Immunomagnetic T-lymphocyte depletion (ITLD) of rat bone marrow using OX-19 monoclonal antibody

Graft versus host disease (GVHD) may be abrogated and host survival prolonged by in vitro depletion of T lymphocytes from bone marrow (BM) prior to allotransplantation. Using a mouse anti-rat pan T-lymphocyte monoclonal antibody (OX19) bound to monosized, magnetic, polymer beads, T lymphocytes were removed in vitro from normal bone marrow. The removal of the T lymphocytes was confirmed by flow cytometry. Injection of the T-lymphocyte-depleted bone marrow into fully allogeneic rats prevents the induction of GVHD and prolongs host survival.     

Induction of stable chimerism and elimination of graft-versus-host disease by depletion of T lymphocytes from bone marrow using immunomagnetic beads

The goal of transplantation is the induction of immunologic tolerance. At present, nonspecific immunosuppression is used to prevent graft rejection and, commonly, graft-versus-host disease (GVHD). Nevertheless, nonspecific immunosuppressive therapy is frequently complicated by infection, malignant tumors, and drug toxicity. In order to examine whether hematopoietic chimerism can be used to induce specific allograft tolerance, we have reconstituted lethally irradiated Lewis rats with ACI bone marrow that has been depleted of T cells with use of immunomagnetic beads. This technique consists of binding OX-19, a mouse anti-rat pan-T lymphocyte monoclonal antibody, to magnetic polymer beads. Mixing of bone marrow or splenocytes with the bead/OX-19 complexes, followed by magnetic separation, results in significant depletion of T cells with minimal nonspecific cell loss. Immunomagnetic T-cell depletion of bone marrow, followed by reconstitution of a lethally irradiated host, allows for the development of stable, mixed hematopoietic chimerae without evidence of GVHD. These hosts are immunocompetent by clinical criteria. Recipients of untreated donor bone marrow that did or did not receive nonspecific immunosuppression demonstrated varying degrees of GVHD and reduced survival. The ability to rapidly and simply deplete T lymphocytes from bone marrow and produce stable, immunocompetent hematopoietic chimerae without GVHD may be an important method for tolerance induction to vascularized allografts.     

Depletion of T cells from human bone marrow using monoclonal antibodies and rabbit complement. A quantitative and functional analysis

Graft-versus-host-disease (GVHD) remains the principal complication of allogeneic bone marrow transplantation. In animal models mature T lymphocytes have been shown to be responsible for GVHD and, therefore, in vitro treatment of donor bone marrow using monoclonal T cell specific antibodies and complement is currently being investigated as a strategy for the prevention of GVHD. In the present studies anti-T12 and anti-T11 monoclonal antibodies and rabbit complement were used to remove T lymphocytes from normal bone marrow. The efficacy of depletion was investigated by immunofluorescence assays and by in vitro culture of the residual cells using nonspecific mitogens or allogeneic B cells as the proliferative stimulus in the presence of lymphocyte-conditioned medium containing interleukin 2 (IL-2). Immunofluorescence analysis showed complete depletion of T12+ and T11+ cells after treatment with the respective antibodies and with the combination. Nevertheless, culture of treated bone marrow with phytohemagglutinin (PHA) or concanavalin A (Con A) and conditioned media containing IL-2 resulted in the proliferation of mature T cells (T3+, T4+ or T8+, T11+). Stimulation of treated marrow with allogeneic cells (Laz 388) resulted in the growth of a population with natural killer (NK) cell phenotype (T3-, T11+, NKH1+). The latter population was found to be strongly cytotoxic against K562 cells, a standard NK target. As expected, NK cells that are T11+ and T12- appeared to be more effected by in vitro treatment with anti-T11 than with anti-T12. A clonogenic assay was then used to quantitate the efficacy of target cell depletion in vitro. Three sequential incubations of bone marrow with either anti-T12 or anti-T11 plus complement resulted in depletion of 1-2 logs of clonogenic cells. Treatment with both antibodies concurrently resulted in elimination of 2-3 logs of clonogenic target cells. Although multiple treatments with both anti-T12 and anti-T11 were more effective than similar treatment with only one antibody, it remains to be established whether such combinations will be necessary in the clinical setting or whether more selective depletion of T cells without removal of NK cells might be optimal.     

