Cécile Guillot

Tolerance to Cardiac Allografts Via Local and Systemic Mechanisms After Adenovirus-Mediated CTLA4Ig Expression

Blockade of the CD28/B7 T cell costimulatory pathway prolongs allograft survival and induces tolerance in some animal models. We analyzed the efficacy of a CTLA4Ig-expressing adenovirus in preventing cardiac allorejection in rats, the mechanisms underlying heart transplant acceptance, and whether the effects of CTLA4Ig were restricted to the graft microenvironment or were systemic. CTLA4Ig gene transfer into the myocardium allowed indefinite graft survival (>100 days vs 9 ± 1 days for controls) in 90% of cases, whereas CTLA4Ig protein injected systemically only prolonged cardiac allograft survival (by up to 22 days). CTLA4Ig could be detected in the graft and in the serum for at least 1 year after gene transfer. CTLA4Ig gene transfer induced local intragraft immunomodulation at day 5 after transplantation, as shown by decreased expression of the IL-2R and MHC II Ags; decreased levels of mRNA encoding for IFN-γ, inducible NO synthase, and TGF-β; and inhibited proliferative responses of graft-infiltrating cells. Systemic immune responses were also down-modulated, as shown by the suppression of Ab production against donor alloantigens and cognate Ags, up to at least 120 days after gene transfer. Alloantigenic and mitogenic proliferative responses of graft-infiltrating cells and total splenocytes were inhibited and were not reversed by IL-2. In contrast, lymph node cells and T cells purified from splenocytes showed normal proliferation. Recipients of long-term grafts treated with adenovirus coding for CTLA4Ig showed organ and donor-specific tolerance. These data show that expression of CTLA4Ig was high and long lasting after adenovirus-mediated gene transfer. This expression resulted in down-modulation of responses against cognate Ags, efficient suppression of local and systemic allograft immune responses, and ultimate induction of donor-specific tolerance.

Prolonged Blockade of CD40-CD40 Ligand Interactions by Gene Transfer of CD40Ig Results in Long-Term Heart Allograft Survival and Donor-Specific Hyporesponsiveness, But Does Not Prevent Chronic Rejection

Previous work on blockade of CD40-CD40 ligand interaction in mice and primates with anti-CD40 ligand mAbs has resulted in a moderate prolongation of allograft survival without the development of true allograft tolerance. In this study, we show in rats that adenovirus-mediated gene transfer of CD40Ig sequences into the graft resulted in prolonged (>200 days) expression of CD40Ig and in long-term (>300 days) survival. Recipients expressing CD40Ig displayed strongly (>90%) inhibited mixed leukocyte reactions and alloantibody production at early (days 5 and 17) and late time points (>100 day) after transplantation, but showed limited inhibition of leukocyte infiltration and cytokine production as evaluated by immunohistology at early time points (day 5). Recipients of long-surviving hearts showed donor-specific hyporesponsiveness since acceptance of second cardiac allografts was donor specific. Nevertheless, long-term allografts (>100 days) displayed signs of chronic rejection vasculopathy. Occluded vessels showed leukocyte infiltration, mainly composed of CD4+ and CD8+ cells, macrophages, and mast cells. These recipients also showed antidonor CTL activity. Recipients expressing CD40Ig did not show nonspecific immunosuppression, as they were able to mount anticognate immune responses that were partially inhibited at early time points and were normal thereafter. We conclude that gene transfer-mediated expression of CD40Ig resulted in a highly efficient inhibition of acute heart allograft rejection in rats. This treatment induced donor-specific inhibition of certain alloreactive mechanisms in the short-, but not the long-term, which resulted in long-term survival of allografts concomitant with the development of chronic rejection.

Interleukin-10 produced by recombinant adenovirus prolongs survival of cardiac allografts in rats

Interleukin-10 (IL-10) and interleukin-4 (IL-4), two Th2-derived cytokines, are molecules with anti-inflammatory and immunodeviating properties whose direct expression in allografts may prolong graft survival. Recombinant adenoviruses represent efficient vectors for gene tranfer in quiescent cells in vivo. Adenoviral vectors encoding rat IL-10 (AdIL-10), rat IL-4 (AdIL-4) or β-galactosidase (AdlacZ) or without transgene (Addl324) were injected directly into rat hearts at the time of transplantation in order to test their potential to prolong heart allograft survival. Expression of vectorized sequences was confirmed in heart biopsies, and kinetic analysis of β-galactosidase showed transient expression. Cardiac allograft survival was significantly prolonged after administration of 109 p.f.u. of AdIL-10 (16.6 ± 3.2 days, P < 0.05), but not adil-4 (9.8 ± 1.6 days), compared with addl324-treated (9.3 ± 3.3 days) or untreated groups (7.8 ± 1.5 days). immunohistochemical analysis of allografts after gene transfer of il-10 showed that leukocyte infiltration was quantitatively equivalent to that seen in control groups but with a strong tendency towards lower levels of cd8+ cells. Importantly, adenovirus-derived IL-10 modified the functional status of leukocytes by inducing a significant decrease in IFN-γ production but significantly increased transforming-growth factor β1 (TGF-β1) expression within the grafts compared with those treated with Addl324. These results show that expression of IL-10 by rat hearts after gene transfer mediated by an adenoviral vector decreases allogeneic immune responses and allows prolongation of allograft survival.

