CRISPR-Edited HLA Donor Kidney Transplant to Reduce Rejection Risk

In organ transplantation, differences in HLA genes between donor and recipient are a primary driver of allorecognition and graft rejection. Mismatched donor HLA antigens are identified as "non-self" by the recipient's immune system, provoking CD8⁺ cytotoxic T lymphocyte responses, CD4⁺ T-helper responses, and natural killer (NK) cell activation that can damage the graft. While immunosuppressive drugs can mitigate rejection, patients remain at risk for rejection if donor HLAs are unfamiliar, and life-long immunosuppression carries significant morbidities (infection, malignancy, etc.).

Complete HLA matching is rarely achievable for all patients, especially for highly sensitized individuals with pre-formed anti-HLA antibodies. To address this, researchers have proposed rendering donor tissues "hypoimmunogenic" by removing or reducing expression of the most immunogenic HLA molecules. Preclinical studies show that eliminating key HLA class I and II antigens can prevent immune recognition and rejection of allogeneic cells. For example, genome editing of induced pluripotent stem cells to knock out HLA-A, HLA-B, and HLA-DR (via the DRA gene) successfully created universal cell grafts that evade T cell responses. Similarly, in animal models, silencing of major histocompatibility complex (MHC) genes in donor organs dramatically prolonged transplant survival. In a recent porcine study, donor lungs with reduced MHC (SLA gene) expression had markedly improved outcomes: ~71% of treated pigs survived long-term (2 years) with little to no rejection,

whereas all control pigs receiving unmodified organs rejected within 3 months. Treated animals showed reduced donor-specific antibody production and T-cell reactivity, demonstrating that lowering graft antigenicity can ameliorate rejection. These findings provide a strong rationale that knocking out donor HLA genes can reduce human allograft immunogenicity and potentially allow better graft survival with less immunosuppression.

This trial is a applying ex vivo CRISPR-Cas9 gene editing to donor organs to reduce HLA expression prior to transplantation. The editing strategy targets the donor kidney's HLA class I and II pathways: both HLA-A and HLA-B genes will be knocked out (biallelic disruption), while HLA class II expression is ablated by knocking out CIITA, a transcriptional activator required for HLA-DR, -DQ, and -DP expression. The intended result is a kidney graft largely devoid of classical HLA class I and II molecules.

Notably, HLA-C (a class I gene) may be partially retained (e.g. only one allele knocked out) to maintain a low level of class I expression - this strategy can help avoid NK cell-mediated "missing-self" responses that occur when all class I is absent. By preserving minimal HLA-C or non-polymorphic HLA-E/G expression, the graft may evade NK cell attack while still lacking the highly polymorphic HLA-A/B and class II antigens that elicit T-cell and antibody responses. The overall hypothesis is that such CRISPR-edited "stealth" kidneys will be significantly less immunogenic, leading to fewer acute rejection episodes and reduced anti-graft antibody formation, thereby improving transplant success.