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.     

Characterization of SCML1, a new gene in Xp22, with homology to developmental polycomb genes

BACKGROUND: Mixed hematopoietic chimerism induced with a nonmyeloablative conditioning regimen leads to donor-specific transplantation tolerance. Analyses of specific Vbeta-bearing T-cell families that recognize endogenous superantigens demonstrated that donor-specific tolerance is due mainly to an intrathymic deletional mechanism in these mixed chimeras. However, superantigens are not known to behave as classical transplantation antigens. We therefore used T-cell receptor (TCR) transgenic (Tg) recipients expressing a clonotypic TCR specific for an allogeneic major histocompatibility complex antigen to further assess deletional tolerance. METHODS: 2C TCR Tg mice (H2b), whose Tg TCR recognizes major histocompatibility complex class I Ld, were used as recipients of Ld+ bone marrow cells after conditioning with depleting anti-CD4 and CD8 monoclonal antibodies, 3 Gy whole-body irradiation, and 7 Gy thymic irradiation. Chimerism and deletion of CD8+ 2C recipient T cells was evaluated by flow cytometry and by immunohistochemical staining. Tolerance was tested with in vitro cell-mediated lympholysis assays and in vivo by grafting with donor skin. RESULTS: Intrathymic and peripheral deletion of 2C+ CD8-single-positive T cells was evident in mixed chimeras, and deletion correlated with the presence of donor-type cells with dendritic morphology in the thymus, and with chimerism in lymphohematopoietic tissues. Chimeras showed tolerance to the donor in cell-mediated lympholysis assays and specifically accepted donor skin grafts. CONCLUSIONS: Tolerance to transplantation antigens is achieved through intrathymic deletion of donor-reactive T cells in mixed chimeras prepared with a nonmyeloablative conditioning regimen and allogeneic bone marrow transplantation.     

Oral health of children undergoing allogeneic bone marrow transplantation

BACKGROUND: Mixed bone marrow chimerism reliably produces donor-specific transplantation tolerance for a variety of solid organ and cellular grafts. We used a rat heterotopic tracheal transplant model for chronic rejection to investigate whether mixed chimerism could successfully prevent obstructive airway disease. METHODS: Mixed allogeneic chimeras were prepared by reconstituting lethally irradiated Wistar-Furth (WF) recipients with a mixture of 5 x 10(6) T-cell-depleted syngeneic (WF) and 100 x 10(6) T-cell-depleted allogeneic (ACI) bone marrow cells (ACI + WF --> WF). Mixed chimerism was present in all animals 28 days after bone marrow transplantation. Donor-specific, syngeneic, or major histocompatibility complex (MHC)-disparate allogeneic tracheas were implanted in recipient's omentum and removed for histologic analysis 30 to 150 days after transplantation. RESULTS: At 30 days after implantation, median luminal obstruction grades (0=none, 4=complete) of syngeneic and allogeneic tracheas were 0 and 4, respectively. Donor-specific (ACI) tracheas implanted in chimeric (ACI + WF --> WF) recipients were remarkably free of obstruction (median luminal obstruction grade=0 at 150 days) and had excellent preservation of respiratory epithelium. Third-party F344 tracheas implanted in chimeric recipients developed progressive luminal obstruction (grade 2 at 30 days, grade 3 at 90 days). CONCLUSIONS: Mixed allogeneic chimerism induces donor-specific tolerance and prevents development of the characteristic fibroproliferative obstructive lesion of bronchiolitis obliterans in a rat heterotopic tracheal transplant model. Excellent preservation of tracheal structure and morphology was achieved across major and minor histocompatibility barriers.     

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.     

