Project Summary Primary immunodeficiency diseases (PIDs) have great potential to provide mechanistic insights into the molecules and pathways fundamentally important for maintenance of human immune health, and the unbiased nature of forward genetics makes these studies particularly exciting to pursue. The phosphoinositide 3-kinase (PI3K) signaling pathway plays important roles in many aspects of cell behavior within and outside the immune system. Both gain-of-function and loss-of-function mutations in the genes encoding the p110 and p85 PI3K subunits have been identified in PID patients and have shed light on basic PI3K biology and underpinnings of inherited immunodeficiency. However, no mutations in the other PI3K genes have been described in inherited human disorders. We have now identified novel loss-of-function mutations in a new PI3K gene, PIK3CG, and our preliminary studies highlight its importance in immune competence and regulation of tissue inflammation in this disorder we have termed Inactivated PI3K Syndrome (IPGS). Using primary human cells and cutting-edge `dirty' mouse modeling approaches that recapitulate human disease by combining genetic manipulation and natural pathogen exposure, two specific aims will be pursued. Aim 1) To define the roles for PI3K in regulating T cell-intrinsic and -extrinsic signals that modulate T cell activation and differentiation. Aim 2) To dissect the mechanistic basis for antibody defects. The results of these investigations will provide significant insights into this novel PID and PI3K signaling in general and will lay the groundwork to improve physiologically relevant models for translational research in PIDs and other human disease contexts.