Low dose busulfan facilitates chimerism and tolerance in a murine model

T cell depletion, sirolimus and "mega" dose donor specific bone marrow (DSBM) infusion promotes stable multilineage chimerism and indefinite survival of skin allografts in completely mismatched mice. The purpose of this study is to determine whether the addition of low dose busulfan can reduce the amount of DSBM required while preserving efficacy. C57BL/6 recipients of BALB/c skin allografts were treated with alphaCD4 and alphaCD8 monoclonal antibodies, DSBM, sirolimus and various doses of busulfan. The kinetics and phenotype of chimerism and the presence of clonal deletion of alloreactive T-cells were defined using flow cytometry. In vitro reactivity was determined using mixed lymphocyte culture. Second skin grafts confirmed the presence of tolerance. All doses of busulfan resulted in engraftment when combined with this regimen using a reduced dose of donor marrow. The level, kinetics and character of chimerism observed were dose related. Chimerism was associated with indefinite allograft acceptance (>200 days). Tolerance was documented both in vitro/in vivo and was associated with clonal deletion. Addition of a single low dose of busulfan to an established tolerance protocol reduced the required DSBM dose by over 80% while still promoting comparable levels of donor chimerism and donor-specific tolerance.     

Establishment of stable multilineage hematopoietic chimerism and donor-specific tolerance without irradiation

BACKGROUND: Induction of tolerance to organ transplants will increase graft survival and decrease patient mortality and morbidity. Radiation-induced cytoreduction/ablation followed by donor hematopoietic cell reconstitution has been the most consistently successful approach to experimental tolerance induction. However, reluctance of clinicians to expose recipients to radiation has hampered its clinical application. METHODS: In the studies described, administration of polyclonal antilymphocyte serum (ALS), donor-specific bone marrow (DSBM) (150x10(6) cells), and sirolimus (24 mg/kg) in a completely mismatched murine model (B10.A donor, C57B/10 recipient) produced 100% indefinite (>250 days) skin graft survival. The level and character of donor-specific chimerism was evaluated with flow cytometry. RESULTS: Specific tolerance was confirmed by continued acceptance of primary and secondary donor-specific skin allografts and rejection of third-party grafts. The level and duration of chimerism induced was directly related to the dose of DSBM administered. Mice given 150x10(6) DSBM cells showed levels of 8-10% donor peripheral blood mononuclear cell chimerism by 30 days, and these levels persisted indefinitely (>250 days) in association with permanent tolerance of donor grafts. Eighty percent of donor chimeric cells were B lymphocytes (MHC class I and II positive, Fc receptor positive, CD45/B220 positive but negative for CD4, CD8 and Thy 1.2) and 20% were sorted in the macrophage monocyte population. CONCLUSIONS: These studies demonstrate for the first time that cytoreduction/ablation with ALS combined with sirolimus and reconstitution with donor bone marrow induces tolerance and chimerism in a completely mismatched murine combination. The use of ALS and sirolimus, currently employed therapies in clinical transplantation, and the lack of requirement for radiation make this tolerance protocol attractive for clinical application.     

Rapamycin and CTLA4Ig Synergize to Induce Stable Mixed Chimerism Without the Need for CD40 Blockade

The mixed chimerism approach achieves donor‐specific tolerance in organ transplantation, but clinical use is inhibited by the toxicities of current bone marrow (BM) transplantation (BMT) protocols. Blocking the CD40:CD154 pathway with anti‐CD154 monoclonal antibodies (mAbs) is exceptionally potent in inducing mixed chimerism, but these mAbs are clinically not available. Defining the roles of donor and recipient CD40 in a murine allogeneic BMT model, we show that CD4 or CD8 activation through an intact direct or CD4 T cell activation through the indirect pathway is sufficient to trigger BM rejection despite CTLA4Ig treatment. In the absence of CD4 T cells, CD8 T cell activation via the direct pathway, in contrast, leads to a state of split tolerance. Interruption of the CD40 signals in both the direct and indirect pathway of allorecognition or lack of recipient CD154 is required for the induction of chimerism and tolerance. We developed a novel BMT protocol that induces mixed chimerism and donor‐specific tolerance to fully mismatched cardiac allografts relying on CD28 costimulation blockade and mTOR inhibition without targeting the CD40 pathway. Notably, MHC‐mismatched/minor antigen‐matched skin grafts survive indefinitely whereas fully mismatched grafts are rejected, suggesting that non‐MHC antigens cause graft rejection and split tolerance.     

