OVERALL PROGRAM PROJECT: ABSTRACT Cell death pathways have historically been characterized by the proteases that become activated during cell fate decisions. Apoptosis has been defined by initiator and effector caspase activation and, largely due to the reagents available; cell death decisions were initially thought to be binary – caspase-dependent (apoptosis) or caspase-independent (all others). Much like other binary distinctions – like Th1 versus Th2 T cells or M1 versus M2 macrophages, which have undergone substantial expansion in the past decade, cell death decisions and their consequences are now recognized to be much more variables. In fact, even the mechanisms of cell death have been refined. They are no longer categorized by the proteases which activate the cascades but rather, by the effector mechanism. Necroptotic cell death is caused by activation of the pore-forming protein, MLKL. Secondary necrosis is caused by activation of the pore-forming protein, DFNA5 (Gasdermin E/GSDME), and pyroptosis is caused by activation of the pore-forming protein, Gasdermin D (GSDMD) This last category of cell death - pyroptosis - is one of the most immunologically important forms of cell death. Not only does pyroptosis kill the cell, but also GSDMD activation allows the release of IL-1β. This cytokine is among the most important in acute and chronic inflammation. Its secretion is implicated in rare genetic inflammatory diseases such as Familial Mediterranean Fever as well as more common diseases such as myocardial infarction, Alzheimer's disease, Crohn's disease and Ulcerative Colitis, Multiple Sclerosis and many others. With the discovery of the inflammasome in 2002 and its subsequent study, it became clear that the amyloid-like activation of these inflammasome complexes drove pro-IL-1β cleavage and IL-1β release from the cell, but also pyroptosis. Missing from this biochemistry, though, was the cell biology underlying IL-1β release. How is IL- 1β recognized by caspases and other proteases? If IL-1β is not released through a secretory ER-Golgi mechanism, how is trafficked out of the cell? How is this release coordinated with pyroptosis and other regulated cell death pathways that are operative in different populations of immune effector cells. This Program Project aims to utilize cell physiology, biochemistry, structural biology, and mouse and human disease models to unravel these important questions.