Permanent and specific transplantation tolerance induced by a nonmyeloablative treatment to a wide variety of allogeneic tissues: I. Induction of tolerance by a short course of total lymphoid irradiation and selective elimination of the donor-specific host lymphocytes

The long-term success of organ transplantation is limited by complications resulting from consistent nonspecific immunosuppression. Induction of stable, donor-specific tolerance remains the main goal of transplantation immunology. In this article, a new, nonmyeloablative method is described for induction of transplantation tolerance to fully mismatched bone marrow cells (BMC), bone marrow stromal precursors, heart muscle, and skin allografts. The method is based on pretransplant conditioning with no postgraft immunosuppression, and consists of a short course (six daily fractions of 200 cGy) of total lymphoid irradiation (sTLI), followed by selective elimination of donor-specific alloreactive cells of the host escaping low-dose sTLI. Donor-specific alloreactive cells were activated by intravenous inoculation with a high dose of donor BMC (3 x 10(7) cells) 1 day after sTLI, and eliminated by a single intraperitoneal dose (200 mg/kg) of cyclophosphamide given 1 day after cell transfer. Infusion of a low number of T cell-depleted BMC (3 x 10(6) cells) after tolerogenic preconditioning converted recipients to stable mixed chimeras free of graft-versus-host disease. The same treatment provided long-lasting acceptance of heterotopically transplanted allografts of the heart muscle and of the stromal precursors to the hematopoietic microenvironment. This treatment also led to acceptance and life-long survival of full-thickness donor skin allografts. However, skin allografts survived only in mice that received donor T cell-depleted BMC after cyclophosphamide and had 20-50% donor cells in the blood. Our results suggest that after sTLI, additional selective clonal deletion of residual host cells induces a state of long-lasting specific tolerance to a wide variety of donor-derived tissues.     

Overcoming the histocompatibility barrier: transferrins as carriers and modulators of immunogenic identity

Proteic molecules were found in the bone marrow that were later identified as transferrins. When applied to transplantation of genetically incompatible bone marrow in supralethally irradiated recipient mice, the transferrins obtained from plasma of bone marrow donors promoted engraftment, permanent hemopoietic chimerism, and donor-type immune character. A combination of donor-matched transferrins and antigens was needed for induction of xenogeneic (interspecies) "tolerance" or unresponsiveness to donor antigens in chemically immunosuppressed mice treated with human transferrins and donor leucocytes. This novel and unique property of transferrins may explain the genesis and maintenance of immunogenic identity and allow a reshaping of the immune system.     

Induction of donor-specific tolerance to cardiac xenografts in utero

BACKGROUND: Problems associated with heart transplantation, such as shortage of suitable organs and the side effects of immunosuppressive therapy, are especially serious for patients in the pediatric age group. Induction of donor-specific immunologic tolerance without immunosuppressive drugs would be ideal for clinical organ transplantation. In this study, we used a vascularized cardiac xenograft model to achieve donor-specific unresponsiveness without immunosuppression by manipulating the intrauterine immune response. METHODS: Lewis rats and Golden Syrian hamsters were used as the recipients and donors, respectively. Donor bone marrow cells (15 x 10(6) in 0.05 mL) were injected into each fetus of pregnant Lewis rats on days 9 (n = 2) and 16 (n = 2) of gestation. Donor hearts were heterotopically transplanted into each surviving (n = 8, n = 5) fetus of the Lewis rats at 8 weeks of age. Donor hearts were also transplanted into untreated rats as controls (n = 8). RESULTS: The mean cardiac xenograft survival time was 2.5 +/- 0.5, 7.4 +/- 4.1, and 2.8 +/- 0.8 days in the control group, gestational day 9 group, and gestational day 16 group, respectively. Chromosomal analysis of the day 9 group showed Golden Syrian hamster chromosomes as well as Lewis rat chromosomes. CONCLUSIONS: Cardiac xenograft survival was significantly prolonged by intrauterine exposure to xenograft bone marrow cells on day 9 but not on day 16 of gestation. Cardiac xenograft survival and chromosomal analysis of the recipient bone marrow suggested that chimerism was achieved between Golden Syrian hamsters and Lewis rats. Cardiac xenotransplantation may be possible by induction of donor-specific tolerance in utero.     

