No sex difference in yolk steroid concentrations of avian eggs at laying

Yolk steroids of maternal origin have been proposed to influence genetic sex determination in birds, based on sex differences in yolk steroid concentrations of peafowl eggs incubated for 10 days. More recent reports dispute this proposal, as yolk steroids in eggs incubated for 3 days do not show such sex differences. To date, research examining this phenomenon has only analysed incubated eggs, although sex in avian species is determined before incubation begins. This may be a serious methodological flaw because incubation probably affects yolk steroid concentrations. Therefore, we investigated sex differences in yolk steroid concentrations of unincubated avian eggs. We withdrew yolk for steroid analysis from fresh, unincubated Japanese quail (Coturnix japonica) eggs by biopsy, and then incubated those eggs for 10 days, after which we harvested the embryonic material for genetic sexing and the incubated yolk for further steroid analysis. We found no sex differences in fresh Japanese quail eggs; however, sex differences were apparent in yolk steroids by day 10 of incubation, when female eggs had significantly more oestrogen in relation to androgen than male eggs. Concentrations of all yolk androgens decreased dramatically between laying and day 10 of incubation, whereas oestradiol (E2) concentrations increased marginally. Thus, yolk concentrations of androgens and E2 do not appear critical for avian sex determination.     

The specificity of intracellular changes in chick embryo blastoderm during the latent period of embryogenesis]

Yolk inclusions, lipids and polysaccharides found in the chicken embryo blastoderm cells are utilized during the latent period of embryogenesis. The yolk outside the blastoderm is not utilized. A delay in the development of the embryo of first days of incubation is related to a switching over the metabolism from utilizaiton of intracellular nutrient material to assimilation of the extracellular yolk. In the course of morphogenetical movements of the embryo, in the process of gastrulation, took place an increased biosynthesis in the blastoderm cell membranes.     

Egg Turning During Incubation has no Effect Upon the Growth of Embryos of Alligator mississippiensis

Alligator eggs are not turned during incubation, instead the embryo adheres to the top inside of the shell. Turning is alleged to shear off the embryo and kill it. Avian egg turning allegedly facilitates embryonic development by stimulating growth of the area vasculosa and minimizing the effects of unstirred yolk and albumen layers. From day 10 to day 45 of incubation, alligator eggs were experimentally turned, gently, through ± 60° in an hourly cycle. This turning regime killed only 6 out of 25 embryos. Compared with unturned controls, no significant effects were observed on the growth, production of extraembryonic fluids or utilization of albumen and yolk for those embryos that survived turning. The protein concentration of amniotic fluid at various stages of alligator development was examined in eggs incubated at 30 and 33°C. The fluid contained very little protein (max <8 mg) at any time: the protein concentration did not change consistently as development progressed. Differences in response to egg turning in birds and reptiles may be associated with the length of the incubation period, the protein content of the albumen and the mechanism of albumen utilization.     

Yolk spherocrystal: the structure, composition and liquid crystal template

The structure and composition of the yolk spherocrystal, a biomineral developed in the egg yolk sac during the incubation of a chicken embryo, were investigated through various modern analytical methods. Additionally, inside the yolk sac, yolk liquid crystal, a liquid crystalline phase of lipid developed during the incubation of the embryo, was found and investigated. The spherocrystal was found to be a composite composed of calcium carbonate (vaterite and calcite, primarily the former) and the yolk liquid crystal, which is believed to act as an organic template for spherocrystals mineralization, in a concentric multi-layered sphere structure. Moreover, the yolk liquid crystal was found to have a concentric multi-layered spherical structure and a composition consistent with lecithin. We believed that the spherocrystals function as a reservoir for the storage of calcium in the egg yolk sac during the development of the embryo.     

Early embryonic development,including germ-disk stage,in the theridiid spider Achaearanea japonica (Bös. et Str.)

Early embryonic development, from the first cleavage to the germ-disk stage, in the theridiid spider Achaearanea japonica was examined by light and electron microscopy. The eggs are syncytial during the first four cleavages, and then invaginations of cell membranes fuse to generate the blastomeres at the sixteen-nucleus stage. The cleavage pattern is a modified type of total cleavage. It appears that radial bundles of microtubules that radiate from the perinuclear cytoplasm may participate in the migration of cleavage nuclei for the formation of the blastoderm. The large yolk granules are sequestered by cell membranes from the blastomeres or blastoderm cells into the interior of the embryo together with various organelles and glycogen granules. Most of the blastoderm cells converge in the upper hemisphere to form the germ disk, whereas a few cells remain in the lower hemisphere. The embryo at the germ-disk stage contains many spherical germ-disk cells. Almost no large yolk granules are found in these cells, but the flat remaining cells each contain several large yolk granules. These remaining cells may preserve a flat shape to cover the surface of the embryo that does not include the germ disk. © 1995 Wiley-Liss, Inc.     

