Structural Changes of Yolk Platelets and Related Organelles during Development of the Newt Embryo

Structural changes in yolk platelets and related organelles in the cytoplasm of the presumptive ectodermal region up to the stage of gastrulation were studied by light and electron microscopies using full-grown oocytes, mature eggs descending the oviduct and embryos of the newt, Cynops pyrrhogaster . Yolk platelets with a superficial layer are first observed in mature eggs descending the oviduct. During the cleavage and early morula stages, the superficial layer increases in thickness and the main bodies become more slender. The superficial layer decreases in thickness in the blastula stage, and many yolk platelets lose this layer in the gastrula stage.
The amount of rough-surfaced endoplasmic reticulum (r-ER) increases rapidly in the morula stage, while Golgi complexes gradually increase in number between the cleavage and gastrula stages. In the cleavage and early morula stages, most of the r-ER is closely adherent to yolk platelets and is associated with several mitochondria. Two types of free vesicles, large (0.5–4.0 μm diameter) and small (0.15–0.3 μm diameter), were seen in abundance from the early morula stage to the early gastrula stages.
Changes in the structure of yolk platelets are discussed in relation to changes in other cytoplsmic organelles.     

Intracellular transport of vitellogenin in Xenopus oocytes: An autoradiographic study

The role of primordial yolk platelets (PYPs) in the transport of the yolk precursor vitellogenin to the yolk platelets in Xenopus laevis oocytes has been demonstrated by electron microscopic autoradiography. Within 20 min after exposure of the oocyte to ³H-labeled-vitellogenin, silver grains are associated with small PYPs which are formed by the fusion of endosomes. At 40 min after incorporation of ³H-labeled vitellogenin, autoradiographic silver grains are associated with larger PYPs and with the superficial layer of yolk platelets. Thus, the results demonstrate that PYPs are an intermediate in the transport of vitellogenin from endosomes to yolk platelets. These observations are consonant with the general hypothesis that vitellogenin first associates (binds?) with the plasma membrane, then is incorporated by endocytosis into endosomes which fuse to form PYPs, and finally the contents of the PYPs are eventually deposited into yolk platelets.     

Osmium Zinc Iodide staining of Golgi elements in oocytes of Triturus cristatus

Summary Developing oocytes of the newt Triturus cristatus were studied in order to clarify the role played by the Golgi apparatus in the formation of yolk. The cytochemical method used for this purpose was that of Maillet (1968) which employs an Osmium Zinc Iodide (OZI) complex.Previtellogenic oocytes reveal a pattern of OZI staining only after hormonal (HCG) stimulation, following which both the Golgi apparatus and the multivesicular bodies are stained.Vitellogenic oocytes taken from non-hormonally stimulated females reveal OZI deposits in a number of vesicles peripheral to the Golgi apparatus as well as within the superficial layer of the forming yolk platelets. Following hormone stimulation, many of the Golgi apparatus located in the central ooplasm of vitellogenic oocytes have all their cisternae blackened by the OZI deposits; other apparatuses, more peripherally located, remain essentially unchanged in their staining pattern. Further, a large number of OZI stained vesicles becomes visible in the vicinity of the Golgi apparatus and within the superficial layer of the forming yolk platelets.The present findings are interpreted as indicating the occurrence of fusion between Golgi derived vesicles and forming yolk platelets. It is also suggested that the vesicles in question function as carriers of Golgi produced enzymes which are presumably required to accomplish the final elaboration of the yolk material.Supported by a grant from the Consiglio Nazionale delle RicercheWe acknowledge the valuable help received from Prof. G. Mancino throughout this investigation     

Absence of DNA in yolk platelets of Bufo arenarum oocytes

The absence of DNA in the yolk platelets of Bufo arenarum oocytes was verified. Oocytes from the coelomic cavity were used in order to avoid possible contamination by the ovarian tissue. Four methods for DNA analysis were employed, and the possibility of interference was carefully checked. The presence of three possible contaminants, which produced positive reactions from the DNA analysis, was detected. These were the glycosaminoglycan from the superficial layer of the platelets, sucrose, and polyvinylpyrrolidone from the buffer commonly used during the isolation of platelets. The present evidence points to the necessity of using at least two different methods for DNA determination with due regard for their sensitivity and specificity before any firm conclusion can be reached on the presence or absence of DNA in nonnuclear and mitochondrial parts of the oocyte.     