Earlier Low-Dose TBI or DST Overcomes CD8+ T-Cell-Mediated Alloresistance to Allogeneic Marrow in Recipients of Anti-CD40L

Treatment with a single injection of anti-CD40L (CD154) monoclonal antibody (mAb) and fully mismatched allogeneic bone marrow transplant (BMT) allows rapid tolerization of CD4+ T cells to the donor. The addition of in vivo CD8 T-cell depletion leads to permanent mixed hematopoietic chimerism and tolerance. We now describe two approaches that obviate the requirement for CD8 T-cell depletion by rapidly tolerizing recipient CD8 T cells in addition to CD4 cells. Administration of donor-specific transfusion (DST) to mice receiving 3 Gy total body irradiation (TBI), BMT and anti-CD40L mAb on day 0 uniformly led to permanent mixed chimerism and tolerance, compared with only 40% of mice receiving similar treatment without DST. In the absence of DST, moving the timing of 3 Gy TBI to day -1 or day -2 instead of day 0 led to rapid (by 2 weeks) induction of CD8+ cell tolerance, and also permitted uniform achievement of permanent mixed chimerism and donor-specific tolerance in recipients of anti-CD40L and BMT on day 0. These nontoxic regimens overcome CD8+ and CD4+ T-cell-mediated alloresistance without requiring host T-cell depletion, permitting the induction of permanent mixed chimerism and tolerance.     

Active role of chimerism in transplantation tolerance induced by antilymphocyte serum, sirolimus, and bone-marrow-cell infusion

BACKGROUND: A regimen consisting of antilymphocyte serum (ALS), sirolimus, and donor bone-marrow-cell (BMC) infusion induces indefinite skin allograft survival across fully mismatched mouse strain combinations. We investigated the role of chimerism in this transplantation tolerance model. MATERIALS: B10.A (H-2a) mice were treated with ALS on day -1 and 2, sirolimus, and infusion of (C57BL/6xDBA/2)F1 (B6D2F1, H-2(b/d)) BMCs on day 7 relative to DBA/2 (D2) skin grafting on day 0. At postgraft days 30, 50 and 120, the recipient mice were injected intravenously with splenocytes prepared from either naive or D2 mixed chimeric B10.A mice that had been sensitized in vivo to B6. Changes in chimerism and graft survival were monitored. RESULTS: Although D2 skin grafts were rejected with a median survival time of 63.8 days in B10.A mice given ALS and sirolimus alone, they survived more than 200 days in all B10.A mice given ALS, sirolimus, and B6D2F1 BMCs. Chimerism became evident 21 days postgrafting and progressively increased thereafter to 20% at postgraft day 200. Infusion of anti-B6 presensitized cells resulted in depletion of chimeric donor cells and subsequent graft rejection regardless of the timing of injection. Injection of presensitized cells in mice given ALS and sirolimus alone had no effect on graft survival. Injection of presensitized cells that were cytotoxic to alloantigen expressed by BMCs but tolerant to skin reduced, but did not deplete, established chimerism and allowed continued allograft survival. CONCLUSIONS: Chimeric donor cells play a major role in both the early and late phases of transplantation tolerance induced by the ALS, sirolimus, and BMC regimen.     

Recipient Dendritic Cells,But Not B Cells,Are Required Antigen‐Presenting Cells for Peripheral Alloreactive CD8+ T‐Cell Tolerance

