Although much is known about the migration of T cells from blood to lymph nodes, less is known about the mechanisms regulating the migration of T cells from tissues into lymph nodes through afferent lymphatics. Here we investigated T cell egress from nonlymphoid tissues into afferent lymph in vivo and developed an experimental model to recapitulate this process in vitro. Agonism of sphingosine 1-phosphate receptor 1 inhibited the entry of tissue T cells into afferent lymphatics in homeostatic and inflammatory conditions and caused the arrest, mediated at least partially by interactions of the integrin LFA-1 with its ligand ICAM-1 and of the integrin VLA-4 with its ligand VCAM-1, of polarized T cells at the basal surface of lymphatic but not blood vessel endothelium. Thus, the increased sphingosine 1-phosphate present in inflamed peripheral tissues may induce T cell retention and suppress T cell egress.
The authors demonstrate an effect of allogeneic exosomes on the modulation of immune responses in vivo, suggesting that, like donor cells, exosomes can stimulate or regulate antigen-specific immune responses.
Recent studies suggest that particular dendritic cells (DC) subpopulations may be tolerogenic. To test the capacity of different DC subpopulations to modulate allograft rejection, we generated two distinct populations of rat bone marrow-derived DCs (BMDC) with low doses of GM-CSF and IL-4. The non-adherent population (nBMDC), which are the 'classical' DCs was able to stimulate naïve allogeneic T cells and could be induced to completely mature using various stimuli. In contrast, the adherent population (aBMDC), which displayed an immature phenotype, was unable to stimulate T cells and was more resistant to maturation. We found that syngeneic aBMDCs, injected one day before transplantation, induced significant prolongation of heart allograft survival and decreased anti-donor humoral and cellular responses. Similarly, syngeneic aBMDCs inhibited T-cell responses to KLH in the spleen but not in lymph node in a KLH immunization model without graft. This effect was not antigen specific and could be reversed using an inhibitor of inducible nitric oxide synthase. This compartmentalized inhibition could be in part explained by the fact that the majority of syngeneic adherent cells administered intravenously were found in the spleen with some of them reaching the T-cell areas. These data suggest that syngeneic aBMDCs can modulate immune responses.
Exosomes are MHC-bearing vesicles secreted by a wide array of cells. We have previously shown that donor-haplotype exosomes from bone marrow dendritic cells (DCs) injected before transplantation significantly prolong heart allograft survival in congenic and fully MHC-mismatched Lewis rats. Here we show that donor exosomes administered after transplantation are similarly able to prolong allograft survival, however, without inducing tolerance. We therefore tested the effect of exosomes combined with shortterm LF 15-0195 (LF) treatment, which blocks the maturation of DCs, so that donor-MHC antigens from exosomes could be presented in a more tolerogenic environment. LF treatment does not preclude the development of a strong antidonor cellular response, and while LF, but not exosome, treatment inhibits the antidonor humoral response and decreases leukocyte graft infiltration, allografts from LF-treated recipients were either acutely or strongly chronically rejected. Interestingly, when combined with LF treatment, exosomes induced a donor-specific allograft tolerance characterized by a strong inhibition of the antidonor proliferative response. This donor-specific tolerance was transferable to naïve allograft recipients. Moreover, exosomes/LF treatment prevented or considerably delayed the appearance of chronic rejection. These results suggest that under LF treatment, presentation of donor-MHC antigens (from exosomes) can induce regulatory responses that are able to modulate allograft rejection and to induce donor-specific allograft tolerance.
We recently showed that injection of recipient-type immature bone marrow-derived dendritic cells (iBMDCs) the day before transplantation induced a significant prolongation of allograft survival. This study aimed at improving the administration protocol to induce allograft tolerance. Various amounts of iBMDCs were administered to syngeneic LEW.1A rats before and after transplantation of an allogeneic LEW.1W heart, with or without additional suboptimal immunosuppression. Allograft survival was not improved by repeated injections of syngeneic iBMDCs or by additional treatment with low-dose rapamycin. Combining injections of iBMDCs and LF 15-0195 showed a striking synergistic effect and induced definitive allograft acceptance in 92% of recipients. Tolerant recipients accepted donor-type, but not third-party type skin grafts, suggesting the development of regulatory mechanisms capable of maintaining donor-specific tolerance. The reported findings may contribute to the development of new therapeutic strategies to induce transplantation tolerance in humans.
We previously reported the characterization of a MHC class IIlowCD4−CD103+ (CD4−) subset of dendritic cells (DC) in rat spleen that exhibit a Ca2+-, Fas ligand-, TRAIL- and TNF-α-independent cytotoxic activity against specific targets in vitro. In this study, we demonstrate that this DC subset was also found in lymph nodes. Freshly extracted and, therefore, immature CD4− DC exhibited a potent cytotoxic activity against a large panel of tumor cell lines as well as primary endothelial cells. The cytotoxic activity of immature CD4− DC required cell-to-cell contact and de novo protein expression. CD4− DC-mediated cell death resembled apoptosis, as evidenced by outer membrane phosphatidylserine exposure and nuclear fragmentation in target cells, but was caspase as well as Fas-associated death domain and receptor-interacting protein independent. Bcl-2 overexpression in target cells did not protect them against DC-mediated cell death. Immature CD4− DC phagocytosed efficiently apoptotic cells in vitro and, therefore, rapidly and specifically engulfed their victims following death induction. Maturation induced a dramatic down-regulation of the killing and phagocytic activities of CD4− DC. In contrast, CD4+ DC were both unable to kill target cells and to phagocytose apoptotic cells in vitro. Taken together, these data indicate that rat immature CD4−CD103+ DC mediate an unusual cytotoxic activity and can use this function to efficiently acquire Ag from live cells.
Donor-specific allograft tolerance can be induced in the adult rat by pregraft donor-specific blood transfusion (DST). This tolerance appeared to be mediated by regulatory cells and to the production of the suppressive cytokine TGF-β1. A potential immunoregulatory CD8+ clone bearing a Vβ18-Dβ1-Jβ2.7 TCR gene rearrangement was previously identified in DST-treated recipients. To assess the functional role of this T cell clone in the induction of tolerance by DST, we have vaccinated DST-treated recipients with a plasmid construct encoding for the Vβ18-Dβ1-Jβ2.7 TCR β-chain. DST-induced allograft tolerance was abolished by anti-TCR Vβ18-Dβ1-Jβ2.7 DNA vaccination in six of seven recipients, whereas vaccination with the vector alone, or with the construct encoding a TCR Vβ13 β-chain, had no effect. However, the transcript number of the Vβ18-Dβ1-Jβ2.7 chain was unchanged in allografts from vaccinated DST-treated rats, suggesting that this clone was not depleted by vaccination, but rather was altered in its function. Moreover, TCR Vβ18-Dβ1-Jβ2.7 DNA vaccination restored the anti-donor alloantibody production, partially restore the capacity of spleen cells from tolerized recipients to proliferate in vitro against donor cells, and decreased the inhibitory effect of TGF-β1, seen in DST-treated recipients, in spleen cells from vaccinated DST-treated ones. This study strongly suggests that this CD8+ TCR Vβ18-Dβ1-Jβ2.7 T cell clone has an effective immunoregulatory function in allograft tolerance induced by DST.
After transplantation the anti-donor cellular response was significantly decreased in vaccinated rats. This was accompanied by a significant reduction in interferon-gamma mRNA expression in the grafted hearts and T helper 1-type alloantibody production, indicating that the vaccination modifies the alloresponse against the grafts.
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