Localization and Characterization of Lectins in Yolk Platelets of Xenopus Oocytes

The localization and characteristics of yolk platelet lectins (YLs) in Xenopus laevis oocytes were studied with antiserum against cortical granule lectins (CGLs) as a probe. In oocytes at stages I, II and III-IV, specific, immunofluorescent staining for the lectins was observed on the cortical cytoplasm extending about 2, 4 and 20 μm, respectively, from the egg surface. In stage III-IV oocytes, the superficial layer of the yolk platelets was also stained. The cortical cytoplasm included cortical granules, coated pits, coated vesicles, multivesicular bodies and primordial yolk platelets. The YLs were incorporated into the oocytes by endocytosis as demonstrated using gold-labeled YLs. On PAGE, native YLs gave two bands of CGL-like proteins and proteins that appeared as a single diffuse band. The YLs and the CGLs shared antigenicity and hemagglutination activity specific to D-galactoside residues. However, the proteins of the diffuse band had little or no activity for either hemagglutination or jelly-precipitation, suggesting that they were monomers with a single reactive site. These results indicate that the YLs are supplied to the oocytes, presumably from extracellular sources, polymerized to CGL-like molecules in the cortical cytoplasm and accumulated in the superficial layer of the yolk platelets.     

Ultrastructure and cytochemistry study of the yolk syncytial layer in the alevin of trout (Salmo fario trutta L.) after hatching

After hatching, the yolk syncytial layer of Salmo fario trutta may be subdivided into two zones, namely, the vitellolysis zone (containing numerous yolk platelets), and the cytoplasmic zone (where yolk platelets are rare). In the vitellolysis zone, two stages in the utilization of the yolk are observed: 1) The first stage, comprises the formation of yolk platelets from coalescent yolk by spherical cutting out and basal scission. This process seems to be achieved by the invagination of fibrillar elements into the coalescent yolk to form individual yolk platelets surrounded by a limiting membrane. 2) The second stage essentially consists of the extrusion or budding of yolk matter from a yolk platelet. Again, where the yolk matter leaves a platelet, fibrillar elements are evident and show an alkaline phosphatase activity. The platelets of the vitellolysis zone have a homogeneous content and variable diameter; they never acquire a heterogeneous and polymorphic aspect which could be interpreted as an intermediate stage in their degradation.     

Some Like It Fat: Comparative Ultrastructure of the Embryo in Two Demosponges of the Genus Mycale (Order Poecilosclerida) from Antarctica and the Caribbean

During embryogenesis, organisms with lecithotrophic indirect development usually accumulate large quantities of energetic reserves in the form of yolk that are necessary for larval survival. Since all sponges have lecithotrophic development, yolk formation is an ineludible step of their embryogenesis. Sponge yolk platelets have a wide range of morphological forms, from entirely lipid or protein platelets to a combined platelet showing both lipids and proteins and even glycogen. So far, there are no comparative studies on the nature and content of yolk in congeneric species of sponges inhabiting contrasting environments, which could have putative effects on the larval adaptation to environmental conditions. Here, we have taken advantage of the worldwide distribution of the sponge genus Mycale, in order to compare the embryogenesis and yolk formation in two species inhabiting contrasting latitudinal areas: M. acerata from Antarctic waters and M. laevis from the Caribbean. We have compared their brooded embryos and larvae using scanning and transmission electron microscopy, and calculated their energetic signatures based on the nature of their yolk. While the general morphological feature of embryos and larvae of both species were very similar, the main difference resided in the yolk nature. The Antarctic species, M. acerata, showed exclusively lipid yolk, whereas the Caribbean species, M. laevis, showed combined platelets of lipids and proteins and less frequently protein yolk platelets. The larvae of M. acerata were estimated to possess a two-fold energetic signature compared to that of M. laevis, which may have important ecological implications for their survival and for maintaining large population densities in the cold waters of the Southern Ocean.     

