Abstract APDS is a primary immunodeficiency condition caused by heterozygous gain-of-function mutations in PIK3CD (APDS1), which encodes the leukocyte-restricted p110-δ catalytic subunit of phosphoinositide 3-kinase (PI3K) or heterozygous loss-of-function mutations in PIK3R1 (APDS2), which encodes the regulatory subunit of PI3K. PI3K is activated downstream of many receptors expressed by lymphocytes and plays important roles in their activation and differentiation. The increased PI3K activity in cells from APDS patients leads to multiple immune manifestations including lymphoproliferation, respiratory tract infections, Th2-related pathologies, impaired Ab responses and autoimmunity. We previously dissected the cellular defects that lead to disease in APDS1 by studying patient cells and our novel mouse model. This revealed changes in lymphocytes including increased memory T cells, defective Tfh function, decreased isotype switching and a break in B cell tolerance and production of autoantibodies. We have now generated a mouse model of APDS2 (Pik3r1E11SpD) and use this together with studies of patients’ cells to determine whether increased PI3K signalling due to loss of regulatory function causes the same cellular dysregulation. While we observed many of the same changes previously observed in APDS1, including altered cytokine production and decreased isotype switching, we also identified multiple differences in the cellular phenotype in APDS2 compared to APDS1. Together, these studies reveal that although APDS1 and 2 both cause increased PI3K signalling and result in similar clinical phenotypes, there are distinctions between how these two types of mutations affect cellular function. Supported by grants from the NHMRC and an AAI Careers in Immunology Fellowship