Characterization of Human CD8(+)TCR(-) Facilitating Cells In Vitro and In Vivo in a NOD/SCID/IL2rγ(null) Mouse Model.

CD8(+)/TCR(-) facilitating cells (FCs) in mouse bone marrow (BM) significantly enhance engraftment of hematopoietic stem/progenitor cells (HSPCs). Human FC phenotype and mechanism of action remain to be defined. We report, for the first time, the phenotypic characterization of human FCs and correlation of phenotype with function. Approximately half of human FCs are CD8(+)/TCR(-)/CD56 negative (CD56(neg)); the remainder are CD8(+)/TCR(-)/CD56 bright (CD56(bright)). The CD56(neg) FC subpopulation significantly promotes homing of HSPCs to BM in nonobese diabetic/severe combined immunodeficiency/IL-2 receptor γ-chain knockout mouse recipients and enhances hematopoietic colony formation in vitro. The CD56(neg) FC subpopulation promotes rapid reconstitution of donor HSPCs without graft-versus-host disease (GVHD); recipients of CD56(bright) FCs plus HSPCs exhibit low donor chimerism early after transplantation, but the level of chimerism significantly increases with time. Recipients of HSPCs plus CD56(neg) or CD56(bright) FCs showed durable donor chimerism at significantly higher levels in BM. The majority of both FC subpopulations express CXCR4. Coculture of CD56(bright) FCs with HSPCs upregulates cathelicidin and ß-defensin 2, factors that prime responsiveness of HSPCs to stromal cell-derived factor 1. Both FC subpopulations significantly upregulated mRNA expression of the HSPC growth factors and Flt3 ligand. These results indicate that human FCs exert a direct effect on HSPCs to enhance engraftment. Human FCs offer a potential regulatory cell-based therapy for enhancement of engraftment and prevention of GVHD.

Immunology of vascularized composite allotransplantation: a primer for hand surgeons.

Vascularized composite allotransplantation is a recent innovation in the fields of transplantation surgery, plastic and reconstructive surgery, and orthopedic surgery. The success of hand and face transplantation has been based on extensive experience in solid organ transplantation. Advances in understanding the immunology of transplantation have had a major role in achieving excellent results in this new field. The purpose of this article is to introduce the basics of human immunology (innate and adaptive systems) and the immunological basis of human transplantation (the importance of human leukocyte antigen, direct and indirect pathways of antigen recognition, the 3 signals for T-cell activation, and mechanisms and types of allograft rejection) and focus on the mode of action of immunosuppressive drugs that have evolved as the mechanisms and pathways for rejection have been defined through research. This includes recent studies involving the use of costimulatory blockade, regulatory T cells, and tolerance induction that have resulted from research in understanding the mechanisms of immune recognition and function.

Bone marrow-derived dendritic cells pulsed with synthetic tumour peptides elicit protective and therapeutic antitumour immunity.

Dendritic cells, the most potent 'professional' antigen-presenting cells, hold promise for improving the immunotherapy of cancer. In three different well-characterized tumour models, naive mice injected with bone marrow-derived dendritic cells prepulsed with tumour-associated peptides previously characterized as being recognized by class I major histocompatibility complex-restricted cytotoxic T lymphocytes, developed a specific T-lymphocyte response and were protected against a subsequent lethal tumour challenge. Moreover, in the C3 sarcoma and the 3LL lung carcinoma murine models, treatment of animals bearing established macroscopic tumours (up to 1 cm2 in size) with tumour peptide-pulsed dendritic cells resulted in sustained tumour regression and tumour-free status in more than 80% of cases. These results support the clinical use of tumour peptide-pulsed dendritic cells as components in developing effective cancer vaccines and therapies.

Alloresistance to engraftment of allogeneic donor bone marrow is mediated by an Lyt-2+ T cell in mixed allogeneic reconstitution (C57BL/10Sn + B10.D2/nSn----C57BL/10Sn).

