Coelomic pouch formation in reconstructing embryos of the starfish Asterina pectinifera

The morphogenetic processes of coelomic pouch (CP) formation in starfish embryos that were experimentally dissociated and induced to undergo reconstruction were studied. An analysis of these embryos randomly chosen from several cultures showed that CP always form on either side of the esophagus, even though the CP formation can differ in timing of initiation and duration, and can vary in number and size from embryo to embryo. Successive observations of CP formation in living embryos revealed two distinct sequences of CP development that were accompanied by different appearances of the blastocoele. These processes were named 'enterocoelic-like' and 'schizocoelic-like' CP formation. The former resembled normal development and occurred in embryos with a transparent blastocoele. The latter was characterized by the aggregation and epithelialization of mesenchyme-like cells on either side of the esophagus and was observed in embryos possessing a cloudy blastocoele. In a few embryos, both types of CP formation were seen in the same individual ('mosaic type' CP formation). Thick sections of embryos possessing a cloudy blastocoele revealed that aggregates of mesenchyme-like cells undergoing CP formation directly contact the developing esophagus. Together, these data demonstrate flexibility in the morphogenetic processes that regulate CP formation, and suggest that positional cues in the esophagus regulate the placement of CP.     

A mass spectrometry-based targeted metabolomics strategy of human blastocoele fluid: a promising tool in fertility research

Embryo assessment is currently performed through the analysis of morphology and cleavage rate. Recent studies have sought to identify a correlation between quali-quantitative profiles of small molecules of metabolic interest and the outcome of embryo transfer. Approaches relying on both optical and non-optical spectroscopy have been proposed to non-invasively monitor the embryo culture media. However, the non-invasive approach only offers an indirect strategy to monitor embryos and a turn-around solution to bypass the limits of detection of these analytical techniques. In this paper we pave the way for direct metabolic assessment of embryos through the mass-spectrometry-based analysis of blastocoele fluid, which is withdrawn from the blastocoele cavity prior to cryostorage of blastocysts. We conclude that it is possible to detect most of the metabolites of potential interest right at the very heart of the blastocyst, without disrupting the workflow of a classic laboratory pipeline.     

Amphibian embryo protease inhibitors. IV. Studies on an inhibitor of chymotrypsin and papain

Amphibian embryo chymotrypsin and papain inhibitor (ACPI) purified by the procedure described in this paper produces a single band on sodium dodecyl sulfate (SDS) gel electrophoresis and a single peak on Sephadex G-75 chromatography. Except for its enzyme specificity, ACPI is very similar to amphibian embryo trypsin inhibitor (ATI). Its molecular weight is about 10,500 and its amino acid composition is typical of many naturally occurring protease inhibitors. Inhibition develops slowly, is retarded by the presence of substrate and is temporary. ACPI is localized in the yolk platelets and its disappearance both from whole embryos and from select tissue types corresponds closely with that of ATI. Possible roles for amphibian embryo proteases and protease inhibitors in development are discussed.     

Development of head and trunk mesoderm in the dogfish,Scyliorhinus torazame: I. Embryology and morphology of the head cavities and related structures

Vertebrate head segmentation has attracted the attention of comparative and evolutionary morphologists for centuries, given its importance for understanding the developmental body plan of vertebrates and its evolutionary origin. In particular, the segmentation of the mesoderm is central to the problem. The shark embryo has provided a canonical morphological scheme of the head, with its epithelialized coelomic cavities (head cavities), which have often been regarded as head somites. To understand the evolutionary significance of the head cavities, the embryonic development of the mesoderm was investigated at the morphological and histological levels in the shark, Scyliorhinus torazame. Unlike somites and some enterocoelic mesodermal components in other vertebrates, the head cavities in S. torazame appeared as irregular cyst(s) in the originally unsegmented mesenchymal head mesoderm, and not via segmentation of an undivided coelom. The mandibular cavity appeared first in the paraxial part of the mandibular mesoderm, followed by the hyoid cavity, and the premandibular cavity was the last to form. The prechordal plate was recognized as a rhomboid roof of the preoral gut, continuous with the rostral notochord, and was divided anteroposteriorly into two parts by the growth of the hypothalamic primordium. Of those, the posterior part was likely to differentiate into the premandibular cavity, and the anterior part disappeared later. The head cavities and somites in the trunk exhibited significant differences, in terms of histological appearance and timing of differentiation. The mandibular cavity developed a rostral process secondarily; its homology to the anterior cavity reported in some elasmobranch embryos is discussed.     

