New strategies for allogeneic BMT

In humans, the success rate of BMT across major histocompatibility complex (MHC) barriers is lowered by graft-versus-host disease (GvHD), graft rejection and incomplete T-cell recovery. To prevent GvHD, we attempted to minimize the contamination of bone marrow cells (BMCs) with T cells from the peripheral blood when donor BMCs were collected, finally establishing a new 'Perfusion Method' using cynomolgus monkeys. There was significantly less contamination of BMCs with T cells in this method (<6%) than in the conventional 'Aspiration Method' (>20%) consisting of multiple aspirations of BMCs from the iliac crest. Using radio-sensitive and chimerism-resistant MRL/lpr mice, we also established a new method for allogeneic (allo) BMT and organ allografts. In this method, whole BMCs, containing a small number of T cells and mesenchymal stem cells (MSCs), were directly injected into the bone marrow cavity (intrabone marrow [IBM]-BMT). MRL/lpr mice treated with IBM-BMT survived more than 2 years without showing the symptoms of autoimmune diseases. IBM-BMT thus has several advantages: (i) no GvHD develops even if T cells are not depleted from BMCs; (ii) no graft failure occurs even if the dose of radiation as the conditioning regimen for allo BMT is reduced to 5Gy x 2; (iii) hemopoietic recovery is rapid; and (iv) the restoration of T-cell functions is quick and complete even in donor-recipient combinations across MHC barriers. We believe that these strategies for allo BMT and organ allografts herald a new era in transplantation, and that they would be helpful in allogeneic HSCT of autoimmune diseases.     

Successful allogeneic bone marrow transplantation. Crucial roles of stromal cells in prevention of graft rejection.

We have previously found that a major histocompatibility complex (MHC) restriction exists between pluripotent hemopoietic stem cells (P-HSCs) and stromal cells. Based on this finding, we have recently found using chimerism-resistant mouse combinations that successful allogeneic (allo) BMT can be executed by recruiting donor bone marrow stromal cells. The strategies include donor bone grafts under the skin, injection of whole bone marrow cells (BMCs) including stromal cells via the portal vein (PV), and injection of whole BMCs directly into the bone marrow cavity (intra-bone marrow [IBM] injection). In this paper, we show how stromal cells play crucial roles in overcoming chimerism-resistant allo BMT.     

New strategies for BMT and organ transplantation

Bone marrow transplantation (BMT) is now one of the most powerful strategies for the treatment of hematologic disorders (leukemia, aplastic anemia, etc), congenital immunodeficiencies, metabolic disorders, and also autoimmune diseases. Using various autoimmune-prone mice, we have previously shown that conventional allogeneic (allo) BMT can be used to treat a range of autoimmune diseases. We have very recently established new strategies for BMT and organ grafts. For BMT, to minimize the contamination of BMCs with T cells from the peripheral blood, we developed, using cynomolgus monkeys, a “Perfusion Method” to replace the conventional aspiration method for collecting bone marrow cells (BMCs). We injected the BMCs collected this way directly into the bone marrow cavity of recipients that had received fractionated irradiation (intra-bone marrow [IBM] injection). This “IBM-BMT” was found to be effective in treating autoimmune diseases in radiation-sensitive and chimeric-resistant MRL/Ipr mice. In addition, this strategy was found to be applicable for the transplantation of organs, such as the skin and pancreas islets in mice and rats. We believe that these strategies for BMT and organ transplantation herald a new era in transplantation.     

New strategies for BMT and organ transplantation

Bone marrow transplantation (BMT) is now one of the most powerful strategies for the treatment of hematologic disorders (leukemia, aplastic anemia, etc), congenital immunodeficiencies, metabolic disorders, and also autoimmune diseases. Using various autoimmune-prone mice, we have previously shown that conventional allogeneic (allo) BMT can be used to treat a range of autoimmune diseases. We have very recently established new strategies for BMT and organ grafts. For BMT, to minimize the contamination of BMCs with T cells from the peripheral blood, we developed, using cynomolgus monkeys, a "Perfusion Method" to replace the conventional aspiration method for collecting bone marrow cells (BMCs). We injected the BMCs collected this way directly into the bone marrow cavity of recipients that had received fractionated irradiation (intra-bone marrow [IBM] injection). This "IBM-BMT" was found to be effective in treating autoimmune diseases in radiation-sensitive and chimeric-resistant MRL/lpr mice. in addition, this strategy was found to be applicable for the transplantation of organs, such as the skin and pancreas islets in mice and rats. We believe that these strategies for BMT and organ transplantation herald a new era in transplantation.     

