Recipient bone marrow engraftment in donor tissue after long-term tolerance to a composite tissue allograft

BACKGROUND: An important component of a composite tissue limb allograft (CTA) is the vascularized bone marrow and bone marrow stroma, which when transplanted could create immediate marrow space and engraftment. We have previously demonstrated that tolerance to musculoskeletal allografts can be achieved with a 12-day course of cyclosporine without the presence of long-term peripheral donor cell chimerism. The objective of this study was to determine the fate of the donor bone marrow after transplantation of a limb allograft in a miniature swine model. METHODS: CTAs from donor swine were heterotopically transplanted into six MHC-matched, minor-antigen-mismatched recipients, and a 12-day course of cyclosporine was given. Previous animals transplanted without cyclosporine rejected their grafts in less than 42 days. A non-MHC-linked marker, pig allelic antigen (PAA), was used to distinguish host and donor cells. Three PAA- animals received PAA+ CTAs, and three PAA+ animals received PAA- CTAs. Bone marrow was harvested from the donor limb grafts and the recipient and analyzed by flow cytometry and histology. Thymus, spleen, and mesenteric lymph nodes were also harvested from the recipient swine and evaluated for the presence of donor cells by flow cytometry. RESULTS: All animals receiving cyclosporine demonstrated permanent tolerance to their allografts. Donor bone marrow cells were present in all grafts at the time of transplantation and during the immediate postoperative period. By 48 weeks, donor cells were no longer detectable within the marrow space of the allograft. In long-term animals host bone marrow cells replaced donor cells in the graft marrow space. No evidence of donor cell engraftment was found in recipient animals. CONCLUSION: This study demonstrates that in long-term tolerant recipients of musculoskeletal allografts there is no evidence of persistent donor bone marrow cells in the hematopoietic tissues of the graft or the host. Rather, the recipient's bone marrow cells and lymphocytes repopulate the donor marrow space of the graft.     

Composite tissue (limb) allografts in rats. II. Indefinite survival using low-dose cyclosporine

Cyclosporine has reawakened interest in transplantation of peripheral composite tissue allografts (CTA) of skin, muscle, bone, vessel, and nerves. The purpose of this study was to examine whether cyclosporine could produce indefinite survival of CTA. Two groups of LEW recipients of LBN limb transplants were given different long-term treatments of cyclosporine. Tolerance was achieved in many of the animals. Several possibilities for the mechanism of this tolerance are discussed.     

Long-term survival of cardiac allografts in lethally irradiated rats repopulated with host-type hemopoietic cells.

To test the hypothesis that hemopoietic cells within a tissue graft are responsible for its immunogenicity, two experimental protocols were followed. LEW hearts were grafted into (LEW X BN)F-1 host rats and LEW or F-1 lymphocytes were injected into the apex of the grafted heart. The LEW but not the F-1 cells induced a local reaction, apparently because the circulating F-1 cells were the necessary immunogens. The second protocol took advantage of the knowledge that lethally irradiated LEW rats were able to reject WF Ag-B-incompatible hemopoietic cells (but not tissue allografts) within a few days. LEW rats were lethally irradiated and grafted with WF hearts on day 0. A mixture of LEW marrow, thymus, spleen and lymph node cells, or marrow cells only were infused either on day 0 or day 2. Cardiac allografts in hosts repopulated with the mixture of lymphoid cells survived a mean of 11.3 days in hosts infused on day 0, but survived indefinitely if the lymphoid cells were infused on day 2. The 2-day interval also prolonged the survival of allografts in rats infused with only marrow cells. The long-term recipients, without any further treatment, rejected WF skin grafts as first-set reactions 1 year later but did not reject second WF cardiac allografts. Lymphoid cells from long-term recipients imparied the rejection of WF cardiac allografts by LEW host rats. The lack of rejection of the original cardiac allograft supported the hypothesis tested. Certain hemopoietic cells responsible for the immunogenicity of cardiac allografts were probably eliminated in the 2-day interval at least in part by host effector cells capable of rejecting allogeneic hemopoietic cells. However, the mechanism of long-term "unresponsiveness" to WF hearts could have been caused by loss of accessory cells during the 2-day interval followed by infusion of immunocompetent cells. Skin rejections in these recipients may have been attributable to reactions against skin differentiation-specific antigens.     