Prevalence of asthma and wheeze in primary school children in northern Jordan

While the existence of chimeric cells in host tissue following organ transplantation is well documented, its distribution, temporal evolution and relationship to allograft survival is less clear. To explore this phenomenon, Lewis recipients of ACI cardiac allografts representing a wide range of immunosuppressive protocols and graft survival times were examined for the presence of chimerism using a sensitive polymerase chain reaction assay. Four groups of animals were examined: untransplanted animals receiving donor specific transfusion (DST)/cyclosporine A (CsA); allograft recipients with no treatment; recipients treated with DST/CsA/supplementary immunosuppression with rejection at 21-183 days; and recipients sacrificed with functioning allografts, treated with DST/CsA/supplementary immunosuppression and surviving > 200 days. To elucidate variations in the tissue distribution of chimeric cells, bone marrow, skin, liver, spleen, and thymus were examined in each animal. Untransplanted animals receiving DST/CsA displayed no evidence of chimerism. In animals receiving a cardiac allograft but no treatment, there was extensive evidence of chimerism in four of five animals. Chimerism was also detected in seven of nine animals with intermediate graft survival at the time of rejection. In animals with long-term graft survival, only four of eight displayed chimerism. These results suggest that, without immunosuppression, early chimerism does not lead to prolonged graft survival and that, even when graft survival is moderately prolonged, these cells are not sufficient to prevent rejection. In conclusion, chimerism appears to be a common phenomenon following transplantation, is not a result of DST, and may not be necessary for maintenance of long-term graft survival.     

Radiation dose-fractionation and dose-rate relationships for long-term repopulating hemopoietic stem cells in a murine bone marrow transplant model

Fractionated and low-dose-rate total-body irradiation (TBI) were compared with single-dose high-dose-rate TBI for induction of long-term hemopoietic chimerism in a murine syngeneic bone marrow transplantation model. At 5 months after TBI and bone marrow transplantation, the degree of stable blood chimerism was determined from the proportion of stem cell-derived donor (B6-Gpi-1a) and host (B6-Gpi-1b) blood erythrocytes. This end point was used to construct radiation dose-response curves for long-term donor marrow engraftment corresponding to ablation of primitive bone marrow stem cells of the host. Increasing dose fractionation and decreasing dose rate had the effect of restoring host hemopoiesis and required higher TBI doses for equal donor engraftment. Most of the dose recovery occurred within the first 6 h between fractions, consistent with the kinetics of sublethal damage repair. The late chimerism data were fitted to the linear-quadratic model using indirect and direct analysis for a fixed threshold response. Both analyses gave relatively low alpha/beta ratios (below 2 Gy), within the range normally seen in late-responding tissues. The dose-rate data gave a repair half-time of 2 h as estimated by the incomplete-repair model. These estimates contrast with the much higher alpha/beta values and lower repair half-times derived from acute hemopoietic failure as indicated by LD50/30, with the implication that separate target cell populations with differing radiosensitivities are involved in these two bone marrow end points.     

Antiviral cytotoxic activity across a species barrier in mixed xenogeneic chimeras: functional restriction to host MHC

Reconstitution of lethally irradiated mice with a mixture of mouse and rat bone marrow cells (mouse + rat-->mouse) results in mixed xenogeneic chimerism and donor-specific tolerance. The current study demonstrates that mouse and rat T lymphocytes that have developed in xenogeneic chimeras are restricted to Ag presentation by mouse, but not rat, APC. Restriction to host Ags results in functional immunocompetence with generation of antiviral cytotoxic activity in vivo, within and across species barriers. These data demonstrate for the first time that the host thymus is sufficient to support development and positive selection of functional cross-species T lymphocytes. The superior immunocompetence, as compared with fully xenogeneic (rat-->mouse) chimeras, may prove to be of significant benefit in the clinical application of xenotransplantation to solid organ transplantation and immune reconstitution for AIDS.     

