Improved experimental cardiac xenograft survival with cyclophosphamide and intrathymic donor cells

Abstract: Tolerance to cardiac allografts can be induced by pretreatment of the recipient with antilymphocyte serum (ALS) and intrathymic donor cells. Our previous efforts to extend this observation to experimental cardiac xenografts in a usually concordant species combination led to antibody and complement mediated hyperacute rejection. Hyperacute rejection can be abrogated by the use of cobra venom factor but this agent even in combination with intrathymic pretreatment is not successful in prolonging xenograft survival in this model. In contrast to the immune response to allografts, which is predominately mediated by T cells, a B cell antibody mediated response plays an important role in xenotransplantation. Cyclophosphamide is active against dividing B cells. In the present experiments in a concordant hamster to rat cardiac xenograft model, we used the combination pretreatment of cyclophosphamide (20 mg/kg IV) injected on days -19, -16, -13, and-10 prior to heart transplantation, ALS (1 ml intraperitoneally), and hamster spleen cells (25 × 10⁶ intrathymically) given on day -18, 1 day after the first dose of cyclophosphamide. Grafted hearts were assessed by daily palpation of the graft pulse through the abdominal wall of the recipient. In untreated control recipients, graft survival was uniformly 3 days. Significant prolongation of graft survival was seen in pretreated animals whose grafts survived 4, 5, 5, 6, and 6 (mean 5.2) days (P<0.01). These studies show that an anti B cell regimen, when coupled with intrathymic pretreatment, results in prolongation of experimental cardiac xenograft survival. However, in contrast to allotransplantation, permanent tolerance cannot be achieved by this pretreatment protocol.     

Blockade of the PD-1/PD-1L pathway reverses the protective effect of anti-CD40L therapy in a rat to mouse concordant islet xenotransplantation model

BACKGROUND: We have previously demonstrated that costimulatory blockade with anti-CD40L monoclonal antibody (mAb) prolongs the survival of non-vascularized concordant rat to mouse islet xenografts. Here, we examine whether signaling through the PD-1/PD-1L pathway is required for the anti-CD40L therapy to prolong concordant islet graft survival using a novel anti-murine PD-1 mAb (clone 4F10). METHODS: C57BL/6 mice received a cellular concordant islet xenograft under the left kidney capsule and four experimental groups were prepared. Group I: untreated control; group II: recipient mice were treated with three doses of 0.5 mg of anti-CD40L mAb (clone MR1) on days 0, 2 and 4; group III: mice were treated with 0.5 mg of anti-PD-1 (CD279) mAb (clone 4F10) every other day for 8 days; and finally group IV: mice received the combined treatment that consisted of anti-CD40L plus anti-PD-1 mAb. RESULTS: Concordant islet xenografts transplanted in control untreated mice showed a median survival time (MST) of 17 +/- 7.43 days, whereas anti-CD40L treatment led to a significant prolongation of graft survival (MST: 154 +/- 65.56, P < 0.0001). The administration of anti-PD-1 alone significantly accelerated graft rejection compared to non-treated controls (MST: 10 +/- 2.24 vs. MST: 17 +/- 7.43, P < 0.0004). Remarkably, the combined administration of anti-CD40L and anti-PD-1 reversed the protective effect obtained with anti-CD40L alone (anti-CD40L, MST: 154 +/- 65.56 vs. anti-CD40L plus anti-PD-1, MST: 10 +/- 7.72, P < 0.0002). CONCLUSION: Overall, our data indicate that the PD-1/PD-1L pathway is required for the achievement of prolonged graft survival in anti-CD40L-treated mice in a setting of rat to mouse concordant islet xenotransplantation.     

Treatment with a short course of LF 15-0195 and continuous cyclosporin A attenuates acute xenograft rejection in a rat-to-mouse cardiac transplantation model