Heterogeneous distribution of "lysosomal" hydrolases in yolk platelets isolated from unfertilized sea urchin eggs by zonal centrifugation.

Three typical “lysosomal” glycosidases, α-L-fucosidase, N-acetyl glucosaminidase and N-acetyl galactosaminidase, were localized within the yolk platelets of unfertilized Strongylocentrotus purpuratus eggs. Homogenates of eggs were fractionated by rate-zonal centrifugation, and the isolated particles were subjected to integrated biochemical and morphological (electron microscopic) analysis. Enzymatic markers were used to determine the distribution of mitochondria (cytochrome oxidase), yolk platelets (acid nitrophenyl phosphatase), and cortical granules (β-1,3 glucanase) in the sucrose density gradient. Yolk platelets were isolated in a high state of purity, with contamination by mitochondria and cortical granules at trace levels. Enzymatic heterogeneity exists within the yolk platelet population. Acid nitrophenyl phosphatase and α-l-fucosidase activities appear to be uniformly distributed within all the yolk platelets, while N-acetyl glucosaminidase and galactosaminidase activities appear to be preferentially distributed within the slower sedimenting sub-population of yolk platelets. Another band of hexosaminidase containing particles sedimented slightly slower than the bulk of the yolk platelets, coincident with the mitochondria. The acid hydrolases packaged in the yolk platelets may participate in the mobilization of yolk material after fertilization. The yolk platelet thus appears to be a highly complex and structured “lysosome-like” storage organelle.     

Yolk organelles and their membranes during vitellogenesis ofXenopus oocytes

Summary The yolk platelets ofXenopus laevis have been studied by thin-section and freeze-fracture electron microscopy to characterize the boundary membrane during yolk formation. Throughout vitellogenesis, large yolk platelets are in close contact with smaller nascent yolk organelles. Two types of primordial yolk platelets (I and II) have been discriminated. After membrane fusion these precursors can be completely incorporated into the main body of existing platelets, numerous yolk crystals then merge and form one uniformly stratified core. Lipid droplets are tightly attached to the membrane at all developmental stages of yolk platelets. A direct connection of endoplasmic reticulum to the membranes of yolk platelets was not observed. On freezeetching replicas, yolk-platelet membranes present fracture faces with intramembranous particles (IMP) of various sizes and a heterogeneous distribution of approximately 200–600 IMP/μm² at the E face, and 1200–2100 IMP/μm² at the P face. Again, this presentation of the membrane exhibits neither anastomoses to the endoplasmic reticulum, nor caveolae that exclude the uptake of yolk-containing vesicles into these yolk organelles. Proteinaceous yolk platelets tend to fracture along their periphery through the superficial layers.     

Cathepsin D Activity in the Vitellogenesis of Xenopus laevis

An ovarian extract of Xenopus laevis exhibited in SDS-PAGE analyses an activity cleaving vitellogenin to lipovitellins under mildly acidic conditions. This activity was pepstatin-sensitive and inhibited by monospecific anti-rat liver cathepsin D antibody and thus identified as cathepsin D. Immunoblot analysis showed that two proteins of 43 kDa and 36 kDa immunoreacted with the antibody.
Immunocytochemical staining revealed that the enzyme was located in the cortical cytoplasm of stage I and II oocytes and in small yolk platelets and nascent forms of large yolk platelets in the cortical cytoplasm of stage III oocytes. In stage IV and V oocytes, small yolk platelets retained the immuno-staining but large yolk platelets decreased it. No immuno-positive signals were observed in oocytes at stage VI. When examined by immunoelectron microscopy, gold particles indicated that cathepsin D was located on dense lamellar bodies in the cortical cytoplasm of stage I and II oocytes. The particles were located on primordial yolk platelets and on the superficial layer of small yolk platelets in stage III oocytes, while they were sparse or not present at all on large yolk platelets in stage IV and V oocytes. These results indicate that cathepsin D plays a key role in vitellogenesis by cleaving endocytosed vitellogenin to yolk proteins in developing oocytes.     