In the mixed allogeneic reconstitution (B10 + B10.D2----B10) model, alloresistance to engraftment of allogeneic donor results if the syngeneic component of the mixed bone marrow inoculum is not depleted of Lyt-2+ cells before transplantation. Resultant experimental animals repopulate as fully syngeneic, reject B10.D2 skin allografts, and are reactive to B10.D2 lymphoid cells in vitro, as assessed by mixed lymphocyte culture proliferative and cellular cytotoxicity assays. In contrast, depletion of Lyt-2-reactive cells from the syngeneic component of the mixed bone marrow inoculum results in mixed lymphopoietic chimerism and specific in vivo transplantation tolerance to B10.D2 allogeneic donor skin grafts and in vitro unreactivity to B10.D2 lymphoid elements. Full reactivity to third party is evident both in vitro and in vivo in these animals. This model may be helpful in further study of the syngeneic host-type cell phenotypes responsible for alloresistance to bone marrow engraftment.

Characterization of mixed allogeneic chimeras. Immunocompetence, in vitro reactivity, and genetic specificity of tolerance.

Mixed allogeneically reconstituted mice (B10 + B10.D2----B10) that specifically accept B10.D2 tail skin allografts were examined for in vivo and in vitro immunocompetence, patterns of hematopoietic repopulation, and in vitro reactivity. In vitro, mixed allogeneic chimeras (B10 + B10.D2----B10) manifested specific tolerance in mixed lymphocyte reactions and cell-mediated lympholysis to B10 and B10.D2 splenocytes, with normal responses to third-party (B10.BR) cells. Such chimeras were immunocompetent in B cell and helper T cell responses, as assessed by their primary plaque forming cell responses to in vivo sheep red blood cell immunization. This is in contrast to fully allogeneic chimeras, which responded less well. In addition, survival of the mixed allogeneic chimeras in a conventional animal facility was superior to that of fully allogeneic chimeras, and similar to syngeneically reconstituted (B10----B10) mice. Specific tolerance to skin grafts, degree of allogeneic engraftment, and persistence of chimerism was also assessed in a noncongenic mixed allogeneic combination (B10 + C3H----B10). Such animals manifested specific hyporeactivity to C3H skin allografts, but eventual chronic rejection of the grafts occurred in spite of stable and persistent mixed chimerism. MHC-congenic (B10.BR) skin grafts were accepted indefinitely in the same animals, suggesting that skin-specific non-major histocompatibility complex antigens were responsible for rejection of the C3H skin allografts.

In vivo and in vitro characterization of specific hyporeactivity to skin xenografts in mixed xenogeneically reconstituted mice (B10 + F344 rat----B10).

Mixed xenogeneically reconstituted mice (F344 rat + C57BL/10Sn----C57BL/10Sn), which specifically retain F344 tail skin xenografts, were studied for the specificity of such hyporeactivity and for in vitro reactivity and immunocompetence. Survival of mixed reconstituted animals was excellent, without evidence for graft vs. host disease. Donor-type tail skin grafts were specifically prolonged (mean survival time = 80 d) in comparison with normal controls and syngeneically reconstituted animals. In vitro, such animals manifested specific hyporeactivity by mixed lymphocyte reaction and cell-mediated lympholysis to F344 rat and B10 cells, with normal response to third-party rat (Wistar-Furth) and mouse (B10.BR). Examination of lymphoid tissues with a fluorescence-activated cell sorter revealed low levels, if any, of donor-type cells detectable. This system offers a model for investigation of xenogeneic transplantation tolerance.

Effect of class II antigen matching on renal allograft survival in miniature swine.