Searching for a novel immunosuppressive agent to effectively prevent acute vascular rejection (AVR) is essential for success in clinical xenotransplantation. We previously reported that Lewis rat hearts transplanted into BALB/c mice developed typical AVR in 6 days. The present study was undertaken to determine the efficacy of LF 15-0195, a new immunosuppressive analog of 15-deoxyspergualin in the prevention of AVR in a rat-to-mouse cardiac xenograft model. We transplanted 2-week old Lewis rat hearts into BALB/c mice. Four groups were included in this study: untreated recipients and cyclosporin A (CsA) treated recipients were controls; LF 15-0195 treated recipients or LF 15-0195 combined with CsA treated recipients were experimental groups. Mouse recipients received either LF 15-0195 2 mg/kg subcutaneously from day-1 to post-operative day 14, or CsA 15 mg/kg subcutaneously daily, from day 0 to endpoint rejection, or the two drugs in combination. We observed that high dose CsA did not inhibit AVR and the graft was rejected in 11.3 +/- 1.9 days. Graft histology and immunohistology showed typical AVR, characterized by interstitial hemorrhage, intravascular fibrin deposition, thrombosis, and massive deposition of anti-rat immunoglobulin G (IgG) and immunoglobulin M (IgM). Serum xenoreactive antibodies (xAbs) were markedly elevated in these animals as well. In contrast, we observed that treatment with LF 15-0195 alone significantly prolonged graft survival to 19.3 +/- 0.7 days. Notably, xAbs were significantly decreased and the rejection pattern of these grafts was cell-mediated rejection (CMR), instead of AVR. When CsA was combined with LF 15-0195, the graft mean survival time was further increased to 58.5 +/- 17.3 days. Antibody production and T-cell infiltration were significantly inhibited at the terminal stages of graft survival and pathology showed striking attenuation of both AVR and CMR. Sequential studies on days 6 and 14 demonstrated that LF 15-0195 either alone or combined with CsA completely inhibited antibody production. However, intragraft infiltration by Mac-1 positive cells including natural killer cells, macrophages and granulocytes in LF 15-0195 treated recipients was similar to that of untreated recipients. We conclude that LF 15-0195 effectively prevented AVR by markedly inhibiting the production of anti-donor IgG xAbs. Also, treatment with short course LF 15-0195 and continuous CsA significantly reduced T-cell infiltration. Studies to test this therapy in inhibiting AVR in a pig-to-non-human primate xenotransplantation model are underway.     

Persistence of allogeneic cells in graft and host tissues after small bowel transplantation.

Small bowel transplantation is associated with a significant risk of graft versus host disease owing to the large amount of organized lymphoid tissue within the graft. This study assessed whether graft lymphoid cells could persist in the long term following fully allogeneic small bowel transplantation when graft rejection was prevented by cyclosporin immunosuppression. Transplantation was carried out between PVG and DA strains of rat. Cyclosporin (15 mg/kg) was given daily from transplantation, and groups of animals were studied at 28 and 56 days after grafting. The proportions of donor- and recipient-derived cells in the graft and in the host gut and lymphoid tissues were assessed using immunohistochemical tissue staining and monoclonal antibodies specific for cells expressing class I antigens from the two strains of rat. Results demonstrated a persisting population of graft-derived T cells which were capable of migration to the host. Therefore, there may be a long-term risk of graft versus host disease after small bowel transplantation under cyclosporin immunosuppression.     

Prolongation of lung xenograft survival in rats with a short course of deoxyspergualin and cyclosporin A

The efficacy of 15-deoxyspergualin (DSG), cyclosporin A (CyA), and splenectomy-alone or in combination-in prologing the survival of concordant lung xenotransplants was studied in the hamster-to-rat model. In the untreated group, rejection occurred within 3 days, with an elevation of lymphocytotoxic antibody titers. The rejected lung revealed that ED1+cells were more prevalent than MRC OX8+cells in the perivascular infiltrates. In the DSG group, the antibody response was suppressed and median survival increased to 7.5 days. The rejected lungs demonstrated a highly significant depression in ED1+cellular infiltration and a moderate MRC OX8+cellular infiltration. When maintenance CyA was combined with a short course of DSG, survival dramatically increased to beyond 100 days. There were no deposits of IgM, IgG, or C3 or of any cell infiltrate in the grafts of two animals sacrificed 107 and 119 days post-transplantation. We conclude that initial treatment with DSG combined with continuous CyA can suppress acute rejection in the hamster-to-rat lung xenograft model, resulting in longterm graft survival.     

