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Mechanisms coordinating cell behaviors within tissues during development

$432,501R35FY2025GMNIH

Columbia Univ New York Morningside, New York NY

Investigators

Linked publications, trials & patents

Abstract

PROJECT SUMMARY/ABSTRACT The formation of functional tissue architectures during embryonic development depends on the ability of cells to orchestrate collective tissue-level movements. The goal of my research program is to understand how cells work together to collectively generate the shape and structure of multicellular tissues in the process of morphogenesis. Our current understanding of morphogenesis has been limited by conceptual and technological barriers to dissecting the mechanical and molecular inputs that together coordinate cell behaviors. During this award, we will address these challenges and focus on resolving several key gaps in our understanding by: (1) analyzing mechanisms by which individual cell activities are coordinated across tissues to give rise to coherent tissue behavior, (2) elucidating how activities of the apical and basal sides of cells are coordinated, and (3) uncovering how mechanical cues coordinate cell and tissue behaviors in distant regions of embryos. Using the model organism Drosophila melanogaster, we are taking innovative approaches to address these questions in the context of epithelial tissue morphogenesis. To enable us to dissect mechanisms that coordinate cell behaviors, we are developing and using new technologies for controlling and quantifying the cell machineries and forces that drive these cell behaviors. These techniques will allow us to dissect the molecular and mechanical mechanisms that coordinate cell behaviors within multicellular tissues. This work will provide a foundation for integrating mechanics into our understanding of how genetic and biochemical factors control development and may motivate new strategies for controlling tissue shape and structure in vivo and in vitro. More broadly, the tools and framework we develop will enable us to investigate the mechanisms that coordinate cell behaviors in a broad range of multicellular processes. A better understanding of the mechanisms underlying collective cell behaviors can elucidate general principles of self-organization in biological systems, provide insight into how improper regulation of these processes leads to human disease, and develop new approaches to manipulate these processes for therapeutic benefit.

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