Temporal and spatial dynamics of immune cells in spontaneous liver transplant tolerance.

The liver has long been deemed a tolerogenic organ. We employed high-dimensional mass cytometry and immunohistochemistry to depict the temporal and spatial dynamics of immune cells in the spleen and liver in a murine model of spontaneous liver allograft acceptance. We depicted the immune landscape of spontaneous liver tolerance throughout the rejection and acceptance stages after liver transplantation and highlighted several points of importance. Of note, the CD4+/CD8+ T cell ratio remained low, even in the tolerance phase. Furthermore, a PhenoGraph clustering analysis revealed that exhausted CD8+ T cells were the most dominant metacluster in graft-infiltrating lymphocytes (GILs), which highly expressed the costimulatory molecule CD86. The temporal and spatial dynamics of immune cells revealed by high-dimensional analyses enable a fine-grained analysis of GIL subsets, contribute to new insights for the discovery of immunological mechanisms of liver tolerance, and provide potential ways to achieve clinical operational tolerance after liver transplantation.

Blockade or deficiency of PD-L1 expression in intestinal allograft accelerates graft tissue injury in mice.

The importance of PD-1/PD-L1 interaction to alloimmune response is unknown in intestinal transplantation. We tested whether PD-L1 regulates allograft tissue injury in murine intestinal transplantation. PD-L1 expression was observed on the endothelium and immune cells in the intestinal allograft. Monoclonal antibody treatment against PD-L1 led to accelerated allograft tissue damage, characterized by severe cellular infiltrations, massive destruction of villi, and increased crypt apoptosis in the graft. Interestingly, PD-L1-/- allografts were more severely rejected than wild-type allografts, but the presence or absence of PD-L1 in recipients did not affect the degree of allograft injury. PD-L1-/- allografts showed increased infiltrating Ly6G+ and CD11b+ cells in lamina propria on day 4, whereas the degree of CD4+ or CD8+ T cell infiltration was comparable to wild-type allografts. Gene expression analysis revealed that PD-L1-/- allografts had increased mRNA expressions of Cxcr2, S100a8/9, Nox1, IL1rL1, IL1r2, and Nos2 in the lamina propria cells on day 4. Taken together, study results suggest that PD-L1 expression in the intestinal allograft, but not in the recipient, plays a critical role in mitigating allograft tissue damage in the early phase after transplantation. The PD-1/PD-L1 interaction may contribute to immune regulation of the intestinal allograft via the innate immune system.

Suppression of liver transplant rejection by anti-donor MHC antibodies via depletion of donor immunogenic dendritic cells.

BACKGROUND: We previously found two distinct passenger dendritic cell (DC) subsets in the rat liver that played a central role in the liver transplant rejection. In addition, a tolerance-inducing protocol, donor-specific transfusion (DST), triggered systemic polytopical production of depleting alloantibodies to donor class I MHC (MHCI) antigen (DST-antibodies). METHODS: We examined the role of DST-antibodies in the trafficking of graft DC subsets and the alloresponses in a rat model. We also examined an anti-donor class II MHC (MHCII) antibody that recognizes donor DCs more selectively. RESULTS: Preoperative transfer of DST-antibodies or DST pretreatment eliminated all passenger leukocytes, including both DC subsets and depleted the sessile DCs in the graft to ~20% of control. The CD172a+CD11b/c+ immunogenic subset was almost abolished. The intrahost direct or semi-direct allorecognition pathway was successfully blocked, leading to a significant suppression of the CD8+ T-cell response in the recipient lymphoid organs and the graft with delayed graft rejection. Anti-donor MHCII antibody had similar effects without temporary graft damage. Although DST pretreatment had a priming effect on the proliferative response of recipient regulatory T cells, DST-primed sera and the anti-donor MHCII antibody did not. CONCLUSION: DST-antibodies and anti-donor MHCII antibodies could suppress the CD8+ T-cell-mediated liver transplant rejection by depleting donor immunogenic DCs, blocking the direct or semi-direct pathways of allorecognition. Donor MHCII-specific antibodies may be applicable as a selective suppressant of anti-donor immunity for clinical liver transplantation without the cellular damage of donor MHCII- graft cells and recipient cells.