Use of Regression Analysis and Flow Cytometry for Determining Levels of Mixed Semiallogeneic Immune Chimerism

Ramon Llull was a participant in a joint PhD program at the Department of Surgery, University of California, Irvine, California, USA

It has been shown that tolerance or specific immunologic nonresponsiveness in various lymphohemopoietic transplant models can be associated with the development of mixed Lymphoid chimerism. As a specific example, composite tissue (limb) allografts were studied as a model for vascularized bone marrow transplantation (VBMT) and it was demonstrated that development of stable cellular immune chimerism is associated with long-term allograft survival. Recently, studies were initiated using a new parental to hybrid VBMT model, but the detection of donor cells is complicated, due to the fact that they share one parental allotypic determinant, Therefore, regression analysis with a flow cytometric immunofluorescent staining assay was evaluated for the assessment of cellular lymphoid chimerism in donor parental to hybrid (P-F₁) lymphohemopoietic transplant models. Standard curves consisting of known mixed populations of parental donor (Lewis, LEW) and hybrid host F₁ (Lew × BN, LBN) lymphocytes were established. Standard curves were analyzed by linear regression statistics and excellent coefficients of determination (r >.881) were obtained for all standard curves. A highly statistically significant (p <. 016) linear relationship between level of donor cell chimerism (independent variable) and percent stained (dependent variable) was determined. The technique was then evaluated using the parental to hybrid VBMT model. Levels of donor LEW lymphoid chimerism in all VBMT LBN recipients were successfully assessed by regression analysis and inverse prediction using distinct recipient allodeterminant markers. In conclusion, this technique was proven to be reliable and accurate for the detection of chimerism in parental to F₁ lymphohemopoietic allograft models.     

Donor DNA can be detected in recipient tissues during rejection of allograft

Abstract The main source of donor DNA in recipients of allograft are “passenger” cells. It is claimed that they are responsible for the posttransplantation microchimerism and prolongation of allograft survival. We have observed that besides cellular microchimerism, donor DNA can be found in the recipient tissues at the time of rejection of the allograft. In this study, we provide evidence for the presence in the recipient of both DNA in “passenger cells” and free DNA in tissues at the terminal stage of rejection. Male BN (RT1 n) rat heart or skin was transplanted to female LEW (RT1 1) rats followed by a vascularized bone marrow in a hind‐limb transplant. In another group, heart and skin were transplanted followed by immediate i. v. infusion of donor‐type bone marrow cells. CsA was given in a dose of 17 mg/kg body weight for 30 days, then the rats were followed up until day 100 unless rejection occurred earlier. LEW blood, spleen, mesenteric node and bone marrow cells were stained with moAb OX27 specific for BN but not LEW. Genomic male DNA was isolated and amplified with SRY oligonucleotide. At day 30 and day 100 cellular microchimerism was detected in blood, spleen, nodes and bone marrow cells. Donor DNA was detected in recipient skin, liver and heart extracts, as well as lymphoid organs, at the time of rejection of allograft, but not when the rats were maintained on CsA. Taken together, donor DNA was detected in recipient tissues at the time of heart or skin rejection. It appeared to be released from cells of rejecting grafts and not from “passenger” cells, representing only a minor cellular mass compared with the graft.     

