Skin Allograft Rejection Research Articles

NK Cells Regulate CD8 T Cell-Mediated Allogeneic Rejection in Immunocompetent Recipients across an MHC Class I Mismatched Barrier

Non-T natural killer (NK) cells are a population of granular lymphoid cells TcR- CD3− CD122+ (NK1.1+ in C57BL/6 mice and DX5+ in Balb/c mice). These innate lymphoid cells mature in the bone marrow and are responsible for killing viral-infected and transformed cells in a non-MHC restricted manner, without the need of prior sensitization due to a recognition mechanism based on the array of germline-encoded inhibitory and activating receptors expressed on the cell surface of NK cells [1]. NK cells modulate CD8 T cell expansion during homeostatic proliferation in response to lymphopenic conditions by killing activated T cells and competing for IL-15 with the proliferating CD8 effector T cells [2]. This NK cell behavior may respond to an adaptive evolutionary mechanism to prevent aggressive anti-viral immune responses during the acute phase of infection and thus attenuate immunopathology [3]. We set up an experimental mouse model of alloreactivity across an MHC class I barrier to evaluate the role of NK cells in CD8 T cell-mediated rejection of bm1 skin allografts in naïve B6 recipients. In this transplant setting, host CD8 T cells are the main effectors T cells involved in the rejection of class I MHC mismatched skin allografts preferentially through the direct pathway of antigen presentation with limited help from CD4 T cells primed by the indirect pathway of antigen presentation. As opposed to previous studies done in lymphopenic immunodeficient recipients [2], depletion of NK cells was performed in immunocompetent C57BL/6 recipients with or without CD8 T depletion, the former displaying homeostatic proliferation in response to lymphopenia due to antibody-mediated elimination of CD8 T cells. We observed that depletion of NK cells in both CD8-repleted and CD8-depleted naïve C57BL/6 immunocompetent mice accelerated significantly bm1 graft rejection compared to non-NK-depleted controls (p<0.0005) (Figure 1). Our data claims for precaution in solid organ transplantation under inducing protocols of extensive depletion of leukocytes, such as ATG or alentuzumab. The immunotherapeutic interventions that include the removal of NK cells may accelerate graft rejection and promote aggressive CD8 T cell cytotoxic responses, which could be refractory to current immunosuppression. It also suggests that enhancing NK-cell functional activity combined with CD8 T cell depletion under tolerogenic regimen that tolerizes CD4 T cells at the time of transplantation may contribute to allogeneic donor-specific tolerance induction by elimination of the direct pathway of antigen presentation and by regulating the recovery of CD8 T cells.Bibliographic

Sertoli cells for cell transplantation: pre-clinical studies and future perspectives.

Sertoli cells are located in the testes where they control several key functions in spermatogenesis. Over the past 30years, Sertoli cells have been upgraded from a simple scaffold-like structural system to a dynamic functional system of intercellular support that delivers potent immunomodulatory and trophic factors. Since the discovery of new Sertoli cell secretory products, these cells have been utilized in experimental cell transplantation and co-transplantation protocols aimed at treating both chronic inflammatory and degenerative disorders. For these reasons, this work reviews the application of both naked and microencapsulated Sertoli cells used in cell transplantation studies of several chronic or autoimmune diseases such as diabetes mellitus, Laron dwarfism, and Duchenne muscular dystrophy and in studies aimed at the prevention of skin allograft rejection.

Interferon-γ converts human microvascular pericytes into negative regulators of alloimmunity through induction of indoleamine 2,3-dioxygenase 1.

