Abstract
Natural killer (NK) cell protection from tumor metastases is a critical feature of the host immune response to cancer, but various immunosuppression mechanisms limit NK cell effector function. The ectoenzyme, CD39, expressed on tumor-infiltrating myeloid cells, granulocytes, and lymphocytes, including NK cells, converts extracellular ATP (eATP) into AMP and, thus, potentially suppresses eATP-mediated proinflammatory responses. A CD39-targeting monoclonal antibody (mAb) that inhibits the mouse ectoenzyme CD39 suppressed experimental and spontaneous metastases in a number of different tumor models and displayed superior antimetastatic activity compared with the CD39 inhibitor POM1 and inhibitors and mAbs that block other members of the adenosinergic family (e.g., A2AR and CD73). The antimetastatic activity of anti-CD39 was NK cell and IFNγ dependent, and anti-CD39 enhanced the percentage and quantity of IFNγ produced and CD107a expression in lung-infiltrating NK cells following tumor challenge and anti-CD39 therapy. Using conditional Cd39 gene-targeted mouse strains and adoptive NK cell transfers, we showed that CD39 expressed on bone marrow-derived myeloid cells was essential for anti-CD39's antimetastatic activity, but NK cell expression of CD39 was not critical. The eATP receptor P2X7 and the NALP3 inflammasome, including downstream IL18, were critical in the mechanism of action of anti-CD39, and the frequency of P2X7 and CD39 coexpressing lung alveolar macrophages was specifically reduced 1 day after anti-CD39 therapy. The data provide a mechanism of action involving NK cells and myeloid cells, and anti-CD39 combined with anti-PD-1, NK cell-activating cytokines IL15 or IL2, or an inhibitor of A2AR to effectively suppress tumor metastases.