Linda Cassis

Proteasomal Processing of Albumin by Renal Dendritic Cells Generates Antigenic Peptides

The role of dendritic cells (DC) that accumulate in the renal parenchyma of non-immune-mediated proteinuric nephropathies is not well understood. Under certain circumstances, DC capture immunologically ignored antigens, including self-antigens, and present them within MHC class I, initiating an autoimmune response. We studied whether DC could generate antigenic peptides from the self-protein albumin. Exposure of rat proximal tubular cells to autologous albumin resulted in its proteolytic cleavage to form an N-terminal 24-amino acid peptide (ALB1-24). This peptide was further processed by the DC proteasome into antigenic peptides that had binding motifs for MHC class I and were capable of activating syngeneic CD8+ T cells. In vivo, the rat five-sixths nephrectomy model allowed the localization and activation of renal DC. Accumulation of DC in the renal parenchyma peaked 1 wk after surgery and decreased at 4 wk, concomitant with their appearance in the renal draining lymph nodes. DC from renal lymph nodes, loaded with ALB1-24, activated syngeneic CD8+ T cells in primary culture. The response of CD8+ T cells of five-sixths nephrectomized rats was amplified with secondary stimulation. In contrast, DC from renal lymph nodes of five-sixths nephrectomized rats treated with the proteasomal inhibitor bortezomib lost their capacity to stimulate CD8+ T cells in primary and secondary cultures. These data suggest that albumin can be a source of potentially antigenic peptides upon renal injury and that renal DC play a role in processing self-proteins through a proteasome-dependent pathway.

The Toll-IL-1R Member Tir8/SIGIRR Negatively Regulates Adaptive Immunity against Kidney Grafts

Members of the TLR/IL-1R superfamily mediate ischemia/reperfusion injury and initiate immune response in transplanted organs. In this study, we tested the hypothesis that Toll-IL-1R8 (TIR8), a negative regulator of TLR/IL-1R highly expressed in the kidney, modulates immune cell activation underlying kidney rejection. In a mouse model of fully mismatched kidney allotransplantation in which the graft is spontaneously accepted, intragraft Tir8 expression was enhanced compared with naive kidneys. Targeted deletion of Tir8 in the graft exerted a powerful antitolerogenic action leading to acute rejection. Similarly, in a mouse model of kidney graft acceptance induced by costimulation blockade, most Tir8−/− grafts were acutely rejected. Despite similar levels of TLR4, IL-1R, and their ligands, the posttransplant ischemia/reperfusion-induced inflammatory response was more severe in Tir8−/− than in Tir8+/+ grafts and was followed by expansion and maturation of resident dendritic cell precursors. In vitro, Tir8−/− dendritic cell precursors acquired higher allostimulatory activity and released more IL-6 upon stimulation with a TLR4 ligand and TNF-α than Tir8+/+ cells, which may explain the increased frequency of antidonor-reactive T cells and the block of regulatory T cell formation in recipients of a Tir8−/− kidney. Thus, TIR8 acts locally as a key regulator of allogeneic immune response in the kidney. Tir8 expression and/or signaling in donor tissue are envisaged as a novel target for control of innate immunity and amelioration of graft survival.

Dendritic cells genetically engineered with adenoviral vector encoding dnIKK2 induce the formation of potent CD4+ T-regulatory cells.

Background. Immature dendritic cells (DC), characterized by low expression of both major histocompatibility complex class II antigens and co-stimulatory molecules, can be instrumental in the induction of peripheral tolerance. Because nuclear factor (NF)-&kgr;B is central to DC maturation, the authors engineered DC with an adenoviral vector (Adv) encoding for a kinase-defective dominant negative form of IKK2 (dnIKK2) to block NF-&kgr;B activation and inhibit DC maturation. Methods. DC were obtained by culturing bone marrow from Brown Norway (BN) rats with granulocyte-macrophage colony-stimulating factor and interleukin-4 for 11 days. To block NF-&kgr;B activation, at day 9, cells were transfected with AdV-dnIKK2. At day 11, cells were used as stimulators in primary mixed leukocyte reaction (MLR) with naive Lewis rat lymphocytes as responders. CD4+ T cells were purified from primary MLR and tested in secondary MLR with allogeneic mature DC and in co-culture MLR with naive lymphocytes. The tolerogenic potential of dnIKK2-DC was evaluated in vivo in a model of rat kidney allotransplantation. Results. DnIKK2-DC were immature and lacked any allostimulatory activity. T cells preexposed to allogeneic dnIKK2-DC were hyporesponsive to a secondary stimulation with mature DC and acquired potent regulatory properties, inhibiting naive T-cell proliferation toward allogeneic stimuli. Pretransplant infusion of allogeneic donor dnIKK2-DC prolonged the survival of a kidney allograft from the same allogeneic donor, without the need for immunosuppressive therapy. Conclusions. Allogeneic DC, rendered immature by dnIKK2 transfection, induce in vitro differentiation of naive T cells into CD4+ T-regulatory cells, effective at low ratios with target cells, rendering them applicable for cellular therapy of immune-mediated abnormalities and for preventing transplant rejection.