The benefit of class II major histocompatibility complex (MHC) antigen matching to renal allograft survival, in the absence of immunosuppression, has been studied in partially inbred miniature swine. Permanent (greater than 6 mo) renal allograft survival was found in 30% of recipients of either class II only or fully matched grafts. Analysis of the survival of the class II-only matched grafts by specific recipient/donor haplotype combinations indicated that survival was regulated by at least three genetic factors, including antigen gene dose, a class I MHC allele-dependent effect, and non-MHC-linked immune response phenomenon. Animals accepting class II-matched kidneys developed spontaneous tolerance to the graft, despite mounting an initial immune response marked by renal damage and the development of serum cytotoxic antibodies directed at the donor MHC antigens. The antibodies were only of the IgM class, suggesting that conversion of the humoral response to IgG was blocked. After acceptance of the kidney, three out of five animals showed specific prolongation of donor skin grafts. At the time of rejection of these skin grafts, no decrease in renal function nor reappearance of anti-donor antibodies was observed.

Cross-species transplantation tolerance: rat bone marrow-derived cells can contribute to the ligand for negative selection of mouse T cell receptor V beta in chimeras tolerant to xenogeneic antigens (mouse + rat----mouse).

Mixed xenogeneic bone marrow reconstitution (mouse + rat----mouse) results in stable mixed lymphopoietic chimerism (1-48% rat), long-term survival, and the induction of stable functional donor-specific transplantation tolerance to xenoantigens in vivo. To examine the role of negative selection of potentially xenoreactive T lymphocytes during tolerance induction across a species barrier, mixed xenogeneic chimeras (mouse + rat----mouse) were prepared and analyzed using a mixture of mouse and rat bone marrow cells for relative T cell receptor (TCR)-V beta expression on mouse T cells. In mixed xenogeneic chimeras (B10 mouse + rat----B10 mouse), T cell maturation proceeded normally in the presence of rat bone marrow-derived elements, and functional donor-specific tolerance to rat xenoantigens was present when assessed by mixed lymphocyte reactivity in vitro. V beta 5, which is expressed at high (undeleted) levels in normal B10 mice, was consistently deleted in B10 recipients of Wistar Furth (WF), but not F344 rat bone marrow, whereas the coadministration of either F344 rat or WF rat bone marrow with B10 mouse bone marrow cells resulted in a significant decrease in expression of TCR-V beta 11. Taken together, these data demonstrate for the first time that rat bone marrow-derived cells can contribute in a strain-specific manner to the ligand for negative selection of specific mouse TCR-V beta during tolerance induction across a species barrier.

Cross-species bone marrow transplantation: evidence for tolerance induction, stem cell engraftment, and maturation of T lymphocytes in a xenogeneic stromal environment (rat----mouse).

Transplantation of untreated F344 rat bone marrow into irradiated B10 mouse recipients (non-TCD F344----B10) to produce fully xenogeneic chimeras resulted in stable xenogeneic lymphoid chimerism, ranging from 82% to 97% rat. Survival of animals was excellent, without evidence for GVH disease. The specificity of tolerance which resulted was highly donor-specific; MHC disparate third party mouse and rat skin grafts were promptly rejected while donor-specific F344 grafts were significantly prolonged (MST greater than 130 days). Multi-lineage rat stem cell-derived progeny including lymphoid cells (T- and B-lymphocytes), myeloid cells, erythrocytes, platelets, and natural killer (NK) cells were present in the fully xenogenic chimeras up to 7 months after bone marrow transplantation. Immature rat T-lymphocytes matured and acquired the alpha/beta T-cell receptor in the thymus of chimeras in a pattern similar to normal rat controls, suggesting that immature T-lymphocytes of rat origin could interact with the murine xenogeneic thymic stroma to undergo normal maturation and differentiation. This model may be useful to study the mechanisms responsible for the induction and maintenance of donor-specific transplantation tolerance across a species barrier.

Sensitization to minor antigens is a significant barrier in bone marrow transplantation and is prevented by CD154:CD40 blockade.