Reprograming of murine blastocoele formation

The present study shows that there is communication between reaggregated asynchronous cleavage stage blastomeres that regulates blastocoele formation. Individual blastomeres from eight-cell murine embryos were transferred to empty zonae pellucidae, intact two-cell embryos, or enucleated two-cell embryos, and were examined over a period of 75 hours for development of cavitation. It was found that the isolated blastomeres cavitated concurrently with intact control eight-cell embryos, while intact control two-cell embryos cavitated 24 hours later. However, the embryos resulting from combining a two-cell embryo and a blastomere from an eight-cell embryo cavitated at a time in between the eight- and two-cell controls.     

Comparative embryology and mammalian cloning

A hypothesis has been advanced that logically combines “contradictory” facts concerning the early mammalian development and shows a natural relationship between the embryos developing from a fertilized ovum and from cells of the inner cell mass of blastocyst. When studying the theoretical questions of cloning, it is necessary to take into consideration the peculiarities of prenatal mammalian ontogeny, which make themselves evident upon comparison with other animals. The absence of yolk in the mammalian ovum defines sharp differences in the early development between mammals and other Amniota. The complete asynchronous cleavage results in the formation of morula followed by blastocyst, which hatches from zona pellucida and is implanted into the uterus tissue. This fact allows us to consider the blastocyst as a mammalian larva, which is fed owing to the maternal organism. It is known that, in the body of a larva (blastocyst), a new embryo develops from some somatic cells. This process is known as polyembryony, which is typical of the development of some parasitic insects. Polyembryony in turn is a variant of somatic embryogenesis, which is a form of asexual reproduction. Thus, the two different embryos, “conceptus” and “embryo proper,” have different origins: the first forms by the sexual way and the second, by the asexual way. Investigation of the mechanisms of somatic embryogenesis in mammals will help us to find conditions necessary for full reprogramming of donor somatic nuclei and provide for successful development of reconstructed embryos.     

Gastrulation and angiogenesis,not endothelial specification,is sensitive to partial deficiency in vascular endothelial growth factor-a in mice

Mouse embryogenesis is dose sensitive to vascular endothelial growth factor-A (VEGF-A), and mouse embryos partially deficient in VEGF-A die in utero because of severe vascular defects. In this study, we investigate the possible causes that underlie this phenomenon. Although the development of vascular defects in VEGF-A-deficient embryos seems to suggest that endothelial differentiation depends on the presence of a sufficient level of VEGF-A, we were surprised to find that endothelial differentiation per se is insensitive to a significant loss of VEGF-A activity. Instead, the development of the multipotent mesenchymal cells, from which endothelial progenitors arise in the yolk sac, is most highly dependent on VEGF-A. As a result of VEGF-A deficiency, dramatically fewer multipotent mesenchymal cells are generated in the prospective yolk sac. However, among the small number of mesenchymal cells that do enter the prospective yolk sac, endothelial differentiation occurs at a normal frequency. In the embryo proper, vasculogenesis is initiated actively in spite of a significant VEGF-A deficiency, but the subsequent steps of vascular development are defective. We conclude that a full-level VEGF-A activity is not critical for endothelial specification but is important for two distinct processes before and after endothelial specification: the development of the yolk sac mesenchyme and angiogenic sprouting of blood vessels.     

Rayleigh instability of the inverted one-cell amphibian embryo

The one-cell amphibian embryo is modeled as a rigid spherical shell containing equal volumes of two immiscible fluids with different densities and viscosities and a surface tension between them. The fluids represent denser yolk in the bottom hemisphere and clearer cytoplasm and the germinal vesicle in the top hemisphere. The unstable equilibrium configuration of the inverted system (the heavier fluid on top) depends on the value of the contact angle. The theoretically calculated normal modes of perturbation and the instability of each mode are in agreement with the results from ComFlo computational fluid dynamic simulations of the same system. The two dominant types of modes of perturbation give rise to axisymmetric and asymmetric sloshing of the cytoplasm of the inverted embryos, respectively. This work quantifies our hypothesis that the axisymmetric mode corresponds to failure of development, and the asymmetric sloshing mode corresponds to development proceeding normally, but with reversed pigmentation, for inverted embryos.     