Manipulation of graft-versus-host disease for a graft-versus-leukemia effect after allogeneic bone marrow transplantation in AKR mice with spontaneous leukemia/lymphoma

Graft-versus-host (GVH) disease can result in a beneficial graft-versus leukemia (GVL) effect after bone marrow transplantation in patients with malignant disease. In this report, we used bacteria-free AKR (H-2k) mice bearing advanced spontaneous T cell leukemia/lymphoma as a moel to evaluate the GVH and GVL effects of bone marrow transplantation using fully incompatible SJL (H-2s) donors. A therapeutic GVL effect, accompanied by increased leukemia-free survival, was obtained only when 0.5 X 10(6) allogeneic lymphocytes (lymph node cells) were added to the marrow inoculum. Transplantation of allogeneic bone marrow without added lymph node cells (or use of syngeneic cells) resulted in a significant increase in leukemia relapse; increasing the dose of allogeneic lymph node cells to 2.0 X 10(6) resulted in significantly higher GVH-associated mortality. Survival and therapeutic benefits were obtained only when the intensity of the GVH reaction was carefully controlled by manipulation of alloreactive lymphocytes present in the marrow. These results suggest, indirectly, that T cell depletion may abolish any GVL effect of marrow transplantation, even if the donor is mismatched with the host at the major histocompatibility complex. The frequency in the spleen of cytotoxic T lymphocytes (CTL) reactive against host alloantigens was estimated using limiting-dilution microcytotoxicity assays at various times after transplantation of allogeneic bone marrow with and without added lymph node cells. The average frequency of CTL was highest in mice that were given marrow plus lymph node cells and tested within the first four weeks after transplantation. The level of CTL activity measured in vitro was dependent on the dose of lymphocytes injected and correlated with both the GVL and GVH effects in vivo. Down-regulation of CTL activity against host, but not third-party, alloantigens in vitro was observed under limiting dilution assay conditions, leading to the suggestion that host-specific regulatory cells may be present in these allogeneic bone marrow chimeras.     

Development of a simplified counterflow centrifugation elutriation procedure for depletion of lymphocytes from human bone marrow

Graft-versus-host disease (GVHD) remains a major complication of allogeneic bone marrow (BM) transplantation. Techniques that effectively purge BM of mature T lymphocytes should reduce the incidence of GVHD and improve survival. We have developed a simplified, two-flow rate, fixed rotor speed counterflow centrifugation-elutriation (CCE) procedure that reproducibly depletes 99% of lymphocytes from Ficoll-Hypaque(F/H)-separated BM or BM buffy-coat. Two predetermined flow rates (24 and 28 ml/min) were used to purge small and intermediate-to-large lymphocytes, respectively, whereas faster sedimenting cells were recovered at the termination of the run. Lymphocyte depletion was substantiated by pan-T monoclonal antibody analysis as well as by complete loss of responsiveness to alloantigens and mitogens. Despite the lack of mature T cells, the depleted marrow fraction retained lymphoid colony-forming ability. Lymphocyte-purged marrow was obtained in high yield (72%), and retained high viability (greater than 97%) and hematopoietic colony-forming ability (greater than 99%). The ratio of total myeloid/erythroid colony-forming cells to T lymphocytes was 73-fold higher in the lymphocyte-depleted fraction than in unseparated BM. We concluded that a two-step CCE procedure can be used to rapidly deplete lymphocytes from both F/H-separated and buffy-coat BM inocula without altering hematopoietic capacity as measured by the in vitro clonogenic assays. It may be possible to adapt this procedure to the separation of the large number of marrow cells required for human BM transplantation.     