Early acute rejection of human allografts is mediated by circulating alloreactive host effector memory T cells (TEM). TEM infiltration typically occurs across graft postcapillary venules and involves sequential interactions with graft-derived endothelial cells (ECs) and pericytes (PCs). While the role of ECs in allograft rejection has been extensively studied, contributions of PCs to this process are largely unknown. This study aimed to characterize the effects and mechanisms of interactions between human PCs and allogeneic TEM. We report that unstimulated PCs, like ECs, can directly present alloantigen to TEM, but while IFN-γ-activated ECs (γ-ECs) show increased ability to stimulate alloreactive T cells, IFN-γ-activated PCs (γ-PCs) instead suppress TEM proliferation but not cytokine production or signaling. RNA sequencing analysis of PCs, γ-PCs, ECs, and γ-ECs reveal induction of indoleamine 2,3-dioxygenase 1 (IDO1) in γ-PCs to significantly higher levels than in γ-ECs that correlates with tryptophan depletion in vitro. Consistently, shRNA knockdown of IDO1 markedly reduces γ-PC-mediated immunoregulatory effects. Furthermore, human PCs express IDO1 in a skin allograft rejection humanized mouse model and in human renal allografts with acute T cell-mediated rejection. We conclude that immunosuppressive properties of human PCs are not intrinsic but instead result from IFN-γ-induced IDO1-mediated tryptophan depletion.

Herbal Components of a Novel Formula PSORI-CM02 Interdependently Suppress Allograft Rejection and Induce CD8+CD122+PD-1+ Regulatory T Cells.

A recipient usually rejects a transplanted organ and thus needs immunosuppressive treatments to prevent rejection. Achieving long-term allograft survival without continuous global immunosuppression is highly desirable in transplantation as long-term immunosuppression causes various side effects. Therefore, it is necessary to search for medicine with potentially less side effects. Traditional Chinese medicine PSORI-CM01 (Yin Xie Ling), a formula with seven natural herbs, has been used to treat patients with psoriasis. Here, we investigated a “sharpened” formula, PSORI-CM02 consisting of only five herbs from PSORI-CM01: Curcumae rhizoma, Radix paeoniae rubra, Rhizoma smilacis glabrae, Mume fructus, and Sarcandrae herba. We examined whether or not PSORI-CM02 would suppress alloimmunity and found that PSORI-CM02 significantly inhibited murine skin allograft rejection and reduced graft-infiltration of CD3+ T cells. Interestingly, omitting any single herbal component rendered the whole formula ineffective in suppression, indicating that these herbal components exert their effects cooperatively as a whole. Moreover, PSORI-CM02 increased CD8+CD122+PD-1+ Treg frequency with CD4+FoxP3+ Tregs remaining unchanged in recipient mice, whereas CsA reduced CD4+FoxP3+ Treg frequency. PSORI-CM02 also hindered CD11c+ DC maturation posttransplantation. Importantly, PSORI-CM02-induced CD8+CD122+PD-1+ Tregs were more potent in suppression of allograft rejection in Rag-/- mice than control Tregs. On the other hand, PSORI-CM02 suppressed T cell proliferation in vitro and reduced their phosphorylation of P70S6K and P50/P65, suggesting that it inhibits both mTOR and NFκB signaling pathways. It also increased IL-10 production while reducing IFNγ level in the supernatant of activated T cells co-cultured with CD8+CD122+PD-1+ Tregs. Furthermore, HPLC fingerprinting ruled out that PSORI-CM02 contained CsA or rapamycin. PSORI-CM02 also did not cause any illness and toxic injury in recipient mice. Thus, we demonstrate that PSORI-CM02 formula suppresses allograft rejection without toxicity.

Induction of immune tolerance and altered cytokine expression in skin transplantation recipients

Apoptotic lymphocytes can induce specific immune tolerance. This study aimed to investigate the influence of the preoperative transfusion of apoptotic lymphocytes on allograft survival after skin transplantation. In addition, we aimed to determine changes in IL-4, IL-10 and IFN-γ mRNA expression in the grafted skin. A total of 20 New Zealand white rabbits were randomly divided into two groups: lymphocyte preconditioned group (n = 10) and control group (n = 10). Rabbits in the lymphocyte preconditioned group were intravenously injected with 60Co γ-treated donor lymphocytes at seven days before the surgery. Rabbits in the control group were intravenously injected with normal lymphocytes at seven days before skin transplantation. The mRNA expression of IL-4, IL-10 and IFN-γ in the grafted skin was determined using real-time PCR. Skin allograft rejection time was 72.63 ± 2.65 days in the lymphocyte preconditioned group and 6.52 ± 0.64 days in the control group. IL-4, IL-10 and IFN-γ mRNA expression in the skin graft was 4.32 ± 0.48, 7.86 ± 0.56 and 2.63 ± 0.25 respectively in the lymphocyte preconditioned group, and 0.58 ± 0.07, 0.91 ± 0.14 and 8.68 ± 1.23 respectively in the control group. The preoperative transfusion of apoptotic lymphocytes induced immune tolerance in the grafted skin, as demonstrated by longer survival time of the grafts before rejection. This coincided with the increased mRNA expression of IL-4 and IL-10, and the decreased expression of IFN-γ.

