophocyte cytoplasm, which are RNA- and PAS-positive. Protein is deposited intensively in the early stages of the trophocytes. The trophocytes of Sarcophaga lineatocollis synthesize RNA and protein more actively than the oocyte. In this fly, protein yolk precursor (PYP) bodies are supplied by the trophocyte cytoplasm to the ooplasm at an advanced stage of development. Nucleolar budding and vacuolation are observed in the trophocytes. RNA, DNA, protein and PYP bodies appear to be transported to the ooplasm from the trophocytes. Pyknotic trophocyte nuclei can be seen entering the ooplasm. The perinuclear Golgi bodies of the trophocytes help in the production and maturation of PYP bodies in the trophocytes before they are organized and passed on to the oocytes. Some RNA is contributed to the oocyte by the follicular epithelium. All these processes leading to maturation and development of the oocyte are discussed and interpreted.     

On the infiltration of Golgi bodies from the follicular epithelium to the egg

Summary 1. In a well advanced oocyte of the tortoise the egg membranes besides the theca and the single-layered epithelium consist of a zona pellucida often differentiated into zona striata and a homogeneous layer; underlying these two layers is a layer of cortical fibrillae or fibrillar layer, Next to this layer, is the limiting membrane of the egg which is not present in all stages and generally disappears in a well developed oocyte. In certain animals either the homogeneous layer or fibrillar layer is absent. 2. In certain animals,Golgi bodies seem to be extruded into the follicle cells from the theca cells. 3. At a particular stage of development the follicle cells become very active and produce a large number of smallGolgi bodies. TheseGolgi granules filter through canalicular passages of the zona radiata into either the homogeneous layer and from thence into the fibrillar layer or where a homogeneous layer is not present directly to the fibrillar layer. Where a fibrillar layer is not present they are transferred directly to the limiting membrane and from thence to the egg. 4. In certain cases e. g. in Fowl, Calotes and Uromastix, fairly large lumps ofGolgi bodies are extruded from the follicle cells through the zona pellucida into the egg. Here the fine canilicular passages do not seem to form a vehicle for the passage of these comparatively larger bodies. 5. The fine canalicular passages in the zona radiata ofTestudo graeca andKachuga smithii and the fibrillar prolongation of the cytoplasm which we have called the fibrillar layer are marked features of the egg membranes at certain stages of development of the egg. During the period when infiltration ofGolgi bodies through these passages takes place slides prepared by silver nitrate and osmic methods show black beaded chains ofGolgi granules in various stages of descent. 6. It is claimed that the extrusion and infiltration ofGolgi bodies from the follicular epithelium to the egg are established phenomena at least in the Vertebrates.     

Der Einfluß von Li- und SCN-Ionen auf die Differenzierungsleistungen desAmbystoma-Ektoderms und ihre Veränderung bei kombinierter Einwirkung beider Ionen

Summary The development of the mouse oocyte during the primordial, primary and secondary follicular growth stages was studied by means of the electron microscope.During the early stages of oocyte maturation, mitochondrial multiplication takes place along with an apparent temporary transition from round to oval shape. The internal structure of many of the mitochondria is altered by separation of membranes of a crista to form a vacuole. This enlarges to pear-shaped configurations and gradually it forms so large a structure as to result in compression of adjacent cristae, thereby altering the entire appearance of the organelle.Dense round bodies encapsulated by a single membrane are found in the cytoplasm of oocytes of primary follicles near the periphery. The Golgi complex appears in primary follicle oocytes as an aggregation of vesicles. Gradually the number of lamellae in the complexes increase and these organelles become more peripherally located. The Balbiani yolk nuclei apparently is represented by a conglomeration of Golgi complexes and are present only in primordial and young primary follicle oocytes.The endoplasmic reticulum appears in the early stages only as rough-surfaced vesicles. At later stages individual cisternae become prominent. Apparently, a modified form of E. R. appears during maturation of the secondary follicle oocyte.Multivesicular complexes, each consisting of two components, small vesicles and larger vesicles enclosing microvesicles (multivesicular bodies), were commonly found during all stages of oocyte growth. The secondary follicle oocytes frequently contain multilamellar bodies. These are commonly found in juxtaposition to the multivesicular complexes and also near the egg periphery and occasionally near the nuclear envelope.This investigation was supported by a Public Health Service Research Career Program Award (5-K3-HD-5356-07) from the National Institute of Child Health and Human Development.     

