Transient-mixed Chimerism With Nonmyeloablative Conditioning Does Not Induce Liver Allograft Tolerance in Nonhuman Primates.

BACKGROUND: Although short-term outcomes for liver transplantation have improved, patient and graft survival are limited by infection, cancer, and other complications of immunosuppression. Rapid induction of tolerance after liver transplantation would decrease these complications, improving survival and quality of life. Tolerance to kidneys, but not thoracic organs or islets, has been achieved in nonhuman primates and humans through the induction of transient donor chimerism. Since the liver is considered to be tolerogenic, we tested the hypothesis that the renal transplant transient chimerism protocol would induce liver tolerance. METHODS: Seven cynomolgus macaques received immune conditioning followed by simultaneous donor bone marrow and liver transplantation. The more extensive liver surgery required minor adaptations of the kidney protocol to decrease complications. All immunosuppression was discontinued on postoperative day (POD) 28. Peripheral blood chimerism, recipient immune reconstitution, liver function tests, and graft survival were determined. RESULTS: The level and duration of chimerism in liver recipients were comparable to those previously reported in renal transplant recipients. However, unlike in the kidney model, the liver was rejected soon after immunosuppression withdrawal. Rejection was associated with proliferation of recipient CD8 T effector cells in the periphery and liver, increased serum interleukin (IL)-6 and IL-2, but peripheral regulatory T cell (Treg) numbers did not increase. Antidonor antibody was also detected. CONCLUSIONS: These data show the transient chimerism protocol does not induce tolerance to livers, likely due to greater CD8 T cell responses than in the kidney model. Successful tolerance induction may depend on greater control or deletion of CD8 T cells in this model.

Genetic correction of the fetal brain increases the lifespan of mice with the severe multisystemic disease mucopolysaccharidosis type VII.

Neurogenetic diseases typically have globally distributed lesions, and pathology usually develops early in life, requiring early diagnosis and treatment. We investigated the effects of transferring a corrective gene into the fetal brain before the onset of pathology in the mucopolysaccharidosis (MPS) type VII mouse, a model of a lysosomal storage disease. A single adeno-associated virus serotype 1 vector injection into the ventricle at 15.5 days of gestation resulted in widespread distribution and lifelong expression of the normal gene in the brain and spinal cord. The normal enzyme was distributed to neighboring cells (as expected) and completely prevented the development of storage lesions throughout the central nervous system (CNS). No vector transfer was found outside the CNS, including the gonads, but a small amount of enzyme was present in visceral tissues, consistent with transfer from cerebrospinal fluid to venous circulation. The enzyme was present peripherally in such low amounts that it did not result in the severe skeletal dysmorphology that occurs readily when systemic treatment is used in neonates. However, the survival probability of the treated animals was significantly increased. The results suggest that the nervous system disease may contribute to the overall physiologic health of the animal in this type of disease.