Prevention of lethal graft-versus-host disease by monoclonal antibody treatment in vivo

Graft-versus-host disease (GVHD) is a major complication of allogeneic bone marrow transplantation (BMT). The disease is caused by mature T cells in the graft that recognize foreign antigens of the host and subsequently elicit an immune response to host tissues [1]. Although T-cell depletion of the graft strongly reduced the incidence and severity of GVHD, the overall survival of allogeneic BMT did not increase because of the increased rate of graft rejection and leukemic relapses [2]. New prophylactic and therapeutic approaches have to be developed to improve the outcome of allogeneic BMT. T-cell-specific monoclonal antibodies (mAb) administered in vivo to the allograft recipients seem to be promising in the prevention and treatment of lethal GVHD [3–5]. In this study we especially addressed the effect of in vivo treatment of recipients with anti-T-cell subset mAb in a murine model for acute GVHD. We also determined the long-term effects.     

Bone marrow transplantation in miniature swine. III. Graft-versus-host disease and the effect of T cell depletion of marrow

Graft-versus-host disease (GVHD) has been evaluated in partially inbred miniature swine in order to study this complication of allogeneic bone marrow transplantation (BMT) in a major histocompatibility complex (MHC) genetically defined large animal model. Bone marrow from MHC homozygous ("parental") swine was injected into irradiated (900 rads total-body irradiation) MHC heterozygous ("F1") swine that shared one haplotype with the donor. All 18 animals successfully engrafted with donor bone marrow, and 17 of these developed skin rash of varying intensity depending on the extent of T cell depletion of infused marrow. Of 18 animals, 8 received undepleted bone marrow from exsanguinated donors and 2 also received additional peripheral blood lymphocytes (PBL) as a source of mature T cells. All 8 showed a moderate-to-severe rash, and the 2 pigs that received additional donor PBL developed the most severe rash. The cutaneous eruption seen in this model clinically, histologically, and immunologically resembled human GVHD. Two protocols of T cell depletion of donor bone marrow by antiporcine T cell monoclonal antibodies plus complement were tested for their effect on development of GVHD. The combination of two monoclonal antibodies, 74-12-4 (PT4) and 76-2-11 (PT8), had a marginal effect on the subsequent development of cutaneous manifestations of GVHD. However, treatment of the donor marrow by a combination of three monoclonal antibodies--PT4, PT8, and MSA4 (PT11)--effectively decreased the severity of the GVHD skin rash. These results indicate that (1) the GVHD associated with allogeneic bone marrow transplantation in swine is dependent on T cells in the marrow; (2) effective T cell depletion of donor marrow by monoclonal antibodies and complement does not prevent engraftment; and (3) this swine GVHD model, which allows study with F1 and homozygous parental combinations in an MHC genetically defined large animal, is particularly useful for the understanding of GVHD pathogenesis, prevention, and treatment.     

UVB pretreatment of rat bone marrow allografts. Prevention of GVHD and induction of allochimerism and donor-specific unresponsiveness

Ultraviolet B irradiation has been used to pretreat blood and islets to prevent subsequent graft rejection. In this study the optimal dose of UVB irradiation of bone marrow was determined in syngeneic recipients and was subsequently applied to in-vitro treatment of bone marrow allografts. UVB pretreatment of donor bone marrow inoculum led to complete prevention of GVHD in allogeneic rat recipients without major marrow or other toxicity. Long-standing recipients of allogeneic UVB-BM became stable adult chimeras. The recipients of allogeneic BM were populated by donor-type peripheral blood lymphocytes and did not reject host or donor-type heart grafts. The BM allograft recipients were immunocompetent as measured by their ability to normally reject third-party cardiac allografts. We suggest that the prevention of GVHD and induction of stable chimerism in adult recipients of allogeneic UVB-BM may be mediated by suppressor mechanisms.     