Ultrastructural observations of previtellogenic ovarian follicles of dove

Dove ovarian follicle is a complex structure composed of oocyte surrounded by a somatic compartment consisting of theca externa, theca interna and granulosa. The structure of ovarian follicle (1 and 2 mm) of dove was studied by electron microscopy. The granulosa was pseudostratified in the 1-mm-diameter follicles and stratified with two or three irregular rows of cells in the 2-mm-diameter follicles. In the larger follicle indentations between oocyte and granulosa cells become more numerous and the microvilli of granulosa cell elongated to form a zona radiata with similarly elongated oocyte microvilli. Lining bodies were present at the tips of granulosa microvilli and in the cortical region of the oocyte. In the oocyte cortex were observed coated pits, coated vesicles, dense tubules, multivesicular bodies and primordial yolk spheres. Primordial yolk spheres may contain lining bodies and were observed fused with dense tubules and multivesicular bodies or associated with smooth cisternae.     

Ultrastructural studies of differentiation in the oocyte of the polyclad turbellarian,Prostheceraeus floridanus

Oocyte differentiation in the polyclad turbellarian Prostheceraeus floridanus has been examined to determine the nature of oogenesis in a primitive spiralian. The process has been divided into five stages. (1) The early oocyte: This stage is characterized by a large germinal vesicle surrounded by dense granular material associated with the nuclear pores and with mitochondria. (2) The vesicle stage: The endoplasmic reticulum is organized into sheets which often contain dense particles. Vesicles are found in clusters in the cytoplasm, some of which are revealed to be lysosomes by treatment with the Gomori acid phosphatase medium. (3) Cortical granule formation: Cortical granules are formed by the fusion of filled Golgi vasuoles which have been released from the Golgi saccules. The association between the endoplasmic reticulum and Golgi suggests that protein is synthesized in the ER and transferred to the Golgi where polysaccharides are added to form nascent cortical granules. (4) Yolk synthesis: After a large number of cortical granules are synthesized, yolk bodies appear. They originate as small membrane-bound vesicles containing flocculent material which subsequently increase in size and become more compact. Connections between the forming yolk bodies and the endoplasmic reticulum indicate that yolk synthesis occurs in the ER. (5) Mature egg: In the final stage, the cortical granules move to the periphery and yolk platelets and glycogen fill the egg. At no time is there any evidence of uptake of macromolecules at the oocyte surface. Except for occasional desmosomes between early oocytes, no membrane specialization or cell associations are seen throughout oogenesis. Each oocyte develops as an independent entity, a conclusion supported by the lack of an organized ovary.     

Oogenesis in the leech Glossiphonia heteroclita (Annelida, Hirudinea, Glossiphoniidae) II. Vitellogenesis, follicle cell structure and egg shell formation

By the end of previtellogenesis, the oocytes of Glossiphonia heteroclita gradually protrude into the ovary cavity. As a result they lose contact with the ovary cord (which begins to degenerate) and float freely within the hemocoelomic fluid. The oocyte's ooplasm is rich in numerous well-developed Golgi complexes showing high secretory activity, normal and transforming mitochondria, cisternae of rER and vast amounts of ribosomes. The transforming mitochondria become small lipid droplets as vitellogenesis progresses. The oolemma forms microvilli, numerous coated pits and vesicles occur at the base of the microvilli, and the first yolk spheres appear in the peripheral ooplasm. A mixed mechanism of vitellogenesis is suggested. The eggs are covered by a thin vitelline envelope with microvilli projecting through it. The envelope is formed by the oocyte. The vitelline envelope is produced by exocytosis of vesicles containing two kinds of material, one of which is electron-dense and seems not to participate in envelope formation. The cortical ooplasm of fully grown oocytes contains many cytoskeletal elements (F-actin) and numerous membrane-bound vesicles filled with stratified content. Those vesicles probably are cortical granules. The follicle cells surrounding growing oocytes have the following features: (1) they do not lie on a basal lamina; (2) their plasma membrane folds deeply, forming invaginations which eventually seem to form channels throughout their cytoplasm; (3) the plasma membrane facing the ovary lumen is lined with a layer of dense material; and (4) the plasma membrane facing the oocyte forms thin projections which intermingle with the oocyte microvilli. In late oogenesis, the follicle cells detach from the oocytes and degenerate in the ovary lumen.     