Inhibition of Glycosphingolipid Biosynthesis Does Not Impair Growth or Morphogenesis of the Postimplantation Mouse Embryo

Abstract: Whole embryo culture (WEC) of organogenesis-stage mouse embryos was adapted for glycosphingolipid (GSL) metabolic studies to evaluate the hypothesis that de novo GSL biosynthesis is a prerequisite for growth and morphogenesis of the early postimplantation embryo. WEC supports the growth and development of postimplantation mouse embryos to stages that are indistinguishable from those achieved in vivo. N -Butyldeoxygalactonojirimycin ( N B-DGJ) is an N -alkylated imino sugar that specifically inhibits biosynthesis of all glucosylceramide-based GSLs. N B-DGJ inhibited glucosylceramide and lactosylceramide biosynthesis nearly completely and inhibited ganglioside biosynthesis ∼90% in both the embryo and visceral yolk sac. N B-DGJ also significantly reduced total ganglioside content in both the embryo and visceral yolk sac as estimated by the cholera toxin immunooverlay technique. A shift in expression from the structurally simple to the structurally complex gangliosides was also observed in N B-DGJ-treated embryos and yolk sacs. Despite causing major changes in GSL biosynthesis and composition, N B-DGJ had no effect on embryo viability, growth, or morphology. The findings suggest that de novo GSL biosynthesis may not be a prerequisite for the growth and morphogenesis of the organogenesis-stage mouse embryo.     

Effects of L-asparaginase on rat embryonic development and yolk sac membrane in vitro

A comparative analysis of the teratogenic effects of L-asparaginase on 10.5- and 11.5-day rat embryos after 24 and 48 hours of exposure in vitro, respectively, were performed. Several medium concentrations of L-asparaginase (0.05, 0.25, and 1.5 IU/ml) were tested in both embryo series. Resulting embryos were submitted to morphological studies in a search for a specific route of pathogenesis. Morphological alterations of the visceral yolk sac were also studied to investigate its contribution to L-asparaginase teratogenicity in rats. Main embryonic malformations (open truncal neural tube, open encephalic vesicles, anophthalmia, lack of inversion, abnormal frontolateral protrusions, great vascular dilations at the cephalic level) and developmental retardation were already generated after the first 24 hours of culture (embryos of 10.5 days) and presented a dose-response relationship. Vascular dilations and neurulation disturbances seemed to be related to an early mesenchyme deficiency. Reduced number of mesenchymal cells was more evident in embryos of 10.5 days than those of 11.5 days, suggesting the existence of a later compensatory mechanism of cellular proliferation in the older embryo. Visceral yolk-sac endodermal cells at both embryonic stages were greatly deformed and enlarged by an increase of the high electron-dense vacuolar system. Therefore, both a blockage of the processes of lysosomal digestion and derived trophic deficiencies probably existed. A double teratogenic mechanism for L-asparaginase is postulated: a direct action mainly in younger embryos (before invagination of the embryo into the yolk sac) and a yolk sac-mediated one.     

A morphometric comparison of dissimilar early development in sibling species of Platynereis (Annelida,Polychaeta)

Summary Early development of Platynereis massiliensis was studied in serial sections of fixed embryos and in living or fixed embryos whose nuclei had been made visible with a fluorescent label. The unfertilized egg is an ellipsoid with three axes of differing length. The longest axis corresponds to the dorsoventral axis of the developing embryo. Egg volume is ten times that in the sibling species, P. dumerilii, mainly due to increased yolk content. The timing and spatial pattern of cleavage were observed from first cleavage to the 62-cell stage. Volumes of the blastomeres, their nuclei, their yolk-free cytoplasm and their yolk were determined from serial sections up to the 29-cell stage. In the P. massiliensis embryo, cell cycles are on average 3.7 times longer than in P. dumerilii; volume proportions among the blastomeres also differ and the macromeres containing the bulk of yolk are particularly large, but otherwise the cleavage patterns, differential segregation of yolk and yolk-free cytoplasm, and the histogenetic fates of the blastomeres are the same as in P. dumerilii. This equivalence of cell lineage and of cytoplasmic segregation mechanisms in both species, maintained in spite of the different appearance of the embryos, suggests functional importance of and selective constraint on these developmental features. The relatively accelerated divisions of the 2d cell line in P. massiliensis may be interpreted as the precocious development of cell lines which give rise to adult structures. Several structures, obviously functional in developing P. dumerilii, have lost their function in P. massiliensis: the egg contains few cortical granules, giving rise to only a moderate egg jelly layer in the zygote; prototroch cells develop cilia, but the heavy embryo is unable to swim; the larva develops three pairs of parapodia but, unlike the corresponding stage in P. dumerilii, is not capable of coordinate locomotion. This loss of motility is related to the brooding habit of the species developing inside the parental tube and is explained as the result of a switch from pelagic to benthic, protected reproduction in P. massiliensis. Offprint requests to: A.W.C. Dorresteijn     