Donor cell engraftment in recipient lymphoid tissues after rat limb allograft

BACKGROUND: The movement of cells from a transplanted tissue into the host organs, the so-called systemic chimerism, is a phenomenon known to occur and be associated with the development of immunologic tolerance in allotransplantation cases. The purpose of this study was to identify donor cell engraftment in recipient lymphoid tissues after performing rat hind limb allograft. MATERIALS AND METHODS: Fifty-five whole-limb allotransplantations were performed in sex-mismatched pairs of rats. Syngeneic male Lewis and allogeneic Dark Agouti donors were transplanted to female Lewis recipients. FK506 was used for immunosuppression. Donor male cells could be identified in the recipient female tissues by semiquantitative polymerase chain reaction analysis for a Y chromosome-specific DNA sequence. Chimerism was assessed at 1, 24, and 48 weeks after transplantation. RESULTS: There was no rejection episode in any of the limb grafts. Although levels of chimerism were highly variable in each lymphoid tissue, a gradual increase was noticed in all during the course of time. At 1 week after the transplant period, only intrasplenic chimerism was at high level (1%) in three groups. At 48 weeks after the transplant, all recipients with allografts showed very high level (10%) of chimerism in the bone marrow. Two, two, and two of six recipients showed very high levels in the spleen, lymph node, and liver, respectively, at 48 weeks. Intrathymic chimerism was higher at 24 weeks after transplant rather than at 48 weeks. CONCLUSION: We demonstrated donor cell engraftment into recipient lymphoid tissues after successful whole limb transplantation. We conclude that limb allograft can work as a vascularized carrier for the bone marrow transplantation, provide a continuous source of donor cells and contribute to chimerism in the recipient.     

Immunologic consequences of combined pancreas-spleen transplantation in the rat

A rat model of combined pancreas-spleen transplantation (PST) was used in order to characterize the immunologic consequences of PST when compared to pancreas transplantation (PT) alone. Weakly MHC disparate Fischer (F344) PST grafts survived significantly longer in LEW recipients than did F344 PT grafts (17.6 +/- 3.4 vs 12.1 +/- 1.0 days, respectively, P less than 0.001). However, graft versus host disease (GVHD) occurred regularly in the PST recipients. Similarly, in haploidentical LBN to LEW donor-recipient pairs, PST graft survival was also modestly but significantly increased over that of the PT controls (10.6 +/- 1.0 vs 8.5 +/- 0.8 days, respectively, P less than 0.001). Conversely, in the ACI to LEW combination where MCH differences are very strong, PST graft survival was not longer than PT controls (7.5 +/- 0.8 vs 7.0 +/- 0.6 days, respectively, P greater than 0.2). GVHD was not observed in either of the latter two experiments. Short-term immunosuppression with cyclosporine further improved the outcome in LEW recipients of F344 grafts by inducing long-term graft survivals in approximately one-fourth of the PST recipients. Host splenectomy did not improve graft survival in PST recipients but did increase the risk of GVHD in LEW recipients of F344 PST grafts. Graft irradiation prior to transplantation with 500 rad not only abrogated the GVHD potential of the F344 PST graft but also eliminated the graft survival prolonging effect of the donor spleen. Donor spleen cells injected at the time of PT in F344 to LEW transplants resulted in graft prolongation not different from spleen intact PST recipients.(ABSTRACT TRUNCATED AT 250 WORDS)     

Donor hematopoietic progenitor cells in nonmyeloablated rat recipients of allogeneic bone marrow and liver grafts

