Targeting the Complement Pathway in ALK Positive Lung Cancer

Targeted therapies, such as ALK inhibitors, represent a major advance in the treatment of lung cancer patients with specific oncogenic drivers. However, these patients relapse due to acquired or intrinsic resistance to these agents. While targeting immnoevasive pathways, such as immune checkpoint inhibitors, have shown efficacy in a subset of lung cancer patients who have progressed on other therapies, the response rate in ALK-positive lung cancer to these agents is very low, underscoring the need to identify other potential regulators of the anti-tumor immune response. The complement pathway is a component of the innate immune response, which regulates the adaptive immune system. Complement activation, initiated through multiple pathways, leads to a series of proteolytic cascades that generate inflammatory mediators designated as anaphylatoxins (C3a, C5a).

Our laboratory has employed an immunocompetent orthotopic model of lung cancer progression, where lung cancer cells are implanted into the lungs of syngeneic mice. To study pathways regulating progression of ALK-positive lung cancer, we have developed a panel of murine lung cancer cell lines with the oncogenic driver EML4/ALK. Using both genetic and pharmacological approaches we have demonstrated that while these tumors are resistant to anti-PD-1/anti-PD-L1 therapy, they are strongly inhibited by blocking the complement pathway. This project will define the mechanisms of complement activation, and the cellular and molecular mechanisms whereby complement inhibition blocks ALK-positive tumor progression. Studies will test a panel of complement inhibitors targeting different steps in the complement cascade and validate complement activation in human ALK-positive lung tumors.