Induction of mixed allogeneic chimerism is a promising approach for achieving donor‐specific tolerance, thereby obviating the need for life‐long immunosuppression for solid organ allograft acceptance. In mice receiving a low dose (3Gy) of total body irradiation, allogeneic bone marrow transplantation combined with anti‐CD154 tolerizes peripheral CD4 and CD8 T cells, allowing achievement of mixed chimerism with specific tolerance to donor. With this approach, peripheral CD8 T‐cell tolerance requires recipient MHC class II, CD4 T cells, B cells and DCs. Recipient‐type B cells from chimeras that were tolerant to donor still promoted CD8 T‐cell tolerance, but their role could not be replaced by donor‐type B cells. Using recipients whose B cells or DCs specifically lack MHC class I and/or class II or lack CD80 and CD86, we demonstrate that dendritic cells (DCs) must express CD80/86 and either MHC class I or class II to promote CD8 tolerance. In contrast, B cells, though required, did not need to express MHC class I or class II or CD80/86 to promote CD8 tolerance. Moreover, recipient IDO and IL‐10 were not required. Thus, antigen presentation by recipient DCs and not by B cells is critical for peripheral alloreactive CD8 T cell tolerance.     

SV40 infection associated with rituximab treatment after kidney transplantation in nonhuman primates

BACKGROUND: A regimen consisting of polyclonal anti-T-cell antibody, sirolimus (SRL), and donor bone marrow (DBM) infusion induces robust transplantation tolerance to skin allografts in mice. We investigated the effect of a similar regimen in a nonhuman primate (NHP) model. METHODS: Cynomolgus macaques (Macaca fascicularis) were transplanted with mismatched kidney allografts. Recipients were treated with 7 doses of antithymocyte globulin (Thymoglobulin, day 1 to 9), sirolimus, and DBM infusion (day 14). Anti-CD20 antibody, rituximab, was given on days 0 and 5. RESULTS: A regimen of Thymoglobulin, 30 days of SRL, and DBM infusion induced significantly greater prolongation of graft survival with a mean survival time of 88 days compared with the control regimen (no DBM) with an mean survival time of 53 days (P=0.022). Unlike the murine skin allograft model, all grafts were rejected within 111 days. A combination of Thymoglobulin, continuous SRL, and rituximab caused graft and systemic SV40 infection and failed to achieve further extension of graft survival. C4d deposition was observed in 50% of recipients as early as 18 days, suggesting antidonor antibody production. A transient, low-to-moderate degrees of multilineage chimerism was observed after DBM infusion. Treatment with Thymoglobulin resulted in profound depletion of CD4+ and CD8+ T cells, whereas addition of rituximab achieved prolonged (up to 3 months) depletion of CD20+ B cells. CONCLUSION: The Thymoglobulin, SRL, and DBM protocol is simple and produces long-term kidney allograft survival in NHP although additional treatment modalities may be necessary for induction of long-term tolerance.     

Tolerance and Withdrawal of Immunosuppressive Drugs in Patients Given Kidney and Hematopoietic Cell Transplants

Sixteen patients conditioned with total lymphoid irradiation (TLI) and antithymocyte globulin (ATG) were given kidney transplants and an injection of CD34+ hematopoietic progenitor cells and T cells from HLA‐matched donors in a tolerance induction protocol. Blood cell monitoring included changes in chimerism, balance of T‐cell subsets and responses to donor alloantigens. Fifteen patients developed multilineage chimerism without graft‐versus‐host disease (GVHD), and eight with chimerism for at least 6 months were withdrawn from antirejection medications for 1–3 years (mean, 28 months) without subsequent rejection episodes. Four chimeric patients have just completed or are in the midst of drug withdrawal, and four patients were not withdrawn due to return of underlying disease or rejection episodes. Blood cells from all patients showed early high ratios of CD4+CD25+ regulatory T cells and NKT cells versus conventional naive CD4+ T cells, and those off drugs showed specific unresponsiveness to donor alloantigens. In conclusion, TLI and ATG promoted the development of persistent chimerism and tolerance in a cohort of patients given kidney transplants and hematopoietic donor cell infusions. All 16 patients had excellent graft function at the last observation point with or without maintenance drugs.     

