Guliang Xia

Induction of specific transplantation tolerance across xenogeneic barriers in the T-independent immune compartment

After transplantation of primarily vascularized xenografts (Xgs), T-independent mechanisms may lead to Xg rejection before T-cell activation even takes place. The possibility of achieving T-independent xenotolerance was evaluated in nude rats that normally reject hamster cardiac Xgs within 4 days by non-T cell-mediated mechanisms. After donor antigen infusion, temporary NK-cell depletion and a 4-week administration of Leflunomide, hamster heart grafts survived even after withdrawal of immunosuppression. Tolerant rats accepted second hamster hearts, but promptly rejected mouse heart Xgs. In vivo immunization and in vitro cy-totoxicity assays indicated that this species-specific tolerance was based on B-lymphocyte and NK-cell tolerance respectively.

Transplantation Tolerance and Autoimmunity After Xenogeneic Thymus Transplantation

Successful grafting of vascularized xenografts (Xgs) depends on the ability to reliably induce both T cell-independent and -dependent immune tolerance. After temporary NK cell depletion, B cell suppression, and pretransplant infusion of donor Ags, athymic rats simultaneously transplanted with hamster heart and thymus Xgs developed immunocompetent rat-derived T cells that tolerated the hamster Xgs but provoked multiple-organ autoimmunity. The autoimmune syndrome was probably due to an insufficient development of tolerance for some rat organs; for example, it led to thyroiditis in the recipient rat thyroid, but not in simultaneously transplanted donor hamster thyroid. Moreover, grafting a mixed hamster/rat thymic epithelial cell graft could prevent the autoimmune syndrome. These experiments indicate that host-type thymic epithelial cells may be essential for the establishment of complete self-tolerance and that mixed host/donor thymus grafts may induce T cell xenotolerance while maintaining self-tolerance in the recipient.

Pathogenesis of Autoimmunity After Xenogeneic Thymus Transplantation

Thymus transplantation is a promising strategy to induce xenotolerance, but may also induce an autoimmune syndrome (AIS). The pathogenesis of this AIS was explored using nude rats as recipients. Thymus grafts consisted of fetal hamster thymic tissue with or without mixing with fetal rat tissue such as thymus, thyroid, salivary gland, and heart. All hamster thymus recipients died of AIS within 2–3 mo. In most recipients of xenothymus mixed with rat tissues such as thymus, thyroid, and salivary gland, but not heart, AIS was prevented, indicating an insufficient presence of rat epithelial cell Ags within the xenothymus. AIS could be transferred to control nude rats by whole splenocytes or by splenocyte subpopulations such as CD3+, CD3−, and B lymphocytes, but not by non-T, non-B cells from AIS animals. This transfer could be suppressed by cotransferring either CD4+ or CD8+ lymphocytes from euthymic rats, but not by splenocytes from recipients of syngeneic or xenogeneic thymus mixed with rat tissue, indicating a defective generation of regulatory lymphocytes. As for CD4+ regulatory cells this defect was probably qualitative, because the percentages of CD4+CD25+ or CD4+CD45RClow populations were normal after xenothymus transplantation. As for the CD8+ regulatory cells, the defect was quantitative, as CD8+ cell levels always remained low. The latter was related to the nonvascularized nature of thymus grafts. In conclusion, AIS after xenothymus transplantation in nude rats is due to a combination of insufficient intrathymic presence of host-type epithelial cell Ags and a defective generation of regulatory T lymphocytes.

Maintenance and reversibility of natural killer cell- and T cell-independent B lymphocyte xenotolerance in athymic nude rats.

BACKGROUND We previously described that a tolerogeneic regimen (TR) including (1) the infusion of a minced hamster heart suspension (MHH), (2) a single injection of an anti-natural killer (NK) cell serum (rabbit anti-asialo GM1 serum), and (3) a 4-week course of the B cell immunosuppressant leflunomide (20 mg/kg/ day) induced T cell-independent (T-I) B lymphocyte and NK cell tolerance for hamster xenoantigens in T-deficient athymic nude rats. In addition, the TR allowed for long-term hamster cardiac xenograft (Xg) survival when Xgs were transplanted 2 weeks (Day 0) after the initiation of the TR (started on Day - 14). The present study was undertaken to investigate some of the characteristics of this T-I xenotolerance in more detail. METHODS To investigate the duration of the effect of the TR on the T-I xenotolerance, hamster Xgs were transplanted at various times after initiation of the TR. To investigate whether the maintenance of the T-I xenotolerance depended on the presence of the graft, tolerated Xgs were removed on Day +28, and the subsequent evolution of the T-I xenotolerance as well as of second hamster Xg was followed. In addition, the reversibility of NK cell nonresponsiveness by recombinant interleukin-2 was investigated in vitro. RESULTS Xgs transplanted on day 0 or Day +7 showed long-term survival. However, all Xgs transplanted on Day +15, +30, and +60 were rapidly rejected. The latter rejection occurred in the absence of formation of anti-hamster immunoglobulin (Ig)M xenoreactive antibodies (xAbs) but correlated with the recovery of anti-hamster NK cell reactivity from day +14 on. Rejected Xgs showed infiltration of NK cells but absence of IgM xAbs or complement factor deposition. When tolerated first Xgs (transplanted on Day 0) were removed on Day +28, second hamster Xgs survived without treatment when transplanted 1 or 2 weeks later. However, second hamster Xgs transplanted 3 weeks after removal of the first Xgs were all rapidly rejected. Again, the latter rejection was characterized by the infiltration of the Xgs with NK cells and by the absence of anti-hamster IgM xAbs formation. Xenoreactive NK cell nonresponsiveness was not only shorter than xenoreactive B cell nonresponsiveness, but was also more fragile. This was evident from the fact that after addition of recombinant interleukin-2 in vitro, specific anti-hamster NK nonresponsiveness was easily broken. CONCLUSIONS NK cell and T-I B cell xenotolerance can be induced in T-deficient rats. Compared with B cell xenotolerance, the maintenance of NK cell xenotolerance is much shorter, more dependent on the presence of the graft, and easily reversible in vitro.