New strategies for BMT,organ transplantation,and regeneration therapy

Bone marrow transplantation (BMT) is becoming a powerful strategy for the treatment of hematologic disorders, congenital immunodeficiencies, metabolic disorders and also autoimmune diseases. We have previously found using various animal models for spontaneous autoimmune diseases, that allogeneic bone marrow transplantation (allo BMT) can be used to prevent and treat various autoimmune diseases. In addition, we have found that autoimmune diseases are stem cell disorders. However, in MRL/lpr mice, which are radiosensitive (<8.5 Gy), we found that conventional BMT had only a transient effect on autoimmune diseases, which were found to recur. Therefore, we concentrated on discovering new strategies to prevent and treat autoimmune diseases in the radiosensitive and chimeric-resistant MRL/lpr mouse. Using MRL/lpr mice, we established a new method for allo BMT. In this method, whole bone marrow cells (BMCs), containing a small number of T cells and mesenchymal stem cells (MSCs), were directly injected into the bone marrow cavity (intra-bone marrow [IBM]-BMT). MRL/lpr mice treated with IBM-BMT survived more than 2 years without showing the symptoms of autoimmune diseases. To apply this BMT method to humans, we have also established a new method for BMC harvesting using cynomolgus monkeys. In this method, BMCs are harvested from the long bones using a "Perfusion Method" (PM) and the whole BMCs (including MSCs) are then injected directly into the IBM. We believe that this new method will become a powerful strategy for the treatment of various intractable diseases, including age-associated diseases such as osteoporosis.     

Donor-lymphocyte infusion induces transplantation tolerance by activating systemic and graft-infiltrating double-negative regulatory T cells

Donor-lymphocyte infusion (DLI) before transplantation can lead to specific tolerance to allografts in mice, nonhuman primates, and humans. We and others have demonstrated a role for regulatory T cells in DLI-induced, donor-specific transplantation tolerance, but it is not known how regulatory T cells are activated and where they execute their function. In this study, we observed, in both transgenic and normal mice, that DLI before transplantation is required for activation of alphabeta-T-cell-receptor-positive, CD3(+)CD4(-)CD8(-) double-negative (DN) regulatory T cells in the periphery of recipient mice. More interestingly, DLI induced DN regulatory T cells to migrate preferentially to donor-specific allogeneic skin grafts and to form a majority of graft-infiltrating T cells in accepted skin allografts. Furthermore, both recipient-derived peripheral and graft-infiltrating DN T cells were able to suppress and kill antidonor CD8(+) T cells in an antigen-specific manner. These data indicate that DLI may induce donor-specific transplantation tolerance by activating recipient DN regulatory T cells in the periphery and by promoting migration of regulatory T cells to donor-specific allogeneic skin grafts. Our results also show that DN regulatory T cells can eliminate antidonor T cells both systemically and locally, a finding suggesting that graft-infiltrating T cells can be beneficial to graft survival.     

Hepatocyte growth factor preserves graft-versus-leukemia effect and T-cell reconstitution after marrow transplantation

Graft-versus-host disease (GVHD) is a major complication of allogeneic bone marrow transplantation (BMT). When GVHD is controlled by T-cell-depleted grafts or immunosuppressants, BM transplant recipients often suffer from an increased rate of leukemic relapse and impaired reconstitution of immunity. Using a mouse BMT model, we investigated the effects of hepatocyte growth factor (HGF) gene transfection on the severity of GVHD, the graft-versus-leukemia effect, and the reconstitution of T cells after BMT. After HGF gene transfer, acute GVHD was reduced, while mature donor T-cell responses to host antigens were preserved, resulting in a significant improvement of leukemia-free survival. HGF gene transfer promoted regeneration of bone marrow-derived T cells and the responsiveness of these cells to alloantigens. Furthermore, HGF preserved the thymocyte phenotype and thymic stromal architecture in mice with GVHD. This suggested that HGF exerts a potent protective effect on the thymus, which in turn promotes reconstitution of bone marrow-derived T cells after allogeneic BMT. These results indicate that HGF gene transfection can reduce acute GVHD preserving the graft-versus-leukemia effect, while promoting thymic-dependent T-cell reconstitution after allogeneic BMT.     