Association of natural killer cell depletion with induction of mixed chimerism and allograft tolerance in non-human primates

BACKGROUND: Nonmyeloablative T cell depletion followed by donor bone marrow infusion has proved to be an effective approach to induction of mixed chimerism and tolerance of organ allografts in non-human primates. To help define the mechanisms involved we have compared T cell depletion with ATG versus anti-CD2 monoclonal antibody with respect to establishment of mixed chimerism and induction of tolerance. METHOD: Both nonmyeloablative regimens included low dose total body irradiation (1.5 Gy x 2), thymic irradiation (7 Gy), splenectomy and kidney plus donor bone marrow transplantation, followed by a 4-week posttransplant course of cyclosporine. In addition, the ATG group (13 recipients) received antithymocyte globulin, although the LOCD2b group (10 recipients) were treated with an anti-CD2 monoclonal antibody (LOCD2b). RESULTS: In the ATG group, 11 of 13 monkeys developed multilineage chimerism and 9 survived for more than 100 days without kidney allograft rejection. In contrast, 0/10 monkeys in the LOCD2b group developed chimerism, 5 died of infection and 5 suffered progressive rejection; only 1 recipient survived beyond 100 days. Sequential monitoring of peripheral blood mononuclear cells revealed greater T cell (CD3+) depletion in the LOCD2b-treated animals compared to those receiving ATG. However, NK cells (CD16+CD8+) were significantly more depleted in the ATG group and NK function remained abrogated longer after ATG than LOCD2b treatment (3 weeks vs. <5 days). CONCLUSION: Despite excellent T cell depletion by LoCD2b, ATG was more effective in inducing chimerism and tolerance. This difference correlated with anti-NK activity of the two reagents. These data suggest that NK cells may also resist engraftment of allogeneic bone marrow cells in this model.     

An MHC‐Defined Primate Model Reveals Significant Rejection of Bone Marrow After Mixed Chimerism Induction Despite Full MHC Matching

In murine models, mixed hematopoietic chimerism induction leads to robust immune tolerance. However, translation to primates and to patients has been difficult. In this study, we used a novel MHC‐defined rhesus macaque model to examine the impact of MHC matching on the stability of costimulation blockade‐/sirolimus‐mediated chimerism, and to probe possible mechanisms of bone marrow rejection after nonmyeloablative transplant. Using busulfan‐based pretransplant preparation and maintenance immunosuppression with sirolimus, as well as CD28 and CD154 blockade, all recipients demonstrated donor engraftment after transplant. However, the mixed chimerism that resulted was compartmentalized, with recipients demonstrating significantly higher whole blood chimerism compared to T cell chimerism. Thus, the vast majority of T cells presenting posttransplant were recipient—rather than donor‐derived. Surprisingly, even in MHC‐matched transplants, rejection of donor hematopoiesis predominated after immunosuppression withdrawal. Weaning of immunosuppression was associated with a surge of antigen‐experienced T cells, and transplant rejection was associated with the acquisition of donor‐directed T cell alloreactivity. These results suggest that a reservoir of alloreactive cells was present despite prior costimulation blockade and sirolimus, and that the postimmunosuppression lymphocytic rebound may have lead to a phenotypic shift in these recipient T cells towards an activated, antigen‐experienced phenotype, and ultimately, to transplant rejection.     

Depletion of CD8 Memory T Cells for Induction of Tolerance of a Previously Transplanted Kidney Allograft

Heterologous immunologic memory has been considered a potent barrier to tolerance induction in primates. Induction of such tolerance for a previously transplanted organ may be more difficult, because specific memory cells can be induced and activated by a transplanted organ. In the current study, we attempted to induce tolerance to a previously transplanted kidney allograft in nonhuman primates. The conditioning regimen consisted of low dose total body irradiation, thymic irradiation, antithymocyte globulin, and anti‐CD154 antibody followed by a brief course of a calcineurin inhibitor. This regimen had been shown to induce mixed chimerism and allograft tolerance when kidney transplantation (KTx) and donor bone marrow transplantation (DBMT) were simultaneously performed. However, the same regimen failed to induce mixed chimerism when delayed DBMT was performed after KTx. We found that significant levels of memory T cells remained after conditioning, despite effective depletion of naïve T cells. By adding humanized anti‐CD8 monoclonal antibody (cM‐T807), CD8 memory T cells were effectively depleted and these recipients successfully achieved mixed chimerism and tolerance. The current studies provide ‘proof of principle’ that the mixed chimerism approach can induce renal allograft tolerance, even late after organ transplantation if memory T‐cell function is adequately controlled.     