Galectin-1 is required for the regulatory function of B cells

Galectin-1 (Gal-1) is required for the development of B cells in the bone marrow (BM), however very little is known about the contribution of Gal-1 to the development of B cell regulatory function. Here, we report an important role for Gal-1 in the induction of B cells regulatory function. Mice deficient of Gal-1 (Gal-1−/−) showed significant loss of Transitional-2 (T2) B cells, previously reported to include IL-10+ regulatory B cells. Gal-1−/− B cells stimulated in vitro via CD40 molecules have impaired IL-10 and Tim-1 expression, the latter reported to be required for IL-10 production in regulatory B cells, and increased TNF-α expression compared to wild type (WT) B cells. Unlike their WT counterparts, T2 and T1 Gal-1−/− B cells did not suppress TNF-α expression by CD4+ T cells activated in vitro with allogenic DCs (allo-DCs), nor were they suppressive in vivo, being unable to delay MHC-class I mismatched skin allograft rejection following adoptive transfer. Moreover, T cells stimulated with allo-DCs show an increase in their survival when co-cultured with Gal-1−/− T2 and MZ B cells compared to WT T2 and MZ B cells. Collectively, these data suggest that Gal-1 contributes to the induction of B cells regulatory function.

Daphnoretin modulates differentiation and maturation of human dendritic cells through down-regulation of c-Jun N-terminal kinase

Daphnoretin, an active constituent of Wikstroemia indica C.A. Meys, has been shown possessing anti-cancer activity. In this study, we examined the effect of daphnoretin on differentiation and maturation of human myeloid dendritic cells (DCs). After treatment with daphnoretin (0, 1.1, 3.3, 10 and 30μM) to initiate monocytes, the recovery rate of DCs was reduced in a dose-dependent manner. The mature DCs differentiated in the presence of daphnoretin had fewer and shorter dendrites. Daphnoretin modulated DCs differentiation and maturation in terms of lower expression of CD1a, CD40, CD83, DC-SIGN, and HLA-DR. Daphnoretin inhibited the allostimulatory activity of DCs on proliferation of naive CD4+CD45+RA+ T cell. On the mitogen-activated protein kinase, daphnoretin down-regulated the lipopolysaccharide-augmented expression of phosphorylated c-Jun N-terminal kinase (pJNK), but not p38 and extracellular signal-regulated kinase 1/2 (ERK1/2). Activation of JNK by anisomycin reversed the effect of daphnoretin on daphnoretin-inhibited pJNK expression and dendrite formation of DCs. In disease model related to maturation of DCs, daphnoretin suppressed the acute rejection of skin allografts in mice. Our results suggest that daphnoretin modulated differentiation and maturation of DCs toward a state of atypical maturation with impaired allostimulatory function and this effect may go through down-regulation of phosphorylated JNK.