BACKGROUND: Although the persistence of multilineage microchimerism in recipients of long-surviving organ transplants implies engraftment of migratory pluripotent donor stem cells, the ultimate localization in the recipient of these cells has not been determined in any species. METHODS: Progenitor cells were demonstrated in the bone marrow and nonparenchymal liver cells of naive rats and in Brown Norway (BN) recipients of Lewis (LEW) allografts by semiquantitative colony-forming unit in culture (CFU-C) assays. The LEW allografts of bone marrow cells (BMC) (2.5x10(8)), orthotopic livers, or heterotopic hearts (abdominal site) were transplanted under a 2-week course of daily tacrolimus, with additional single doses on days 20 and 27. Donor CFU-C colonies were distinguished from recipient colonies in the allografts and recipient bone marrow with a donor-specific MHC class II monoclonal antibody. The proportions of donor and recipient colonies were estimated from a standard curve created by LEW and BN bone marrow mixtures of known concentrations. RESULTS: After the BMC infusions, 5-10% of the CFU-C in the bone marrow of BN recipients were of the LEW phenotype at 14, 30, and 60 days after transplantation. At 100 days, however, donor CFU-C could no longer be found at this site. The pattern of LEW CFU-C in the bone marrow of BN liver recipients up to 60 days was similar to that in recipients of 2.5x10(8) BMC, although the donor colonies were only 1/20 to 1/200 as numerous. This was expected, because the progenitor cells in the passenger leukocytes of a single liver are equivalent to those in 1-5x10(6) BMC. Using a liquid CFU-C assay, donor progenitor cells were demonstrated among the nonparenchymal cells of liver allografts up to 100 days. In contrast, after heart transplantation, donor CFU-C could not be identified in the recipient bone marrow, even at 14 days. CONCLUSION: effective immunosuppression, allogeneic hematopoietic progenitors compete effectively with host cells for initial engraftment in the bone marrow of noncytoablated recipients, but disappear from this location between 60 and 100 days after transplantation, coincident with the shift of donor leukocyte chimerism from the lymphoid to the nonlymphoid compartment that we previously have observed in this model. It is possible that the syngeneic parenchymal environment of the liver allografts constitutes a privileged site for persistent progenitor donor cells.     

Role of thymus in operational tolerance induction in limb allograft transplant model

BACKGROUND: In this study, we evaluated the role of host thymus in tolerance induction in composite tissue allografts (CTA) across major histocompatibility complex (MHC) barrier during a 7-day alphabeta- T-cell receptor (TCR)/ cyclosporine A (CsA) protocol. MATERIALS AND METHODS: A total of 62 limb allograft transplants were studied. Euthymic (group A) and thymectomized (group B) Lewis recipients (LEW, RT1(1)) received vascularized hind-limb allografts from hybrid Lewis x Brown-Norway (F1), (LBN, RT1(1+n)) donors. Mixed lymphocyte reaction (MLR) and skin grafting assessed donor-specific tolerance in vitro and in vivo, respectively. Flow cytometry determined the efficacy of immunosuppressive protocols and the presence of donor-specific chimerism. Immunocytochemistry revealed the presence of donor-specific cells in the lymphoid organs of recipients. RESULTS: Isograft transplants survived indefinitely. For thymectomized rats, the median survival time (MST) of limb allograft in non-treated recipients was 7 days; monotherapy with alphabeta-TCR extended MST to 16 days, and CsA therapy extended it to 30 days. Using the alphabeta-TCR/CsA protocol, the MST of allografts was 51 days. For euthymic rats, the MST of limb allograft in non-treated recipients was 7 days; monotherapy with alphabeta-TCR or CsA extended MST to 13 or 22 days, respectively. Treatment with alphabeta-TCR/CsA resulted in indefinite allografts survival (MST=370 days). MLR and skin grafting confirmed donor-specific tolerance in euthymic recipients. Flow cytometry showed stable chimerism in the euthymic rats and transient chimerism in thymectomized limb recipients. Immunoperoxidase staining revealed the persistence of donor-derived cells in the lymphoid tissues of euthymic recipients. CONCLUSION: We found that the presence of thymus was imperative for the induction of donor-specific tolerance in rat hind-limb composite tissue allografts using a alphabeta-TCR/CsA protocol.     

New composite tissue allograft model of vascularized bone marrow transplant: the iliac osteomyocutaneous flap