Prevention of graft-versus-host disease in rat small bowel transplantation by recipient pretreatment with UV-B-modulated bone marrow cells

UV-B irradiation (700 J/m2) of bone marrow cells (BMC) before transplantation into lethally irradiated (1050R) allogeneic rats prevents graft-versus-host disease (GVHD) and results in stable chimerism. This study examined whether UV-B modulation of BMT is useful in the subsequent induction of tolerance to small bowel transplant (SBT) and avoids the danger of GVHD, which remains the major obstacle to successful SBT. Lethally irradiated Lewis recipients of UV-B irradiated (700 J/m2) BMT (10(8) BMC admixed with 5 x 10(6) splenic leukocytes) either from ACI or Wistar-Furth (WF) rats developed stable chimerism without any evidence of GVHD for > 360 days. Lewis recipients of UV-B ACI BMC expressed 95 +/- 6% ACI lymphoid cells at 50 and 150 days after BMT using complement-dependent cytotoxicity assay. Unmodified Lewis recipients of orthotopic ACI SBT rejected their grafts and died in 7-9 days, whereas Lewis chimeras accepted permanently (> 200 days) bone marrow donor (ACI) SBT without any evidence of GVHD when the SBT was performed at 60 or 150 days after BMT. In contrast, when SBT was performed, only 30 days after induction of chimerism with UV-B ACI BMT, the recipients developed severe GVHD and died between 17 and 21 days. The Lewis chimeras rejected third part (WF) SBT acutely and died in 7-9 days, thus demonstrating the specificity of the induction of tolerance in this model. That this immunologic unresponsiveness is not restricted by the recipient-donor rat strain combination was shown by the permanent acceptance of WF SBT without GVHD by Lewis/WF chimeric recipients. Furthermore, the Lewis chimeras that were made diabetic with STZ 28 days after BMT permanently accepted (> 300 days) BM donor-type (WF) and recipient-type (Lewis) islet cells and became normoglycemic, thus indicating tolerance to both donor and recipient Ags. The diabetic Lewis chimeras that became normoglycemic permanently accepted (> 200 days) WF SBT without any evidence of GVHD after donor-type SBT 110 days after WF islet transplantation. The apparent lack of organ-specific unresponsiveness in this model confirmed our previous observation with combined islet and heart transplants. In vitro MLR studies showed that the chimeric animals were specifically unreactive to donor- and recipient-type alloantigens. Our results demonstrate that UV-B irradiation of BMT is a promising approach to the induction of tolerance to SBT.     

Outcomes of recipients of both bone marrow and solid organ transplants. A review

In this review we examine the clinical outcomes of patients who have received both bone marrow transplantation (BMT) and solid organ transplantation (SOT) and discuss the possible immunologic consequences of the dual transplants. We collected cases through a comprehensive literature search (MEDLINE database, English literature only) covering the years 1990 through 1997 and correspondence with the International Bone Marrow Transplant Registry. Our study selected case reports of patients who have undergone both bone marrow and solid organ transplants; cases in which bone marrow transplantation was undertaken as an adjunct ot induce or augment donor-specific tolerance in a recipient to the transplanted organ were excluded. Clinical characteristics included patient's demographic information, underlying disorders for each transplant, source of donor organ or tissue, time between transplants, and immunosuppressive regimens used to prevent graft-versus-host disease (GVHD) or graft rejection. Clinical outcomes included patient survival, complications of transplantation, and donor-specific tolerance that was experienced in many cases. Twenty-one cases of SOT after BMT and 7 cases of BMT after SOT were reviewed. Solid organ transplantations included lung, liver, cardiac, and kidney for a variety of BMT-related complications including GVHD, hepatic veno-occlusive disease, chronic renal failure, end-stage pulmonary disease, and severe cardiomyopathy. Bone marrow transplants were performed following SOT for aplastic anemia and hematologic malignancies. Clinical outcomes for patients who received both BMT and SOT were variable and depended on transplant indication and degree of histocompatibility. Prior bone marrow transplantation may tolerize for a subsequent organ transplant from the same donor. Conversely, severe GVHD may follow BMT from human leukocyte antigen (HLA)-matched donors following SOT. The favorable survival in this high-risk group of patients may represent a literature review bias (that is, an undetermined number of unsuccessful cases may not have been reported). Nonetheless, dual transplantation is clearly feasible in selected cases.     

The role of cell migration and microchimerism in the induction of tolerance after solid organ transplantation

A new hypothesis has been proposed which states that microchimerism is the basis for the clinical tolerance seen in long-term survivors of solid organ transplants. Efforts to enhance microchimerism include simultaneous infusion of bone marrow of donor origin and transplantation of a solid organ. Studies are in progress to verify the phenomenon of microchimerism and its role in clinical tolerance.     