Prevention of Donor Specific Antibody Production after Skin Allografting by Mobilization of Endogenous Stem Cells Using a Combination of AMD3100 and Low-dose FK506 in Rats

Background: We have developed a stem cell mobilizing strategy that enables long-term liver and kidney allograft survival without sustained immunosuppression in small and large animals using a safe combination of two FDA approved drugs AMD3100 and low-dose FK506 (AF). Furthermore, no increase in serum DSA levels was detected in animals displaying long-term survival even after donor skin grafts were rejected. Therefore, the purpose of this study is to determine if AF combination treatment prevents de novo DSA production in a rat model of skin allograft rejection. Methods: Split thickness skin allografts from Dark Agouti (DA, RT1a) rats were transplanted into adult Lewis (RT11) recipients. Recipient animals were randomly divided into AF treatment group (AMD3100 1 mg/kg and FK506 0.1 mg/kg, s.c., every other day for 14 days) and control group (same volume of saline, s.c.). Serum levels of DSA including both IgG and IgM were measured by flow cytometry at 14 days, 1 and 2 months after skin transplantation. The sensitization to donor antigens in Lewis rats at 2 months after skin allografting was further confirmed by transplanting donor DA kidneys. Full dose FK506 (1 mg/kg/day, s.c) was given to prevent acute cellular rejection after kidney transplantation. Results: Skin allografts were rejected in 8–10 days after transplantation in both groups. Serum levels of DSA-IgG increased 6 to 10 folds in control animals (n = 10), but only 2 to 3 folds in animals treated with AF combination (n = 11) at 1 month and remained at similar levels at 2 months after skin transplantation. All control animals (n = 5) died within 7 days after kidney transplantation. DSA deposition and AMR in kidney allografts were confirmed with signs of IgG deposition in and around glomeruli with C4d deposition on peritubular capillaries. In contrast, about 64% (7/11) animals with AF treatment after skin allografting survived over three weeks without antibody mediated rejection (AMR) and no increase in serum levels of DSA at 14 days after kidney transplantation. Conclusion: Mobilizing endogenous stem cells with AF combination treatment does not prolong skin allograft survival but prevents de novo DSA production after allograft rejection. AF treatment may inhibit B cell sensitization, prevent de novo DSA production and improve long-term allograft function after organ transplantation.

Transient Anti-CD45RC mAb Treatment Induces Specific Transplant Tolerance Through Potentiation of Tregs

Introduction: The main goal in transplantation is to induce specific rather than general immunosuppression. The CD45 protein is an essential regulator of T and B cell antigen receptor signaling. We have previously shown that T cells expressing low levels of CD45RC have strong immunoregulatory properties while T cells expressing high levels of CD45RC are essentially effector cells. Thus, we investigated the effect of depleting CD45RC+ cells on graft survival. Methods: Tregs were analyzed for the expression of CD45 isoforms by flow cytometry. LEW-1A rats were grafted in a heterotopic position with a LEW-1 W heart. NSG mice were 2Gy-irradiated or grafted with human skin and injected with 5x106 or 1,5x107 human PBMCs respectively. Animals were treated with 0.8 mg/kg/2.5d for 20d of anti-CD45RC mAb (OX22 or MT2 clones) or isotype. Humoral responses were assessed after KLH + CFA or exogenous red blood cells immunization. FACS Aria-sorted Tregs were i.v. transferred in 4,5Gy-irradiated recipients. CD45RClow/- Tregs were analyzed by RNA sequencing. Results: First, we have shown that CD45RC is the only CD45-isoform not expressed by Foxp3+ Tregs both in human and rat. Interestingly, transient treatment with anti-CD45RC Mabs induced transplant tolerance in a fully mismatch cardiac allograft model in rat. Importantly, this treatment prevented specifically anti-donor humoral responses while preserved primary and memory responses against cognate antigens. As expected, anti-CD45RC Mabs induced rapid cell death of CD45RC+ T cells through intrinsic cell signaling while preserved CD45RClow/- Tregs. Furthermore, the short-term treatment induced a transient homeostatic proliferation and sustained transcriptional changes in long-term CD8+ and CD4+ CD45RClow/- Tregs that maintained an indefinite, dominant and donor-specific tolerance, as adoptive transfer of Tregs succeeded in this allograft combination only. Finally, we translated these findings to human, in humanized mice models of xenogeneic GVHD and human skin allograft rejection. We demonstrated that ex vivo depletion of CD45RC+ PBMCs prevented development of GVHD, and that transient treatment with anti-human CD45RC Mabs delayed GVHD development and allograft rejection. Conclusion: This is the first proof of concept that targeting CD45RC with short-term Mabs treatment is an efficient innovative strategy to induce a donor-specific tolerance in transplantation without any other treatment.