Vascularized bone marrow transplant (VBMT) induces donor-specific chimerism in experimental models across the major histocompatibility barrier. An experimental model for immunotolerance studies should sustain a high antigenicity with low morbidity. Accordingly, we introduced an iliac bone osteomusculocutaneous (IBOMC) transplant model in rat. It consists of a large skin component and an abundant bone marrow cells (BMC) population. We tested this model with isograft transplantations between Lewis rats (RT1^l) and with allograft transplantation between Lewis-Brown Norway (LBN RT1^l + n) donors and Lewis (RT1^l) recipients under low dose of cyclosporine A monotherapy. Immunologic responses were tested for donor cell engraftment and chimerism induction. All isografts survived indefinitely and allografts were viable at 200 days post-transplant under low dose of cyclosporine A. Microangiography of the graft revealed preservation of skin, muscle, and bone components. Histologic examination confirmed viability of all allograft components without signs of rejection. Long-term engraftment of donor-origin (RT1ⁿ) BMC was confirmed by donor-specific chimerism (1.2%) in peripheral blood and bone marrow (1.65%) compartments and by engraftment into lymphoid organs of recipients. The IBOMC transplant proved to be a reliable composite tissue allotransplantation (CTA) model. Moreover, because of its robust bone marrow component and large skin component, it is applicable to studies on immunologic responses in CTA.     

Examination of the mechanisms responsible for tolerance induction after intrathymic inoculation of allogeneic bone marrow.

OBJECTIVE: This study examined the immunologic mechanism(s) responsible for the induction of transplantation tolerance in rats pretreated with intrathymic inoculation of donor strain bone marrow. SUMMARY BACKGROUND DATA: Induction of unresponsiveness may involve deletion and/or inactivation of donor-reactive T-cell precursors maturing in a thymus harboring donor alloantigen or generation of regulatory/suppressor cells. It was reasoned that, if unresponsiveness is caused by deletion of alloreactive clones, the presence of additional thymic tissue devoid of donor alloantigen permits normal maturation of T-cells and, thus, prevents induction of tolerance. However, if unresponsiveness were primarily mediated by regulatory/suppressor cells, the presence of noninoculated thymic tissue should not affect the induction of tolerance. METHODS: Three strategies were used to define the cellular basis of cardiac and islet allograft survival in WF recipients of intrathymic LEW donor bone marrow as follows: (1) inoculation of bone marrow either into the native thymus and/or into an ectopic thymus, (2) limiting dilution analyses of the frequency of precursor cytotoxic T-lymphocytes (CTLp), and (3) adoptive transfer to syngeneic secondary hosts. RESULTS: Inoculation of bone marrow into only one lobe of the native thymus and/or into an ectopic thymus did not promote consistent survival of subsequent LEW cardiac allografts. Tolerant hosts displayed significant reductions in CTLp frequencies against donor alloantigens. Adoptive transfer of spleen cells from tolerant WF hosts harboring long-standing cardiac allografts led to permanent survival of LEW cardiac allografts in all secondary recipients. However, transfer of spleen cells from WF animals that received intrathymic LEW bone marrow (but no cardiac allograft) did not promote survival of LEW cardiac allografts in naive secondary hosts. CONCLUSIONS: These results indicate that the unresponsive state after intrathymic inoculation of bone marrow cells is primarily mediated by deletion and/or inactivation of donor-specific T-cell precursors maturing in a chimeric thymus. The demonstration by adoptive transfer studies of putative regulatory/suppressor cells suggested an important role for the persistence of donor alloantigen (supplied by a vascularized allograft) in the maintenance of the unresponsive state.     

Induction of tolerance to hind limb allografts in rats receiving cyclosporine A and antilymphocyte serum: effect of duration of the treatment