In vitro and in vivo effects of monoclonal antibodies against T cell subsets on allogeneic and xenogeneic responses in the rat

The Syrian hamster-to-rat represents an example of a concordant species difference, and therefore organ transplants using the hamster as the donor and the rat as the recipient are not rejected hyperacutely, as in discordant species combinations. Cellular mechanisms of xenogeneic rejection of hamster hearts by rats were studied both in vitro and in vivo, using monoclonal antibodies to rat T cell antigens. The results of this study reveal that CD4-positive cells of rats proliferated in vitro to both allogeneic stimulators and xenogeneic stimulators from a concordant strain, but required accessory cells of the responder phenotype to proliferate to discordant human stimulators. Monoclonal antibody therapy was used to prevent graft rejection in allogeneic and xenogeneic species combinations, using the rat as the recipient. Treatment with anti-CD4 antibodies was effective in prolonging allograft survival across a full MHC mismatch. No rejection occurred during antibody therapy, and long-term graft survival was achieved in 1/3 of transplanted grafts. The same monoclonal antibody therapy led to increased survival of grafts from hamster donors, but all of these grafts were rejected during therapy, and no long-term graft survival was achieved. Anti-CD8 antibody therapy, combined with anti-CD4 did not improve survival of hamster hearts in rats. Addition of cyclosporine to the anti-CD4 regimen also did not improve graft survival. Injection of an anti-T cell receptor antibody was no better than the anti-CD4 antibody in prolonging the survival times of heart grafts from the concordant xenogeneic species. These data suggest that the rejection of concordant xenogeneic tissue is not wholly a T cell-dependent phenomenon.     

Characteristics of mouse to rat xenograft heart transplantation

A simple technique for grafting a mouse heart heterotopically to rat neck vessels in experimental xenotransplantation is described. In this series, graft survival was tested with the following modes of immunomodulation: ciclosporin (Cy), athymic and nude rats, splenectomy, total lymphoid irradiation (TLI), 15-deoxyspergualin in two different doses and various combinations of these. The mean graft survival time, with Cy or athymic and nude rats as recipients, was 3 days as also seen in animals without treatment. With either irradiation, splenectomy or 15-deoxyspergualin, 10 mg/kg daily, the graft survival time was prolonged to 7.8, 4.7 and 6.8 days, respectively. In combination, TLI + splenectomy gave a graft survival of 9.7 days and Cy + splenectomy 7.2 days. With 15-deoxyspergualin at 10 mg/kg/day plus splenectomy, done 1 week prior to transplantation, graft survival was extended to 17.8 days.     

The effect of immunoglobulin immunadsorptions on delayed xenograft rejection of human CD55 transgenic pig kidneys in baboons

Delayed xenograft rejection (DXR) remains a major obstacle in discordant xenotransplantation. As strategies of complement inhibition and xenogeneic natural antibody (Ab) removal have been shown to give prolonged xenograft survival, we endeavored to determine whether combining these two strategies would lead to an additive effect in terms of graft survival. The study was initiated with two groups, A and B, where group A received normal kidneys and group B received hCD55 transgenic kidneys. Both groups underwent pre-transplant (day-1) total immunoglobulin (Ig) immunoadsorption (IA) and received an immunosuppression of cyclophosphamide, cyclosporine A, mycophenolate mofetil and corticosteroids. Two subsequent groups (C and D) receiving hCD55 transgenic pig kidneys were then performed with an 'optimized' immunosuppression (Cyclophosphamide starting 1 day earlier) but only group D recipients were immunoadsorbed. Biopsies taken during the post-transplantation period were analyzed for Ab deposition, compliment activation and cellular infiltration. No hyperacute rejection was observed. In the initial immunoadsorbed groups A and B, all baboons underwent DXR, which started surprisingly early (day 5 in most cases. In the subsequent two groups, the immunoadsorbed group D baboons also underwent DXR, again as early as day 5. In contrast, group C baboons did not show any signs of DXR on their day 6 biopsy or at their time of death. Analysis of graft biopsies from the kidneys undergoing rejection or with stable function showed strong deposition of anti-Gal IgM in all cases whereas strong complement C5b-9 deposits were only observed in biopsies at rejection. Cellular infiltration consisted mostly of monocytes/macrophages, was more pronounced in biopsies taken at rejection and was associated with a pro-inflammatory environment involving interleukins 1alpha, 6 and 8. Our findings suggest non-specific Ig (anti-Gal and non-Gal Ig of all isotypes) IA or even incomplete IA in immunosuppressed baboon recipients of transgenic pig kidneys is detrimental to graft survival by being associated with an Ab and compliment driven rejection. We speculate that the IA were insufficient in terms of Ig depletion or frequency inducing an Ab rebound or that this total Ig depletion also removed components facilitating graft survival.     

