Ex Ovo Culture System for Avian Embryos and its Application.

Ex ovo culture of avian embryos can be applied not only to embryology but also to various fields of basic research such as embryo manipulation, toxicology, and regenerative medicine. The windowing method, which facilitates various manipulations and observations by opening a hole in one part of the eggshell, and culture systems using surrogate eggshells, are widely used. Despite this, biology lessons in high schools cover shell-less culture systems, which involve the development of avian embryos in artificial vessels, such as rice bowls, without using surrogate eggshells. However, as embryo development stops at its early stages in this method, it is not possible to continuously observe the development of the embryo. This led to attempts to develop an embryo culture method using a complete artificial culture vessel that does not use surrogate eggshells, and Kamihira et al. (1998) succeeded in hatching quail embryos in an artificial culture vessel using polytetrafluoroethylene membranes. In addition, Tahara succeeded in hatching chick embryos in artificial culture vessels that used cling film made of polymethylpentene and reported their detailed methodology (Tahara and Obara, 2014). These technologies are being applied not only to school education but also to various fields of research.

Calcium carbonate supplementation to chorioallantoic membranes improves hatchability in shell-less chick embryo culture.

Developing chick embryos are a classical research tool in developmental biology. The whole embryo culture technique can be applied to various fields, such as embryo manipulation, toxicology, tumorigenesis, and basic research in regenerative medicine. When used for the generation of transgenic chickens, a high hatchability of genetically engineered embryos is essential to support normal embryonic development during culture. In this study, calcium carbonate, which is the main component of eggshells, was added as a calcium source in shell-less chick embryo cultures using a transparent plastic film as a culture vessel. In the absence of a calcium source in the shell-less culture system, embryogenesis ceased during culture, resulting in failed embryonic hatching. We found that the direct addition of calcium carbonate to the chorioallantoic membrane of the developing embryo was effective for the hatching of cultured chick embryos. The amount, timing, and location of calcium carbonate addition were investigated to maximize the hatchability of cultured embryos. Starting from the time of calcium carbonate supplementation, >40% hatchability was obtained with the optimal condition. This established method of shell-less chick embryo culture provides a useful tool in basic and applied fields of chick embryo manipulation.

CHANGES IN SUSCEPTIBILITY OF CHICK EMBRYONIC BLOOD CELLS TO NEWCASTLE DISEASE VIRUS.

To analyse the age-dependent changes in susceptibility of chick embryonic cells to viral infection, observations were made on the blood cells after the inoculation of Newcastle disease virus. A lethal dose of Sato strain of Newcastle disease virus was introduced into chick embryos via injection of inoculum into the blood vessel and allantoic sac. Observations of blood cells by immunofluorescent technique revealed two types of cells, susceptible and resistant to the virus infection. Erythroblasts of both primitive and definitive lines, embryonic thromboblasts and thrombocytes were of the former type and mid- and late-polychromatic erythrocytes and mature ones were of the latter. Erythroblasts gradually decrease in their viral susceptibility as they differentiate into polychromatic erythrocytes and finally become resistant to the virus at the mid-polychromatic erythrocyte stage or later. Thromboblasts, on the other hand, retain high susceptibility to the virus throughout the course of their differentiation to mature thrombocytes. The change in the viral susceptibility of erythroid cells with differentiation is discussed in relation to the structural and functional alterations during the cell specialization.

The Blood Island is a Site of Formation of the Primary Embryo Thrombocyte in the Chick Blastoderm: (anti-thrombocyte antibody/embryo thromboblast/site of production/blood island/chick embryo).

Using the immunohistological technique we inquired at what developmental stage and in which site of chick blastoderm does the embryo thrombocyte (ET) begin to differentiate. An anti-ET antibody was raised against rabbits by injecting ETs isolated from blood of 10 day chick embryos. By applying the indirect staining method to smear preparations of blood collected from developing embryos it was confirmed that cytoplasm of the ET showed more intense staining than that of the erythroid cell and that the ET population could be distinguished from the erythrocyte population by this antibody. Cells showing the intense staining could be detected first in blood islands of the area opaca vasculosa of stage 9+ blastoderms. These embryo thromboblasts were found singly or in groups of a small number at dorsal periphery of cell clusters in the blood island. The electron microscopy revealed that embryo thromboblasts appeared in the same position in the stage 9+ blastoderm. At stage 10+ or later embryo thromboblasts were also present adhering to the vascular endothelium or free in the vessel lumen. We conclude that ETs start differentiating from primitive mesenchymal cells localized in the blood island of the area opaca vasculosa at stage 9 or earlier, migrate thereafter to vessel lumen, and enter the blood stream.

Formation of Embryo Thromboblasts in Chick Blastoderm: Morphology, Site of Production and Time of Emergence in the Blood: (embryo thromboblast/glycogen deposit/differentiation/chick blastoderm).

Thrombocytes in the blood of chick embryos (termed embryo thrombocytes by Lucas and Jamroz) have PAS-positive granules in their cytoplasm. Electron microscopic observations reveal that the embryo thrombocytes contain glycogen granules present singly or in clumps. The presence of these inclusions and other morphological characteristics were used as specific markers to distinguish embryo thrombocytes from primitive erythroid cells. These markers also made it possible to determine the time at which the immature thromboblasts first emerge in blood vessels, and the period of their continued presence in the circulation. In this way we found that thromboblasts were detectable in embryos as early as stage 10+ of Hamburger and Hamilton (after 35 hr incubation) and that the thromboblasts were present in the circulation until day 4 of incubation (stage 23). In ovo and in vitro culture of de-embryonated blastoderm demonstrated that thromboblasts were formed in the area opeca vasculosa. The present observations suggest that embryo thromboblasts are formed at the same time and in the same area as the primitive cells of erythroid line.