BACKGROUND: This study assessed the ability of antilymphocyte serum (ALS) and cyclosporine A (CsA) to induce tolerance for hind limb composite tissue allograft in rats without chronic immunosuppression. METHODS: Hind limb transplantations were performed in Lewis-Brown-Norway (LBN, RT1(1+n)) and Lewis (LEW, RT1(1)) rats. Treatment consisted of ALS only (0.4 mL/kg), CsA only (16 mg/kg), and a combination of CsA and ALS, and it was administered 12 hr before surgery at three different intervals (7, 14, and 21 days). Long-term survivors were tested for tolerance by standard skin grafting from the recipient (LEW), the donor (LBN), and the third party (ACI, RT1 ) 60 days after cessation of the treatment and by mixed lymphocyte reaction at 100 days. T-cell lines were analyzed with flow cytometry. RESULTS: Single use of ALS in all treatment intervals did not prolong allograft survival. Single use of CsA extended survival up to 23 days in the 21-day protocol group. CsA and ALS caused indefinite survival in two of six rats in the 14-day protocol and in all six rats in the 21-day protocol (>420 days). The six long-term survivors in the 21-day protocol accepted the skin grafts from the donor (LBN) and the recipient (LEW) and rejected third-party grafts (ACI). Tolerant animals showed a donor-specific hematopoietic chimerism of 35% to 42% in the peripheral blood. Mixed lymphocyte reaction assay demonstrated tolerance to the host and donor alloantigens and increased response to the third party. CONCLUSIONS: Administration of CsA and ALS for 21 days induced donor-specific tolerance in the recipients of the rat hind limb composite tissue allografts. The mechanism of tolerance should be investigated further.     

Induction of tolerance in composite-tissue allografts

BACKGROUND: Transplantation of composite-tissue allograft (CTA) such as the human hand recently became a clinical reality. The high risks associated with the use of lifelong immunosuppression have been the prohibiting factor in the routine use of the CTA transplants. In this article, we present a new approach of inducing long-term, donor-specific tolerance to CTAs without recipient preconditioning and need for chronic immunosuppression. METHODS: We have developed a clinically applicable 35-day protocol that induces donor-specific tolerance in a rat hindlimb-transplantation model across major histocompatibility complex (MHC) barrier [Lewis-Brown-Norway (LBN, RT1 -->F1) to Lewis (LEW, RT1 ) by using cyclosporine A (CsA) and a mouse monoclonal antibody against rat alphabeta-T-cell receptor (TCR) to systemically eliminate alloresponsive cells. Standard skin grafting, flow cytometry (FC), and mixed lymphocyte reaction (MLR) were used to assess efficacy of immunodepletion and confirm donor-specific tolerance and chimerism. RESULTS: Under this protocol long-term tolerance (>720 days) was induced in all (n=5) CTA recipients across the MHC barrier without further need for immunosuppression. Tolerance was confirmed in all limb-allograft recipients by skin grafting in vivo and by MLR in vitro. The animals rejected third-party grafts, indicating immunocompetence. CONCLUSIONS: In this CTA model, combined protocol of alphabeta-TCR monoclonal antibody and CsA resulted in induction of donor-specific tolerance across the MHC barrier without recipient conditioning. We believe that our findings will foster development of new therapeutic strategies and expand clinical applications for composite-tissue transplantation.     

Immunosuppressive and trafficking properties of donor splenic and bone marrow dendritic cells

BACKGROUND: Infusion of donor dendritic cells (DC) has been shown to prolong allograft survival in a number of models. However, many regimens that utilize donor DC do not consistently produced tolerance or long-term allograft survival. We hypothesized that one factor limiting the therapeutic effect of donor DC is their relative inability to traffic to recipient peripheral lymph nodes and inhibit the function of resident alloreactive T cells. METHODS: Donor strain DC isolated from the spleens or bone marrow of Flt3L-treated mice were transferred intravenously into recipients at the time of skin grafting. Where indicated, recipients were treated with an anti-CD40L antibody and CTLA4-Ig. RESULTS: Infusion of donor DC together with costimulatory blockade promoted donor-specific prolongation of skin allograft survival in mice. Perhaps due to their more immature phenotype, bone marrow DC trafficked more effectively to the spleen, bone marrow, and thymus and were associated with significantly longer allograft survival than were splenic DC. Neither population of DC trafficked well to peripheral lymph nodes. Consistent with our hypothesis, splenic but not lymph node T cells from DC-treated recipients displayed donor-specific hyporesponsiveness in vitro. CONCLUSION: These data suggest that one factor contributing to rejection following treatment with donor DC plus costimulation blockade is the persistence of donor-reactive T cells within the recipient's secondary lymphoid structures. Strategies to improve DC trafficking to these structures may enhance their therapeutic effect.     