STUDIES ON AMPHIBIAN YOLK : 1. The Ultrastructure of the Yolk Platelet

The yolk platelets of mature eggs and young embryonic cells of all amphibian species studied (Rana pipiens, Triturus pyrrhogaster, Diemictylus viridescens, Rana nigromaculata, and Bufo vulgaris) have a superficial layer of fine particles or fibrils (ca. 50 A in diameter), a central main body with a crystalline lattice structure, and an enclosing membrane approximately 70 A in thickness. Electron micrographs of the main body reveal hexagonal net (spacing ca. 70 A), square net (spacing ca. 80 A), and parallel band (spacing from 35 to 100 A but most frequent at ca. 70 A) patterns. The crystalline structure is believed to be a simple hexagonal lattice made of closely packed cylindrical rods. Each rod is estimated to be about 80 A in diameter and 160 A in length.     

Amphibian embryo protease inhibitor. V. Effect of calcium on the distribution of amphibian trypsin inhibitor during fertilization and subsequent development of Rana pipiens.

In previous publications we have documented the existence in oocytes and embryos of a variety of forms (notably Rana pipiens), massive amounts of a powerful inhibitor of trypsin-like enzymes (ATI). The bulk of the inhibitor in Rana pipiens is localized in yolk platelets. We present evidence here that the distribution of the inhibitor between yolk platelets and cytosol changes and that this change is mediated by variations in the distribution of calcium ions. There is an inverse relationship between ATI and free calcium in the cytosol. Several workers have demonstrated a dramatic rise in free cytosol calcium immediately following fertilization. We confirm this observation, and demonstrate that there is a parallel and equally dramatic decrease in free cytosol ATI during this period. Experiments with purified yolk platelets indicate that calcium effects a release of sequestered inhibitor from these particles. Other experiments indicate that calcium mediates ATI-lippovitellin associations. A calcium mediated flux of ATI from cytosol to yolk is proposed as a device for controlling limited proteolysis in the cytoplasm. We offer this as a model for studying the unmasking of mRNA which follows fertilization.     

Yolk platelets in artemia embryos: are they really storage sites of immature mitochondria?

We have used semi-quantitative polymerase chain reaction (PCR) technology to determine the mitochondrial DNA (mtDNA) content of yolk platelets isolated from embryos of the brine shrimp, Artemia franciscana, and ultrastructural analysis of yolk platelet formation to determine whether these organelles contain mitochondria as reported previously. Using six different isolation and purification protocols, we found one yolk platelet preparation to be devoid of mtDNA, while four yolk platelet preparations contained mtDNA ranging from 16.4 to 85 pg/10(6) yolk platelets. One preparation contained 600 pg mtDNA per 10(6) yolk platelets. Based on our PCR analyses, the mtDNA component of Artemia yolk platelets represented 0.16-4.5% of the total DNA isolated from the platelets. We calculated that Artemia yolk platelets contain, on average, approximately 1.78 molecules of mtDNA/platelet. Direct analysis of mtDNA in "free" mitochondria isolated from yolk platelet-free preparations of Artemia embryos and newly hatched larvae yielded 0.76-0.80 ng/animal. Based on these values, the mtDNA content of yolk platelets was approximately 0.2% of total mtDNA in Artemia embryos. Microscopic analysis of yolk platelet formation during oogenesis in Artemia failed to show the inclusion of mitochondria during the assemblage of yolk platelets. The "mitochondria-like" structures that appear in yolk platelets during their utilization lack the well defined inner and outer membranes characteristic of mitochondria making it unlikely that the yolk platelet inclusions are mitochondria. Our results from PCR technology and ultrastructure analysis demonstrate that mtDNA in yolk platelets of Artemia franciscana embryos is a minor component of the total mtDNA in the embryo, and they fail to support the notion that yolk platelets in Artemia are a major source of immature mitochondria for development.     