New Strategies for BMT,Organ Transplantation,and Regeneration Therapy

Bone marrow transplantation (BMT) is becoming a powerful strategy for the treatment of hematologic disorders, congenital immunodeficiencies, metabolic disorders and also autoimmune diseases.

We have previously found using various animal models for spontaneous autoimmune diseases, that allogeneic bone marrow transplantation (allo BMT) can be used to prevent and treat various autoimmune diseases. In addition, we have found that autoimmune diseases are stem cell disorders. However, in MRL/lpr mice, which are radiosensitive (<8.5 Gy), we found that conventional BMT had only a transient effect on autoimmune diseases, which were found to recur. Therefore, we concentrated on discovering new strategies to prevent and treat autoimmune diseases in the radiosensitive and chimeric-resistant MRL/lpr mouse.

Using MRL/lpr mice, we established a new method for allo BMT. In this method, whole bone marrow cells (BMCs), containing a small number of T cells and mesenchymal stem cells (MSCs), were directly injected into the bone marrow cavity (intra-bone marrow [IBM]-BMT). MRL/lpr mice treated with IBM-BMT survived more than 2 years without showing the symptoms of autoimmune diseases.

To apply this BMT method to humans, we have also established a new method for BMC harvesting using cynomolgus monkeys. In this method, BMCs are harvested from the long bones using a "Perfusion Method" (PM) and the whole BMCs (including MSCs) are then injected directly into the IBM. We believe that this new method will become a powerful strategy for the treatment of various intractable diseases, including age-associated diseases such as osteoporosis.     

Treatment of autoimmune diseases by hematopoietic stem cell transplantation

Remarkable advances have been made in bone marrow transplantation (BMT), which now has become a powerful strategy for the treatment of leukemia, aplastic anemia, congenital immunodeficiency disorders, and autoimmune diseases. Using various animal models, allogeneic BMT has been found to be useful in the treatment of autoimmune diseases. In MRL/lpr mice, which are radiosensitive (<8.5 Gy) and are an animal model for autoimmune disorders, conventional BMT resulted in only transient effects; the manifestations of the autoimmune diseases recurred 3 months after BMT. However, the combination of BMT plus bone grafts (to recruit donor stromal cells) was capable of preventing the recurrence of autoimmune diseases in MRL/lpr mice. This strategy was found to be ineffective in the treatment of MRL/lpr mice that had developed autoimmune diseases, because these mice were more sensitive to the effects of radiation after the onset of lupus nephritis due to uremic enterocolitis. We have recently discovered a safer strategy for treatment of autoimmune diseases, which includes fractionated irradiation (5.5 Gy x 2) (day -1) followed by portal venous injection (day 0) plus intravenous injection (day 5) of donor unfractionated bone marrow cells. We successfully treated autoimmune diseases in MRL/lpr mice using this strategy; 100% of MRL/lpr mice treated in this fashion survive >1 year after treatment. We identified the mechanisms underlying the components of this approach and have found that stromal cells play a crucial role in successful BMT. In this review, the conditions essential for successful allogeneic BMT are discussed.     

Keratinocyte growth factor and androgen blockade work in concert to protect against conditioning regimen-induced thymic epithelial damage and enhance T-cell reconstitution after murine bone marrow transplantation

Myeloablative conditioning results in thymic epithelial cell (TEC) injury, slow T-cell reconstitution, and a high risk of opportunistic infections. Keratinocyte growth factor (KGF) stimulates TEC proliferation and, when given preconditioning, reduces TEC injury. Thymocytes and TECs express androgen receptors, and exposure to androgen inhibits thymopoiesis. In this study, we have investigated whether TEC stimulation via preconditioning treatment with KGF and leuprolide acetate (Lupron), 2 clinically approved agents, given only before conditioning would circumvent the profound TEC and associated T-cell deficiency seen in allogeneic bone marrow transplant (BMT) recipients. Only combined treatment with KGF plus leuprolide acetate normalized TEC subset numbers and thymic architecture. Thymopoiesis and thymic output were supranormal, leading to the accelerated peripheral reconstitution of naive CD4 and CD8 T cells with a broad Vβ repertoire and decreased homeostatic T-cell proliferation. Combined therapy facilitated T:B cooperativity and enabled a B-cell humoral response to a CD4 T cell–dependent neoantigen challenge soon after BMT. In vivo antigen-specific CD8 T-cell responses and clearance of a live pathogen was superior with combined versus individual agent therapy. Thus, KGF combined with androgen blockade represents a novel approach to restore thymic function and facilitates the rapid recovery of peripheral T-cell function after allogeneic BMT.     

