AXL Is a Potential Target for the Treatment of Intestinal Fibrosis

Background: Fibrosis is the final common pathway to intestinal failure in Crohn's disease, but no medical therapies exist to treat intestinal fibrosis. Activated myofibroblasts are key effector cells of fibrosis in multiple organ systems, including the intestine. AXL is a receptor tyrosine kinase that has been implicated in fibrogenic pathways involving myofibroblast activation. We aimed to investigate the AXL pathway as a potential target for the treatment of intestinal fibrosis. Methods: To establish proof of concept, we first analyzed AXL gene expression in 2 in vivo models of intestinal fibrosis and 3 in vitro models of intestinal fibrosis. We then tested whether pharmacological inhibition of AXL signaling could reduce fibrogenesis in 3 in vitro models of intestinal fibrosis. In vitro testing included 2 distinct cell culture models of intestinal fibrosis (matrix stiffness and TGF-beta 1 treatment) and a human intestinal organoid model using TGF-beta 1 cytokine stimulation. Results: Our findings suggest that the AXL pathway is induced in models of intestinal fibrosis. We demonstrate that inhibition of AXL signaling with the small molecule inhibitor BGB324 abrogates both matrix-stiffness and transforming growth factor beta (TGF-beta 1)-induced fibrogenesis in human colonic myofibroblasts. AXL inhibition with BGB324 sensitizes myofibroblasts to apoptosis. Finally, AXL inhibition with BGB324 blocks TGF-beta 1-induced fibrogenic gene and protein expression in human intestinal organoids. Conclusions: The AXL pathway is active in multiple models of intestinal fibrosis. In vitro experiments suggest that inhibiting AXL signaling could represent a novel approach to antifibrotic therapy for intestinal fibrosis such as in Crohn's disease.

Automated summary

The AXL pathway is activated in multiple models of intestinal fibrosis, and inhibiting AXL signaling with a small molecule inhibitor has shown promising results in reducing fibrogenesis and sensitizing myofibroblasts to apoptosis. Inhibition of AXL also blocks the expression of fibrogenic genes and proteins in human intestinal organoids, suggesting a potential novel approach to antifibrotic therapy for intestinal fibrosis such as in Crohn's disease.