Depletion of T lymphocytes from human bone marrow. Use of magnetic monosized polymer microspheres coated with T-lymphocyte-specific monoclonal antibodies

A new technique for depletion of T cells from bone marrow is presented. Bone marrow cells (BMC) were rosetted with magnetic monosized polystyrene microspheres coated with monoclonal antibodies (MAbs) specific for T cell CD2 and CD3 antigens. Rosetted T cells were subsequently removed from non-T cells with the aid of a magnet. This immunomagnetic separation procedure was carried out in less than 40 min and reproducibly removed T cells, leaving a maximum of 0.025% sheep-red-blood-cell (SRBC) rosette-forming cells and less than 0.02% T cells as detected by a T cell limiting dilution assay. The efficacy of the depletion procedure was further shown by flow cytometry data, by effective removal of cells from a T cell line added to the BMC prior to immunomagnetic separation, and by abrogation of interleukin 2 (IL-2)-producing capacity in T-cell-depleted BMC (BMC-T). The T cell depletion procedure provided a 43-74% recovery of non-T cells present in the Isopaque-Ficoll-isolated bone marrow mononuclear cell fraction and did not disturb the growth potential of stem cells, as assayed by hematopoietic stem cell assays.     

Preservation of lymphokine-activated killer activity following T cell depletion of human bone marrow.

T cell depletion has decreased the incidence and severity of graft-versus-host disease following transplantation of allogeneic bone marrow. In the treatment of leukemia, decreased GVHD has often been associated with diminished antileukemia or graft-versus-leukemia (GVL) reactivity resulting in higher relapse rates. However, we have not seen a loss of the GVL effect following transplantation of marrow grafts depleted of CD3+ T cells. This suggests that non-T-cell effectors may play a role in preventing leukemic relapse. To study whether natural killer and lymphokine-activated killer (LAK) activity in BM was compromised by T cell depletion, the effect of T-cell-specific monoclonal antibodies against CD3 and CD6 determinants alone, or in combination, on the generation and expansion of NK/LAK cells was examined in vitro and compared to the effect of T depletion on mitogen-driven T cell proliferation. Limiting dilution analysis revealed that T depletion with CD3 and/or CD6 specific antibodies significantly reduced the number of proliferating T lymphocytes but did not significantly affect the frequency of cells able to expand and mediate LAK activity. Bone marrow, depleted of CD3+ or CD6+ T cells, generated levels of LAK activity equivalent to non-T-cell-depleted bone marrow following long-term culture in recombinant interleukin 2. CD3- NKH-1+ cells were the predominant population in rIL-2 expanded marrow cultures prior to transplant and in the peripheral blood of patients who had received a CD3-depleted marrow graft 21-65 days earlier. These studies show that it is possible to selectively reduce GVH-reactive T cells in allogeneic bone marrow while retaining non-T-effector cells with potential to mediate an antileukemia effect in vivo.     

Bone marrow transplant conditioning intensified with liposomal clodronate to eliminate residual host antigen presenting cells fails to ameliorate GVHD and increases PERI-BMT mortality

BACKGROUND: Graft versus host disease (GVHD) mediated by allogeneic donor T cells may be initiated and/or exacerbated by residual host antigen presenting cells (APC) which survive the transplant conditioning regimen. We examined whether the depletion of hepatic and splenic APC could reduce the severity of hepatic GVHD after bone marrow transplantation (BMT). METHODS: Recipient mice were depleted for hepatic and splenic phagocytic APCs by i.v. injection of clodronate- (dichloromethylene diphosphonate) containing liposomes before fully allogeneic or MHC-matched, minor Ag-mismatched BMT. Severity of hepatic GVHD was scored on histological sections 2, 3, 4, or 9 weeks after BMT. RESULTS: No differences in the severity of GVHD were observed between APC-depleted mice and control mice. APC-depleted mice had increased peritransplant mortality due to sepsis. Bacterial clearance assays showed that APC-depleted mice were unable to efficiently clear bacteria, although nondepleted, transplanted mice were able to clear bacteria as quickly as naive control mice. CONCLUSIONS: Residual host phagocytic APC do not appear to play a role in the induction of GVHD after BMT. They are, however, essential for prevention of sepsis in the transplant host.     

Reduction in the severity of graft-versus-host disease and increased survival in allogenic mice by treatment with monoclonal antibodies to cell adhesion antigens LFA-1 alpha and MALA-2.

