Project Summary/Abstract The major deficiency E342K mutant or “Z-variant” of the abundant serum antiprotease Alpha-1 antitrypsin (AAT) is responsible for the vast majority of morbidity and mortality associated with Alpha-1 antitrypsin deficiency (AATD), a leading cause of hereditary lung and liver disease affecting millions of patients globally. This missasembly-prone variant is known to be highly polymerogenic, owing to a widened -sheet A domain which predisposes the AAT-Z monomer to form cytotoxic loop-sheet oligomers. These toxic oligomers accumulate in producing hepatocytes leading to chronic liver disease, and build up extracellularly leading to both gain-of-toxic function in the lung with a concomitant loss of serum AAT-Z antiprotease activity which leads to proteolytic destruction of lung parenchyma by neutrophil proteases like elastase. Crystal structures of monomeric AAT-Z have been studied and previous mutational analyses have demonstrated the capacity for space-filling mutations within surface-accessible hydrophobic pockets on this protein to prevent polymerization without abrogating antiprotease activity. It has thus been hypothesized that small molecules could be discovered which act as pharmacological chaperones, preventing AAT-Z polymer formation while permitting native antiprotease activity of the stabilized monomer, serving to ameliorate the multiorgan injury (including lung pathology) associated with AATD. While stabilizing ligands for AAT-Z have previously been reported, these ligands universally fail to permit the native antiprotease activity of AAT-Z. In this training proposal, I propose to use Fully-Functionalized Fragment” (FFF) substructures along with photo-crosslinking, affinity chromatography and tandem mass-spectrometry in Aim 1 to identify the small molecule sites on the AAT-Z monomer accessible to binding by drug-like substructures. In Aim 2 I will develop a novel screening assay that I conceived of for identifying AAT-Z stabilizing ligands or pharmacologic chaperones that prevent RCL insertion while permitting antiprotease activity of ligand-bound AAT-Z. In Aim 3 I will employ a cell-based phenotypic assay already developed and validated by our collaborators in the Balch Lab to simultaneously evaluate the capacity for screening hits to restore functional monomeric AAT-Z secretion efficiency, while reducing intracellular oligomers in cultured hepatocyte and pulmonary cell models of AATD. This project will afford a multidisciplinary training experience with guidance from experts in the fields of protein misfolding biology, chemical proteomics, high-throughput assay development, as well as AATD patient treatment. Through the research proposed herein, I will develop a robust expertise in state-of-the-art methods for proteomic analysis, screening assay optimization, and applications of mammalian cell models of disease. These valuable discovery-oriented research competencies, together with my previous training background...