DnIKK2-transfected dendritic cells induce a novel population of inducible nitric oxide synthase-expressing CD4+CD25- cells with tolerogenic properties

Background. We previously documented that rat bone marrow-derived dendritic cells (DCs), transfected with an adenovirus encoding a dominant negative form of IKK2 (dnIKK2), have impaired allostimulatory capacity and generate CD4+ T cells with regulatory function. Here we investigate the potency, the phenotype, and the mechanism of action of dnIKK2-DC-induced regulatory cells and we evaluated their tolerogenic properties in vivo. Methods. Brown Norway (BN) transfected dnIKK2-DCs were cultured with Lewis (LW) lymphocytes in primary mixed lymphocyte reaction (MLR). CD4+ T cells were purified from primary MLR and incubated in secondary coculture MLR with LW lymphocytes. Phenotypic characterization was performed by fluorescence-activated cell sorting and real-time polymerase chain reaction. The tolerogenic potential of CD4+ T cells pre-exposed to dnIKK2-DCs was evaluated in vivo in a model of kidney allotransplantation. Results. CD4+ T cells pre-exposed to dnIKK2-DCs were CD4+CD25−/dim and expressed interleukin (IL)-10, transforming growth factor-beta, interferon-gamma, IL-2, and inducible nitric oxide synthase (iNOS). These cells (dnIKK2-Treg), cocultured (at up to 1:105 ratio) with a primary MLR, suppressed T-cell proliferation to alloantigens. The regulatory effect was cell-to-cell contact-independent since it was also observed in a transwell system. A nitric oxide synthase inhibitor significantly reverted dnIKK2-Treg-mediated suppression, whereas neutralizing antibodies to IL-10 and TGF-beta had no significant effect. DnIKK2-Treg given in vivo to LW rats prolonged the survival of a kidney allograft from BN rats (the donor rat strain used for generating DCs). Conclusions. DnIKK2-Treg is a unique population of CD4+CD25− T cells expressing high levels of iNOS. These cells potently inhibit T-cell response in vitro and induce prolongation of kidney allograft survival in vivo.

Extracellular vesicles derived from T regulatory cells suppress T cell proliferation and prolong allograft survival

We have previously shown that rat allogeneic DC, made immature by adenoviral gene transfer of the dominant negative form of IKK2, gave rise in-vitro to a unique population of CD4+CD25− regulatory T cells (dnIKK2-Treg). These cells inhibited Tcell response in-vitro, without needing cell-to-cell contact, and induced kidney allograft survival prolongation in-vivo. Deep insight into the mechanisms behind dnIKK2-Treg-induced suppression of Tcell proliferation remained elusive. Here we document that dnIKK2-Treg release extracellular vesicles (EV) riched in exosomes, fully accounting for the cell-contact independent immunosuppressive activity of parent cells. DnIKK2-Treg-EV contain a unique molecular cargo of specific miRNAs and iNOS, which, once delivered into target cells, blocked cell cycle progression and induced apoptosis. DnIKK2-Treg-EV-exposed T cells were in turn converted into regulatory cells. Notably, when administered in-vivo, dnIKK2-Treg-EV prolonged kidney allograft survival. DnIKK2-Treg-derived EV could be a tool for manipulating the immune system and for discovering novel potential immunosuppressive molecules in the context of allotransplantation.

Effect of seliciclib (CYC202, R-roscovitine) on lymphocyte alloreactivity and acute kidney allograft rejection in rat.

Background. T cell stimulation by alloantigens is followed by cell cycle progression, an event that is critically dependent on cyclin-dependent kinases. Methods. We conducted a study to evaluate whether the cyclin-dependent kinase inhibitor seliciclib affected rat lymph node cells (LNc) activation and proliferation induced by either concanavalin A or allogeneic splenocytes in vitro and studied the mechanisms underlying the suppressive effect. We also investigated the immunosuppressive properties of seliciclib in vivo. Results. Seliciclib completely inhibited in vitro proliferation of LNc and CD8+ T cells, in response to either concanavalin A or allogeneic splenocytes. The percentage of activated LNc was lower in mixed leukocyte reactions (MLR) added with seliciclib than in MLR added with vehicle. The percentages of viable and apoptotic cells at the end of MLR with seliciclib were comparable to those of MLR with vehicle. LNc pre-exposed in MLR to seliciclib did not respond to further stimulation with alloantigens, and neither IL-2 nor IL-15 restored proliferation. These data indicate that the inhibitory effect of seliciclib on T cell alloreactivity is not because of cytotoxic effect but is associated with induction of profound T cell anergy. LNc harvested at the end of the primary MLR with seliciclib did not suppress the proliferation of syngeneic LNc cells toward allogeneic splenocytes, thus excluding that seliciclib induced the formation of regulatory cells. Finally, seliciclib partially prolonged grafted animal survival in a rat model of fully major histocompatibility complex-mismatched kidney transplantation. Conclusions. Altogether these results document that seliciclib regulates lymphocyte reactivity and may exert an immunosuppressive effect in vivo in the setting of transplantation.