Abstract Apical constriction is a change in cell shape that drives critical morphogenetic events, including gastrulation and branching morphogenesis in diverse animals and neural tube formation in vertebrates. Fundamental questions about mechanisms of apical constriction remain unanswered. Research in this laboratory focuses on understanding how cells accomplish this change in shape. Apical constriction is being studied to uncover insights into how animals are shaped, and to contribute to a foundation of basic science leading to improved diagnosis and prevention of neural tube defects. This proposal will support projects to answer how the molecules that contribute to apical constriction generate and transmit the forces that change cell shapes, how a cell’s actin architecture is dynamically altered, how developmental patterning mechanisms deploy cell biological players with the necessary spatial and temporal precision, and how novel mechanisms contribute to apical constriction. The laboratory has developed technical innovations to address critical barriers to progress in this field, and the proposed projects build on the lab's strength in dissecting cell biological mechanisms of development more generally. Study of apical constriction intersects with some of the major themes in cell and developmental biology including cell polarization, control of motor activity, and dynamic control of forces, in a complex in vivo context. The proposed projects seek to combine in a single model system the tools that are valuable to different model systems, plus the new tools that the lab has developed, to produce unique and sustained contributions to unraveling mechanisms that are relevant to critical morphogenetic events.