Origin and organization of the zebrafish fate map

We have analyzed lineages of cells labeled by intracellular injection of tracer dye during early zebrafish development to learn when cells become allocated to particular fates during development, and how the fate map is organized. The earliest lineage restriction was described previously, and segregates the yolk cell from the blastoderm in the midblastula. After one or two more cell divisions, the lineages of epithelial enveloping layer (EVL) cells become restricted to generate exclusively periderm. Following an additional division in the late blastula, deep layer (DEL) cells generate clones that are restricted to single deep embryonic tissues. The appearance of both the EVL and DEL restrictions could be causally linked to blastoderm morphogenesis during epiboly. A fate map emerges as the DEL cell lineages become restricted in the late blastula. It is similar in organization to that of an amphibian embryo. DEL cells located near the animal pole of the early gastrula give rise to ectodermal fates (including the definitive epidermis). Cells located near the blastoderm margin give rise to mesodermal and endodermal fates. Dorsal cells in the gastrula form dorsal and anterior structures in the embryo, and ventral cells in the gastrula form dorsal, ventral and posterior structures. The exact locations of progenitors of single cell types and of local regions of the embryo cannot be mapped at the stages we examined, because of variable cell rearrangements during gastrulation.     

The embryo pancreas is a source of increased yolk amylase in the fertilized eggs of domestic fowls.

The amylases were studied in the yolk of fertilized eggs and in the pancreases of the embryos of domestic fowls. The amylase activity in the yolk increased markedly from 13 days of incubation until hatching, but the activity decreased when the embryos were taken out of the eggs. The isoamylases in the yolk and in the pancreas of the embryo were identical electrophoretically. The amylase occurs mainly in the pancreas of the embryo. We think that the increase in amylase activity in the yolk of fertilized eggs during incubation depends upon the accumulation of pancreatic amylase synthesized by the developing embryo in the egg.     

Rapid and improved method for windowing eggs accessing the stage X chicken embryo

The chick stage X blastoderm is routinely accessed through a small window in a freshly laid egg. However, windowing severely compromises embryo survival with hatch rates as low as a few percent. We previously reported a simple modification to the standard method that reduced introduction of air into the sealed egg and improved the hatchability to 32%. Here, we describe an even simpler and more rapid method for sealing a windowed egg using hot glue or paraffin in which the hatch rate increased to an average of 63% of the unwindowed control eggs. The primary reason for low hatchability can be attributed to air trapped within the egg during windowing and/or leakage during incubation, as shown by increased lethality by artificially introducing air into windowed and sealed eggs. Although the hatch rate was considerably improved, air can still enter the egg during incubation and is likely to account for less than 100% hatchability of the sealed eggs. The success of this new windowing method will facilitate high throughput for the production of transgenic birds and find use in developmental biology, toxicity testing, and avian disease research.     

Metabolic fates of yolk lipid and individual fatty acids during embryonic development of the coot and moorhen

There is currently little information regarding the metabolic fates of yolk lipid and individual fatty acids during embryonic development of free-living avian species. Here we report the pattern of lipid utilization during embryonic development of the coot (Fulica atra) and the moorhen (Gallinula chloropus), two related species producing precocial offspring from eggs with a distinctive fatty acid composition and with an incubation period similar to that of the chicken. By the time of hatching, the proportions of the initial yolk lipid that had been transferred to the embryo were 88.2% and 79.8% for the coot and moorhen respectively. During the whole incubation period, 42.9% and 40.0% of the initial yolk lipid of the coot and moorhen respectively were lost from the system due to oxidation for energy, equating to 47.8% and 50.0% respectively of the actual amount of lipid transferred over this time. Thus, the lipid received by the embryos of both species is partitioned almost equally between the alternative fates of energy metabolism and incorporation into tissue lipids. In the coot, this 50:50 split between oxidation and tissue formation was maintained during the hatching process. The proportions of arachidonic (20:4n-6) and docosahexaenoic (22:6n-3) in the yolk lipids of these species were 2.5-3.5 times higher than in eggs of domestic poultry. In contrast to the situation in the chicken, there was no preferential uptake of 22:6n-3 from the yolk during coot and moorhen development. The fatty acid compositions of the whole body lipids of the coot and moorhen hatchlings were almost identical to those of the initial yolks indicating that, unlike the chicken, these species display relatively little overall biomagnification of 20:4n-6 and 22:6n-6 during development. It is suggested that the yolk fatty acid profiles of the coot and moorhen are particularly well matched to the requirements of the embryo, reducing the need for selective uptake of 22:6n-3 and for the overall biomagnification of 22:6n-3 and 20:4n-6.     