Induction Of T-independent Xenotolerance In A Semi-discordant Hamster-to-presensitized, Nude Rat Model

BACKGROUND We have previously demonstrated that in a concordant hamster-to-nude rat cardiac transplant model, T-independent specific B-lymphocyte and natural killer (NK)-cell tolerance could be induced, leading to long-term xenograft (Xg) survival. Here, we investigated whether the same could be achieved in a clinically more relevant semi-discordant model involving hamster hearts transplanted into pre-sensitized, nude rats. METHODS Sensitized, nude rats with high titers of anti-hamster immunoglobulin (Ig)M xenoantibodies (XAbs) were prepared by transplanting a first hamster heart without treatment. One week after rejection, a complete tolerizing regimen was given, including the following: a) an i.v. injection of hamster heart antigens; b) a 4-week administration of malononitriloamide; and c) a single injection of an anti-NK antiserum. Two weeks later, a second hamster heart was grafted. The isotype and level of XAb were examined by fluorescence-activated cell sorting. NK cytotoxicity was evaluated by a standard 4-hr 51Cr release assay. Hamster heart Xgs were examined by conventional histologic and immunohistochemical analysis. RESULTS Untreated, presensitized, nude rats developing high titers of IgM XAb underwent hyperacute rejection within 4 hr (n=4) after transplantation of the second hamster heart. Immunohistochemical analysis showed intensive staining for IgM and C3 along the vascular endothelia in the rejected Xgs. In contrast, presensitized, nude rats receiving the complete tolerizing regimen had a rapid decrease in anti-hamster IgM XAb. The second hamster hearts were not rejected and showed long-term survival even after withdrawal of malononitriloamide (n=6). Moreover, tolerant rats showed specific B-lymphocyte tolerance and a specific continuous absence of anti-hamster NK-cell reactivity. CONCLUSION T-independent B-lymphocyte and NK-cell xenotolerance can also be achieved in recipients with pre-existing IgM XAb.

Immunomodulatory effects of pretransplant donor blood transfusion on T-cell-independent xenoreactive immunity.

BACKGROUND Pretransplant blood transfusions have beneficial effects on both clinical and experimental allograft survival. In the present study, we examined whether pretransplant hamster blood transfusions (pHBT) alone or together with peritransfusion immunosuppressive strategies designed to target B cells and/or natural killer (NK) cells, could modulate T cell-independent (T-I) xenoreactivity in athymic nude rats. METHODS Hamster or mouse hearts were heterotopically xenotransplanted into untreated or treated athymic nude rats receiving either pHBT, anti-B cell or anti-NK cell therapy alone or their combinations. Xenoreactive antibodies (xAbs) and the percentage of NK cells were analyzed by FACScan analysis. NK cytotoxicity was measured by a standard 4 hr 51Cr release assay. Xenografts (Xgs) were examined by hematoxylin-eosin (H&E), by light microscopic method with Massons trichrome and orcein staining, by immunofluorescent staining for immunoglobulin M and C3 deposition, and by immunohistochemical staining for infiltration of NK cells and macrophages (Mphis). RESULTS In 1 of 6 rats given pHBT alone 2 weeks before receiving hamster xenografts, Xg survival was prolonged to 55 days compared with 3.0+/-1.2 days in the other 5 animals and with 3.0+/-0.6 days in untreated animals. In the 55 days, surviving Xg infiltration of Mphis and NK cells was seen together with severe signs of chronic rejection, such as fibrosis and obliterative vasculopathy. The addition of the anti-B cell immunosuppressant MNA715 (malononitriloamide x920715, 20 mg/kg/day) from day -14 to day +14 or of 100 microL of rabbit anti-asialo GM1 serum ([anti-ASGM1] an NK cell depleting antibody) on day -14 resulted in a significant and species-specific prolongation of the survival of hamster Xgs, respectively 59.8+/-9.6 days and 58.2+/-14.7 days (P<0.001 vs. control group), but not of mouse heart Xgs that were rejected in a normal tempo. All prolonged hamster Xgs were infiltrated with Mphis and NK cells and developed severe lesions of chronic rejection, such as fibrosis and obliterative vasculopathy. In contrast, MNA715 or anti-ASGM1 alone had no effect on Xg survival (4.8+/-1.7 days and 2.7+/-0.6 days, respectively). Combined MNA715/anti-ASGM1 treatment only moderately promoted Xg survival (10+/-5.0 days; P<0.001). A simultaneous administration of pHBT, MNA715, and anti-ASGM1 induced indefinite and species-specific Xg survival in all recipients. In vivo and in vitro studies demonstrated that both T-I B cell and NK cell species-specific xenotolerance were achieved. CONCLUSIONS Pretransplant blood transfusion may have a species-specific immunomodulatory effect on T-I xenoreactivity. This effect is further enhanced by a temporary co-administration of MNA715 or by a single injection of anti-ASGM1. A combination of pHBT, MNA715, and anti-ASGM1 induces species-specific T-I xenotolerance.