Sensitization to major histocompatibility complex (MHC) alloantigens is critical in transplantation rejection. The mechanism of sensitization to minor histocompatibility antigens (Mi-HAg) has not been thoroughly explored. We used a mouse model of allosensitization to Mi-HAg to study the Mi-HAg sensitization barrier in bone marrow transplantation (BMT). AKR mice were sensitized with MHC congenic Mi-HAg disparate B10.BR skin grafts. Adaptive humoral (B-cells) and cellular (T cells) responses to Mi-HAg are elicited. In subsequent BMT, only 20% of sensitized mice engrafted, while 100% of unsensitized mice did. In vivo cytotoxicity assays showed that Mi-HAg sensitized AKR mice eliminated CFSE labeled donor splenocytes significantly more rapidly than naïve AKR mice but less rapidly than MHC-sensitized recipients. Sera from Mi-HAg sensitized mice also reacted with cells from other mouse strains, suggesting that Mi-HAg peptides were broadly shared between mouse strains. The production of anti-donor-Mi-HAg antibodies was totally prevented in mice treated with anti-CD154 during skin grafting, suggesting a critical role for the CD154:CD40 pathway in B-cell reactivity to Mi-HAg. Moreover, anti-CD154 treatment promoted BM engraftment to 100% in recipients previously sensitized to donor Mi-HAg. Taken together, Mi-HAg sensitization poses a significant barrier in BMT and can be overcome with CD154:CD40 costimulatory blockade.

Composite tissue allotransplantation: past, present and future-the history and expanding applications of CTA as a new frontier in transplantation.

Composite tissue allotransplantation (CTA) transplantation is currently being performed with increasing frequency in the clinic. The feasibility of the procedure has been confirmed in over 40 successful hand transplants, 3 facial reconstructions, and vascularized knee, esophageal, abdominal wall, and tracheal allografts. The toxicity of chronic, nonspecific immunosuppression remains a major limitation to the widespread availability of CTA and is associated with opportunistic infections, nephrotoxicity, end-organ damage, and an increased rate of malignancy. Methods to reduce or eliminate the requirement for immunosuppression would represent a significant step forward in the field. Mixed chimerism induces tolerance to solid organ and tissue allografts, including CTA. This overview focuses on the history and expanding applications of CTA as a new frontier in transplantation, and considers the important hurdles that must be overcome through research to allow widespread clinical application.

The history of human composite tissue allotransplantation.

Restoration of amputations and disfigurement are represented in ancient mythology, but the modern history of composite tissue allotransplantation begins with World War II injuries that generated seminal immunologic experiments by Medawar and co-workers. These studies led to the first successful human allografts in the 1950s by Peacock with composite tissue and Murray and co-workers with solid organs. Pharmacologic immunosuppression brought rapid growth of solid organ transplantation over the next 50 years, but composite tissue transplantation virtually disappeared. This evolution was judged to be a consequence of the greater antigenicity of skin, which that was insurmountable by the available immunosuppression. In the mid-1990s, progress in immunosupression allowed skin-bearing grafts, led by successful hand transplants, which produced a renaissance in composite tissue allotransplantation. Since then, graft types have expanded to over 10, and graft numbers to over 150, with success rates that equal or exceed solid organs. The field has emerged as one of the most exciting in contemporary medicine, although accompanied by substantial challenges and controversy. This paper reviews the origins and progress of this field, assessing its potential for future evolution.

Composite tissue transplantation: a rapidly advancing field.

Composite tissue allotransplantation (CTA) is emerging as a potential treatment for complex tissue defects. It is currently being performed with increasing frequency in the clinic. The feasibility of the procedure has been confirmed through 30 hand transplantation, 3 facial reconstructions, and vascularized knee, esophageal, and tracheal allografts. A major drawback for CTA is the requirement for lifelong immunosuppression. The toxicity of these agents has limited the widespread application of CTA. Methods to reduce or eliminate the requirement for immunosuppression and promote CTA acceptance would represent a significant step forward in the field. Multiple studies suggest that mixed chimerism established by bone marrow transplantation promotes tolerance resulting in allograft acceptance. This overview focuses on the history and the exponentially expanding applications of the new frontier in CTA transplantation: immunology associated with CTA; preclinical animal models of CTA; clinical experience with CTA; and advances in mixed chimerism-induced tolerance in CTA. Additionally, some important hurdles that must be overcome in using bone marrow chimerism to induce tolerance to CTA are also discussed.