Studies on the ovotestis of the slug Agriolimax reticulatus (Müller)

Summary The ovarian oocytes of Agriolimax reticulatus (Müller) have been studied by light and electron microscopy and electron cytochemistry. The development of the oocyte in the ovotestis may be divided into three stages.During Stage I the oocyte cytoplasm contains mainly ribosomes and also strands of endoplasmic reticulum, scattered mitochondria and Golgi systems. The nucleus contains both a paranucleolus and an eunucleolus. By Stage II the oocyte has enlarged, especially in a plane parallel to the basement membrane. In addition to the above mentioned organelles, the cytoplasm contains lipid, glycogen and early yolk platelets. During Stage III, the oocyte continues to enlarge, but mainly in a plane perpendicular to the basement membrane. A considerable degree of cytoplasmic differentiation has also taken place. The plasma membrane of the oocyte has become specialized with the appearance of a polysaccharide-rich glycocalyx, microvilli and pinocytotic tubules. Elsewhere, much of the background cytoplasm, containing Golgi-derived, polysaccharide and acid phosphatase-rich multivesiculate bodies, lipid and glycogen, is sequestered by smooth membranes and ultimately fuses with the growing yolk platelets. The nucleus contains an amphinucleolus, characteristic of many gastropods.The findings of this study are discussed in relation to results from other studies on oogenesis.     

中华蚱蜢卵子发生中花生凝集素受体的初步鉴定和发育表达

The distributions of PNA binding glycoconjugates in the plasma membrane of Acrida cinerea Thunberg germ cells were detected using biotin labeled PNA, for better understanding of the formation and changes of glycoconjugates during oogenesis. The ultrastructure of vitellogenesis also was observed by electron microscopy for detection of the origin and track of vitelline material. In the ovary, PNA receptors appeared in the oocyte cytoplasm of the second phases of oogenesis; positive granules gradually increased from the third phase to the fourth, and they exhibited a maximum expression before the vitellogennic stage in the cytoplasm of the oocyte. From the vitellogennic to chorionation stage, positive granules gradually declined. Binding sites on follicle cells were changed with their morphological variation in every stage of oogenesis. The vitelline of A. cinerea formed within the oocyte by degrees. The results suggest that PNA receptors and yolk materials are synthesized by the oocytc at an early period. With the development of the oocyte, some exogeous materials from two sources act as PNA receptors and others take part in vitelline synthesis. One is blood lymph that offers some useful materials to the oocyte directly through follicle cell gaps; the other are follicle cells that produce and transmit some materials to oocyte to support vitellogenesis. In addition, PNA receptors secreted by follicle cells participate in the formation of yolk membrane [ Acta Zoologica Sinica 5 l （5） ： 932 - 939, 2005 ].     

The follicle cell-oocyte interaction in ovarian follicles of the stick insect Bacillus rossius (Rossi): (Insecta: Phasmatodea)

Developing ovarian follicles of Bacillus rossius have been examined ultrastructurally in an attempt to understand how inception of vitel-logenesis is controlled. Early vitellogenic follicles are characterized by a thick cuboidal epithelium that is highly interlocked with the oocyte plasma membrane. Gap junctional contacts are present both at the follicle cell/oocyte interface and in between adjacent follicle cells. In addition, microvilli of follicle cells protrude deeply into the cortical ooplasm of these early vitellogenic oocytes. With the onset of vitellogenesis, wide intercellular spaces appear in the follicle cell epithelium and at the follicle cell/oocyte interface. Gap junctions become progressively reduced both on the follicle cell surface and on the oocyte plasma membrane. Microvilli from the two cell types no longer interlock. From a theoretical standpoint each of the two structural differentiations present at the follicle cell/oocyte interface—gap junctions and follicle cell microvilli—could potentially trigger inception of vitellogenesis. Gap junctions might permit the passage of a regulatory molecule, transferring from follicle cells to oocyte, which would control the assembly of coated pits on the oocyte plasma membrane. Alternatively cell interaction via microvilli might induce the appearance of coated pits, thus creating a membrane focus for vitellogenin receptors. Both possibilities are discussed in relation to current literature.     