A novel strategy for allogeneic stem cell transplantation: perfusion method plus intra-bone marrow injection of stem cells

Using long bones of cynomolgus monkeys, we have recently developed a new "Perfusion Method (PM)" for harvesting bone marrow cells (BMCs) while minimizing the contamination of BMCs with T cells from the peripheral blood. When thus collected BMCs, which contain not only pluripotent hemopoietic stem cells (P-HSCs) but also mesenchymal stem cells (MSCs), are directly injected into the bone marrow cavity of recipients (intra-bone marrow BMT: "IBM-BMT"), the donor-derived hemopoietic cells quickly recover even when the radiation doses used as the conditioning regimen are reduced. Recipient mice, rats, and even monkeys show neither graft-vs-host disease (GVHD) nor graft failure.In this article, we discuss why this new method (PM+IBM-BMT) may become a valuable strategy for allogeneic stem cell (both P-HSC and MSC) transplantation.     

A novel application of cyclosporine A in nonmyeloablative pretransplant host conditioning for allogeneic BMT

The treatment of mice with anti-CD4 and anti-CD8 monoclonal antibodies (mAbs) on day -5, plus 3 Gy whole body irradiation (WBI) and 7 Gy thymic irradiation (TI) on day 0, allows fully major-histocompatibility-complex-mismatched allogeneic bone marrow engraftment and the induction of immunologic tolerance. TI is required in this model to overcome alloreactivity and possibly to make "space" in the recipient thymus so that lasting central tolerance can be achieved. In addition to suppressing mature T cells in the periphery, Cyclosporine A (CYA) and glucocorticoids have a powerful influence on the thymus. In this study, we evaluated whether the administration of CYA to recipient mice for 12 days prior to bone marrow transplant (BMT), of glucocorticosteroids on the day of BMT, or a combination of both, could create space and overcome alloresistance in the thymus by specifically depleting immature and mature thymocytes prior to BMT. High levels of multilineage donor hematopoietic repopulation and specific transplantation tolerance were achieved in mice treated from days -15 to -3 with CYA (20 mg/kg/d subcutaneously), anti-CD4/CD8 mAbs on day -5, followed by 3 Gy WBI and 15 x 10(6) allogeneic bone marrow cells on day 0. Vbeta analysis suggested a central deletional tolerance mechanism. The same treatment without CYA pretreatment allowed only transient chimerism, without tolerance. Corticosteroid treatment abolished the engraftment-promoting and tolerance-inducing effects of CYA. These results demonstrate a novel pretransplantation-only application of CYA, which facilitates allogeneic marrow engraftment with minimal conditioning, by creating thymic space and/or overcoming intrathymic alloresistance.     

Treatment of intractable autoimmune diseases in MRL/lpr mice using a new strategy for allogeneic bone marrow transplantation

A new bone marrow transplantation (BMT) method for treating severe autoimmune diseases in chimeric resistant MRL/lpr mice is presented. The method consists of fractionated irradiation (5.5 Gy x 2), followed by portal venous (PV) injection of whole bone marrow cells (BMCs) from allogeneic normal C57BL/6 (B6) mice and intravenous (IV) injection of whole B6 BMCs 5 days after the PV injection (abbreviated as 5.5 Gy x 2 + PV + IV). All recipients survived more than 1 year after this treatment (more than 64 weeks after birth). Abnormal T cells (Thy1.2(+)/B220(+)/CD3(+)/CD4(-)/CD8(-)) present in MRL/lpr mice before the treatment disappear, and hematolymphoid cells are reconstituted with donor-derived cells. The treated mice are free from autoimmune diseases. Levels of autoantibodies (IgG/IgM anti-ssDNA antibodies and IgG/IgM rheumatoid factors) decrease to normal levels. Successful cooperation is achieved among T cells, B cells, and antigen-presenting cells (APCs) of the treated MRL/lpr mice when evaluated by in vitro anti-SRBC responses. Newly developed T cells are tolerant to both donor (B6)-type and host (MRL/lpr)-type major histocompatibility complex (MHC) determinants. These findings clearly indicate that severe autoimmune diseases in MRL/lpr mice are completely ameliorated by the treatment without recourse to immunosuppressants, and that the treated MRL/lpr mice show normal immune functions, strongly suggesting that this strategy would be applicable to humans. (Blood. 2000;95:1862-1868)     