The Role of TNF-Related Activation-Induced Cytokine–Receptor Activating NF-κB Interaction in Acute Allograft Rejection and CD40L-Independent Chronic Allograft Rejection

We analyzed the role of TNF-related activation-induced cytokine (TRANCE), a member of the TNF family expressed on activated T cells that shares functional properties with CD40L, and its receptor-activating NF-κB (RANK) which is mostly expressed on mature dendritic cells, during allogenic responses in vivo using a rodent heart allograft model. TRANCE mRNA was strongly up-regulated in acutely rejected allografts on days 4 and 5 posttransplantation whereas RANK was detected as early as day 1 but did not show further up-regulation during the first week. Immunofluoresence analyses of heart allografts showed that 80 and 100% of TRANCE and RANK-expressing cells were T cells and APCs, respectively. We show for the first time that short-term TRANCE blockade using a mouse RANKIg fusion molecule can significantly prolong heart allograft survival in both rat and mouse models. Similarly, rat heart allografts transduced with a RANKIg encoding recombinant adenovirus exhibited a significant prolongation of survival (14.3 vs 7.6 days, p < 0.0001). However, TRANCE blockade using RANKIg did not appear to inhibit allogeneic T and B cell priming humoral responses against RANKIg. Interestingly, TRANCE blockade induced strong up-regulation of CD40 ligand (CD40L) mRNA in allografts. Combined CD40L and TRANCE blockade resulted in significantly decreased chronic allograft rejection lesions as well as allogeneic humoral responses compared with CD40L blockade alone. We conclude that TRANCE-RANK interactions play an important role during acute allograft rejection and that CD40L-independent allogeneic immune responses can be, at least in part, dependent on the TRANCE pathway of costimulation.

Lethal Hepatitis After Gene Transfer of IL-4 in the Liver Is Independent of Immune Responses and Dependent on Apoptosis of Hepatocytes: A Rodent Model of IL-4-Induced Hepatitis

The putative role of IL-4 in human and animal models of hepatitis has not yet been directly determined. We now report that direct expression of IL-4 in the liver of rats or mice using recombinant adenoviruses coding for rat or mouse IL-4 (AdrIL-4 and AdmIL-4, respectively) results in a lethal, dose-dependent hepatitis. The hepatitis induced by IL-4 was characterized by hepatocyte apoptosis and a massive monocyte/macrophage infiltrate. IL-4-induced hepatitis was independent of T cell-mediated immune responses. Hepatitis occurred even after gene transfer of IL-4 into nude rats, CD8-depleted rats, cyclosporine A-treated rats, or recombinase-activating gene 2−/− immunodeficient mice. Peripheral depletion of leukocytes using high doses of cyclophosphamide, and/or the specific depletion of liver macrophages with liposome-encapsulated dichloromethylene diphosphonate in rats did not block lethal IL-4-induced hepatitis. Direct transduction of hepatocytes with adenoviruses was not essential, since injection of AdrIL-4 into the hind limb induced an identical hepatitis. Finally, primary rat hepatocytes in culture also showed apoptosis when cultured in the presence of rIL-4. IL-4-dependent hepatitis was associated with increases in the intrahepatic levels of IFN-γ, TNF-α, and Fas ligand. Administration of AdmIL-4 to IFN-γ, TNF-α receptor type I, or TNF-α receptor type II knockout mice also resulted in lethal hepatitis, whereas a moderate protection was observed in Fas-deficient lpr mice. IL-4-dependent hepatocyte apoptosis could be abolished by treatment with caspase inhibitory peptides. Our results thus demonstrate that IL-4 causes hepatocyte apoptosis, which is only partially dependent on the activation of Apo-1-Fas signaling and is largely independent of any immune cells in the liver.

Gene therapy in transplantation in the year 2000 : Moving towards clinical applications?

Transplantation faces several major obstacles that could be overcome by expression of immunomodulatory proteins through application of gene therapy techniques. Gene therapy strategies to prolong graft survival involve gene transfer of immunosuppressive or graft-protecting molecules. Very promising results have been obtained in small animal experimental models with inhibitors of co-stimulatory signals on T cells, immunosuppressive cytokines, donor major histocompatibility antigens and regulators of cell apoptosis or oxidative stress. The application of gene therapy techniques to transplantation offers a great experimental and therapeutic potential. Local production of immunosuppressive molecules may increase their therapeutic efficiency and reduce their systemic effects. When compared with other clinical situations, gene therapy in transplantation offers several potential advantages. Gene transfer into the graft can be performed ex vivo, during the transit between the donor and the recipient, thus avoiding many of the hurdles encountered with in vivo gene transfer. Furthermore, the difficulties associated with immune responses to the gene transfer vectors and transient gene expression may be easier to overcome when gene therapy protocols are applied to transplantation than when applied to other clinical situations. The next century should witness a rapid increase in the application of gene therapy techniques to large animal pre-clinical models of transplantation and later to clinical trials.

Adenovirus-mediated CD40Ig expression attenuates chronic vascular rejection lesions in an aorta allotransplantation model

THE ACTIVATION of T cells is a key event leading to chronic vascular rejection. The costimulatory pathway involving CD40-CD40L interactions mediates both T-cell and antigen-presenting cell (APC) activation. CD40-expressing cells such as macrophages, vascular smooth muscle cells, endothelial cells, and B cells receive activation signals following CD40L binding. Blockade of CD40-CD40L pathway using mAb prevents or delays acute allograft rejection processes. However, in murine studies, antiCD40L mAb treatment did not abrogate the development of chronic rejection unless combined with other treatments. CD40Ig is a receptor fusion protein including the murine extracellular portion of the CD40 receptor and the human Fc portion of IgG1 that blocks CD40-CD40L interactions. We hypothesized that local and sustained expression of CD40Ig through adenovirus-mediated gene delivery would prevent or attenuate the development of graft arteriosclerosis.