In Vivo Study of Vitellogenin-Gold Transport in the Ovarian Follicle and Oocyte of Xenopus laevis

The transport of injected vitellogenin (VTG)-gold in the ovarian follicle and developing oocyte in Xenopus is described. The gold particles reached the extracellular spaces of the theca and interfollicular spaces within 1 and 2 hr, respectively, after a tracer injection at 20°C. The tracers moved through channels between the constitutive cells of both the capillary endothelium and the follicle cell layer.
Compartments in the peripheral cytoplasm of vitellogenic oocytes at stage IV, which relate to yolk formation, seemed to be segregated as follows: (a) internalization compartment consisting of coated pits and vesicles of the oolemma covering the oocyte "macrovilli", (b) transport compartment of endosomes and multivesicular endosomes in the oocyte cortex, and (c) crystallization compartment of primordial yolk platelets (PYP) in the sub-cortical region. The gold particles appeared in the internalization and transport compartments at 3–6 hr after the tracer injection and in the cystallization compartment at 12–18 hr. The VTG, internalized by receptor-mediated endocytosis, was transferred from coated vesicles to multivesicular endosomes by vesicle-to-vesicle fusion. VTG crystallization took place in globular-shaped PYPs of about 1 μm. At 24 hr after the tracer injection, the gold particles appeared in completely crystallized yolk platelets, most of them clustered in the superficial layer and some integrated into the crystals.     

Incorporation of 35S-sulfate into yolk platelets of Xenopus laevis embryos. A study using electron microscope autoradiography.

Inorganic 35S-sulfate was injected into Xenopus laevis embryos before first cleavage to study incorporation of the label into the yolk platelets in order to localize glycosaminoglycan synthesis. Electron microscope autoradiography of embryonic thin sections from blastulae and gastrulae revealed that the primary site of label incorporation is at the edge of the yolk platelets, and, to a lesser extent, in their interiors. Autoradiography of isolated yolk platelets, lacking unit membranes, indicated the absence of label. Thus, edge associated label comes from the yolk platelets membrane, and interior label is solubilized in the glycerol-water gradient during yolk platelets isolation. Ruthenium red staining of yolk platelet in situ shows haavy deposits of the dye on the yolk platelet membrane surface facing the cytoplasmic surface. The crystalline main body of isolated yolk platelets does not take up the dye. It appears that continuous synthesis or sulfation of glycosaminoglycan occurs primarily at the outer surface yolk platelet membranes during early development, providing a novel site for this process.     

Incorporation of 35S-Sulfate into Yolk Platelets of Xenopus laevis Embryos

Inorganic ³⁵S-sulfate was injected into Xenopus laevis embryos before first cleavage to study incorporation of the label into the yolk platelets in order to localize glycosaminoglycan synthesis. Electron microscope autoradiography of embryonic thin sections from blastulae and gastrulae revealed that the primary site of label incorporation is at the edge of the yolk platelets, and, to a lesser extent, in their interiors. Autoradiography of isolated yolk platelets, lacking unit membranes, indicated the absence of label. Thus, edge associated label comes from the yolk platelets membrane, and interior label is solubilized in the glycerol-water gradient during yolk platelets isolation.
Ruthenium red staining of yolk platelet in situ shows heavy deposits of the dye on the yolk platelet membrane surface facing the cytoplasmic surface. The crystalline main body of isolated yolk platelets does not take up the dye.
It appears that continuous synthesis or sulfation of glycosaminoglycan occurs primarily at the outer surface yolk platelet membranes during early development, providing a novel site for this process.     