A novel BMT technique for treatment of various currently intractable diseases

A recently-developed BMT method combines a "Perfusion Method" (PM) for collecting bone marrow cells (BMCs) with the Intra-Bone Marrow (IBM) injection of BMCs (IBM-BMT). As distinct from the conventional aspiration method (AM), the PM allows rapid (within 1?h) collection of BMCs without T cell contamination (T cells?相似文献   

Quantitation of T-cell neogenesis in vivo after allogeneic bone marrow transplantation in adults

Following myeloablative therapy, it is unknown to what extent age-dependent thymic involution limits the generation of new T cells with a diverse repertoire. Normal T-cell receptor gene rearrangement in T-cell progenitors results in the generation of T-cell receptor rearrangement excision circles (TRECs). In this study, a quantitative assay for TRECs was used to measure T-cell neogenesis in adult patients with leukemia who received myeloablative therapy followed by transplantation of allogeneic hematopoietic stem cells. Although phenotypically mature T cells had recovered by 1 to 2 months after bone marrow transplantation (BMT), TREC levels remained low for 3 months after BMT. T-cell neogenesis became evident by 6 months, and normal levels of adult thymic function were restored at 6 to 12 months after BMT. Subsequent leukemia relapse in some patients was associated with reduced TREC levels, but infusion of mature donor CD4(+) T cells resulted in rapid restoration of thymic function. These studies demonstrate that T-cell neogenesis contributes to immune reconstitution in adult patients and suggest that thymic function can be manipulated in vivo. (Blood. 2001;98:1116-1121)     

Donor-derived thymic-dependent T cells cause chronic graft-versus-host disease

Chronic graft-versus-host disease (GVHD) is the most common cause of poor long-term outcomes after allogeneic bone marrow transplantation (BMT), but the pathophysiology of chronic GVHD still remains poorly understood. We tested the hypothesis that the impaired thymic negative selection of the recipients will permit the emergence of pathogenic T cells that cause chronic GVHD. Lethally irradiated C3H/HeN (H-2k) recipients were reconstituted with T-cell-depleted bone marrow cells from major histocompatibility complex [MHC] class II-deficient (H2-Ab1-/-) B6 (H-2b) mice. These mice developed diseases that showed all of the clinical and histopathological features of human chronic GVHD. Thymectomy prevented chronic GVHD, thus confirming the causal association of the thymus. CD4+ T cells isolated from chronic GVHD mice were primarily donor reactive, and adoptive transfer of CD4+ T cells generated in these mice caused chronic GVHD in C3H/HeN mice in the presence of B6-derived antigen-presenting cells. Our results demonstrate for the first time that T cells that escape from negative thymic selection could cause chronic GVHD after allogeneic BMT. These results also suggest that self-reactivity of donor T cells plays a role in this chronic GVHD, and improvement in the thymic function may have a potential to decrease chronic GVHD.     

Interleukin 7 worsens graft-versus-host disease

Impaired immune reconstitution has moved to the forefront of clinical problems limiting progress in allogeneic bone marrow transplantation (BMT). The identification of therapies that can enhance immune reconstitution by increasing thymopoiesis is critical to solving this problem. Interleukin 7 (IL-7) is the most potent thymopoietic cytokine identified thus far. To study the effects of IL-7 on immune reconstitution and graft-versus-host disease (GVHD) following allogeneic BMT, we administered recombinant human IL-7 (rhIL-7) in a murine parent into an F1 model. Results showed that rhIL-7 therapy lowered the "threshold" T-cell dose required to induce both clinical signs of GVHD as well as lethal GVHD. Histologic analysis of GVHD target tissues revealed that rhIL-7 increased the degree of inflammation and tissue damage observed at all T-cell doses studied, but did not change the pattern of organs affected or the histologic appearance of the GVHD within target organs. In addition, we evaluated the capacity for rhIL-7 to enhance thymopoiesis in the setting of allogeneic T cell-depleted (TCD) and T-cell-replete BMT. We observed that rhIL-7 therapy enhanced thymic function in TCD allogeneic BM transplant recipients, but not in animals that received even modest doses of T cells presumably due to thymic toxicity of the graft-versus-host reaction. Thus, caution must be exercised as IL-7 is developed clinically as an immunorestorative agent for use in the setting of allogeneic BMT. These results suggest that use of IL-7 should be limited to the setting of TCD BMT to obtain the greatest benefit on immune competence with the least toxicity.     