Characterization of host lymphoid cells in antibody-facilitated bone marrow chimeras

We have produced stable murine antibody-facilitated (AF) chimeras by the simultaneous injection of P1 bone marrow cells and anti-P2 monoclonal antibody into normal (unirradiated) adult (P1 X P2)F1 recipients. These AF chimeras are healthy, long-lived, and exhibit no overt signs of graft-versus-host disease. They are immunocompetent and tolerant of host, P2-encoded alloantigens. Donor cell engraftment and takeover, monitored by glucosephosphate isomerase isozyme patterns, is usually complete (greater than 95%) in the peripheral blood, bone marrow, and hemopoietic stem cell compartments of long-term (greater than 3 months posttransplantation) AF chimeras. We report here, however, that splenic, lymph node, and thymic leukocytes of AF chimeras represent donor/host chimeric populations. Spleen cell populations of AF chimeras exhibit substantial chimera-to-chimera variation in the preponderant residual host cell type(s) present. Our interpretations of the implications of these findings are discussed.     

Enhancement of rat renal allografts with monoclonal antibody.

Treatment of rat allograft recipients before grafting with donor spleen cells and whole, pooled antidonor alloimmune serum results in indefinite renal allograft survival. The enhancement is immunologically specific. In these experiments a monoclonal, homogenous anti-BN antibody was produced by a hybridoma clone created by fusing the mouse-P3 myeloma with spleen cells from Lewis rats immunized with BN lymphoid cells. The hybridoma supernatent enhanced survival of LBN renal allografts in Lewis recipients as effectively as whole Lewis anti-BN antiserum. Dilution of the hybridoma supernatent by tenfold or a hundredfold abrogated the enhancement effect.     

Splenectomy and renal allograft survival in the rat

The effect of splenectomy on renal allograft survival is not clear. In the rat, spleens isolated from recipients with functioning grafts have been shown to be a major source of cells that are capable of suppressing the rejection response (suppressor T lymphocytes). Thus the removal of the spleen in these allograft recipients could be detrimental to renal allograft survival. This study investigates this hypothesis, and looks for the presence of suppressor cells in other lymphoid organs apart from the spleen. In the rat renal allograft model, donor Lewis spleen cells given to DA recipients intravenously 1 week before transplantation of a Lewis kidney leads to indefinite allograft survival (median survival time (MST) greater than 100 days). Splenectomy before or after pretreatment with donor spleen cells failed to abrogate this effect (MST greater than 100 days). Experiments were performed in which cells or serum were prepared from long-term surviving splenectomized animals which had already been pretreated and transplanted, and then were injected into untreated recipients (adoptive transfer experiments). This was done to determine if cells capable of suppressing graft rejection were present in lymphoid organs outside the spleen in these splenectomized recipients. Thus the IV transfer of 10(8) lymph node cells harvested from splenectomized DA recipients with a long-term surviving LEW graft (LTS), into untreated but lightly irradiated (200 rad) DA recipients resulted in indefinite survival of a fresh Lewis kidney (MST greater than 100 days). In contrast, adoptive transfer of normal DA lymph node cells was ineffective (MST 13 days). Thus splenectomy is not necessarily detrimental to graft survival, as cells capable of preventing graft rejection are found in other lymphoid organs, such as lymph nodes, in splenectomized recipients.     

Alloreactive T suppressor cells in the rat. I. Evidence of three distinct subsets of splenic suppressor T cells resistant to cyclosporine

