Electrophoretic characterization of glycosaminoglycans during development of the chick embryo skin

Glycosaminoglycans extracted by CPC precipitation from chick embryo skin at 9, 12, 15, 18, 21 days of incubation were separated by three different electrophoretic methods on acetate cellulose strips. We observed the presence of Hyaluronic acid, Dermatan Sulfate and Chondroitin-4-Sulfate during the whole period considered and of Heparan Sulfate only after the 9th day. Dermatan Sulfate increases until the 15th day then decreases progressively; on the contrary Hyaluronic acid and Chondroitin-4-Sulfate decrease during days 9 to 15 then increase until hatching. Heparan Sulfate appear the 9th day then increases progressively until hatching.     

Histochemical localization of skin glycosaminoglycans during feather development in the chick embryo

Summary The distribution of glycosaminoglycans (GAGs) was studied in embryonic chick skin, using alcian blue staining with critical electrolyte concentration and glycanase treatment, immunofluorescence and transmission electron microscopy. Light microscopy revealed an uneven distribution of sulphated and non-sulphated GAGs at all stages of feather development. Along the dermal-epidermal junction and throughout the depth of the dermis, staining was stronger inside the feathers than in the interplumar skin. With increasing MgCl₂ concentration, the decrease in stain intensity along the dermal-epidermal junction was stronger in interplumar skin than inside feather structures, indicating that sulphated GAGs are more abundant within feathers than in interplumar skin. The same differential sensitivity to electrolyte concentration was noted in the dermis, except at the feather placode stage, when labelling inside the dermal condensation was virtually wiped out at 0.6 M MgCl₂ and higher concentrations, whereas it persisted in the surrounding dermis up to 0.8 M MgCl₂, indicating that the dermal condensation contains a larger amount of hyaluronate than non-feather-forming dermis. Enzyme treatment of sections with Streptomyces hyaluronidase as compared with those treated with chondroitinase ABC corroborated these findings. Immunofluorescent detection of heparan sulphate proteoglycan revealed the presence of the antigen along the dermal-epidermal junction at all stages of feather development, with peaks of brightness in discrete spots of feather structures. Electron microscopy revealed the presence of ruthenium red and tannic acid positive material in the dermal-epidermal junctional zone and inside the dermis. The density of marked granules was somewhat higher in intraplumar than in interplumar regions. These observations demonstrate that certain sulphated and non-sulphated GAGs are distributed in a microheterogeneous manner, which appears to be related to the morphogenetic events of feather development. They are discussed in view of the possible role these components might play in dermal-epidermal interactions. They strengthen the notion, already gained from previous studies on the localization of interstitial collagens and fibronectin, that extracellular matrix components play an important structural and informative role in organogenesis.     

Action of acetazolamide on the chick embryo during late development.

Acetazolamide was injected into chick embryos on the 14th or 15th day of incubation. Doses ranging between 5 and 10 mg per egg produced a retardation in the growth of long bones. The affected bones contained a normal proportion of mineral as determined by ashing and presented a normal histological picture. On the basis of these findings, it is suggested that the alterations were not due to a specific direct effect of the drug on bones. The incorporation of 131-I by the thyroid glands of acetazolamide-injected embryos was analyzed radioautographically and quantitated on the same 6 mu-paraffin sections, with a thin window Geiger counter. The incorporation appeared notably reduced 3 h after the injection of acetazolamide and the reduction persisted for a least 24 h.the electron microscopical observation of thyroid follicular cells from similarly treated embryos showed that the cytological characteristics indicating an active protein synthesis were unmodified with respect to those found in control embryos. These results may indicate that acetazolamide inhibits the iodination of the throid hormone without interfering with the synthesis of the globulin. It is suggested that the growth retardation observed in the embryos treated with acetazolamide may be secondary to the action of the drug on the thyroid gland, although this action appears to be a transitory one.     

Extracellular matrix assembly and 3D organization during paraxial mesoderm development in the chick embryo

The extracellular matrix (ECM) is a major player in the microenvironment governing morphogenesis. However, much is yet to be known about how matrix composition and architecture changes as it influences major morphogenetic events. Here we performed a detailed, 3D analysis of the distribution of two ECM components, fibronectin and laminin, during the development of the chick paraxial mesoderm. By resorting to whole mount double immunofluorescence and confocal microscopy, we generated a detailed 3D map of the two ECM components, revealing their supra-cellular architecture in vivo, while simultaneously retaining high resolution cellular detail. We show that fibronectin assembly occurs at the surface of the presomitic mesoderm (PSM), where a gradual increase in the complexity of the fibronectin matrix accompanies PSM maturation. In the rostral PSM, where somites form, fibronectin fibrils are thick and densely packed and some occupy the cleft which comes to separate the newly formed somite from the PSM. Our 3D approach revealed that laminin matrix assembly starts at the PSM surface as small dispersed patches, which are always localized closer to cells than the fibronectin matrix. These patches gradually grow and coalesce with neighboring patches, but do not generate a continuous laminin sheet, not even on epithelial somites and dermomyotome, suggesting that these epithelia develop in contact with a fenestrated laminin matrix. Unexpectedly, as the somite differentiates, its fibronectin and laminin matrices are maintained, thus initially containing both the epithelial dermomyotome and the mesenchymal sclerotome within the somite segment. Our analysis provides unprecedented details of the progressive in vivo assembly and 3D architecture of fibronectin and laminin matrices during paraxial mesoderm development. These data are consistent with the hypothesis that progressive ECM assembly and subsequent 3D organization are active driving and containing forces during tissue development.     

DNA repair in lens cells during chick embryo development.

When chick lens epithelium is cultured in vitro, differentiation into lens fiber cells is accompanied by DNA degradation. This phenomenom of terminal differentiation was studied in the epithelium from embryos at the 6th and 11th days of development. DNA size and the ability of the cells to repair DNA damage induced by X-rays were analysed in alkaline sucrose gradients. In the 6-day epithelium a rapid degradation and complete lack of DNA repair were recorded. Similar observations have been made in previous studies on the 11-day sample, but here degradation is progressive and occurs after a lag of several days. In the younger epithelium, internal irradiation by [3H]thymidine also had a drastic effect resembling that caused by X-rays. In order to assess the process of differentiation in our experimental system the synthesis of delta- and alpha-crystallins was monitored. Stage-related modifications in the rates of synthesis were recorded. The results confirm that the DNA repair system is impaired during terminal differentiation. The differences observed between the two stages may reflect either a developmental modification in DNA repair mechanisms or a change in the relative proportions of differentiating cells. An hypothesis is proposed in support of the latter case.