Inhibition of rejection of hamster-to-rat heart xenografts

Prolonged survival of concordant organ xenografts as typified by hamster-to-rat heart transplants is difficult to produce. Studies have revealed that T cells are not primarily involved in rejecting such xenografts and that the rat recipients produce high titres of lytic anti-hamster antibodies. In this study, 200 hamster-to-rat cardiac xenografts performed in 30 different experiments revealed that cyclophosphamide (CyP) and cyclosporin A (CyA) could inhibit this antibody production. CyP alone was relatively ineffective in prolonging graft survival (the median survival time was 14 days versus 3 days in untreated controls). Combining CyP and CyA virtually abolished rejection in this model. Four critically timed doses of CyP combined with continuous CyA resulted in recipients not producing anti-hamster antibodies, despite cessation of CyP therapy, and prolonged graft survival time (median survival time was more than 100 days). Cessation of CyA at 60 and 100 days resulted in the rejection of the xenografts and the appearance of the rat anti-hamster antibodies. Xenografts in recipients given only one or two doses of CyP (and continuous CyA) had a median survival time of 7 and 12 days respectively. However xenograft rejection in rats given only 1 or 2 doses of CyP could be averted by complement depletion using a 3-week course of cobra venom factor (CoF) starting on day 4 or day 7 post-transplantation respectively. Discontinuation of CoF after 3 weeks did not result in graft rejection. These results showed that immunosuppressive therapies directed at inhibiting antibody production may be of value in preventing rejection of concordant xenografts. Short-term complement depletion could rescue xenografts from rejection such that rescued grafts appear to be accommodated.     

Glomerular filtration rate after liver transplantation with a low-dose cyclosporin protocol

Cyclosporin nephrotoxicity is a well-known complication in organ transplantation. In successful liver transplantation, a moderate degree of renal impairment is accepted. Whether this impairment is continuously progressive, stabilizes with time, or is reversible is not known. We have prospectively evaluated the glomerular filtration rate (GFR) using ⁵¹CrEDTA plasma clearance in 29 liver transplant patients (11 males and 18 females) with a mean age of 49 years (range 22–62 years). The ⁵¹CrEDTA plasma clearance measurements were performed preoperatively and at 3, 6, 12, 24, and 36 months after the liver transplantation. All but six patients were given sequential, quadruple drug therapy with antithymocyte globulin, azathioprine, steroids, and cyclosporin. Intravenous cyclosporin was avoided and oral cyclosporin started when renal function was stable. Cyclosporin was started in a dose of 8 mg/kg body weight, aiming at whole blood trough levels (specific monoclonal technique) of 200 g/l in the postoperative period; thereafter, the dosage was rapidly tapered down, aiming at whole blood trough levels of less than 100 g/l at 3 months (1.5–2 mg/kg body weight). From a mean preoperative GFR of 89±3 ml/min per 1.73 m², all patients declined in renal function after transplantation to a mean of 64±4 ml/min per 1.73 m² 3 months after transplantation, and starting in the 3rd month the renal function was stable at about 70% of the preoperative value. No correlations were found between cyclosporin weak level or accumulated cyclosporin dose and renal impairment. We conclude that liver transplantation with cyclosporin immunosuppression will induce renal impairment even if cyclosporin blood levels are carefully monitored and kept low. However, with a low-dose regimen, a progressive decline can be avoided.     

Pig islet xenograft rejection in a mouse model with an established human immune system

Abstract: Background: Xenotransplantation from pigs provides a potential solution to the severe shortage of human pancreata, but strong immunological rejection prevents its clinical application. A better understanding of the human immune response to pig islets would help develop effective strategies for preventing graft rejection. Methods: We assessed pig islet rejection by human immune cells in humanized mice with a functional human immune system. Humanized mice were prepared by transplantation of human fetal thymus/liver tissues and CD34⁺ fetal liver cells into immunodeficient mice. Islet xenograft survival/rejection was determined by histological analysis of the grafts and measurement of porcine C‐peptide in the sera of the recipients. Results: In untreated humanized mice, adult pig islets were completely rejected by 4 weeks. These mice showed no detectable porcine C‐peptide in the sera, and severe intra‐graft infiltration by human T cells, macrophages, and B cells, as well as deposition of human antibodies. Pig islet rejection was prevented by human T‐cell depletion prior to islet xenotransplantation. Islet xenografts harvested from T‐cell‐depleted humanized mice were functional, and showed no human cell infiltration or antibody deposition. Conclusions: Pig islet rejection in humanized mice is largely T‐cell‐dependent, which is consistent with previous observations in non‐human primates. These humanized mice provide a useful model for the study of human xenoimmune responses in vivo.     