UVB-irradiation of human bone marrow: potential for donor specific tolerance

Bone marrow mononuclear cell (BMMC) transplant may serve to produce donor specific tolerance for a coincident solid organ graft, but with the risk of graft versus host disease (GVHD). We examined in vitro the immunomodulatory effect of UVB on human BMMCs as potential prophylaxis against GVHD for clinical transplantation. After 10-200 J/m2 UVB-irradiation, BMMCs were examined by proliferative response (in mixed lymphocyte reaction and following phytohemagglutinin stimulation) and by cytokine profile. We also evaluated CFU-GM, CFU-GEMM, and BFU-E progenitor viability by 2-week methyl cellulose cultures following UVB-irradiation. Parallel studies were applied to marrow that was T-cell depleted by soybean agglutination (SBA) or by SBA and sheep erythrocyte rosetting (SBA-E-). We found that (1) UVB produces a dose-dependent inhibition of the proliferative response to stimulators by human BMMCs; (2) increasing doses of UVB-irradiation and increasing levels of T-cell depletion (TCD) are both inversely related to production of lymphokines (IL2, IL3, LIF, IFN-gamma, and GMCSF) and (3) T-cell depletion, but not UVB-irradiation, decreases the production of monokines (IL1, TNF, IL6). Progenitor cell viability was decreased but preserved at 100 J/m2 of UVB. Our findings suggest that UVB compares favorably with TCD as a technique for inhibition of GVHD and therefore that UVB-modulation of bone marrow (BM) inoculum may be useful in the prevention of GVHD in clinical bone marrow transplantation accompanying a solid organ graft.     

Stable mixed chimerism without relapse after related allogeneic umbilical cord blood transplantation in a child with severe aplastic anemia

Umbilical cord blood (UCB) cells from HLA-matched donors are used as an alternative to bone marrow for allogeneic transplantation and reports of successful UCB transplantation in patients with severe aplastic anemia (SAA) are scarce. SAA was discovered in a 4-year-old girl in February 1990. Transfusion support started in August 1990 and standard treatments were unsuccessful. The birth of an HLA-compatible brother in October 1993 permitted the cryopreservation of UCB. In December 1994 UCB transplantation was decided upon. No toxicity occurred. G-CSF was started at day 28. WBC and PMN reached 0.5 x 10(9)/l at days 33 and 37. RBC and platelet transfusion independence were reached at days 50 and 52. Mixed chimerism was demonstrated in blood cells at 1.5, 4 and 6 months after UCBT by molecular biology (VNTR). FISH studies yielded similar results at 15 and 18 months. Twenty months after UCBT, molecular biology showed full donor chimerism. Clinical follow-up (last follow-up: 32 months post transplant) is unremarkable. We suggest that CY and ATG may be a suitable regimen for related HLA-compatible UCBT in patients with SAA. Residual recipient cells can disappear even very late after UCBT, permitting the establishment of complete donor chimerism.     

Nonmitogenic anti-CD3F(ab')2 fragments inhibit lethal murine graft-versus-host disease induced across the major histocompatibility barrier

