Analyzing Porcine Corneal Xenograft Compatibility: In Silico Insights on Graft Outcomes

Abstract

Background: Corneal transplantation faces significant challenges due to the shortage in donor corneas. Porcine corneas have emerged as a potential solution due to their similarities in biomechanical properties with pigs, yet xenoimmune rejection poses an obstacle to their efficacy. Methods: In this study, in silico methods were employed to analyze the compatibility of porcine corneal xenografts, focusing on two key aspects: the comparison of corneal matrix proteins and investigation of the immunological mediators and pathways involved in corneal graft rejection. The amino acid sequences of the fourteen (14) most abundant proteins in the corneal matrix were compared to determine their structural and functional differences. The primary amino acid structures and compositions, theoretical pI, and grand average of hydropathicity were determined and compared between the two species. Results: In graft performance, similarities and differences between the donor and recipient tissues influence the success of transplantation. When the proteins closely resemble each other, in terms of structural characteristics and biochemical properties, the host’s immune system is less likely to recognize the tissue as foreign. The immunological mediators and pathways involved in corneal graft rejection were investigated, elucidating the mechanisms underlying xenograft incompatibility. Based on the results generated from STRING, the specific groups of molecules that are involved in the immune-mediated rejection process are costimulatory molecules, cytokines, immune checkpoint molecules, apoptosis regulators, cell adhesion molecules, growth factors, neuropeptides and hormones, certain receptors, the cytotoxic molecule GZMA, and the chemokine CCL5. Conclusions: The results of this study establish that the porcine cornea has a high suitability for corneal xenotransplantation into humans but requires immune-based therapeutic interventions to increase graft acceptance.