Abstract
During the development of the face, tissues move, change shape, and fuse in tightly orchestrated patterns to create all the parts of a normal face. These shape changes are driven by factors such as cell signaling, migration, proliferation, and apoptosis. However, the contributions of each of these drivers to morphogenesis are poorly studied. Here, we explore differential cell proliferation as a driver of mouse facial morphogenesis. We quantify patterns in both the spatial distribution and orientation of proliferation in the developing face in 3D over a critical period of murine facial development (E9.5‐E11.5). We use immunostaining with light sheet microscopy (LSM) to capture total and proliferating nuclei. To compare proliferative density in facial tissues, we segment these images using a novel convolutional neural network. We then generate atlases of average proliferation at each half‐day age point within our range and use these to identify relationships between morphology and cell proliferation. We show that regions with more dense proliferation tend to undergo more intensive shape changes. We then simulate outgrowth of the maxillary process using a cell simulation engine, PhysiCell, to demonstrate that differential proliferation is necessary to maintain expected morphology in growing tissues. In addition to differential proliferation, localized orientation of cell division could also affect morphology. In plants and some animal tissues, including murine limb buds, preferentially oriented cell proliferation drives shape change by causing tissue elongation in specific directions. We explore the orientation and distribution of cell proliferation using LSM: we inject pregnant dams with a synthetic nucleotide, EdU, 5 minutes before harvest to mark the daughter cells of proliferative events occurring in the interim. We then compare the angles of the proliferative axes for each pair of daughters relative to the primary direction of tissue growth. Preliminary results suggest that cell proliferation in the maxillary and nasal processes is oriented preferentially towards the axis of tissue growth. These results suggest that both the distribution and orientation of cell proliferation play a role in murine facial morphogenesis. Understanding the mechanisms underlying morphogenesis is important to guide future research that could lead to earlier and more robust diagnosis and treatment of syndromes and facial abnormalities.
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