Mouse nidovirus LDV infection alleviates graft versus host disease and induces type I IFN-dependent inhibition of dendritic cells and allo-responsive T cells.

IntroductionViruses have developed multiple mechanisms to alter immune reactions. In 1969, it was reported that lactate dehydrogenase‐elevating virus (LDV), a single stranded positive sense mouse nidovirus, delays skin allograft rejection and inhibits spleen alterations in graft versus host disease (GVHD). As the underlying mechanisms have remained unresolved and given the need for new therapies of this disease, we reassessed the effects of the virus on GVHD and tried to uncover its mode of action.MethodsGVHD was induced by transfer of parent (B6) spleen cells to non‐infected or LDV‐infected B6D2F1 recipients. In vitro mixed‐lymhocyte culture (MLC) reactions were used to test the effects of the virus on antigen‐presenting cells (APC) and responder T cells.ResultsLDV infection resulted in a threefold increase in survival rate with reduced weight loss and liver inflammation but with the establishment of permanent chimerism that correlated with decreased interleukine (IL)‐27 and interferon (IFN)γ plasma levels. Infected mice showed a transient elimination of splenic CD11b+ and CD8α+ conventional dendritic cells (cDCs) required for allogeneic CD4 and CD8 T cell responses in vitro. This drop of APC numbers was not observed with APCs derived from toll‐like receptor (TLR)7‐deficient mice. A second effect of the virus was a decreased T cell proliferation and IFNγ production during MLC without detectable changes in Foxp3+ regulatory T cell (Tregs) numbers. Both cDC and responder T cell inhibition were type I IFN dependent. Although the suppressive effects were very transient, the GVHD inhibition was long‐lasting.ConclusionA type I IFN‐dependent suppression of DC and T cells just after donor spleen cell transplantation induces permanent chimerism and donor cell implantation in a parent to F1 spleen cell transplantation model. If this procedure can be extended to full allogeneic bone marrow transplantation, it could open new therapeutic perspectives for hematopoietic stem cell transplantation (HSCT).

Suppression of allograft rejection by CD8+CD122+PD-1+ Tregs is dictated by their Fas ligand-initiated killing of effector T cells versus Fas-mediated own apoptosis

Mounting evidence has shown that naturally occurring CD8+CD122+ T cells are regulatory T cells (Tregs) that suppress both autoimmunity and alloimmunity. We have previously shown that CD8+CD122+PD-1+ Tregs not only suppress allograft rejection, but also are more potent in suppression than conventional CD4+CD25+ Tregs. However, the mechanisms underlying their suppression of alloimmunity are not well understood. In an adoptive T-cell transfer model of mice lacking lymphocytes, we found that suppression of skin allograft rejection by CD8+CD122+PD-1+ Tregs was mostly dependent on their expression of Fas ligand as either lacking Fas ligand or blocking it with antibodies largely abolished their suppression of allograft rejection mediated by transferred T cells. Their suppression was also mostly reversed when effector T cells lacked Fas receptor. Indeed, these FasL+ Tregs induced T cell apoptosis in vitro in a Fas/FasL-dependent manner. However, their suppression of T cell proliferation in vitro was dependent on IL-10, but not FasL expression. Furthermore, adoptive transfer of CD8+CD122+PD-1+ Tregs significantly extended allograft survival even in wild-type mice if Tregs lacked Fas receptor or if recipients received recombinant IL-15, as these two measures synergistically expanded adoptively-transferred Tregs in recipients. Thus, this study may have important implications for Treg therapies in clinical transplantation.

The ligands of translocator protein inhibit human Th1 responses and the rejection of murine skin allografts.