Donor T cells are not required for induction of allograft tolerance in mice treated with antilymphocyte serum, rapamycin, and donor bone marrow cells

BACKGROUND: Postgraft infusion of donor bone marrow cells (BMC) effectively induces tolerance to skin allografts in antilymphocyte serum- and rapamycin-treated recipients in fully major histocompatibility complex-mismatched mouse strain combinations. We used various gene knockout mice to examine the role of donor T cells and B cells in BMC-induced allograft tolerance. METHODS: All recipient mice received ALS on days -1 and 2 and rapamycin (6 mg/kg) on day 7 relative to fully major histocompatibility complex-mismatched skin grafting on day 0. Donor BMC prepared either from mice lacking CD4- and/or CD8a-, or CD3epsilon-expressing cells or B cells, or from corresponding wildtype mice, were given on day 7. The level and phenotypes of chimerism was determined by flow cytometry. RESULTS: All T cell- and B cell-deficient BMC were as effective as wild-type BMC in inducing prolongation of skin graft survival. A low degree of chimerism without donor type T cells was detected in tolerant mice given T cell-deficient BMC or wild-type BMC 60 days after transplantation. Chimeric cells were composed of B cells and macrophages/monocytes. Low level chimerism without donor T or B cells was also present in tolerant mice given B cell-deficient BMC. CONCLUSION: Donor type T cells and T cell chimerism are not required for induction of allograft tolerance by the antilymphocyte serum/rapamycin/donor BMC-infusion protocol. Donor B cells also do not participate in tolerance induction. Thus, infusion of T cell-depleted BMC in conjunction with conventional immunosuppressive regimens will be a simple, safe, and effective way to induce allograft tolerance in clinical organ transplantation.     

Blockade of the CD40/CD154 pathway enhances T-cell-depleted allogeneic bone marrow engraftment under nonmyeloablative and irradiation-free conditioning therapy

BACKGROUND: T-cell-depleted bone marrow transplantation (TDBMT) can prevent graft-versus-host disease (GvHD). However, depleting T cells from allogeneic bone marrow often results in failure of bone marrow engraftment under irradiation conditioning. It is not know whether donor T cells are essential for bone marrow engraftment and whether blocking the CD40/CD154 pathway promotes allogeneic TDBM engraftment under nonmyeloablative and irradiation-free fludarabine phosphate and cyclophosphamide conditioning therapy. METHODS: Using fully major histocompatibility complex (MHC)-matched mouse models, we investigated whether donor T cells are essential for bone marrow engraftment under fludarabine phosphate and cyclophosphamide conditioning therapy. We also determined whether the barrier of allogeneic TDBM could be overcome by blocking the CD40/CD154 pathway. Donor chimerism was detected by flow cytometric analysis. Donor-specific tolerance through establishing mixed chimerism was tested in vivo by skin transplantation and in vitro by mixed leukocyte reaction and enzyme-linked immunospot (ELISPOT) assay. RESULTS: Compared with unmodified bone marrow, TDBM resulted in poor engraftment when fully MHC-mismatched donors were used. However, anti-CD154 monoclonal antibody (mAb) treatment significantly enhanced donor TDBM engraftment. TDBM engraftment was also seen in CD154 knockout mice. A stable and high level of multilinage donor chimerism was achieved. Recovery of host CD3 T cells was suppressed, and recovery of donor CD3 T cells was promoted, after TDBMT and anti-CD154 mAb treatment. Donor chimerism was established by TDBMT induced donor-specific tolerance in vivo and in vitro. CONCLUSION: Donor T cells facilitate bone marrow engraftment under nonmyeloablative and irradiation-free conditioning therapy, and the blocking the CD40/CD154 pathway can replace donor T cells to promote TDBM engraftment.     

iNKT cell activation plus T‐cell transfer establishes complete chimerism in a murine sublethal bone marrow transplant model