Cells enriched in markers of neural tissue-committed stem cells reside in the bone marrow and are mobilized into the peripheral blood following stroke.

The concept that bone marrow (BM)-derived cells participate in neural regeneration remains highly controversial and the identity of the specific cell type(s) involved remains unknown. We recently reported that the BM contains a highly mobile population of CXCR4+ cells that express mRNA for various markers of early tissue-committed stem cells (TCSCs), including neural TCSCs. Here, we report that these cells not only express neural lineage markers (beta-III-tubulin, Nestin, NeuN, and GFAP), but more importantly form neurospheres in vitro. These neural TCSCs are present in significant amounts in BM harvested from young mice but their abundance and responsiveness to gradients of motomorphogens, such as SDF-1, HGF, and LIF, decreases with age. FACS analysis, combined with analysis of neural markers at the mRNA and protein levels, revealed that these cells reside in the nonhematopoietic CXCR4+/Sca-1+/lin-/CD45 BM mononuclear cell fraction. Neural TCSCs are mobilized into the peripheral-blood following stroke and chemoattracted to the damaged neural tissue in an SDF-1-CXCR4-, HGF-c-Met-, and LIF-LIF-R-dependent manner. Based on these data, we hypothesize that the postnatal BM harbors a nonhematopoietic population of cells that express markers of neural TCSCs that may account for the beneficial effects of BM-derived cells in neural regeneration.

T-cell depletion of allogeneic bone marrow using anti-alphabetaTCR monoclonal antibody: prevention of graft-versus-host disease without affecting engraftment potential in rats.

Bone marrow chimerism may solve two major limitations in the transplantation of solid organs and cellular grafts: (1) the requirement for life-long immunosuppressive therapy, and (2) acute and chronic rejection. When untreated bone marrow is transplanted into major histocompatibility complex (MHC)-disparate rats, lethal graft-vs-host disease (GVHD) occurs in the majority of recipients. T-cell depletion using anti-CD3 and anti-CD5 monoclonal antibody (mAb) to avoid GVHD led to an increased occurrence of failure of engraftment. We previously identified a cellular population in mouse bone marrow that facilitates engraftment of highly purified hematopoietic stem cells (HSC) across complete MHC barriers. In light of the fact that facilitating cells have a CD8+/CD3+/TCR- phenotype and mostly coexpress CD5, we evaluated in this study whether T-cell depletion of rat bone marrow using anti-alphabetaTCR mAb would retain engraftment potential yet avoid GVHD. T-cell depletion of bone marrow was performed using anti-alphabetaTCR mAb and immunomagnetic beads. Recipients were conditioned with 1100 or 1000 cGy of total body irradiation and reconstituted with 100 x 10(6) T-cell depleted (TCD) MHC- and minor antigen-disparate bone marrow cells. Animals were monitored clinically and histologically for GVHD. Chimerism was assessed by flow cytometry. Immunomagnetic bead depletion resulted in a reduction of T cells from 1.92%+/-0.21% to 0.10%+/-0.04% of total bone marrow. T-cell depletion did not remove facilitating cells (CD8+/alphabetaTCR-/gammadeltaTCR-/NK3.2.3-) from bone marrow. Further, the engraftment potential of TCD bone marrow was not affected, as 100% of animals engrafted and high levels of donor chimerism were detectable. Animals reconstituted with TCD bone marrow showed no clinical evidence of GVHD and histology revealed none to minimal changes, whereas recipients transplanted with untreated bone marrow succumbed to severe lethal GVHD. T-cell depletion using antialphabetaTCR mAb and immunomagnetic beads selectively removes T cells from the bone marrow graft while sparing facilitating cells that are required for engraftment of allogeneic bone marrow across MHC barriers. Moreover, the cells required for engraftment of HSC do not produce GVHD.