The translocator protein (TSPO) ligands affected inflammatory and immune responses. However, the exact effects of TSPO ligands on Th1 responses invitro and invivo are still unclear. In the present study, we found that TSPO ligands, FGIN1-27 and Ro5-4864, suppressed the cytokine production in a dose-dependent manner by purified human CD4+ T-cells from peripheral blood mononuclear cells (PBMCs) after stimulation. TSPO ligands inhibited the production of interferon γ (IFN-γ) by memory CD4+ T-cells and the differentiation of naïve CD4+ T-cells into Th1 cells via suppressing the activity of the corresponding transcription factors as indicated by reduced expression of T-bet and down-regulation of STAT1, STAT4 and STAT5 phosphorylation. TSPO ligands suppressed cell proliferation and activation of CD4+ T-cells by the inhibition of TCR signal transduction including membrane proteins: Zap, Lck, Src; cytoplasm proteins: Plcγ1, Slp-76, ERK, JNK and the nucleoproteins: c-Jun and c-Fos. In addition, FGIN1-27 inhibited mixed lymphocyte reactions by human or murine cells. After the transplantation of allogeneic murine skin, injection of FGIN1-27 into mice prevented graft rejection by inhibition of cell infiltration and IFN-γ production. Taken together, our data suggest that TSPO ligands inhibit Th1 cell responses and might be novel therapeutic medicine for the treatment of autoimmune diseases and prevention of transplant rejection.

Inhibition of Histone Deacetylase 6 Reveals a Potent Immunosuppressant Effect in Models of Transplantation

Current transplant immunosuppression regimens have numerous limitations. Recent evidence suggests histone deacetylase inhibitors (HDACis) may represent a class of drug with immunosuppressive properties. This study compares cyclosporin A (CyA) with the pan-HDACi suberoylanilide hydroxamic acid (SAHA) and a novel HDAC6-specific inhibitor (KA1010) in models of alloreactivity. Proliferation and mixed lymphocyte reaction (MLR)-based assays were used to determine the immunosuppressive effect of compounds, and a murine model of allogeneic skin transplantation was adopted to assess the in vivo effects of HDAC6 inhibition. KA1010 displayed superior inhibitory effects on the activation of peripheral mononuclear cells using in vitro models of transplantation. In a 1-way MLR, KA1010 (5 μΜ) reduced parent cell proliferation from 92% to 64% (P = 0.001). A 2-way MLR, adopting IFN-γ production as a marker of alloresponse, resulting in up to 91% reduction. Dose-response curves revealed dose-dependent profiles with greater potency of HDACis over CyA (IC50 values of 82.0 nM and 13.4 nM for KA1010 and SAHA).Mice treated with KA1010 displayed no significant features of skin allograft rejection upon histological analysis at 70 days and graft survival of 80% in subjects treated with 160 mg/kg. Immunological assessment, revealed a significant increase in CD4CD25forkhead box P3 regulatory T cells (from 18% to 25%, P = 0.0002) and a corresponding reduction in CD4 T cells (from 58% to 42%, P = 0.0009). HDAC6 may represent an optimal target for future immunosuppressant therapeutics with a particular role in transplantation. In this article, we have demonstrated a superior immunosuppressive effect of KA1010 over both CyA and SAHA, in the models of allotransplantation adopted.

Ribosome-inactivating Proteins from Root Tubers and Seeds of Trichosan-thes kirilowii and Other Trichosanthes Species.

Ribosome-inactivating proteins have been isolated from Trichosanthes kirilowii root tubers and seeds, including trichosanthin, karasurin and T 33 from root tubers and trichosanthrip, trichokirin, alpha-kirilowin, beta-kirilowin and trichoanguin from seeds. The aforementioned proteins show structural and functional similarities. Among them trichosanthin is the best known and most intensely studied. Trichosanthin manifests anticancer activity in vitro and in tumor bearing mice against a variety of cancers/cancer cell lines. It also exhibits anti-HIV-1 and anti-HSV-1 activities. Trichosanthin has been found to be useful for treatment of cesarean scar pregnancies and ectopic pregnancy, and for preventing acute rejection of major histocompatibility complex-mismatched mouse skin allograft. Trichosanthin selectively lesions some neurons and thus can be used in neuroscience research.

The composition of the microbiota modulates allograft rejection.

