Two distinct types of axis lacking embryos resulted from partial deletion of the vegetal part of early one-cell-stage embryos. When the deleted volume was 20-40% (relative surface area), the embryos underwent ventral-type gastrulation and formed ventral mesodermal tissues. When the deleted volume was more than 60%, the embryo did not gastrulate nor make mesodermal structures (M. Sakai, 1996, Development 122, 2207-2214). We have designated these two types of embryos as "gastrulating nonaxial embryos (GNEs)" and "permanent blastula-type embryos (PBEs)," respectively. Using these embryos as recipients, a series of Einsteck transplantation experiments were carried out to investigate mechanisms controlling anteroposterior patterning during early Xenopus development. GNEs receiving dorsal marginal zone (DMZ) transplants (GNE/DMZs) elongated and formed posteriorized phenotypes, which had muscle cells, melanocytes, and tail fins. In contrast, PBE/DMZs did not elongate but formed cement glands and brain-like structures showing strong anteriorization. Simultaneous transplantation of the cells from various regions of normal embryos with the DMZ into PBEs revealed that the entire vegetal half of normal embryos, except for the DMZ, showed posteriorizing activity. These results strongly suggest that anteroposterior patterning in Xenopus is not achieved solely by the dorsal marginal zone (the Spemann organizer), but instead by a synergistic mechanism of the dorsalizing domain (DMZ) and the posteriorizing domain (the entire vegetal half except for the DMZ).
An inverse opal structure was created using artificial melanin particles composed of a polystyrene core and a polydopamine shell as the template. The melanin-mimicking polydopamine that remained inside the inverse opal structure effectively absorbed multiple scattered light, producing bright structural color that was reversibly changed by solvent penetration.
We perceive structural colors by optical phenomena such as light interference and diffraction caused by a fine structure of the object surface. One of the characteristics of structural colors is that a wavelength distribution of light changes depending on an incident angle of a light
source and a viewing angle. Generally, for color evaluation and reproduction, it is required to acquire reflection characteristics of objects. Therefore, BRDF (Bidirectional Reflectance Distribution Function) is often used as a function that represents reflection characteristics depending
on incident and viewing angles. In this study, we measured BRDF of structural colors based on a method to acquire image-based material reflection characteristics using a spectral camera. The measurement was performed by aligning an optical axis of a spectral camera with a structural color
sample and changing an irradiation angle of a light source. Reflection characteristics were represented by using a radiance factor, which was a ratio between a spectral radiance of white material and that of structural color. From measurement results, we confirmed an angle-dependent radiance
factor. Finally, based on a measured spectral radiance of a structural color sample, we spectrally reproduced the structural color using a spectral projector based on model fitting of spectral data.
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