Enhancement of the immunosuppressive effect of cyclosporin A by ciprofloxacin in a rat cardiac allograft transplantation model

Ciprofloxacin hyperinduces interleukin-2 production in stimulated human and mouse lymphocytes. In this study, an enhanced and prolonged interleukin-2 response was also detected in polyclonally stimulated rat splenocytes in the presence of ciprofloxacin (5–80g/ml) compared to control cells without any antibiotic. Ciprofloxacin was able to counteract the immunosuppressive effect of 10ng/ml cyclosporin A (CyA) but did not interfere with higher CyA concentrations. In parallel, ciprofloxacin did not influence thymidine uptake in mixed lymphocyte reactions in the presence of CyA. To obtain an in vivo application of these findings, graft survival was studied by performing rat cardiac allograft transplantations in the presence or absence of CyA. Brown Norway rats served as donors and Wistar Furth rats as recipients. Ciprofloxacin was injected intraperitoneally either at a high-dose regimen (240 mg/kg per 24h) into rats every 8th h starting 1 day before transplantation until day 21 or graft loss, or it was injected at a low and clinically relevant dose regimen (45mg/kg per 24h) until day 9. CyA was administered orally (10mg/kg per 24h) from day 1 through day 9. Ciprofloxacin given alone at a high-dose regimen resulted in a median graft survival of 14.8 days, which was significantly longer than graft survival in rats without treatment (median 8.0 days). A low-dose regimen of ciprofloxacin alone did not affect graft survival. Ciprofloxacin at a highdose regimen combined with CyA prolonged graft survival to a median of 24.0 days compared to 20.5 days with CyA alone. Ciprofloxacin administered in the drinking water (200mg/kg per 24h) until day 9 in addition to CyA did not affect graft survival. However, when the same dose regimen was used in experiments with PVG rats as donors and Wistar/Kyoto as recipients, graft survival was significantly prolonged to a median of 45 days. Ciprofloxacin, given orally without the addition of CyA, did not influence graft survival in either of the two strain combinations. Thus, our data show that ciprofloxacin has no negative impact on heart graft survival rats. It remains to be clarified whether ciprofloxacin influences graft survival in humans.     

Restoration of T cell responsiveness to interleukin-2 in recipients of pancreatic islet xenografts treated with cyclosporine

The immunosuppressive mechanism of cyclosporine (CsA) was studied using pancreatic islet xenotransplantation. A dose of 40 mg/kg/day CsA significantly prolonged survival of hamster islet grafts in BDE rats to 14.0 +/- 7.1 days compared with 2.0 +/- 0.9 days in controls (P less than 0.01), and antihamster lymphocytotoxic antibody was not detected in recipient sera even after rejection. Responses of spleen cells to pokeweed mitogen (PWM) and to phytohemagglutinin (PHA) were inhibited at least 21 days after transplantation in recipients treated with CsA. The addition of exogenous interleukin-2 (IL-2) to spleen cell cultures on day 7 had no effect on the impaired response to PHA. At the time of graft rejection (day 14), the T cell response to PHA recovered with the addition of IL-2. However, significant changes were not observed in the ratio of spleen cell subpopulations, which were studied with monoclonal antibodies of W3/ 13, OX-12, W3/25, and OX-8. From these results we conclude that CsA can significantly prolong islet xenograft survival in closely related species, and inhibit the production of humoral antibodies and T cell responses. At the time of graft rejection, recipient T cell responsiveness to IL-2 was restored. This suggest that islet xenograft rejection is caused by the recovery of cellular immunity in recipients treated with CsA.     

Adoptive transfer of double negative T regulatory cells induces B-cell death in vivo and alters rejection pattern of rat-to-mouse heart transplantation

