KRas, in addition to Tp53 is a driver for early carcinogenesis and a molecular target in a mouse model of invasive gastro-esophageal adenocarcinoma

Abstract

AbstractObjectiveThe incidence of gastro-esophageal adenocarcinoma (GEAC) has increased dramatically and is associated with Barrett’s Esophagus (BE). Gastric cardia progenitors are the likely origin for BE and GEAC. Here we analyzep53, Rb1andKrasalterations in Lgr5 progenitor cells during carcinogenesis.DesignWe introduced single and combined genetic alterations (p53, Rb1andKras) in Lgr5-expressing progenitor cells at the inflamed gastroesophageal junction in the L2-IL1b (L2) mouse model crossed toLgr5-CreERTmice. Forin-vitrotreatment we utilized mouse and human 3D organoids.ResultsInactivation ofTp53orRb1alone (L2-LP and L2-LR mice) resulted in metaplasia, and mild dysplasia, while expression ofKrasG12D(L2-LK) accelerated dysplasia in L2-IL1b mice. Dual induction of genetic alteration in L2-LPR, L2-LKP and L2-LKR mice confirmed the accelerating role of mutantKras, with the development of invasive cancer in mice with combinedTp53andKrasalteration. All three genetic events in cardia progenitor cells generated invasive cancer at 6 months of age, with chromosomal instability (CNV). The dominant role ofKrasprompted us to treat with a SHP2 inhibitor in combination with an ERK or MEK inhibitor, leading to reduced growth inKrasmutant organoids. SHP2 and MEK inhibitionin-vivoreducedKrasdependent tumor formation.ConclusionIn the first invasive GEAC mouse model,Krasmutation in combination with loss of tumor suppressor genes Tp53 or Rb1 emerges as a key player in GEAC and with importance of p53 and Rb1 in promoting metaplasia. Targeting this SHP2/MEK/KRAS pathway represents a promising therapeutic option forKrasaltered GEAC.What is already known on this topicThe increased incidence of GEAC is challenging current screening and surveillance strategies. Therapeutic and preventive options are limited due to a lack of knowledge on the role of genetic alterations commonly associated with GEAC and their function during progression to dysplasia.What this study addsWe generate the first invasive GEAC model and show thatKRASat least in combination with a second genetic alterations (Tp53 and/or Rb1) may be a driver of tumorigenesis, and targeting KRAS alterations could be a promising now treatment substitution.How this study might affect research, practice or policyTargeting KRAS alterations will be important for GEAC, especially as specific KRAS inhibitor are on the horizon. In addition, a concept of single genetic alteration inducing metaplasia as an adaptation to chronic inflammation might emerge as an important factor for surveillance.