Comparative Response of Rat and Rabbit Conceptuses In Vitro to Inhibitors of Histiotrophic Nutrition

Histiotrophic nutrition via the visceral yolk sac is an essential nutritional pathway of the rodent conceptus, and inhibition of this pathway may cause growth retardation, malformations, and death in rodent embryos. Morphologic differences among species during early development indicate that the visceral yolk sac histiotrophic nutrition pathway may be of lesser importance in nonrodent species, including humans. Here, comparative studies were conducted with inhibitors of different steps in the visceral yolk sac histiotrophic nutrition pathway to determine whether the rabbit is similarly responsive to the rat. Early somite stage New Zealand White rabbit and Crl:CD(SD) rat conceptuses (gestation day 9, rabbits; gestation day 10, rats) were exposed for 48 hr to three different histiotrophic nutrition pathway inhibitors using whole embryo culture techniques, after which they were evaluated for growth and malformations. Cubilin antibody, an inhibitor of endocytosis, reduced growth and development and increased malformations in both rat and rabbit embryos, although the rabbit appeared more sensitive. Leupeptin, a lysosomal cysteine protease inhibitor, also impaired growth and development and increased malformations in rat embryos, while in the rabbit it induced malformations and a slight decrease in morphology score but had no effect upon growth. Trypan blue, an inhibitor of endocytosis and endosome maturation, affected all measures in both species to a similar degree at the highest concentration (2500 μg/ml), but rat embryos responded to a greater extent at lower concentrations. Although the specific adverse outcomes appear to be different, these results demonstrate that rabbits, like rats, are sensitive to inhibitors of the histiotrophic nutrition pathway     

Lipid dynamics in the embryos of Patiriella species (Asteroidea) with divergent modes of development

Evolution of lecithotrophic development in sea stars involved a modification in maternal provisioning from the production of yolk-dominated to lipid-dominated eggs. The dynamics of lipid reserves in the embryos of four Patiriella species differing in their lipid provisions were examined. Patiriella regularis had small yolk protein-dominated eggs (150 microm in diameter) and an ancestral mode of development through planktotrophic larvae. Patiriella calcar, Patiriella exigua and Patiriella pseudoexigua had large eggs (390-440 microm in diameter) and lecithotrophic planktonic, benthic and intragonadal larvae, respectively. Patiriella exigua deposited negatively buoyant eggs containing substantial yolk protein and lipid reserves onto the substratum. In contrast, the planktonic eggs of P. calcar and the intragonadal eggs of P. pseudoexigua were dominated by lipid and were neutrally and positively buoyant, respectively. By the blastula stage there was little trace of lipid in P. regularis embryos. Blastulae of the lecithotrophic developers, by contrast, had conspicuous lipid droplets distributed through their cells. In parallel with the change from cuboidal to columnar epithelium during the blastula to gastrula transition, lipid reserves became redistributed into the basal cytoplasm. The extent of lipid transport reflected the amount of lipid reserves. In P. pseudoexigua embryos with the greatest lipid load, basal shunting was followed by secretion of lipid into the blastocoele where it was stored for the perimetamorphic period. Evolution of lecithotrophy in Patiriella appears to reflect selection to provide metamorphic stages with nutrients normally accrued by feeding larvae with the consequence that early development is burdened by voluminous, potentially inert nutritive stores. Lipid redistribution coincident with a major developmental stage transition may be required to facilitate unimpeded morphogenesis. This phenomenon may be characteristic of lecithotrophic development in echinoderms and appears pre-adaptive for extrusion of lipid in species like P. pseudoexigua with particularly extensive lipid reserves.     