Bone marrow transplantation is a therapeutic treatment for many life-threatening hematologic disorders, especially leukemia and certain immune deficiency diseases. However, acute graft-versus-host disease is often associated with bone marrow transplantation. In mice, allogeneic GVHD appears to be mediated by both host natural killer cells and donor T cells. In vitro and in vivo experiments demonstrate that treatment with either YN1/1.7 or M17/4.2 mabs is immunomodulatory and inhibits both the mixed lymphocyte reaction and natural killer cell activity. In addition, utilizing an allogeneic model of acute, lethal GVHD with C57B1/6 mice as donors and sublethally irradiated BDF1 mice as recipients, treatment of host mice with anti-LFA-1 alpha (M17/4.2) or anti-MALA-2 (YN1/1.7) mabs at a dose of 10 mg/kg/day for 10 days significantly reduced GVHD and enhanced survival. Mabs to lymphocyte adhesion molecules such as LFA-1 alpha and MALA-2 may provide a useful therapy for the treatment of GVHD.     

Selective depletion of marrow-T cytotoxic lymphocytes (CD8) in the prevention of graft-versus-host disease after allogeneic bone-marrow transplantation

Abstract. In vitro depletion of mature pan-T lymphocytes has been widely and successfully used to prevent acute graft-versus-host disease (GVHD) after allogeneic bone-marrow transplantation (BMT). Hpwever, this procedure has been associated with a high incidence of graft failure and leukemic relapse. In this pilot study, we evaluated the efficiency of a selective depletion of human marrow T cytotoxic lymphocytes (CD8), a subset essential to induce GVHD in mice. Eleven patients with hematologic malignancies were included (7 HLA-matched BMT, 4 HLA-mismatched BMT). Marrow treatment with 7 anti-CD8 mAbs and rabbit complement resulted in a marked reduction of CD8 + lymphocytes from 15% (median value; range 7%-31%) to 1% (median value; range <1%-11%). Acute GVHD was not abolished by this procedure despite postgraft immunosuppression. One patient (HLA-mismatched BMT) rejected his graft and had a full autologous recovery. In conclusion, when compared to the data in the literature, CD8 depletion was shown to be less efficient than pan-T-cell depletion in the prevention of GVHD after allogeneic BMT and was still associated with a major complication associated with this procedure, i.e., graft failure.     

Selective depletion of marrow-T cytotoxic lymphocytes (CD8) in the prevention of graft-versus-host disease after allogeneic bone-marrow transplantation

In vitro depletion of mature pan-T lymphocytes has been widely and successfully used to prevent acute graft-versus-host disease (GVHD) after allogeneic bone-marrow transplantation (BMT). However, this procedure has been associated with a high incidence of graft failure and leukemic relapse. In this pilot study, we evaluated the efficiency of a selective depletion of human marrow T cytotoxic lymphocytes (CD8), a subset essential to induce GVHD in mice. Eleven patients with hematologic malignancies were included (7 HLA-matched BMT, 4 HLA-mismatched BMT). Marrow treatment with 7 anti-CD8 mAbs and rabbit complement resulted in a marked reduction of CD8+lymphocytes from 15% (median value; range 7%–31%) to 1% (median value; range<1%–11%). Acute GVHD was not abolished by this procedure despite postgraft immunosuppression. One patient (HLA-mismatched BMT) rejected his graft and had a full autologous recovery. In conclusion, when compared to the data in the literature, CD8 depletion was shown to be less efficient than pan-T-cell depletion in the prevention of GVHD after allogeneic BMT and was still associated with a major complication associated with this procedure, i.e., graft failure.     

Specific elimination of alloreactive T cells by an anti-interleukin-2 receptor B chain-specific immunotoxin