In this study we examined the effect of cyclosporine on three distinct subsets of T suppressor (Ts) cells identified in a rat renal allograft model. Ts inducer (Ts1) cells having the CD4 marker are found in the spleens of DA rats undergoing acute rejection of LEW kidneys. Transducer (Ts2) and effector (Ts3) cells both carry the CD8 marker and are found in the spleens of long-term surviving DA rats bearing LEW kidney allografts made tolerant by donor-specific blood transfusions or by cyclosporine (in most cases). These latter cells are distinguished by their susceptibility to cyclophosphamide (CY), Ts2 cells being resistant while Ts3 cells are sensitive to CY. When Ts cells from DA rats undergoing acute graft rejection of LEW kidneys or bearing long-term-surviving LEW kidneys that had been treated with cyclosporine (10mg/kg/day) for 2 or 10 days, respectively, were adoptively transferred into lightly irradiated DA recipients, these cells were still able to specifically induce long-term survival of LEW kidneys. LEW kidney survival was not prolonged in DA rats given no cells or cells from rats treated with cyclosporine for 10 days. Thus it would appear that the three functional subsets of Ts cells demonstrated in this renal allograft model by adoptive transfer of spleen lymphocytes are not inhibited by cyclosporine, suggesting that this resistance of Ts cells to cyclosporine may be partly responsible for the immunosuppressive effect of this agent.     

Suppressed alloreactivity and mixed chimerism in rats with accepted cardiac allografts by intrathymic injection of donor bone marrow cells

Intrathymic injection of donor bone marrow cells (ITBMCs) at the time of transplantation and treatment with antilymphocyte serum (ALS) permitted the indefinite survival of Brown Norway (BN, RT1ⁿ) rat heart grafts in 6 out of 8 Lewis (LEW, RT1^l) rat recipients. LEW recipients with long-surviving BN heart grafts (LSGs) also accepted additional BN heart grafts without further immunosuppression, though they rejected Piebald Virol Glaxo (PVG, RT1^c) rat heart grafts in the usual fashion. In the in vitro study, the proliferative response of the lymphocytes from LEW recipients with LSGs remained suppressed when they were stimulated by BN spleen cells, but not when stimulated by PVG cells. Bone marrow cells (BMCs) from LEW rats with LSGs showed strong, nonspecific, suppressive effects on the proliferative response in the mixed lymphocyte culture reaction, suggesting that one of the possible explanations for tolerance might be the involvement of a suppressor mechanism. Received: 7 August 1996 Received after revision: 12 February 1997 Accepted: 17 February 1997     

Chronic graft-versus-host disease in rats after syngeneic bone marrow transplantation

A disease similar to the chronic graft-versus-host disease (cGVHD) seen following transplantation of human bone marrow was observed after syngeneic and allogeneic bone marrow transplantation in rats. Bone marrow grafts were exchanged between donors and recipients that were syngeneic or genetically different for the RT2 erythrocyte antigen locus by the use of AUG/AUG.2B and PVG/PVG.2A congenic pair donor/recipient strain combinations. After an initial period of well-being (120-180 days posttransplantation), several AUG and AUG.2B recipients of syngeneic or RT2-mismatched bone marrow developed clinical signs compatible with cGVHD. The clinical signs of the disease included: erythema, diffuse alopecia, thickened skin folds, and conjunctivitis. Laboratory findings included peripheral blood eosinophilia and impaired in-vitro proliferative responses to third-party spleen cells in the mixed lymphocyte reaction. Histological examination of the tissues of a limited number of rats with cGVHD showed subepidermal mononuclear inflammation with atrophy of the epidermis and adnexa of the skin, as well as plasmacytic hyperplasia of the lymphoid tissues. None of the PVG or PVG.2A recipients of syngeneic or RT2-mismatched marrow developed cGVHD. The development of cGVHD in AUG.2B recipients of syngeneic marrow and the absence of the disease in reciprocal marrow grafts between the PVG/PVG.2A rat strains suggests that the development of the disease in the AUG and AUG.2B recipients of RT2-mismatched bone marrow is not due to the RT2 disparity, but may be due to an autologous immune reaction. Furthermore, the finding that the cGVHD is only observed when the AUG and AUG.2B strains are used as recipients--not when the PVG or PVG.2A strains are used as recipients--suggests that the development of the disease is associated with the genetic background of the host and is independent of the background of the donor. It is possible that the use of high-dose cyclophosphamide treatment is involved in the pathogenesis of cGVHD, because the disease is observed only when the recipients are conditioned for transplantation with this immunosuppressive agent.