ELECTRON MICROSCOPY OF BASOPHILIC STRUCTURES OF SOME INVERTEBRATE OOCYTES : II. FINE STRUCTURE OF THE YOLK NUCLEI

RNA containing yolk nuclei from the surf clam Spisula solidissima have been studied with the light microscope and with the electron microscope. A variety of structures can be seen with both and a correlation can be made between bodies studied with the electron microscope and those studied with the light microscope. The electron microscope shows many of these structures to be composed of double walled lamellae arranged in space, in various ways. The variety of patterns seen with the electron microscope can be satisfactorily explained on the basis of a hypothetical model. The presence of yolk platelets within the yolk nuclei lends support to classical observations on the synthesis of yolk within yolk nuclei or yolk nuclei derivatives. Small granules (about 100 A) are included within the double walled lamellae and their presence probably accounts for the basophilic nature of the entire body. The presence of small granules attached to electron-dense layers relates the yolk nuclei described here to ergastoplasm discussed by others.     

Ferromagnetic isolation of endosomes involved in vitellogenin transfer into Xenopus oocytes

The transport pathway of the yolk precursor vitellogenin (VTG) has been followed using the techniques of ferrolabeling and ferromagnetic sorting, coupled with electron microscopic visualization. Vitellogenin conjugated to colloidal ferric particles of ca. 11 nm is selectively transported from the oolemma to the yolk platelets of vitellogenic Xenopus oocytes after gonadotropin stimulation of the female. Several cortical membrane compartments, labeled or unlabeled with ferric particles, are involved in the internalization and the transfer of vitellogenin to the yolk platelets. 1) Coated pits apparently fuse with coated vesicles, and coated vesicles fuse with each other in the outermost cortical cytoplasm. 2) Vesicles, depleted of their clathrin coat, fuse with cortical tubular endosomes and discharge their contents into yolk endosomes. 3) These endosomes are the direct precursors of the yolk organelles. 4) Endocytic vesicles fuse only with primordial yolk platelets of type I and not with type II or fully grown yolk platelets. After pulse-chase loading with ferric particles conjugated to vitellogenin and subsequent subcellular fractionation of the oocytes, ferromagnetic sorting of the various vesicle populations has been performed by using a "free-flow magnetic chamber". This novel method enables specification and characterization of purified endosomal compartments that accumulate protein yolk in Xenopus oocytes.     

Dependence of the superficial layers of Spirillum putridiconchylium on Ca2+ or Sr2+.

Chelating agents disrupted the superficial layers on Spirillum putridiconchylium and adsorption of cationized ferritin indicated that both upper and lower surfaces of superficial layer fragments, as well as the outer membrane surface, possessed areas which were negatively charged. Growth of the bacterium in 1% casamino acids (vitamin free) resulted in cells which were devoid of the superficial layers, and negative staining of these cells revealed in amorphous precipitate together with a vesicular outer membrane component extruding from their surfaces into the medium. Addition of either 1 mM Ca2+ or 1 mM Sr2+ to the growth medium produced the typical regularly structured cell surface, whereas addition of equal concentrations of Li+, Na+, K+, Mg2+, Ba2+, Mn2+, Fe3+, or three polyamines produced the structureless surface.     

鸡蛋胚下表层卵黄DNA的提取方法

利用Ficoll-400不连续密度梯度离心将受精和未受精鸡蛋的胚下表层卵黄进行纯化, 显微镜观察表明卵黄球形态良好, 没有胚细胞的存在.然后利用较高浓度的蛋白酶K消化,较长时间的酚抽提,最后提取了DNA. 电泳显示DNA条带清晰.该方法简便快速,从每个鸡蛋的胚下表层卵黄可回收10 ng DNA.