Whole-mount staining with Alcian blue for cartilage and alizarin red for bone has been widely used for visualizing the skeletal patterns of embryos and small adult vertebrates. The possibility of decalcification by the acidic Alcian blue solution is known, but standard staining protocols do not always avoid this issue. We investigated the effects of acidity on the stainability of developing bones in stage 36 chick embryos and developed an optimal procedure for obtaining reliable results with minimal decalcification. The diaphyses of long bone rudiments and the maxillofacial membranous bones progressively lost their stainability with alizarin red when the chick embryos were soaked for long periods in the preceding acidic Alcian blue staining solution for cartilage. Unless the acidity was neutralized with an alkaline solution, the remaining acidity in the specimens rendered the pH sufficiently low to prevent the subsequent alizarin red staining of the bones. These findings indicate that the mineralizing bones at the early stages of development are labile to acidity and become decalcified more substantially during the staining process than previously appreciated. The following points are important for visualizing such labile mineralizing bones in chick embryos: 1) fixing with formaldehyde followed by soaking in 70% ethanol, 2) minimizing the time that the specimens are exposed to the acidic Alcian blue solution, and 3) neutralizing and dehydrating the specimens by an alkaline-alcohol solution immediately after the cartilage staining. When the exact onset and/or an early phase of ossification are of interest, the current double-staining procedure should be accompanied by a control single-staining procedure directed only toward bone.
The formation of cross-linkages betweenand within collagen is catalyzed by lysyl oxidase, which can be inhibited by β-aminopropionitrile (BAPN), a lathyrogen from sweet pea (Lathyrus odoratus) seeds. The quality and integrity of the collagenous template of skeletal elements depend on an appropriate concentration of collagen cross-links. In this study, chick embryos treated in ovo with BAPN on embryonic days (ED) 4-9 were found to develop multiple skeletal deformities. The most readily discernible and highly reproducible deformity was evident in the tibiotarsus, on which we focused to explore the chronology of the malformation process. Several lines of observation indicated that the bending deformity observable at ED10 in the tibiotarsus was inducible by BAPN administered on ED4-8; in other words, administration of BAPN on ED8 was sufficient to induce the deformity by ED10, whereas administration on ED9 was ineffective. Ultrastructurally, osteoclasts appeared to show enhanced activity in the medullary surface of the bone collar after BAPN administration. In addition, bone hyperplasia associated with the bending deformity was suggested to be correlated with higher osteoblast activity on the concave (or flexor) side of the tibiotarsal skeleton. These findings indicate that the bending deformity due to reduced mechanical integrity of the collagenous template is also associated with aberrant bone remodeling. (J Oral Sci 58, 255-263, 2016)Keywords: β-aminopropionitrile; lathyrogen; bone development; skeletal deformity. IntroductionEmbryonic skeletal elements (cartilage and bone) are fundamentally composed of extracellular collagen fibrils. In the process of ontogenesis, a collagenous template becomes calcified directly or via cartilage to build a specific bony skeleton for each species (1,2), and also, at appropriate sites, cartilaginous tissue itself functions as part of the complete skeletal system. Therefore, the quality and integrity of the collagenous template is particularly crucial for building a skeleton with sufficient inherent strength. The required properties of template collagenous tissue are closely related to the formation of cross-links both between and within collagen molecules (3-5). Such cross-link formation is catalyzed by lysyl oxidase (LOX, EC1.4.3.13), an amine oxidase that converts peptidyl lysine side chains in collagen to allysine, the latter then forming covalent cross-linkages (6,7).
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