A Novel Injury Site-Targeted Complement Inhibitor Which Protects against Lung Transplant Ischemia Reperfusion Injury

Abstract

Purpose Self-reactive natural Abs initiate complement activation and injury following ischemia and reperfusion of certain tissues, but their role in post-ischemic lung injury is unknown. Here, we investigated the expression of two previously identified post-ischemic neoepitopes, namely a modified annexin IV epitope recognized by B4 IgM mAb, and an epitope consisting of a subset of phospholipids recognized by C2 IgM mAb, and additionally determined their role in lung transplant ischemia reperfusion injury (IRI). Methods Lungs from C57Bl/6 mice were orthotopically transplanted into Rag1-/- (antibody-deficient) mice reconstituted with either B4 and C2 mAbs. Results Rag1-/- mice were protected from lung IRI, but reconstitution with either B4 or C2 natural IgM mAbs restored lung IRI. The C2 mAb was more effective than the B4 mAb at restoring injury, as determined by histological and micro-CT analysis. Based on this information, we developed and characterized a therapeutic strategy that exploited the post-ischemia recognition system of natural antibodies. We constructed a single-chain antibody (scFv) derived from C2 mAb and linked it to Crry, an inhibitor of C3 activation (C2scFv-Crry). In models of syngeneic (B6-B6) and allogeneic (Balb/c-B6) lung transplant models in which recipients contain a full natural antibody repertoire, a single post-transplant injection of C2scFv-Crry blocked the binding of endogenous IgM to the graft, inhibited complement activation, and significantly reduced graft inflammation and injury as determined by histology, μCT, and immunhistochemical analysis. The severity of IRI is associated with the onset of acute rejection. Conclusion We identified pathophysiologically important epitopes expressed within the lung after lung ischemia and reperfusion post transplantation. We further describe a novel translatable strategy for complement inhibition that is specifically targeted to the transplanted lung, and that has several advantages over currently available approaches that rely on systemic complement inhibition. Significantly, the C2 epitope has been identified in both mouse and man, increasing the translational relevance of the approach.