Embryonic development of the hemipteran insect Rhodnius prolixus

The embryonic development of the hemipteran insect Rhodnius prolixus was studied by use of contemporary light and electron microscopy. Embryos were staged according to days postoviposition. Eggs laid on day one complete blastoderm formation and anatrepsis, the first phase of blastokinesis, by day 5. The embryo develops in a cephalocaudal orientation which is 180° to the anteroposterior axis of the egg. Subsequent development, prior to the second phase of blastokinesis (katatrepsis), leads to segmentation of the germ band, evagination of appendages, and histogenesis of germ layers. Concomitantly with these events, the amnion undergoes dramatic change. By day 7 the embryo begins a 180° revolution while migrating to the ventral surface of the yolk. This restores its polarity with respect to that of the egg and facilitates hatching. The serosa contracts, pulling the amnion and embryo anteriorly. Eventually the serosa is internalized at a point dorsal to the head and the lateral walls of the embryo grow up and surround the yolk. Development continues until day 15 when the embryo hatches as a first instar larva.     

Distribution and origin of steroid hormones in the yolk of Japanese quail eggs (Coturnix coturnix japonica)

The yolk of avian eggs contains steroid hormones, which may influence the development and behaviour of hatched birds. The aim of the present study was to investigate the concentration as well as the distribution of various gonadal steroids in the yolk spheres of quail eggs. Steroid concentrations of dissected yolk layers were analysed after alcoholic extraction using enzyme immunoassays (EIAs) for progesterone, androstenedione and testosterone. To monitor the uptake of testosterone into the yolk, radioactive testosterone was injected i.m. into six female quails. The radioactivity of yolk layers of subsequently laid eggs was measured by liquid scintillation counting. Progesterone concentrations were highest in the outer layer (median: 2265 nmol/kg). Androstenedione (median: 453 nmol/kg), as the major androgen, and testosterone (median: 99 nmol/kg) reached their highest concentrations in interior layers, whereas in the centre the concentration of all three hormones was low. No significant variation of steroid levels in yolk layers of subsequently laid eggs was found. The highest radioactivity was detected in the outer yolk layer in those eggs laid 1 day after injection and in subsequently laid eggs was measured nearer to the centre. These results indicated local origin of the steroid hormones especially because of the result that only 0.1% of the radioactivity entered the yolk. We conclude that steroid concentrations in the yolk layers reflected progesterone and androgen production of the cells of the follicular wall at the time.     

Dynamics of the nuclear envelope and of nuclear pore complexes during mitosis in the Drosophila embryo

Early embryonic development in Drosophila melanogaster is marked by a series of thirteen very rapid (10-15 min) and highly synchronous nuclear divisions, the last four of which occur just beneath the embryo surface. A total of some 6000 blastoderm nuclei result, which are subsequently enclosed by furrow membranes to form the cellular blastoderm. We have examined the fine structure of nuclear division in late syncytial embryos. The mitotic spindle forms adjacent to the nuclear envelope on the side facing the embryo surface. During prophase, astral microtubules deform the nuclear envelope which then ruptures at the poles at the onset of prometaphase. The nuclear envelope remains essentially intact elsewhere throughout mitosis. A second envelope begins to form around the nuclear envelope in prometaphase and is completed by metaphase; the entire double layered structure, referred to as the spindle envelope, persists through early in the ensuing interphase. Pole cell spindles are enclosed by identical spindle envelopes. Interphase and prophase nuclei contain nuclear pore complexes (PCs) of standard dimensions and morphology. In prometaphase PCs become much less electron-dense, although they retain their former size and shape. By metaphase, no semblance of PC structure remains, and instead, both layers of the spindle envelope are interrupted by numerous irregular fenestrae. PCs are presumably disassembled into their component parts during mitosis, and reassembled subsequently. Yolk nuclei remain among the central yolk mass when most nuclei migrate to the surface, cease to divide, yet become polyploid. These nuclei nonetheless lose and regain PCs in synchrony with the dividing blastoderm nuclei. In addition, they gain and lose a second fenestrated membrane layer with the same timing. Cytoplasmic membranes containing PCs (annulate lamellae) also lose and regain pores in synchrony with the two classes of nuclear envelopes. The factors that affect the integrity of PCs in dividing blastoderm nuclei appear to affect those in other membrane systems to an equivalent degree and with identical timing.     