Ultrastructure of mouse blastocysts during blastocoele expansion

Summary The ultrastructure of mouse blastocysts with nascent and expanded blastocoele is described. In the early blastocyst cells adhere tightly and the blastocoele is often limited at its apex by cells containing a midbody. The expanding blastocyst exhibits a loose cell arrangement due to the presence of intercellular spaces and a cortical layer of filaments develops in cells enclosing the expanded blastocoele. When the blastocoele exceeds 1/2 the embryo diameter desmosomes appear between trophectoderm cells. Possible factors essential for blastocoele formation are discussed.     

31P nuclear-magnetic-resonance studies on the developing embryos of Xenopus laevis.

The concentrations of nucleoside triphosphate, inorganic phosphate and the yolk proteins, phosvitin and lipovitellin, have been monitored in living embryos of Xenopus laevis by 31P nuclear magnetic resonance (NMR) spectroscopy. The nucleoside triphosphate levels remain relatively constant at about 3.5-4.5 nmol/embryo at least until the 'spontaneous movement' stage of development. By the swimming tadpole stage an inorganic phosphate resonance representing about 30 nmol/embryo becomes evident in the NMR spectrum. Computer manipulation also shows such a resonance, although smaller, to be present at a somewhat earlier developmental stage; these findings are confirmed biochemically. The major contribution to the NMR spectrum of oocytes, unfertilized eggs and early embryos is the yolk phosphoprotein resonance. On isolation of the yolk from the embryos it is possible to quantify the contribution to the NMR spectrum from the lipid-phosphate and protein-phosphate moieties of the yolk proteins. During development, as the yolk is used up, it is found that the protein-phosphate resonance disappears at a greater rate than the lipid-phosphate peak. The total phosphorus content of the embryo (approximately 200 nmol/embryo) is shown biochemically to remain constant during development; however, the total amount of phosphorus observed by NMR decreases by about 40% during development. From the resonance positions of their alpha, beta and gamma phosphate groups it is deduced that the nucleoside triphosphate molecules are liganded in vivo to a divalent cation which is not manganese, but could be either magnesium or calcium. From the position of the inorganic phosphate resonance it is deduced that the internal pH of embryos where this resonance is evident is 6.8 +/- 0.2.     

Developmental expression of aquaporin-3 in zebrafish embryos (Danio rerio)

Fish embryos have never been successfully cryopreserved because of the low permeability of cryoprotectants into the yolk. Recently, we used aquaporin-3 fused with a green fluorescent protein (AQP3GFP) to modify the zebrafish embryo, and demonstrated that the pores functioned physiologically. This increased the water and cryoprotectant permeability of the membranes. We have continued our work on AQP3-modified embryos and here we report their developmental expression of AQP3, the success of various culture media on their survival and development, and their reproductive success. The AQP3GFP expression begins within 30 m after the mRNA AQP3GFP injection into the yolk of the 1- to 4-cell embryo. This expression is distributed in the membranes throughout the blastoderm and the yolk syncytial layer within 24 h. It diminishes after 96 h. We found no difference in the survival or normal development of embryos from AQP3GFP or wild-type adults. Additionally, zebrafish embryos did not require special culture medium to survive after AQP3GFP modification. In fact, they survived best in embryo medium (ca. 40 mOsm). Embryos reared entirely in embryo medium had a higher percent survival and a higher percent normal development than those exposed to a high osmolality sucrose culture medium (ca. 330 mOsm). The mechanism whereby these embryos can maintain their internal osmolality in a hypoosmotic solution with water channels in their membranes is unknown.     

乌骨鸡胚胎发育过程中卵内蛋白质脂肪的变化研究

对乌骨鸡胚胎发育过程中卵内各组成成分(蛋清、蛋黄、胚胎)在不同胚龄(即入孵的第0、3、6、9、12、15、18d和出壳)时蛋白质、脂肪含量变化进行测定与分析．结果表明：在不同胚龄时,蛋清中蛋白质含量显著高于蛋黄,蛋黄中脂肪含量始终高于蛋清;而胚胎中的蛋白质、脂肪逐渐增加。另外,胚胎发育过程中胚胎蛋白质的主要来源是蛋黄中的蛋白质,说明蛋黄是禽类胚胎发育过程中营养需要的主要来源。