Transplantation is the only cure for end-stage organ failure, but without immunosuppression, T cells rapidly reject allografts. While genetic disparities between donor and recipient are major determinants of the kinetics of transplant rejection, little is known about the contribution of environmental factors. Because colonized organs have worse transplant outcome than sterile organs, we tested the influence of host and donor microbiota on skin transplant rejection. Compared with untreated conventional mice, pretreatment of donors and recipients with broad-spectrum antibiotics (Abx) or use of germ-free (GF) donors and recipients resulted in prolonged survival of minor antigen-mismatched skin grafts. Increased graft survival correlated with reduced type I IFN signaling in antigen-presenting cells (APCs) and decreased priming of alloreactive T cells. Colonization of GF mice with fecal material from untreated conventional mice, but not from Abx-pretreated mice, enhanced the ability of APCs to prime alloreactive T cells and accelerated graft rejection, suggesting that alloimmunity is modulated by the composition of microbiota rather than the quantity of bacteria. Abx pretreatment of conventional mice also delayed rejection of major antigen-mismatched skin and MHC class II-mismatched cardiac allografts. This study demonstrates that Abx pretreatment prolongs graft survival, suggesting that targeting microbial constituents is a potential therapeutic strategy for enhancing graft acceptance.

Anthony David Barnes

Anthony David Barnes (“Tony”) was in the vanguard of renal transplantation in the UK and made major contributions to the establishment of the specialty. As a teenager during the second...

Incomplete clonal deletion as prerequisite for tissue-specific minor antigen tolerization.

Central clonal deletion has been considered the critical factor responsible for the robust state of tolerance achieved by chimerism-based experimental protocols, but split-tolerance models and the clinical experience are calling this assumption into question. Although clone-size reduction through deletion has been shown to be universally required for achieving allotolerance, it remains undetermined whether it is sufficient by itself. Therapeutic Treg treatment induces chimerism and tolerance in a stringent murine BM transplantation model devoid of myelosuppressive recipient treatment. In contrast to irradiation chimeras, chronic rejection (CR) of skin and heart allografts in Treg chimeras was permanently prevented, even in the absence of complete clonal deletion of donor MHC-reactive T cells. We show that minor histocompatibility antigen mismatches account for CR in irradiation chimeras without global T cell depletion. Furthermore, we show that Treg therapy-induced tolerance prevents CR in a linked suppression-like fashion, which is maintained by active regulatory mechanisms involving recruitment of thymus-derived Tregs to the graft. These data suggest that highly efficient intrathymic and peripheral deletion of donor-reactive T cells for specificities expressed on hematopoietic cells preclude the expansion of donor-specific Tregs and, hence, do not allow for spreading of tolerance to minor specificities that are not expressed by donor BM.

239. Induction of Allograft Immune Tolerance with Bioengineered Thymus Organoids

One of the major obstacles in solid organ transplantation is to establish immune tolerance of allografts. While immunosuppressive drugs can prevent graft rejection to a certain degree, their efficacies are limited, impermanent, and associated with severe side effects. As a primary immune organ essential to adaptive immunity, the thymus continuously generates a diverse population of naive T-cells, which can effectively react to invading pathogens, but remains unresponsive to self-antigens. Many factors (e.g. infection, irradiation, drug treatments, or aging) can irreversibly compromise thymic function, resulting in immune deficiency, cancer, autoimmunity and other immunodysregulatory diseases. While numerous efforts have been made to modulate/rejuvenate thymic function, manipulating the thymus, either in vitro or in vivo, proves to be difficult. The major challenge is to reproduce its unique extracellular matrix microenvironment that is critical for the survival and function of thymic epithelial cells (TECs). TECs are the predominant population of thymic stromal cells that are essential for T-cell lineage determination and maturation. TECs cultured in the traditional 2-D culture rapidly lose their molecular properties and fail to grow, which prohibits them from undergoing genetic modification. We have recently developed a thymus decellularization technique, which allows us to reconstruct a functional thymus organoid de novo with isolated TECs. The 3-D thymic scaffolds can support the survival of TECs in vitro, and maintain their unique molecular properties. When transplanted into athymic nude mice, the bioengineered thymus organoids could effectively promote the homing of lymphocyte progenitors and support the development of a diverse, self-tolerant T-cell repertoire. The thymus-reconstructed nude mice could promptly reject skin allografts, and were able to mount antigen-specific humoral responses against ovalbumin upon immunization. Notably, tolerance to allogeneic skin grafts could be achieved by transplanting thymus organoids constructed with either TECs co-expressing both syngeneic and allogenic MHCs, or mixtures of donor and recipient TECs. Our results demonstrate the technical feasibility of inducing donor-specific allogeneic tolerance with bioengineered thymus organoids and highlight the clinical implications of this thymus reconstruction technique in solid organ transplantation and regenerative medicine.

