Cellular carbon accumulation systems are a fundamental prerequisite for biomineralization to stabilize pH and to supply inorganic carbon for CaCO₃ precipitation under changing environmental conditions.

Primary cilia of neural crest-derived cells mediate Indian hedgehog-induced signal transduction in the periocular mesenchyme and are required for normal anterior segment development.

The transcriptional control system of a sea urchin gene reveals the deep evolutionary conservation of a gene regulatory network underlying morphogenesis.

Cell-cell interaction between neural crest-derived cells and mesoderm-derived cells determine cell fate of mesoderm-derived cell in tongue development through Hh signaling.

Understanding novel cell types and their evolutionary history is re-evaluated using single nuclei transcriptomic approaches and their inferred underlying gene regulatory networks.

A comprehensive analysis of mutant animal model shows the important role of KDM6B and how it cooperates with TFDP1 to achieve its functional specificity in regulating Trp53 expression to control the fate of cranial neural crest cells during palatogenesis.

Regulation of cellular properties such as ligand secretion and migratory ability through changes in the cytoskeleton mediated by a Wnt5a–Ror2–Vangl2 axis is a major determinant of alveolar formation.

The molecular regulatory mechanisms that control the interaction between mesenchymal stem cells and transit amplifying cells to maintain tissue homeostasis.

An expandable cell population derived from human pluripotent stem cells exhibits properties of mesoderm and is restricted to differentiate into derivatives of intermediate mesoderm.

Mitochondrial activity and distribution control alveolar formation by conferring distinct cellular properties.