Availability of avidin-bound biotin to the chicken embryo.

Avidin, an exceptionally stable protein in egg white, binds the vitamin biotin with very high affinity and can induce biotin deficiency when fed to animals. To determine if biotin bound to avidin is available to the chicken embryo, the fate of [3H]biotin complexed to avidin was monitored during embryonic development. The majority (greater than 85%) of the [3H]biotin was extraembryonic until the day before hatching, when embryos swallow egg white and withdraw the yolk sac into their abdomen. Thus, biotin in the egg white of chicken eggs contributes little to the biotin status of the chick prior to hatching. After hatching, much of the [3H]biotin was assimilated. About 30% of the total was found in the liver and kidneys by 4 days of age. The biotin in liver was associated with large proteins and not with avidin. In a separate experiment, biotin injected into the egg white of biotin-deficient eggs failed to increase embryonic development or hatchability. Both experiments suggest that biotin in egg yolk is the primary and virtually sole source of biotin for the chicken embryo.     

Toxic effects of phencyclidine on developing chick embryo brain

We studied the effects of Phencyclidine (PCP, Angel Dust) on the developing chick embryo brain. In Group-1, the eggs were injected with PCP on the 7th day of incubation and the embryo brains were studied on the 10th day. In Group-2, eggs were injected twice; first on the 7th day and then on the 10th day of incubation. Group-2 brains were then studied on the 16th day of incubation. PCP significantly depressed the development of embryo brains. Cerebral hemisphere weight, total protein and total DNA were significantly lower on day 10 of incubation in Group-1. Similar results were observed in Group-2. Concomitantly, the concentration of brain serotonin at day 10 was also significantly reduced when PCP was injected into the eggs on the 7th day of incubation. Since serotonin has been reported to influence development of the chick embryo brain, the present finding of the effect of PCP on brain development might be a secondary phenomenon. The possible implications of the effects of PCP on human brain development are also discussed.     

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。     

Effect of gravity on the interaction between the avian germ and neighbouring ooplasm in inverted egg yolk balls

The developmental capacities of an avian germ (from before symmetrization to the moment of laying) are strongly diminished after inversion of its egg yolk ball followed by culture in egg white. Our present experiments show that even when the avian germ is completely horizontally inverted (without an upper or lower border) below its egg yolk ball before symmetrization, symmetrization and gastrulation phenomena take place. The germ grows slower and becomes smaller than after normal incubation. After culture of inverted unincubated germs, localized on freshly laid eggs, the closure of the neural tube is impaired and it remains open over a long distance. Although a primitive streak (PS) develops, mesoderm migration (mainly from the lateral part of the area pellucida) is also impaired. On sections through the germinal disc one can see the abnormal upward migration into the depth of the ooplasm and yolk of cells from the germ wall and the development of large cellular extensions encircling the yolk globules. Most prominent is the loss of contact between the superficial cell layers and the deep layer elements (junctional endoblast and yolk endoblast in the area opaca). Large areas without deep layer elements (even visible on surface micrographs) develop in the area vasculosa and area vitellina interna. The margin of overgrowth grows and extends normally over the egg yolk ball. An autoradiographic study after labelling of the yolk layers in inverted egg yolks reveals that mainly compression of the peripheral subgerminal and perigerminal ooplasm takes place. This suggests that the compression by the neighbouring yolk and upwards growth of cells are at the origin of the impaired development. After return to the normal upward orientation of the germ on the topmost part of the egg yolk ball, a more or less pronounced restoration to normal development takes place (depending on the duration of the inversion period and the age of the germ).     