The function of the golgi complex in transitional epithelium. Synthesis of the thick cell membrane

The superficial squamous cells of rat transitional epithelium are limited, on their luminal face, by an asymmetrically thickened membrane. Patches of similar thick membrane are found in the walls of the Golgi cisternae and it is suggested that the Golgi system is the site of assembly of the thick plasma membrane. This implies membrane flow from the Golgi apparatus to the cell surface, and there is indirect evidence that the membrane is transported in the form of fusiform vacuoles, derived from the Golgi cisternae, which fuse with, and become part of, the free cell membrane. Uptake of injected Imferon shows that similar, large, thick-walled vacuoles may be formed by invagination of the free cell surface. Some of these vacuoles are subsequently transformed into multivesicular bodies and autophagic vacuoles. The formation of other large heterogeneous bodies is described, and some of these are shown to have acid phosphatase activity.     

The role of the follicle cells during oogenesis in the chiton Sypharochiton septentriones (Ashby) (Polyplacaphora,Mollusca)

Summary Histochemical studies and electron microscopic investigations on the role of the follicle cells during oogenesis in the chiton Sypharochiton septentriones showed that the main role of the follicle cells was the deposition of a spiny chorion around each oocyte. The chorion was composed of three layers; an inner, acid mucopolysaccharide layer, which was a primary egg membrane secreted by Golgi bodies in the cortical cytoplasm of the oocyte, an intermediate layer of protein and an outer layer of lipid. The intermediate and outer layers were secreted by the follicle cells and were thus secondary egg membranes.     

An EM autoradiographic study on ovarian follicle cells of Drosophila melanogaster with special reference to the formation of egg coverings.

Ovarian follicle cells of Drosophila melanogaster have been studied by ultrastructural and autoradiographic analyses. During their migration through the germarium, follicle cells undergo several structural changes and, of these, the most conspicuous one occurs at the level of the nucleolus. By the time the first ovarian chamber is formed, follicle cells have formed a layer of uniform thickness all around a cluster or nurse cells and the oocyte. Following the initiation of vitellogenesis, the follicle cells overlaying the oocyte become columnar while those over the nurse cells become very thin. During stages 9-10, the columnar follicle cells are involved in the formation of the vitelline membrane, while from stages 11 to 13 these cells produce the endochorion. An EM autoradiographic analysis has shown that the rate of 3H-uridine incorporation in follicle cells nuclei is low in previtellogenic chambers, while it becomes very high in nuclei of stage 9-10 chambers. After short exposure to uridine, silver grains are located predominantly over nucleoli. Evidence from incorporation studies with 3H-lysine indicates that the columnar follicle cells and the region of the various egg coverings are highly labelled within an hour of incubation in the tracer. The observations confirm that columnar follicle cells are the only cells in the chamber involved in the formation of materials which make up the egg coverings.     

Ultrastructural characteristics of the follicle cell-oocyte interface in the oogenesis of Ceratophrys cranwelli

In this work we carried out an ultrastructural analysis of the cell interface between oocyte and follicle cells during the oogenesis of the amphibian Ceratophrys cranwelli, which revealed a complex cell-cell interaction. In the early previtellogenic follicles, the plasma membrane of the follicle cells lies in close contact with the plasma membrane of the oocyte, with no interface between them. In the mid-previtellogenic follicles the follicle cells became more active and their cytoplasm has vesicles containing granular material. Their apical surface projects cytoplasmic processes (macrovilli) that contact the oocyte, forming gap junctions. The oocyte surface begins to develop microvilli. At the interface both processes delimit lacunae containing granular material. The oocyte surface has endocytic vesicles that incorporate this material, forming cortical vesicles that are peripherally arranged. In the late previtellogenic follicle the interface contains fibrillar material from which the vitelline envelope will originate. During the vitellogenic period, there is an increase in the number and length of the micro- and macrovilli, which become regularly arranged inside fibrillar tunnels. At this time the oocyte surface exhibits deep crypts where the macrovilli enter, thus increasing the follicle cell-oocyte junctions. In addition, the oocyte displays coated pits and vesicles evidencing an intense endocytic activity. At the interface of the fully grown oocyte the fibrillar network of the vitelline envelope can be seen. The compact zone contains a fibrillar electron-dense material that fills the spaces previously occupied by the now-retracted microvilli. The macrovilli are still in contact with the surface of the oocyte, forming gap junctions.     

