ABSTRACT The pulmonary fibrosis that accompanies many conditions is characterized by progressive scar formation in the adult human lung. Regardless of the underlying disease state, the presence of this complication portends a worse outcome that is curable only by lung transplantation. Proposed pathogenic mechanisms suggest a poorly understood interaction between epithelial cells and fibroblasts that is orchestrated by microenvironmental cues. Understanding these aspects in the fibrotic microenvironment is of particular importance in diseases such as Idiopathic Pulmonary Fibrosis (IPF) where patients present with established and often progressive disease. As a result, identification of intervenable processes that can be targeted for safe and effective therapies remains a critical unmet need. It is therefore relevant that in a groundbreaking set of studies we have found that fibrotic lungs are enriched for ectopically patterned adrenergic nerves, that these nerves drive fibrosis by releasing NA, that NA driven fibrosis can be treated with α1 adrenoreceptor antagonists. This axis is active in IPF where lung tissues are enriched for markers of adrenergic innervation and NA, and patients treated with α1 adrenoreceptor antagonists experience improved clinical outcomes. We will now determine how NA accumulates in fibrotic lungs and define its fibrogenic functions. For example, while we have found that adrenergic nerve remodeling is stimulated by the dependence receptor deleted in colorectal carcinoma (DCC), the mechanism(s) of this observation are unknown. We have found that fibrotic lung macrophages are deficient in NA catabolism machinery, but whether they contribute to fibrosis via perturbed NA recycling has not been shown. Finally, we have found an association between fibroblast proliferation and α1 adrenoreceptor subtype ADRA1D in fibrotic mouse models and in human IPF that requires more study. This application will explore the mechanistic impact and therapeutic potential of these findings using a unified vision and conceptual framework that will study how nerve-derived NA accumulates in the lung and causes fibrosis. We propose an integrated project that pursues three independent aims using a translational platform combining two animal models, manipulation of adrenergic nerves, neuroengineering, cell specific knockout mice, genetic and pharmacologic gain and loss of function approaches, ex vivo study of human cells and tissues, single cell sequencing, and microCT. The first aim will probe whether adrenergic nerve remodeling and accumulation of fibrostimulatory NA requires expression of the dependence receptor deleted in colorectal carcinoma (DCC) on adrenergic nerves in the lung. The second aim will determine if perturbed NA recycling by macrophages exacerbates fibrosis in animal models and in human cells and tissues. The third aim will use cell specific knockout mice and primary human cells and tissues to determine wither NA-associated lung fibros...