Transplant tolerance induction makes it possible to preserve functional grafts for a lifetime without immunosuppressants. One powerful method is to generate mixed hematopoietic chimeras in recipients by adoptive transfer of donor‐derived bone marrow cells (BMCs). In our murine transplantation model, we established a novel method for mixed chimera generation using sublethal irradiation, CD40‐CD40L blockade, and invariant natural killer T‐cell activation. However, numerous BMCs that are required to achieve stable chimerism makes it difficult to apply this model for human transplantation. Here, we show that donor‐derived splenic T cells could contribute to not only the reduction of BMC usage but also the establishment of complete chimerism in model mice. By cotransfer of T cells together even with one‐fourth of the BMCs used in our original method, the recipient mice yielded complete chimerism and could acquire donor‐specific skin‐allograft tolerance. The complete chimeric mice did not show any remarks of graft versus host reaction in vivo and in vitro. Inhibition of the apoptotic signal resulted in increase in host‐derived CD8⁺ T cells and chimerism brake. These results suggest that donor‐derived splenic T cells having veto activity play a role in the depletion of host‐derived CD8⁺ T cells and the facilitation of complete chimerism.     

The Knife's Edge of Tolerance: Inducing Stable Multilineage Mixed Chimerism but With a Significant Risk of CMV Reactivation and Disease in Rhesus Macaques

Although stable mixed‐hematopoietic chimerism induces robust immune tolerance to solid organ allografts in mice, the translation of this strategy to large animal models and to patients has been challenging. We have previously shown that in MHC‐matched nonhuman primates (NHPs), a busulfan plus combined belatacept and anti‐CD154‐based regimen could induce long‐lived myeloid chimerism, but without T cell chimerism. In that setting, donor chimerism was eventually rejected, and tolerance to skin allografts was not achieved. Here, we describe an adaptation of this strategy, with the addition of low‐dose total body irradiation to our conditioning regimen. This strategy has successfully induced multilineage hematopoietic chimerism in MHC‐matched transplants that was stable for as long as 24 months posttransplant, the entire length of analysis. High‐level T cell chimerism was achieved and associated with significant donor‐specific prolongation of skin graft acceptance. However, we also observed significant infectious toxicities, prominently including cytomegalovirus (CMV) reactivation and end‐organ disease in the setting of functional defects in anti‐CMV T cell immunity. These results underscore the significant benefits that multilineage chimerism‐induction approaches may represent to transplant patients as well as the inherent risks, and they emphasize the precision with which a clinically successful regimen will need to be formulated and then validated in NHP models.     

CD8+ T‐Cell Depletion and Rapamycin Synergize with Combined Coreceptor/Stimulation Blockade to Induce Robust Limb Allograft Tolerance in Mice

The growing development of composite tissue allografts (CTA) highlights the need for tolerance induction protocols. Herein, we developed a mouse model of heterotopic limb allograft in a stringent strain combination in which potentially tolerogenic strategies were tested taking advantage of donor stem cells in the grafted limb. BALB/c allografts were transplanted into C57BL/6 mice treated with anti‐CD154 mAb, nondepleting anti‐CD4 combined to either depleting or nondepleting anti‐CD8 mAbs. Some groups received additional rapamycin. Both depleting and nondepleting mAb combinations without rapamycin only delayed limb allograft rejection, whereas the addition of rapamycin induced long‐term allograft survival in both combinations. Nevertheless, robust donor‐specific tolerance, defined by the acceptance of a fresh donor‐type skin allograft and simultaneous rejection of third‐party grafts, required initial CD8⁺ T‐cell depletion. Mixed donor‐recipient chimerism was observed in lymphoid organs and recipient bone marrow of tolerant but not rejecting animals. Tolerance specificity was confirmed by the inability to produce IL‐2, IFN‐γ and TNF‐α in MLC with donor antigen while significant alloreactivity persisted against third‐ party alloantigens. Collectively, these results show that robust CTA tolerance and mixed donor‐recipient chimerism can be achieved in response to the synergizing combination of rapamycin, transient CD8⁺ T‐cell depletion and costimulation/coreceptor blockade.     

