Regulation of esophageal tumorigenesis by protein adduction

SUMMARY Esophageal adenocarcinoma (EAC) is the most prevalent histological type of esophageal malignancy in the US and many Western nations. This tumor remains deadly as approximately 80% of patients are diagnosed at advanced stages and have a low five-year survival rate. Gastroesophageal reflux disease (GERD) is one of the

strongest risk factors for EAC. In GERD patients, the epithelial lining of the esophagus is exposed to the gastroesophageal reflux (GER) that contains gastric acid frequently mixed with duodenal bile. The esophageal epithelial cells undergoes severe damage from exposure to acid and bile salts. This exposure also promotes

inflammation, which can exacerbate tissue damage and lead to the development of Barrett's esophagus (BE). BE is a preneoplastic condition that is disposed to malignant transformation. The molecular mechanisms of esophageal tumorigenesis in conditions of esophageal reflux injury remain poorly understood. We have

developed an innovative hypothesis to investigate how isolevuglandin (isoLG) lipid derivatives that adduct multiple proteins in conditions of esophageal reflux facilitate tumorigenic processes by protein adduction. IsoLGs are formed from the free radicals induced peroxidation of lipids and cyclooxygenase (COX) and are highly

reactive for lysine as well as other cellular amines. IsoLGs bind covalently with the protein molecules to inflict damage before being recognized by cellular defense mechanisms. In our experimental conditions of esophageal reflux, p63 is found to be one of the most adducted proteins by isoLGs. P63 is a master regulator of esophageal

epithelial development, which also regulate a broad spectrum of genes involved in different cellular processes such as DNA repair, stemness, proliferation and differentiation. Our preliminary data strongly support the hypothesis by providing evidence of the alteration of p63 protein by adduction. In aim 1, using in vitro cell

systems, this proposal will examine the unique mechanisms regulating p63 signaling pathway by protein adduction and its biological impact in conditions of esophageal reflux injury. In aim 2, we will study the p63 protein adduction in in vivo mice model and test various pharmacological options to reverse this process. If

successful, this study will provide a new therapeutic approach to prevent the pro-tumorigenic alterations of esophageal cancer.