PROJECT SUMMARY Systemic sclerosis (scleroderma) is a deadly connective tissue disorder of unknown etiology affecting the skin, lungs and other visceral organs. The disease is characterized by immune dysfunction, vascular pathology, chronic inflammation, fibroblast overproliferation and collagen buildup. Current estimates of disease incidence are 20 cases per million and include about 100,000 cases in the United States. Although there are limited treatment options including immunosuppressive drugs, these therapies only alleviate symptoms but are unable to reverse established fibrosis and cure scleroderma. Thus, there is an opportunity to develop novel antifibrotic therapies that target chief drivers of the disease: fibroblast overproliferation and collagen accumulation. According to our new study, the parent compound esomeprazole and its topically-formulated analog (coined Dermaprazole) might be novel therapy to halt progression of scleroderma. This understanding is based on our extended studies of high throughput screening (HTS) 130,000 small molecules to discover and validate compounds that regulate processes involved in tissue inflammation and fibrosis. Our published molecular, cell biological and in vivo data demonstrate that systemic administration of esomeprazole inhibits bleomycin- induced lung inflammation and fibrosis by 50%. The study also showed that esomeprazole is anti-proliferative with profound effect on fibroblast proliferation. Encouraged by these, we recently reformulated esomeprazole into Dermaprazole for the treatment of scleroderma with limited cutaneous involvement, while the systemically administered esomeprazole is being developed for severe forms of scleroderma. Our data using human 3D skin model, dermal fibroblasts isolated from scleroderma patients, and mouse model of scleroderma revealed that both forms of the drug are effective in blocking collagen buildup and restoring normal skin appearance. Our molecular studies indicate that esomeprazole/Dermaprazole simultaneously modulates oxidative stress, inflammation and fibrosis through upregulation of the master antioxidant and cytoprotective pathway: nuclear factor erythroid 2-related factor 2 (Nrf2)/heme oxygenase 1 (HO1), and suppression of key extracellular matrix (ECM) components such as collagen and fibronectin. Accordingly, we plan to test our central hypothesis “the antioxidant and antifibrotic actions of esomeprazole are able to slow or halt established fibrosis in scleroderma”. To test this, we propose the following Specific Aims: i) Understand the mechanism(s) by which esomeprazole activates HO1 to control inflammatory and fibrotic processes in scleroderma. In this Aim, we will evaluate the mechanistic interaction between esomeprazole and Nrf2 to activate HO1 and its effectors, as well as investigate whether activation of Nrf2/HO1 by esomeprazole is required in the regulation of scleroderma fibroblast proliferation and collagen deposition. ii) Evaluate the effica...