Graft-versus-host disease and graft rejection remain the two principal causes of morbidity and mortality after major-histocompatibility-complex-mismatched bone marrow transplantation. Human and animal models suggest that both CD4+ and CD8+ T cell subsets present in the donor inoculum are responsible for their initiation. Since the human mixed lymphocyte culture (MLC) and the HLA-restricted cytotoxicity may reflect cellular interactions occurring during GVHD and graft rejection, inhibitions of these responses may represent useful approaches for screening functional T cell depletion in experimental bone marrow transplantation studies. For this purpose, we have tested the possibility of removing the host-specific allogeneic T cells present in the marrow. After a two-day MLC, the specifically activated host alloreactive blood or bone marrow T cells were incubated with the ricin A-chain toxin conjugated with the antibody 33B3.1 directed against the human receptor of interleukin 2 (33B3.1-IT). A complete inhibition of a primary MLC and of cytotoxic activities was observed as well as a disappearance of IL-2R(+) (p55) T cells. This method had limited consequence upon the alloreactivity of blood or marrow T cells toward a third unrelated party. The limiting-dilution analysis of residual alloantigen-reactive T lymphocytes has shown that this depletion results in a twentyfold to fiftyfold reduction of antihost reactivity. The procedure was also shown not to inhibit the growth of marrow precursors for granulocytes and macrophages.     

Tolerance induction permits the development of graft-versus-host disease: donor-mediated attack following small bowel transplantation in mixed chimeras.

The induction of tolerance to organ allografts would eliminate acute and chronic rejection as well as the need for nonspecific immunosuppression. We have shown that tolerance induced through the creation of mixed allogeneic bone marrow chimeras allows for the long-term engraftment of cardiac and small bowel allografts across strong multiple major histocompatibility barriers. The possibility that tolerance might render the host susceptible to graft-versus-host disease (GVHD) has not been investigated in this or other models of tolerance. To test this possibility chimeras were created by transplantation of T-cell depleted ACI and Lewis bone marrow into lethally irradiated Lewis rats. Chimerism was determined post bone marrow transplant (BMTx) by flow cytometry of lymphocytes from reconstituted animals. ACI/Lew chimeras (ALC), Lewis/ACI F1 (LACF1), and Lewis (LEW) rats all received heterotopic ACI vascularized small bowel grafts. A second group of chimeras received small bowel grafts from ACI rats pretreated with low dose irradiation to eliminate T-cells from the graft. LEW-->LEW small bowel isografts were also performed. Animals were examined for evidence of GVHD by clinical signs and histologic examination of biopsied tissues. GVHD was quantified using the popliteal lymph node enlargement assay. All LACF1 rats developed severe lethal GVHD following ACI small bowel transplant. Bone marrow chimeras, ALC (n = 6), developed fatal GVHD in a similar fashion after receiving a small bowel transplant. LEW-->LEW isografts and chimeras receiving bowel from irradiated ACI rats survived long term without GVHD while ACI-->LEW allogeneic transplants all underwent acute rejection. GVHD or its absence was confirmed histologically. Popliteal lymph node enlargement indices reflected the presence of GVHD in the chimeras (1.87) and LACF1 (5.4) receiving allografts, but not in isografts or chimeras receiving irradiated allogeneic transplants. Analysis of cytokines in the tongues of rats undergoing GVHD showed elaboration of Th1 type proinflammatory cytokines which was not seen in isografted rats or rats receiving preirradiated small bowel. These results demonstrate that tolerance induction through mixed chimerism results in susceptibility to small bowel induced GVHD. Preirradiating the donor bowel prior to SBTx can prevent GVHD.     

The role of alphabeta- and gammadelta-T cells in allogenic donor marrow on engraftment, chimerism, and graft-versus-host disease.

