Project Summary Progressive scarring of the lung interstitium is a common feature of many systemic and primary lung diseases including Idiopathic Pulmonary Fibrosis (IPF). IPF is a common disorder, and patients diagnosed with this disorder experience substantial morbidity and a median survival of 3-5 years. Although recently approved therapies slow the rate of disease progression, more efficacious interventions that interfere with precise disease mechanisms are desperately needed. Plasminogen activator inhibitor-1 (PAI-1) holds substantial promise as a therapeutic target for lung fibrosis as experiments in multiple complementary animal models reveal a direct correlation between the activity of this molecule and the severity of scarring. These studies substantiate PAI-1 as a critical down-stream mediator of prominent pro-fibrotic stimuli including TGF-β and matrix stiffness. Despite the large amount of data implicating PAI-1 as a critical pro-fibrotic protein, the mechanism by which it promotes fibrosis remains elusive. PAI-1 is a multifunctional protein with inhibitory activity against the plasminogen activators through which it regulates fibrinolysis and wound healing. PAI-1 also interacts with non-protease ligands including the provisional matrix protein vitronectin (VTN). Using mutant proteins lacking specific functions and transgenic mice, we demonstrated that the pro-fibrotic action of PAI-1 is largely independent of its plasminogen activator inhibitory activity and that vitronectin is not required for PAI-1 to fully promote scarring of the lung. These results led us to perform an unbiased proteomic study to identify novel PAI-1 binding partners within the injured lung. With this approach, we identified sortilin related receptor-1 (SorlA) as the most enriched protein. SorlA is a multi-domain receptor implicated in the uptake and intracellular sorting of proteins. Our preliminary data confirm that PAI-1 binds to SorlA and that this interaction is prevented by mutations that suppress the profibrotic activity of PAI-1. We further find that PAI-1 is taken up by key cellular constituents of the fibrotic lesion. Importantly, we also identify a previously unrecognized and potent role for SorlA in lung fibrosis, and using human cells, we find that SorlA expression is upregulated in fibrotic epithelial cells and fibroblasts. These preliminary data motivate our hypothesis that PAI-1 promotes lung fibrosis through an interaction with SorlA that leads to cell uptake, cytosolic localization, and a profibrotic alteration in cell phenotype. To interrogate this hypothesis, we have designed a multifaceted approach incorporating molecular biology techniques, in vitro experiments with cells from patients and mice (as well as cell lines), and in vivo experiments using transgenic mice, mutant PAI-1 proteins, and complementary models of lung fibrosis. To accomplish our proposed studies, we have brought together a synergistic investigative team with expertise i...