Donor-antigen Inoculation in the Testis Promotes Skin Allograft Acceptance Induced by Conventional Costimulatory Blockade via Induction of CD8 + CD122+ and CD4 + CD25+ Regulatory T Cells.

Immune responses are somewhat suppressed in immune privileged sites, including the testes, which provide a preexisting opportunity to prolong allograft survival. Previous studies have shown that intratesticular islet allografts enjoy extended survival even without any immunosuppression. However, it is unknown if testicular immune privilege can be exploited to prolong the survival of a solid allograft, including the skin, because it is impractical to implant a solid tissue in human testes. To immunize recipient mice, splenocytes from BALB/c mice were injected into the testis of C57BL/6 recipients 1 week before skin transplantation. CD8 + CD122+ and CD4 + FoxP3+ regulatory T [Treg] cells were quantified by fluorescence-activated cell sorting. Although donor-antigen inoculation alone did not delay skin allograft rejection, it significantly extended the allograft survival when combined with CD40/CD40L or B7/CD28 costimulatory blockade and further induced long-term skin allograft acceptance when both costimulatory pathways were blocked. Similarly, donor-antigen inoculation suppressed alloreactive T cell proliferation in draining lymph nodes of skin recipients in the presence of the same costimulatory blockade. Interestingly, donor-antigen inoculation via intratesticular injection increased CD8 + CD122+, but not CD4 + FoxP3+, Treg numbers after transplantation. However, both CD8 + CD122+ and CD4 + CD25+ Treg cells induced by donor-antigen inoculation and the costimulatory blockade were more potent in suppression than that induced without the inoculation. Depletion of CD8+ or CD25+ T cells largely abrogated long-term skin allograft survival induced by donor-antigen inoculation and the costimulatory blockade. Intratesticular inoculation with donor antigens promotes long-term skin allograft survival induced by conventional costimulatory blockade via the induction of both CD8 + CD122+ and CD4 + CD25+ Treg cells.

Ouro proteins are not essential to tail regression during Xenopus tropicalis metamorphosis.

Tail regression is one of the most prominent transformations observed during anuran metamorphosis. A tadpole tail that is twice as long as the tadpole trunk nearly disappears within 3 days in Xenopus tropicalis. Several years ago, it was proposed that this phenomenon is driven by an immunological rejection of larval-skin-specific antigens, Ouro proteins. We generated ouro-knockout tadpoles using the TALEN method to reexamine this immunological rejection model. Both the ouro1- and ouro2-knockout tadpoles expressed a very low level of mRNA transcribed from a targeted ouro gene, an undetectable level of Ouro protein encoded by a target gene and a scarcely detectable level of the other Ouro protein from the untargeted ouro gene in tail skin. Furthermore, congenital athymic frogs were produced by Foxn1 gene modification. Flow cytometry analysis showed that mutant frogs lacked splenic CD8(+) T cells, which play a major role in cytotoxic reaction. Furthermore, T-cell-dependent skin allograft rejection was dramatically impaired in mutant frogs. None of the knockout tadpoles showed any significant delay in the process of tail shortening during the climax of metamorphosis, which shows that Ouro proteins are not essential to tail regression at least in Xenopus tropicalis and argues against the immunological rejection model.