We have investigated the in vivo administration of nonmitogenic anti-CD3F(ab')2 fragments for the prevention of lethal graft-vs-host disease (GVHD) in irradiated recipients of fully allogeneic bone marrow cells plus splenocyte (BMS) inocula. Recipients of anti-CD3F(ab')2 fragments administered for 1 mo post-bone marrow transplantation (BMT) had 100% survival without clinical or histopathological evidence of GVHD. Controls given saline injections succumbed by 39 days post-BMT. Similar results were obtained in groups of recipient mice given BMS in which T cells were depleted by in vitro anti-Thy-1.2 plus C' treatment. Further studies were undertaken to define mechanistic differences in the two approaches. Using Ly-5 congenic sources of donor bone marrow and spleen, we determined that anti-CD3F(ab')2 fragments induced TCR modulation and T cell depletion. Mature splenic-derived CD4+ cells were depleted to a greater extent than CD8+ cells. Early post-BMT, recipients receiving injections with control saline had the highest number of CD4+ and CD8+ cells (which may cause GVHD) followed by recipients of anti-CD3F(ab')2 fragments, with the fewest CD8+ cells observed in the anti-Thy-1.2 + C' treated group. CD3+CD4-CD8- cells (which may suppress GVHD generation) were present in higher numbers early post-BMT in recipients given anti-CD3F(ab')2 fragments as compared to recipients given anti-Thy-1.2 + C'-treated BMS. In long term survivors, a mononuclear T cell containing infiltrate without evidence of destruction was observed in sites of GVHD (lung and liver), consistent with a "Quilty" effect, which was not observed in either of the other two groups. Although survivors were tolerant of donor skin grafts and rejected third party grafts, recipients given anti-CD3F(ab')2 fragments but not anti-Thy-1.2 + C'-treated BMS had vigorous anti-host proliferative responses. These results demonstrate that although in vitro anti-Thy-1.2 + C' treatment of BMS (which is highly depletionary) and in vivo administration of anti-CD3F(ab')2 fragments (which is modulatory and less depletionary) are both effective strategies for GVHD, the cellular events involved in achieving GVHD prevention are indeed different.     

CD40 ligation prevents neonatal induction of transplantation tolerance

To investigate the consequences of CD40 engagement on the neonatal induction of transplantation tolerance, BALB/c mice were injected at birth with (A/J x BALB/c) F1 spleen cells together with activating anti-CD40 mAb and grafted 4 wk later with A/J skin. Whereas A/J allografts were accepted in mice neonatally injected with F1 cells and control Ab, they were acutely rejected in mice injected with F1 cells and anti-CD40 mAb. Neonatal administration of anti-CD40 mAb resulted in enhanced anti-A/J CTL activity, increased IFN-gamma, and decreased IL-4 production by donor-specific T cells in vitro. Experiments using anti-cytokine mAb and IFN-gamma-deficient mice demonstrated that CD40 ligation prevents neonatal allotolerance through an IFN-gamma- and IL-12-dependent pathway. Finally, we found that newborn T cells express less CD40L than adult T cells upon TCR engagement. Taken together these data indicate that insufficiency of CD40/CD40L interactions contribute to neonatal transplantation tolerance.     

The differing impact of chloroquine and pyrimethamine/sulfadoxine upon the infectivity of malaria species to the mosquito vector

BACKGROUND: Mixed lymphohematopoietic chimerism can provide an effective means of inducing longterm immunological tolerance and has been documented in a monkey allograft model. A conditioning regimen including nonmyeloablative or myeloablative irradiation and splenectomy has been used to induce chimerism in a pig-to-primate transplantation model. Since the presence of anti-Gal(alpha)1-3Gal (alphaGal) natural antibodies leads to the hyperacute rejection of pig organs transplanted into primates, extracorporeal immunoaffinity adsorption (EIA) of anti-alphaGal antibodies is also included in the regimen. The effect of the tolerance induction protocol on the anti-alphaGal antibody response has been assessed. METHODS: Anti-alphaGal antibody was measured after the EIA of plasma through an alphaGal immunoaffinity column in baseline studies involving two unmodified baboons, one splenectomized baboon, and one baboon that received a challenge with porcine bone marrow (BM), and in three groups of baboons (n=2 in each group) that received different conditioning regimens for tolerance induction. Group 1 received a nonmyeloablative conditioning regimen without porcine BM transplantation. Group 2 received nonmyeloablative conditioning with pig BM transplantation and pig cytokine therapy. Group 3 received myeloablative conditioning, an autologous BM transplant (with BM depleted of CD2+ or CD2+/CD20+ cells), and pig BM transplantation. RESULTS: In the baseline studies, a single EIA of anti-alphaGal antibodies in an unmodified animal initially depleted anti-alphaGal antibody, followed by a mild rebound. Nonmyeloablative conditioning (group 1) in the absence of pig cell exposure reduced the rate of anti-alphaGal antibody return. Pig BM cells markedly stimulated anti-alphaGal antibody production in an unmodified baboon (alphaGal IgM and IgG levels increased 40- and 220-fold, respectively). This response was significantly reduced (to an only 2- to 5.5-fold increase of IgM and IgG) in baboons undergoing nonmyeloablative conditioning (group 2). A myeloablative conditioning regimen (group 3) prevented the antibody response to pig BM, with the reduction in response being greater in the baboon that received autologous BM depleted of both CD2+ and CD20+ cells. No new antibody directed against pig non-aGal antigens was detected in any baboon during the 1 month follow-up period. CONCLUSIONS: (i) EIA of anti-alphaGal antibody in unmodified baboons results in a transient depletion followed by a mild rebound of antibody; (ii) exposure to pig BM cells results in a substantial increase in anti-alphaGal antibody production; (iii) a nonmyeloablative conditioning regimen reduces the rate of antibody return and (iv) markedly reduces the response to pig BM cells; (v) the anti-alphaGal response is completely suppressed by a myeloablative regimen if CD2+ and CD20+ cells are eliminated from the autologous BM inoculum. Furthermore, (vi) challenge with pig BM cells appears to stimulate only an anti-alphaGal antibody response without the development of other (non-alphaGal) anti-pig antibodies. We conclude that regimens used for T-cell tolerance induction can be beneficial in reducing the anti-alphaGal antibody response to porcine BM.     

