298. Transfection of Neutrophils from X-Linked Chronic Granulomatous Disease Patients with gp91phox mRNA Restores Oxidase Activity with High Efficiency and Viability

Abstract

Chronic granulomatous disease (CGD) is an inherited immune deficiency due to defective phagocyte NADPH oxidase required for production of antimicrobial oxidants. Fungal or bacterial infections in CGD may persist despite intensive and prolonged antibiotic therapy. In settings where conventional antibiotic therapy and/or surgical debridement do not control infection, use of allogeneic unmatched donor granulocyte transfusions has been therapeutic. However, CGD patients treated with granulocyte transfusions may develop high titers of anti-HLA antibodies, restricting use of allogeneic granulocyte transfusions and further complicating potentially curative bone marrow transplant. Using the CGD patient as an autologous donor for granulocyte transfusions would be a helpful solution.Here we demonstrate highly efficient functional correction of the functional defect in CGD by transfection of patient's own granulocytes with mRNA while retaining viability using a scalable, cGMP-compliant MaxCyte® GT™ electroporation system capable of handling clinically relevant numbers of cells (>1010cells).Freshly collected granulocytes from normal volunteers were electroporated using the MaxCyte electroporation system with eGFP-mRNA on the day of collection. Flow cytometry of demonstrated that >90% of neutrophils expressed eGFP with viability exceeding 90% at 24 hrs after electroporation. Phagocyte NADPH oxidase activity of the normal neutrophils was retained as well as bactericidal activity against Burkolderia cepacia, a CGD bacterial pathogen. Antibacterial activity of electroporated granulocytes was comparable to unmanipulated granulocytes confirming retention of cellular function following the electroporation. Finally, electroporated eGFP positive human neutrophils injected into CGD mice were shown to remain in circulation as well as migrate to the peritoneal cavity following thioglycollate IP injection and there were no adverse effects observed in the mice.Electroporation of gp91phox mRNA into human X-linked CGD (gp91phox-deficient) patient neutrophils resulted in expression of gp91phox protein in >70% of cells with >90% viability at 24 hours after treatment. Using the dihydrorhodamine assay of phagocyte NADPH oxidase activity, >70% of neutrophils remained functionally corrected 2 days after transfection. Other studies of cellular function in vitro and in vivo with electroporated corrected CGD neutrophils are in progress. In summary, we show the feasibility of restoring the function of CGD patient-autologous neutrophils via electroporation of mRNA encoding the defective gene product. This approach may have potential clinical utility in the management of severe chronic bacterial and fungal infections in CGD but also short-term correction of other hematopoietic gene diseases.