Autoradiographic study of protein and RNA formation during early development of Drosophila eggs

Permeabilized eggs of Drosophila melanogaster were incubated in tritiated uridine, valine, and phenylalanine. The uptake and incorporation into TCA-insoluble material were measured by scintillation counting. There was very little incorporation of uridine before the blastoderm stage. At the blastoderm stage, the egg took up 2.4 pmoles/hr of uridine and incorporated 0.13 pmoles into RNA (assuming no dilution of specific activity of the precursor). The uptake of amino acids varied with the age of the embryo; virgin eggs synthesized about as much protein as fertilized eggs. Autoradiography of eggs incubated in uridine showed a lack of RNA synthesis in nuclei until the start of the blastoderm formation. The small amount of uridine incorporation before this stage was due to mitochondria. Incorporation of amino acids was uniform in the cytoplasm until the blastoderm; there was no incorporation by yolk granules. Regional difference in labeling appeared during gastrulation. The pole cells did not form RNA during the blastoderm stage, formation started during gastrulation. Protein labeling of the pole cells, on the contrary, was very strong in the blastoderm and early gastrula. These results indicate that the expression of zygotic genome before the blastoderm stage is unlikely.     

The constituent oocytal layers of the avian germ and the origin of the primordial germ cell yolk

By radioactive or trypan blue induced fluorescence yolk labelling (used at certain developmental stages as intravital cytoplasmic markers), it can be demonstrated that the constituent yolk layers of quail blastoderms are formed when the precursor oocyte is growing from 3 to approximately 18 mm (rapid growth period). A previous study ( Callebaut , 1974) and the present study demonstrate that 2 cytoplasmic regions, each with a different constitution and behaviour, can be discerned in the avian germinal disc: 1) a deep and paraxial region, containing yolk that has been in contact with the t.i.c.o.s. (3H-thymidine incorporating cytoplasmic organelles) during oogenesis; 2) a superficial and peripheral region, which has not been in contact with the t.i.c.o. material and which penetrates into the first region along with the cleavage furrows. In the large blastomeres, the originally superficial ooplasm surrounds the deep ooplasm. The area centralis of the unincubated blastoderm must be considered as a heterogeneous cell population, containing both deep and superficial material in variable amounts. After laying and incubation, extra-embryonic tissues such as yolk endoderm and margin of overgrowth develop in the superficial and peripheral region. The embryonic mesoderm also develops from the latter. The yolk, which will be incorporated in the primordial germ cells (germinal yolk), derives only from the original deep and paraxial region of the oocytal germinal disc, i.e. from the region which has been in contact with the t.i.c.o.s. The germinal yolk plasm can be traced in the deep paraxial region of the oocytal germinal disc, in the central region of the unincubated blastoderm, in the endophyll (early primitive streak stage) and finally in the primordial germ cells (P.G.C.s.) at the moment of their separation from the endophyll wall (early somite stage). Thus our results provide evidence for the existence of a germ cell plasm in the avian postlampbrush oocyte.     

The effects of simulated microgravity on avian embryonic development.

Based on the few reports available, microgravity (MG) can have adverse effects on the early development of vascularised extra-embryonic membranes in avian eggs. Whether gravity or oxygen availability is the stimulus for development of the blood vessels in the chorioallantoic membranes (CAM) remains unclear. Under gravity the blastoderm forms on top of the yolk sac, closest to the oxygen rich region beneath the shell membranes, and from there the CAM buds from an abdominal extension subsequently to form a close contact with shell membranes. Then as the embryo develops it spreads beneath the eggshell surface to maximise the surface area of the CAM vascular bed available for O2 uptake. To investigate how simulated MG influences development of the CAM and embryo we conducted experiments on chicken embryos during incubation in a 3D-clinostat (control or continuous MG treatment at 5 rpm). Further, to determine if CAM angiogenesis is directed towards regions of high O2 tension or gravity we investigated the effects of wax treatment (50% shell surface area) on development in MG. We found that clinostat MG caused embryonic failure between day 0-5 by preventing normal development of CAM-shell membrane complex. Thereafter acute MG promoted increases in CAM mass, but did not affect embryo mass. Preliminary findings suggest that combined acute MG and wax treatment did not significantly affect embryonic growth in either MG or control groups, but retarded CAM growth in control embryos only. Finally, we will present evidence to show that acute and prolonged exposure to MG does not prevent normal growth and hatching, but might have more subtle effects on hatchling physiology, including reduced heart mass.