Potent skin allograft survival prolongation using a committed progenitor fraction of bone marrow in mice

BACKGROUND: The infusion of donor bone marrow (BM) into mice conditioned with antilymphocyte serum (ALS) and sirolimus (Sir) prolongs skin allograft survival and produces chimerism. This study identifies the BM cell(s) responsible for this effect and determines whether enrichment for these cells will improve efficacy. METHODS: Skin grafts from BALB/C mice were transplanted into C57BL/6 or C57BL/10 recipients by using ALS, Sir, and BM (or fractions). BM was fractionated by using immunomagnetic beads. Flow cytometry was used for phenotyping and detecting chimerism. RESULTS: The median graft survival in mice receiving 25 million BM cells was 61 days. Infusion of BM depleted of cells expressing CD19, CD3, CD11c, and c-kit had no effect on median graft survival, whereas infusion of fractions enriched for those cells resulted in median graft survival of 38, 48, 28, and 83 days, respectively. The administration of higher doses (4 x 10(6) and 8x10(6)) of fractions enriched for c-kit resulted in median graft survival of 124 and 197 days, respectively, without chimerism. This favorably compared with mice receiving 150 million BM cells that demonstrated transient mixed chimerism and a median graft survival of 190 days. The majority of cells in the c-kit+-enriched fraction expressed lineage markers. Removal of lineage positive cells from BM before infusion shortened median graft survival (90 days), indicating that the c-kit+ lin+ population is largely responsible for prolongation of graft survival. CONCLUSIONS: Cells enriched for C-kit+lin+ constitute approximately 5% of murine BM cells and are more potent than whole BM at prolonging skin allograft survival in mice treated with ALS and Sir.     

Mixed chimerism and immunosuppressive drug withdrawal after HLA-mismatched kidney and hematopoietic progenitor transplantation

BACKGROUND: Rodents and dogs conditioned with total-lymphoid irradiation (TLI), with or without antithymocyte globulin (ATG), have been shown to develop mixed chimerism and immune tolerance without graft-versus-host disease (GVHD) after the infusion of major histocompatability complex (MHC)-mismatched donor bone marrow cells given alone or in combination with an organ allograft. METHODS: Four human leukocyte antigen (HLA)-mismatched recipients of living donor kidney transplants were conditioned with TLI and ATG posttransplantation and infused with cyropreserved donor granulocyte colony-stimulating factor (G-CSF) "mobilized" hematopoietic progenitor (CD34+) cells (3-5x10(6) cells/kg) thereafter. Maintenance prednisone and cyclosporine dosages were tapered, and recipients were monitored for chimerism, GVHD, graft function, T-cell subsets in the blood, and antidonor reactivity in the mixed leukocyte reaction (MLR). RESULTS: Three of the four patients achieved multilineage macrochimerism, with up to 16% of donor-type cells among blood mononuclear cells without evidence of GVHD. Prolonged depletion of CD4+ T cells was observed in all four patients. Rejection episodes were not observed in the three macrochimeric recipients, and immunosuppressive drugs were withdrawn in the first patient by 12 months. Prednisone was withdrawn from a second patient at 9 months, and cyclosporine was tapered thereafter. CONCLUSIONS: Multilineage macrochimerism can be achieved without GVHD in HLA-mismatched recipients of combined kidney and hematopoietic progenitor transplants. Conditioning of the host with posttransplant TLI and ATG was nonmyeloablative and was not associated with severe infections. Recipients continue to be studied for the development of immune tolerance.     

Different Mechanisms Control Peripheral and Central Tolerance in Hematopoietic Chimeric Mice

Regulatory T cells (Treg) are important in peripheral tolerance, but their role in establishing and maintaining hematopoietic mixed chimerism and generating central tolerance is unclear. We now show that costimulation blockade using a donor‐specific transfusion and anti‐CD154 antibody applied to mice given bone marrow and simultaneously transplanted with skin allografts leads to hematopoietic chimerism and permanent skin allograft survival. Chimeric mice bearing intact skin allografts fail to generate effector/memory T cells against allogeneic targets as shown by the absence of IFNγ‐producing CD44^highCD8⁺ T cells and in vivo cytotoxicity. Depletion of Tregs by injection of anti‐CD4 or anti‐CD25 antibody prior to costimulation blockade prevents chimerism, shortens skin allograft survival and leads to generation of effector/memory cytotoxic T cells. Depletion of Tregs by injection of anti‐CD4 or anti‐CD25 antibody two months after transplantation leads to loss of skin allografts even though mice remain chimeric and exhibit little in vivo cytotoxicity. In contrast, chimerism is lost, but skin allografts survive following naïve T‐cell injection. We conclude that hematopoietic chimerism and peripheral tolerance may be maintained by different mechanisms in mixed hematopoietic chimeras.