A partial conditioning strategy for achieving mixed chimerism in the rat: tacrolimus and anti-lymphocyte serum substantially reduce the minimum radiation dose for engraftment.

Development of partial conditioning strategies to achieve reliable engraftment of allogeneic bone marrow with minimum recipient morbidity could extend the therapeutic application of bone marrow transplantation (BMT) to enzyme deficiency states, hemoglobinopathies, autoimmune diseases, and the induction of tolerance for solid organ and cellular allografts. In this study we describe a nonmyeloablative rat BMT model and examine the effect of clinically available immunosuppressants on the minimum amount of total body irradiation (TBI) required for allogeneic engraftment. Donor ACI marrow was depleted of T cells using immunomagnetic beads and transplanted to major histocompatibility complex- and minor antigen-mismatched Wistar Furth (WF) rats (ACI --> WF) conditioned with varying doses of TBI. Recipients conditioned with TBI alone required myeloablation with 1000 cGy for reliable allogeneic marrow engraftment. Administration to WF recipients of a single dose of anti-lymphocyte serum (ALS) 5 days prior to BMT together with a limited course of tacrolimus (1 mg/kg/day) resulted in engraftment of ACI bone marrow at only 500 cGy TBI. ACI --> WF recipients were stable mixed chimeras (mean donor chimerism 49% at 330 days post-BMT). Chimerism was multilineage. All recipient animals were free of graft-versus-host disease. These results suggest that a nonmyeloablative conditioning strategy based on low-dose TBI and a limited course of tacrolimus plus ALS can produce long-term mixed multilineage chimerism.

A nonlethal conditioning approach to achieve engraftment of xenogeneic rat bone marrow in mice and to induce donor-specific tolerance.

BACKGROUND: The supply of solid organs for transplantation will never meet the growing demand. Xenotransplantation is considered to be a potential solution for the critical shortage of allografts. However, xenograft rejection is currently not controlled by conventional immunosuppressive agents. Bone marrow chimerism induces donor-specific tolerance without the requirement for chronic immunosuppressive therapy. The aim of this study was to develop a nonlethal recipient-conditioning approach to achieve mixed bone marrow chimerism and donor-specific tolerance. METHODS: C57BL/10SnJ mice were conditioned with total body irradiation followed by a single injection of cyclophosphamide on day +2. On day 0, mice were reconstituted with untreated bone marrow cells from Fischer 344 rats. Recipients were analyzed by flow cytometry for donor bone marrow engraftment and multilineage chimerism. Donor-specific tolerance was tested by skin grafting. RESULTS: One hundred percent of recipients engrafted after irradiation with 600 cGy total body irradiation, transplantation with 80 x 10(6) Fischer 344 bone marrow cells, and injection with 50 mg/kg cyclophosphamide intraperitoneally. Donor chimerism was detectable in all engrafted animals for up to 11 months. This conditioning was nonlethal, because conditioned untransplanted animals survived indefinitely. Mixed xenogeneic chimeras were tolerant to donor-specific skin grafts but rejected third-party (Wistar Furth) grafts as rapidly as naive C57BL/10SnJ mice. In contrast, animals that received less efficacious conditioning regimens and did not exhibit detectable chimerism showed prolonged graft survival, but delayed graft rejection occurred in all animals within 10 weeks. CONCLUSION: The induction of bone marrow chimerism and donor-specific tolerance after nonlethal conditioning might be useful to prevent the vigorous cellular and humoral rejection response to xenografts.

Mixed allogeneic chimerism achieved by lethal and nonlethal conditioning approaches induces donor-specific tolerance to simultaneous islet allografts.