BACKGROUND: We previously characterized a facilitating cell (FC) in mouse marrow that enables engraftment of allogeneic hematopoietic stem cells (HSCs) without causing graft-versus-host disease (GVHD). The FC shares some cell surface molecules with T cells (Thy1+, CD3epsilon+, CD8+, CD5+, and CD2+) but is T-cell receptor (TCR) negative. Historically, depletion of CD3+ or CD8+ cells from rat marrow was associated with an increased rate of failure of engraftment. In this study, we evaluated whether depletion of alphabeta- and gammadelta-TCR(+) T cells from donor marrow would retain engraftment potential yet avoid GVHD. METHODS: Wistar-Furth rats were conditioned with 950 cGy of total body irradiation and transplanted with ACI bone marrow processed to remove either alphabeta-TCR(+), gammadelta-TCR(+), or alphabeta- plus gammadelta-TCR(+) T cells. Recipients were typed for chimerism at 28 days and monthly thereafter. RESULTS: Recipients of marrow depleted of alphabeta- (group A), gammadelta- (group B), or alphabeta- and gammadelta-TCR(+) T cells (group C) engrafted and had an average chimerism level of 73.0+/-8.3%, 92.3+/-9.2%, and 46.3+/-32.8%, respectively. Aggressive T-cell depletion did not remove the FC population (CD8+/CD3+/TCR(-)). Group A and group B both developed GVHD, with a higher incidence of GVHD in group B compared to group A. None of the recipients in group C developed GVHD. CONCLUSIONS: These data demonstrate that depletion of T cells from rat marrow does not impair engraftment of HSCs, indirectly supporting the existence of FCs in rat marrow. Moreover, donor alphabeta- and gammadelta-TCR(+) T cells contribute to GVHD in a nonredundant fashion, although alphabeta-TCR(+) T cells are more potent as the effector cells. Finally, the level of donor chimerism is influenced by the composition of the graft, because recipients of marrow that contain alphabeta-TCR(+) T cells exhibited significantly higher donor chimerism compared to recipients of marrow depleted of both alphabeta- and gammadelta-TCR(+) T cells.     

Establishment of fully xenogeneic (mouse-->rat) bone marrow chimeras: evidence for normal development and clonal deletion of mouse T cells

BACKGROUND: Xenotransplantation is a potential solution to the critical shortage of transplantable organs. However, conventional immunosuppressive agents do not control the vigorous cellular and humoral rejection across species disparities. The induction of donor specific tolerance via bone marrow chimerism may be a method to avoid xenograft rejection. In xenogeneic chimeras, T cell repertoire selection plays an important role in the induction of tolerance. Until now a model of mouse-->rat multilineage chimerism has not been reported. This study reports the establishment of fully xenogeneic mouse-->rat multilineage chimeras and evaluates the role of T cell development and repertoire selection in tolerance induction in a xenogeneic environment. METHODS: Recipient rats were irradiated at a dose of total body irradiation ranging between 800-1100 cGy and injected with 120-300x10(6) donor mouse bone marrow cells. Chimeras were typed for engraftment at 4 weeks and then monthly thereafter. T cell repertoire was evaluated in chimeras using two-color flow cytometry and monoclonal antibodies directed against the variable portion of the beta chain of the T cell receptor. RESULTS: Fully xenogeneic multilineage bone marrow chimerism was produced in a mouse-->rat model by using ablative radiation and a high dose of donor cells. Mouse T cells develop in a phenotypically normal fashion in chimeric rats and the host rat is capable of deleting T cells that are reactive to the donor mouse strain. CONCLUSION: Long-term multilineage bone marrow chimerism can be produced in a mouse-->rat bone marrow transplant model. Mouse T cells develop in a phenotypically normal fashion and negative selection of specific T cell receptor-Vbeta occurs in a xenogeneic environment in a predictable fashion paralleling that for syngeneic or allogeneic transplantation.     

Specific tolerance and immunocompetence in haploidentical, but not in completely allogeneic, canine chimeras treated with methotrexate and cyclosporine