Abstract: Background: Antibody‐mediated hyperacute and acute graft rejection are major obstacles in achieving long‐term graft survival in xenotransplantation. It is well documented that regulatory T (Treg) cells play a very important role in regulating immune responses to self and non‐self antigens. Our previous studies have shown that TCRαβ⁺CD3⁺CD4^?CD8^? (double negative, DN)‐Treg cells can suppress anti‐donor T‐cell responses and prolong graft survival in allo‐ and xenotransplantation models. We have demonstrated that DN‐Treg cells can induce B‐cell apoptosis in vitro through a perforin‐dependent pathway. Methods: B6 mice received rat heart grafts, followed by 14 days of LF15‐0195 treatment. Some mice received Lewis rat cell activated DN‐Treg cells after LF treatment. DN‐Treg cells, purified from perforin^?/? mice and from B6 mice pre‐immunized with third party rat cells, were used as controls. Results: In this study, we investigated the possibility that adoptive transfer of xenoreactive DN‐Treg cells could suppress B cells in vivo, thus prolonging xenograft survival. We found that apoptotic death of B cells significantly increased after adoptive transfer of DN‐Treg cells. In addition, anti‐donor IgG subtypes were significantly inhibited in the DN‐Treg cell‐treated group, in which the rejection pattern was altered towards cellular‐mediated rejection rather than antibody‐mediated acute vascular rejection. However, perforin‐deficient DN‐Treg cells failed to induce B‐cell death and to prolong heart graft survival, indicating a perforin‐dependent mechanism contributes to B‐cell death in vivo. Conclusions: This study suggests that adoptive transfer of xenoreactive DN‐Treg cells can inhibit B‐cell responses in vivo. DN‐Treg cells may be valuable in controlling B‐cell responses in xenotransplantation.     

The beneficial effects of oral nifedipine on cyclosporin-treated renal transplant recipients — a randomised prospective study

The aim of this study was to test the hypothesis that nifedipine will improve graft survival in cyclosporin A (CyA)-treated renal transplant recipients. One hundred and forty-seven patients were randomised to one of three regimens. Group A received CyA, 7 mg/kg per day, and prednisolone; group B followed the same regimen as group A plus oral nifedipine and group C received CyA, 4 mg/kg per day, prednisolone and azathioprine. Calcium channel blockers were avoided in groups A and C. The crude 2-year (P=0.0223) and 4-year (P=0.0181) graft survival was significantly better in group B (86% and 81%, respectively) than in group A (75% and 63%, respectively). Delayed initial function was seen least frequently in group B (10.2%) compared to groups A (31%) and C (28%; P<0.01). Group B also experienced fewer rejection episodes than groups A and C (P<0.05). We conclude that the combination of oral nifedipine and CyA significantly improves initial graft function, rejection frequency and long term graft survival.     

Simultaneous protection against allograft rejection and graft-versus-host disease after total lymphoid irradiation: role of natural killer T cells

BACKGROUND: The use of combined organ and bone marrow transplantation has been studied extensively in rodent models to induce immune tolerance to organ grafts. However, bone marrow transplants with mature donor T cells can induce graft-versus-host disease even in human leukocyte antigen-matched humans. We determined whether total lymphoid irradiation can simultaneously protect against graft-versus-host disease while facilitating tolerance. METHODS: To more closely model clinical studies, we added mature donor T cells to bone marrow grafts combined with heart grafts, and compared murine graft and host survival after conditioning with nonmyeloablative total body or total lymphoid irradiation and depletive anti-T-cell antibodies. RESULTS: Conditioning with total lymphoid irradiation protected hosts against both graft-versus-host disease and organ graft rejection. Although nonmyeloblative total body irradiation prevented organ graft rejection, all hosts succumbed to lethal graft-versus host disease. Induction of tolerance with total lymphoid irradiation and anti-T-cell antibodies was dependent on the presence of regulatory host natural killer T cells, and expression of CD1d on donor marrow but not heart graft cells. CONCLUSION: Conditioning with total lymphoid irradiation and anti-T-cell antibodies prevented host-versus-donor and donor-versus-host alloimmune responses. Tolerance required host natural killer T-cell recognition of CD1d on donor marrow cells.     

Total lymphoid irradiation for treatment of intractable cardiac allograft rejection

The ability of postoperative total lymphoid irradiation to reverse otherwise intractable cardiac allograft rejection was examined in a group of 10 patients in whom conventional rejection therapy (including pulsed steroids and monoclonal or polyclonal anti-T-cell antibody therapy) had failed to provide sustained freedom from rejection. Follow-up periods range from 73 to 1119 days since the start of total lymphoid irradiation. No patient died or sustained serious morbidity because of the irradiation. Three patients have had no further rejection (follow-up periods, 105 to 365 days). Two patients died--one in cardiogenic shock during the course of total lymphoid irradiation, the other with recurrent rejection caused by noncompliance with his medical regimen. Total lymphoid irradiation appears to be a safe and a moderately effective immunosuppressive modality for "salvage" therapy of cardiac allograft rejection unresponsive to conventional therapy.     