We previously reported that donor-specific, but not third party, skin allografts were permanently accepted if mixed allogeneic (B10+BR-->B10) reconstitution and skin graft placement were performed sequentially or simultaneously in lethally conditioned (950 cGy) recipients. The purpose of the present study was to examine whether a similar outcome would occur if islets were placed coincident with the time of bone marrow infusion and to establish the minimum dose of cytoreduction sufficient to achieve chimerism and tolerance for simultaneous islet allografts. B10 (H-2b) mice were rendered diabetic using streptozotocin. After sustained hyperglycemia (> 300 mg/dl), diabetic B10 mice were irradiated (950 cGy) and reconstituted with 5 x 10(6) T cell-depleted (TCD) B10 + 15 x 10(6) TCD B10.BR bone marrow cells. Islet allografts genetically matched or disparate to the bone marrow donor were placed under the renal capsule within 24 hr following infusion of bone marrow cells. All donor-specific B10.BR mouse (H-2k) islet allografts were permanently accepted (n = 8; MST > or = 173 days), while 7 of 9 MHC-disparate third-party BALB/c mouse (H-2d) islet grafts were rejected. The other 2 allografts remained functional over 200 days posttransplantation. We recently established a nonlethal conditioning strategy to achieve multilineage mixed chimerism. We applied this model to examine whether simultaneous islet grafts matched to the donor would be permanently accepted if the donor was incompletely myeloablated. Diabetes was induced in B10 mouse recipients. Animals with hyperglycemia were conditioned with 500 cGy of TBI followed by an infusion of 15 x 10(6) untreated B10.BR bone marrow cells. A simultaneous islet allograft matched or MHC-disparate to the bone marrow donor was performed the same day. Two days following bone marrow transplantation, a single dose of cyclophosphamide (200 mg/kg) was injected via the intraperitoneal route. Islet allografts matched to the bone marrow donor were significantly prolonged (n = 9; MST > or 226 days) and showed no evidence for chronic rejection, while MHC-disparate grafts were rejected (n = 5; MST = 34 days). Animals that received islet grafts but no bone marrow also rejected their grafts with a similar time course. These data suggest that permanent donor-specific tolerance to islet allografts placed coincident with bone marrow transplantation can be achieved after lethal as well as incompletely myeloablative conditioning.

Mixed allogeneic chimerism in the rat. Donor-specific transplantation tolerance without chronic rejection for primarily vascularized cardiac allografts.

Graft loss secondary to chronic rejection remains a major source of morbidity and mortality in solid organ transplantation. Mixed chimerism has been suggested as one potential approach to overcome this limitation. Until now, whether long-term tolerance for primarily vascularized allografts can be achieved with mixed chimerism has not been adequately assessed due to technical limitations in the mouse and the inability to establish a reliable model of mixed chimerism in the rat. We now report that stable multilineage mixed hematopoietic chimerism can be achieved following the transplantation of a mixture of T cell-depleted syngeneic and allogeneic bone marrow cells into myeloablated rat recipients using a number of MHC plus minor antigen-disparate donor and recipient strain combinations (F344+WF-->F344, F344+ACI-->F344, WF+F344-->WF, and WF+ACI-->WF). Ninety-one percent of animals engrafted with a level of lymphoid chimerism ranging between 12% and 93% (73.3 +/- 4.8%). Peripheral blood lymphocyte chimerism remained stable for up to 13 months after reconstitution. Multilineage chimerism for lymphoid (T and B cells) and myeloid (granulocyte and macrophage) lineages was present, which suggests that engraftment of the pluripotent rat stem cell had occurred. There was no clinical or histologic evidence of graft-versus-host disease. Donor-specific skin (mean survival time [MST] > or = 177 days) and primarily vascularized cardiac (MST > or = 213 days) grafts were accepted without evidence for acute or chronic rejection. In contrast, MHC-disparate third-party skin (MST = 14 days) and cardiac grafts (MST = 13 days) were rapidly rejected. The tolerance was systemic, since donor-specific tolerance was present in vitro as assessed by the mixed lymphocyte proliferation assay. These data suggest that mixed chimerism prevents graft loss secondary to chronic rejection in skin as well as primarily vascularized grafts. Furthermore, a rat model for mixed allogeneic chimerism may provide insight into the mechanisms involved in tolerance induction for a variety of allografts (lungs, small bowel, limb, etc.) not readily transplantable in mouse recipients.