ULTRASTRUCTURAL LOCALIZATION OF PHOSPHOLIPID SYNTHESIS IN THE RAT TRIGEMINAL NERVE DURING MYELINATION

A method for the ultrastructural localization of acyltransferase enzymes involved in phospholipid metabolism has been applied to the developing rat trigeminal nerve. Determination of acyltransferase levels in the nerve indicated that a peak of activity occurs at the 8th day after birth with gradual declines of activity up to 15 days. Morphological surveys and determinations of cholesterol levels suggested that heavy myelin formation occurs in the nerve during this latter period. Fixed nerves incubated in a medium for localization of acyltransferases indicated deposition of reaction product associated with Golgi cisternae, intracellular smooth vesicles, and the plasma membrane of the Schwann cell in the incipient stages of myelin formation. Golgi-derived vesicles appeared to move toward the Schwann cell surface and fuse with the plasma membrane. Activity continued to be detectable in the plasma membrane of the internal mesaxon as long as cytoplasm was evident and mature myelin membrane was not yet formed. Cells in which myelin formation appeared advanced showed little or no enzyme marker. Consistent with cytochemical observations were biochemical determinations of acyltransferases which showed high levels of the enzymes in microsomes, while no activity could be detected in the myelin fraction. Acyltransferase reaction product was also observed in the Golgi apparatus of ganglion cell bodies, axoplasmic smooth vesicles, and the axolemma. Localization of acyltransferase enzymes in Schwann cells, ganglion cell bodies, and axons during development of the nerve is discussed in relation to membrane biogenesis in the nervous system.     

The histology and histochemistry of oogenesis in the water strider, Gerris remigis Say

In each ovariole of Gerris remigis, nurse cells arise by mitotic divisions at the anterior end of the germarium. These cells enlarge as they move posteriorly. This size increase is possibly caused by fusion of cells, but probably by endopolyploidy as well. The nurse cells then establish connections with a central trophic core, which receives the products of subsequent nurse cell degradation. Two possible pathways of nuclear degradation are suggested: one involves the condensation of chromatin within the nucleus; the other, the release of DNA as fine granules into the cytoplasm. Cytoplasmic areas containing such DNA are also rich in proteinaceous granules, but have a meager content of RNA. The remainder of the cytoplasm of the mature nurse cells contains a high concentration of RNA, as do the nucleoli. Posteriorly the trophic core connects via nutritive cords with each developing oocyte in the prefollicular region and in the anterior vitellarium. RNA is apparently contributed to the ooplasm via the trophic stream. Patches of cytoplasmic DNA are present in the young oocytes; the origin and fate of this DNA is uncertain. During early oocyte maturation chromosomal stainability decreases, and the nucleolus enlarges. In previtellogenic stages, numerous proteinaceous bodies appear in association with the nucleolus-chromosome complex. These bodies, like the nucleolus, have only a low RNA content. They may pass to the cytoplasm, but cannot be traced with certainty. During the latter part of this period a complex population of small proteinaceous and lipid preyolk bodies accumulates peripherally in the oocyte. Definitive protein and lipid yolk are probably derived by the enlargement and inward migration of these bodies. The oocytes are each surrounded by a layer of follicle cells proliferated in the prefollicular region. These become binucleate and enlarge as the enclosed oocytes grow and elongate. RNA also increases in the nucleoli and cytoplasm of the follicle cells as they move posteriorly in the vitellarium. There is no evidence of transfer of nucleic acids or protein from the follicle cells to the oocyte. The nurse cells are therefore implicated as the major source of nucleic acids for the maturing oocyte.     

A network system for vitellogenin synthesis in the mussel Mytilus galloprovincialis (L.)