Mixed allogeneic chimerism to induce tolerance to solid organ and cellular grafts

Transplantation of solid organs and cellular grafts has become clinical routine in the last 30 years. However, the requirement for life-long immunosuppression is associated with infections, malignancies and end-organ toxicity. Moreover, the treatment fails to prevent chronic rejection. The induction of donor-specific transplantation tolerance would solve these problems, but has remained an elusive goal. One approach to achieve transplantation tolerance is through hematopoietic chimerism. This review outlines different concepts of hematopoietic chimerism focusing on macrochimerism. Mixed allogeneic chimerism, also known as macrochimerism, is defined as engraftment of hematopoietic stem cells achieved by bone marrow transplantation (BMT). It discusses the advantages and limitations of the BMT as well as approaches to overcome these limitations in the future.     

Rapidly proliferating CD44hi peripheral T cells undergo apoptosis and delay posttransplantation T-cell reconstitution after allogeneic bone marrow transplantation

Delayed T-cell recovery is an important complication of allogeneic bone marrow transplantation (BMT). We demonstrate in murine models that donor BM-derived T cells display increased apoptosis in recipients of allogeneic BMT with or without GVHD. Although this apoptosis was associated with a loss of Bcl-2 and Bcl-X(L) expression, allogeneic recipients of donor BM deficient in Fas-, tumor necrosis factor-related apoptosis-inducing ligand (TRAIL)- or Bax-, or BM-overexpressing Bcl-2 or Akt showed no decrease in apoptosis of peripheral donor-derived T cells. CD44 expression was associated with an increased percentage of BM-derived apoptotic CD4(+) and CD8(+) T cells. Transplantation of RAG-2-eGFP-transgenic BM revealed that proliferating eGFP(lo)CD44(hi) donor BM-derived mature T cells were more likely to undergo to apoptosis than nondivided eGFP(hi)CD44(lo) recent thymic emigrants in the periphery. Finally, experiments using carboxyfluorescein succinimidyl ester-labeled T cells adoptively transferred into irradiated syngeneic hosts revealed that rapid spontaneous proliferation (as opposed to slow homeostatic proliferation) and acquisition of a CD44(hi) phenotype was associated with increased apoptosis in T cells. We conclude that apoptosis of newly generated donor-derived peripheral T cells after an allogeneic BMT contributes to delayed T-cell reconstitution and is associated with CD44 expression and rapid spontaneous proliferation by donor BM-derived T cells.     

Requirements for induction and maintenance of peripheral tolerance in stringent allograft models

Peripheral tolerance can be achieved in many but not all murine allograft models. The requirements for controlling more aggressive immune responsiveness and generating peripheral tolerance in stringent allograft models are unknown. Understanding these requirements will provide insight toward ultimately achieving tolerance in humans, which are also resistant. We now demonstrate that the combination of donor-specific transfusion, anti-CD45RB, and anti-CD154 uniformly achieves >90-d survival of BALB/c skin allografts on C57BL/6 recipients. Recipients exhibit marked hyporesponsiveness to alloantigen in vitro. In distinct contrast to less rigorous models, engraftment remains absolutely dependent on cytotoxic T lymphocyte antigen 4 signaling, even after grafts are healed, suggesting that prolonged engraftment cannot simply be attributed to more effective depletion of alloreactive T cells but is actively maintained by regulation. Concordantly, we show that both CD4 and CD8 regulatory cells are required and can transfer donor-specific tolerance to na?ve recipients. Nonetheless, most recipients ultimately develop gradual graft loss (median survival time = 140 d), suggesting that alloreactive cells emerging from the thymus eventually overwhelm regulatory capacity. In agreement, adding thymectomy to the regimen results in permanent engraftment (>250 d) and donor-specific tolerance not observed previously in this model. These results highlight the potency of both CD4 and CD8 regulatory cells but also suggest that in stringent settings, regulatory T cell longevity and capacity for infectious tolerance compete with prolonged graft immunogenicity and thymic output. These results provide insight into the mechanisms of tolerance in stringent models and provide a rational basis for innovative tolerogenic strategies in humans.