Polymorphism in programmed cell death 1 gene is strongly associated with lung and kidney allograft survival in recipients from CMV-positive donors.

BACKGROUND: Cytomegalovirus (CMV) has a role in chronic rejection and graft loss in kidney transplant (KTx) and lung transplant (LTx) recipients. In addition, donor CMV seropositivity is an independent risk factor for renal graft loss. The anti-CMV response might modulate this risk. Expression of programmed cell death 1 (PD-1), a receptor involved in viral-specific T-cell exhaustion, is influenced by a single nucleotide polymorphism called PD-1.3 (wild-type allele G, variant allele A). METHODS: We performed a retrospective study to assess the impact of PD-1.3 on graft outcome in donor CMV seropositive (D+) and donor CMV seronegative (D-) KTx and LTx. We also performed a case-control study to evaluate the anti-CMVpp65 response according to genotype. RESULTS: PD-1.3 was determined in 1,119 KTx and 181 LTx. In 481 D+ KTx, A allele carriers (24%) experienced significantly less graft failure compared with GG carriers (p = 0.001). Multivariate analysis showed that this association was independent of donor and recipient age, acute rejection episodes, and number of human leukocyte antigen mismatches (hazard ratio, 0.381; 95% confidence interval, 0.209-0.696; p = 0.002). Analysis in 85 D+ LTx showed similar results: A allele carriers had better survival (hazard ratio, 0.302; 95% confidence interval, 0.128-0.716; p = 0.006) and greater 6-month forced expiratory volume (71% ± 17% vs 54% ± 16%, p = 0.001). In D- recipients, PD-1.3 did not affect KTx or LTx outcome. Finally, AA recipients had a stronger anti-CMVpp65 T-cell response than matched GG recipients (p = 0.003). CONCLUSIONS: The A variant allele in PD-1.3 single nucleotide polymorphism improved graft survival in kidney and lung transplant recipients receiving grafts from CMV-positive donors.

IL-2 phosphorylates STAT5 to drive IFN-γ production and activation of human dendritic cells.

Human dendritic cells (hDCs) produce IL-2 and express IL-2R α-chain (CD25), but the role of IL-2 in DC functions is not well defined. A recent study suggested that the main function of CD25 on hDCs was to transpresent IL-2 to activate T lymphocytes. Our results demonstrate the expression of the three chains of the IL-2R on hDCs and that IL-2 induces STAT5 phosphorylation. Interestingly, use of inhibitors of p-STAT5 revealed that IL-2 increases LPS-induced IFN-γ through STAT5 phosphorylation. Finally, we report that IL-2 increases the ability of hDCs to activate helpless CD8(+) T cells, most likely because of IL-2-triggered IFN-γ synthesis, as we previously described. For the first time, to our knowledge, we disclose that IL-2 induces monocyte-derived hDC's functional maturation and activation through IL-2R binding. Interestingly, our study suggests a direct effect of anti-CD25 mAbs on hDCs that may contribute to their clinical efficacy.

Mycophenolic acid-treated dendritic cells generate regulatory CD4+ T cells that suppress CD8+ T cells' allocytotoxicity.

Regulatory T cells (Treg) play a crucial role in controlling immunity and transplant rejection. Two main groups of Treg have been described: antigen-induced Treg (iTreg) and natural Treg (nTreg). The ways to induce and the mechanisms of action of Treg subsets remained ill defined, particularly for their effects on CD8(+) T cells. CD8(+) T cells are major agents in the rejection of allografts; the aim of this study is to investigate the effects exerted on CD8(+) T cells by human CD4(+) iTreg induced by mycophenolic acid-treated dendritic cells. iTreg suppress the proliferation of CD8(+) T cells by allogeneic cell-cell interaction with mature dendritic cells and irrespectively of the TCR specificity of the CD8(+) T cells and cell-cell contact of iTreg with CD8(+) T cells. In our model, this suppression is independent of the action of IL-10 and TGF-ß1. iTreg were able to modify phenotype and inhibited IFN-γ and TNF-α secretion by CD8(+) T cells. Most interestingly, iTreg inhibit the synthesis of perforin and of granzymes A and B by CD8(+) T cells and impaired their cytotoxicity against allogeneic targets. In summary, our study showed the involvement of iTreg in the down-regulation of cytotoxic responses mediated by CD8(+) T cells in an allospecific context. Following studies that have shown the existence of a regulation control exerted by iTreg on CD4(+) T cells and dendritic cells, this work ultimately shows that this regulation can reach CD8(+) T-cell functions.