The aim of this study is to assess, by RT‐PCR, in situ hybridization, electron microscopy, and immunohistochemistry, the site/s of vitellogenin (VTG) synthesis in the mussel Mytilus galloprovincialis. Our investigations demonstrate that, among the analyzed tissues, the synthesis of VTG occurs only in the female gonad, that is, within the oocyte and follicle and connective cells. Such a synthesis is just evident in early vitellogenic oocytes, whose cytoplasm is characterized by numerous RER cisternae and an extended Golgi complex surrounded by nascent yolk platelets. The synthesis of VTG goes on in vitellogenic oocytes assuming a pear form, and progressively reduces once the oocyte shows the pear or polygonal form, typical of those oocytes that have concluded the growth. The expression of VTG occurs also within follicle (auxiliary) and connective cells. In particular, it is noteworthy that follicle cells are characterized by numerous RER cisternae and an active Golgi complex surrounded by numerous vesicles and vacuoles containing electron dense material. The same material is also present along their plasma membrane, within the intercellular space between oocyte and follicle cells, and finally within invaginations of the oocyte surface, thus suggesting a VTG transfer to the oocyte via endocytosis. Differently, no VTG synthesis was observed within digestive gland. All together the findings here reported strongly suggest that in M. galloprovincialis, inside the gonad, the VTG synthesis occurs in the oocyte (autosynthesis) and in the follicle and adipogranular cells (heterosynthesis). J. Cell. Physiol. 228: 547–555, 2013. © 2012 Wiley Periodicals, Inc.     

Early Stages in Wheat Endosperm Formation and Protein Body Initiation

The early stages of endosperm formation and protein body initiationare described for hard red winter wheat using light and transmissionelectron microscopy. Two days after flowering (DAF) the endospermwas a thin layer of coenocytic cytoplasm lining the embryo sac.By 4 DAF the endosperm had cellularized and completely filledthe embryo sac. Enough differentiation had occurred by 6 DAFto distinguish cells destined to become the aleurone layer,sub-aleurone region and central endosperm. Protein bodies wereinitiated at about 6–7 DAF and were first found near theGolgi apparatus. Wheat was ready for combine harvest at 34 DAF.Enlargement of the small protein bodies near the Golgi apparatusoccurred by several mechanisms: (1) fusion with one or moreof the dense Golgi vesicles or fusion with other protein bodies,(2) fusion with small electron-lucent Golgi-derived vesicles,(3) pinocytosis of a portion of the adjacent cytoplasm intothe developing protein body and (4) fusion of large proteinbodies with one another at later stages of grain development.Of the four mechanisms described, the pinocytotic vesicles andfusion of protein bodies were the most frequent and consistentprocesses observed. Direct connections between rough endoplasmicreticulum (RER) and protein bodies were not observed. The resultssuggest a rôle for the Golgi apparatus in the initiationof protein bodies. Also, the lack of RER derived vesicles suggestsa soluble mode of secretion of storage proteins involved inthe enlargement of protein bodies. Triticum aestivum, wheat endosperm, protein bodies Golgi apparatus     

An EM autoradiographic study on ovarian follicle cells of Drosophila melanogaster with special reference to the formation of egg coverings

Summary Ovarian follicle cells of Drosophila melanogaster have been studied by ultrastructural and autoradiographic analyses.During their migration through the germarium, follicle cells undergo several structural changes and, of these, the most conspicuous one occurs at the level of the nucleolus. By the time the first ovarian chamber is formed, follicle cells have formed a layer of uniform thickness all around a cluster or nurse cells and the oocyte. Following the initiation of vitellogenesis, the follicle cells overlying the oocyte become columnar while those over the nurse cells become very thin. During stages 9–10, the columnar follicle cells are involved in the formation of the vitelline membrane, while from stages 11 to 13 these cells produce the endochorion.An EM autoradiographic analysis has shown that the rate of ³H-uridine incroporation in follicle cell nuclei is low in previtellogenic chambers, while it becomes very high in nuclei of stage 9–10 chambers. After short exposure to uridine, silver grains are located predominantly over nucleoli.Evidence from incorporation studies with ³H-lysine indicates that the columnar follicle cells and the region of the various egg coverings are highly labelled within an hour of incubation in the tracer.The observations confirm that columnar follicle cells are the only cells in the chamber involved in the formation of materials which make up the egg coverings.This work was partly supported by C.N.R. (Italy)I am indebted to Dr. J. Jacob from the Institute of Animal Genetics (Edinburgh) for introducing me to the use of EM autoradiography