Recipient dogs were conditioned with 9.2 Gy of total-body irradiation followed by the infusion of bone marrow and peripheral blood leukocytes from a DLA-haploidentical littermate (N = 10) or a completely allogeneic unrelated donor (n = 9). Graft-vs.-host disease (GVHD) prophylaxis consisted of methotrexate (MTX) and cyclosporine (CsA). Postgrafting all dogs were complete lymphohemopoietic chimeras. Lymphocytes of haploidentical chimeras without GVHD were unresponsive to stimulation by host lymphocytes cryopreserved pregrafting. Lymphocytes of haploidentical chimeras with GVHD proliferated in response to host cells, albeit less than donor cells pregrafting. In completely allogeneic chimeras, neither lymphocytes from dogs with GVHD, nor those from dogs without the disease showed responses to host lymphocytes. In addition, cells from haploidentical chimeras obtained early after transplantation nonspecifically suppressed donor cell proliferation. Later on, lymphocytes from dogs without GVHD showed specific suppression of donor cells, while lymphocytes from chimeras with GVHD continued to show nonspecific suppression. Cells from completely allogeneic chimeras both with and without GVHD never suppressed donor cells specifically. Both specific and nonspecific suppressor cells were enriched by nylon wool adherence, expressed T cell markers, and were not affected by the addition of indomethacin. Even after removing nylon wool-adherent cells, however, chimera cells were unresponsive to stimulation by host cells. By one year after transplant, chimera lymphocytes no longer showed suppression. In cell-mediated lympholysis assays, lymphocytes from all chimeras, regardless of GVHD, failed to generate cytotoxic cells against host cell targets. However, while haploidentical chimeras showed cytotoxicity against third-party targets, completely allogeneic chimeras did not. This deficiency was not overcome by the addition of mixed leukocyte culture supernatant or donor lymphocytes. All chimeras had basically normal antibody responses to keyhole limpet hemocyanin and phage X174. However, while haploidentical chimeras had normal responses to bacillus Calnette-Guerin (BCG) sensitization and rejected DLA-incompatible skin grafts within the normal time frame, completely allogeneic chimeras were not sensitized by BCG and showed delayed skin graft rejection. Histopathological studies revealed slow thymic reconstitution in all chimeras, particularly in the presence of GVHD. However, while healthy haploidentical chimeras eventually showed thymic histology normal for age, completely allogeneic chimeras did not.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mixed allogeneic chimerism as a reliable model for composite tissue allograft tolerance induction across major and minor histocompatibility barriers

BACKGROUND: Although prolonged composite tissue allograft (CTA) survival is achievable in animals using immunosuppressive drugs, long-term immunosuppression of CTAs in the clinical setting may be unacceptable for most patients. The purpose of this study was to develop a model for reliable CTA tolerance induction in the adult rat across a major MHC mismatch without the need for long-term immunosuppression. METHODS: Mixed allogeneic chimeras were prepared by using rat strains with strong MHC incompatibility [WF (RT1Au), ACI (RT1Aa)] WF + ACI-->WF, n=23. The bone marrow (BM) of recipient animals was pretreated with low-dose irradiation (500-700 cGy), followed by reconstitution with a mixture of T cell-depleted syngeneic (WF) and allogeneic (ACI) cells. Additionally, the recipient animals received a single dose of anti-lymphocyte serum (10 mg) 5 days before bone marrow transplantation (BMT) and tacrolimus (1 mg/kg/day) from the day before BMT to 10 days post-BMT. Hindlimb transplants were performed 12 months after BMT. Five animals received a limb allograft irradiated (1000 cGy) just before transplantation. Rat chimeras were characterized (percentage of donor cells present within the bloodstream) by flow cytometry at 3 and 12 months after BM reconstitution and after hindlimb transplantation. RESULTS: Peripheral blood lymphocyte chimerism (WF/ACI) remained stable >12 months after BM reconstitution in 18/23 animals. Multi-lineage chimerism of both lymphoid and myeloid lineages was present, suggesting that engraftment of the pluripotent rat stem cell had occurred. In animals with donor chimerism >60% (n=18) no sign of limb rejection was present for the duration of the study. All animals with chimerism <20% (n=5) developed moderate signs of rejection clinically and histologically. Gross motor and sensory reinnervation (weight bearing, toe spread) developed at >60 days in 14/21 rats. Postoperative flow cytometry studies demonstrated stable chimerism in all animals studied (n=10). Five out of five animals with irradiated limb transplants showed no sign of GVHD at >100 days. CONCLUSIONS: Stable mixed allogeneic chimerism can be achieved in a rat hindlimb model of composite tissue allotransplantation. Hindlimb allografts to mixed allogeneic chimeras exhibit prolonged, rejection-free survival. Partial functional return should be expected. The BM transplanted as part of the hindlimb allograft plays a role in the etiology of GVHD. Manipulating that BM before transplantation may influence the incidence of GVHD. This represents the first reliable rat hindlimb model demonstrating rejection-free CTA survival in an adult animal across a major MHC mismatch without the long-term need for immunosuppressive agents.