Optimizing Strategies to Overcome Kidney Xenograft Rejection
Adams, Andrew B.    Tector, A Joseph   
Emory University, Atlanta, GA, United States

With over 100,000 patients now on the waiting list for a kidney transplant it is obvious that there is a critical shortage of available donor organs. Xenotransplantation represents a promising solution. While pigs are viewed as the optimal non-human source of organs, the potency of the human immune response to pig organs has prevented the clinical application of pig-to-human kidney transplantation. In this application we propose using cutting-edge genetic engineering approaches in combination with the use of the next generation of agents targeting critical T cell costimulatory pathways to reduce both the humoral and cellular immune response of nonhuman primates (NHP) undergoing kidney transplantation as a preclinical model to inform future human trials. The first and dominant obstacle is the robust humoral immune response of primates to pig kidneys. Despite the gradual introduction of a number of genetic modification to pig donors including knocking out ?-1,3-gal, the presence of pre-formed, naturally occurring antibodies as well as the de novo formation of xenoantigen-specific antibodies continues to result in early rejection. Here, we will use the powerful CRISPR/Cas9 system of genome editing to eliminate novel carbohydrate xenoantigens generated by the ?4GAL-NT2 enzyme , and interrogate the impact of this gene deletion (layered onto GAL-/- hCD55 transgenic animals) on the survival of pig kidneys transplanted into NHP recipients. Beyond the humoral barrier to xenotransplantation, the robust cellular immune response to pig organs poses a second challenge to the clinical application of xenotransplantation. The development of immunosuppressive strategies based on the blockade of critical costimulatory signals that are required for T cell activation offers a potential strategy to more effectively control the cellular immune response with less toxicity in comparison to standard immunosuppressive regimens. However, current strategies targeting the two dominant costimulatory pathways, CD28 and CD154 using CTLA4-Ig and anti-CD154 mAb have been associated with issues of efficacy and safety. Importantly, our work has demonstrated the superior efficacy and safety of novel ?next-generation costimulation blockers? compared to current costimulation blockers in both mouse and NHP models. Thus we will next interrogate the ability of these next generation reagents, or domain antibodies, to better control xeno- reactive immunity and prolong kidney xenograft survival. Finally, we will employ additional strategies that are synergistic with the blockade of T cell costimulation to consolidate graft acceptance: 1) genome-editing strategies to delete SLA class I/ class II on donor tissue and thereby mitigate T cell responses elicited via direct presentation following xenotransplantation, and 2) blockade of the cell adhesion molecule VLA-4 and cytokine signaling through CD122 as adjunct immunotherapeutic strategies to control the xeno-reactive, costimulation- independent T cell response xenotransplantation. In sum, this project uses cutting-edge technology to develop novel strategies to reduce both the humoral and cellular immunity barriers and prolong xenotransplant survival.

Public Health Relevance

Xenotransplantation has the potential to solve the organ donor shortage and provide life-saving transplants to the ~100,000 Americans currently on the transplant wait list. However, overcoming formidable immunologic barriers is necessary before this becomes a clinical reality. This application proposes use cutting edge genome engineering technology to generate novel pig donors for use in xenotransplantation. In addition, it proposes to develop novel immunosuppressive strategies to overcome these barriers and bring xenotransplantation to the clinic.