DNA polymorphism, allogenic bone marrow transplantation and peripheral cell chimerism

BACKGROUND: Bone marrow transplantation or transplantation of peripheral stem cells is an effective treatment of a number of diseases. Its increasing success and expanding use in associated with the development of molecular diagnostic methods which enable to follow up the graft from its engraftment in a recipient and then during the whole posttransplantation period at the level extremely small numbers of cells. METHODS AND RESULTS: In peripheral blood of patients, genotypes of the following loci were examined by polymerase chain reaction (PCR): APOB, COL2A1, D17S20, D1S80, HVR/1G, SRY and AMXY. Technique of restriction analysis was used for loci DXYS20 and DXYS75. 1. The first signs of donor bone marrow activity were observed in 50% of patients already at the beginning of the second week after transplantation, while in the second half of patients increasing number of donor cells in peripheral blood was noticed in the second and third week. 2. Engraftment with full and permanent substitution of own bone marrow without presence of recipients cells in peripheral blood--complete chimerism--was achieved only in a part of patients (cca 50%). 3. Peripheral blood of other patients did not contain only donor cells but also recipients cells--mixed chimerism. With regard to its onset, the authors have divided mixed chimerism into early and late, taking into account that some patients can develop both types. In patients under study, early chimerism was found more frequently, which apparently resulted from a shorter period of observation of lately transplanted patients. 4. In cases of oncohaematologic patients, which allowed to study specifically the presence of a pathologic clone, the follow-up of chimerism enabled to distinguish between relapse of the original disease and "biologic" recovery--resurrection of original disease-free haematopoiesis. 5. Regression of mixed chimerism was supposed to be the result of treatment focused at the original disease (CML), in some patients, however, it was a spontaneous process. CONCLUSIONS: Follow-up of cellular chimerism in transplanted patients by means of molecular genetic methods provides substantial information about patient's shape which can be utilized it is necessary to decide on treatment procedures. For this reason it is desirable that examination of chimerism by molecular methods should form integral part of care of these patients.     

IL-12 prevents neonatal induction of transplantation tolerance in mice

We investigated the effect of IL-12 on the induction of transplantation tolerance by neonatal injection of allogenic cells. We first observed that injection of newborn BALB/c mice with IL-12 and (A/J x BALB/c)F1 spleen cells prevented the Th2 alloimmune response induced by neonatal inoculation of F1 cells alone and allowed the differentiation of T cells secreting high amounts of IL-2 and IFN-gamma in mixed lymphocyte cultures with donor-type stimulators. Furthermore, IL-12 administration resulted in the emergence of anti-donor cytotoxic T lymphocyte responses although at lower levels than in control uninjected mice. In parallel, we found that mice injected at birth with IL-12 and F1 cells did not develop chimerism and were able to reject a donor-type skin graft as efficiently as control mice. We conclude that IL-12 inhibits the Th2 polarization of the newborn response to alloantigens and prevents thereby the establishment of transplantation tolerance.