The study of mitoxantrone as a potential immunosuppressor in transgenic pig renal xenotransplantation in baboons: comparison with cyclophosphamide

Mounting evidence suggests that delayed xenograft rejection (DXR) of discordant xenografts has a strong humoral component. To explore the possibility of targeting this humoral response more efficiently, we performed a preliminary study in baboons immunized against pig blood cells using the immunosuppressor mitoxantrone (Mx). The results from this study showed that, in comparison with cyclophosphamide (CyP), Mx induced a long-lasting depletion of circulating B cells within 6 days of its administration and delayed secondary anti-Gal antibody (Ab) responses to pig blood cell immunizations. Given these results, we next evaluated Mx in an in vivo model of pig to baboon renal xenotransplantation. We performed a series of renal xenotransplantations in baboons using human CD55-CD59 transgenic donor pigs. In the first group of baboons (Mx group; n = 4) Mx was administered 6 days prior to the day of transplantation, the objective being to perform the xenotransplantation in a context where the recipient would have few remaining circulating B cells and thus have an impaired capacity to mount an Ab response to the xenograft. We compared this group to a second group of baboons treated with CyP starting 1 day prior to transplantation (CyP group; n = 2). All baboons receiving Mx or CyP received an additional immunosuppression of cyclosporin A, mycophenolate mofetil and steroids. No hyperacute rejection was observed in either group but all xenografts underwent DXR. Mx did not show superiority to CyP in terms of graft survival with a mean survival time of 8 +/- 2 days compared with 9 days for both CyP-treated baboons. Neither CyP nor Mx decreased serum levels of pre-existing anti-Gal Abs but levels of these Abs decreased dramatically within 1 day of transplantation, likely reflecting their immediate trapping within the xenograft. Interestingly however, in contrast to CyP, Mx inhibited the return of anti-Gal immunoglobulin M (IgM) to the circulation, even at the time of rejection. Nevertheless, strong intragraft deposits of IgM, IgG and the activated complement complex C5b-9 were observed in biopsies at rejection. Furthermore, despite the expected profound depletion of circulating B cells by Mx within 6 days of its administration, biopsies from both groups at rejection displayed a mild B cell infiltrate accompanied by a strong macrophage and intermediate T-cell infiltration, the latter tending to be more abundant in Mx-treated animals. Our data show that in this particular model of pig to baboon xenotransplantation and at the dose used, Mx was not superior to CyP in conferring protection against rejection, despite its capacity to profoundly deplete circulating B cells and to inhibit anti-Gal Ab responses to xenografts. DXR was thus possible without the return of anti-Gal Abs and may have been mediated by the early fixation of pre-existing Abs with secondary complement activation. However, although Mx was not more efficient than CyP in controlling DXR, its capacity to deplete B cells and delay Ab recovery may be beneficial in the context of Gal knockout organ transplantation where the induced Ab response is likely to take precedence over the preformed response.     

Prolonged survival of fetal pig islet xenografts in mice lacking the capacity for an indirect response

BACKGROUND: Xenografts of islets from organ-cultured fetal pig pancreases transplanted into non-immunosuppressed mice are rejected within 10 days. Immunosuppression with anti-T cell (anti-CD4) monoclonal antibody alone delays rejection of these xenografts for about 28 days, but rejection eventually occurs despite marked depletion of T cells. To determine if the critical CD4+ T cells responsible for xenograft islet rejection function through the direct or indirect pathway, selective class II-deficient mice that express class II antigens only on their thymic epithelium (not on peripheral cells) with normal numbers of CD4+ T cells, (class II-, CD4+), were used as recipients of xenograft islets to test if rejection occurs in the absence of an indirect response. METHODS: Control (C57BL/6) or class II-, CD4+ mice were transplanted under the kidney capsule with cultured fetal pig islets. Class II-, CD4+ mice have normal numbers of B cells, CD4+, gamma delta T cells, and slightly increased numbers of CD8+ T cells. Additional mice were thymectomized before receiving anti-CD4 or anti-CD8 monoclonal antibodies. Islet graft survival was determined histologically as fetal pig islets were too immature to secrete insulin. RESULTS: Xenograft survival in control animals was 7 to 14 days. In contrast, graft survival in class II-, CD4+ mice was significantly prolonged to greater than 35 days. Depletion of CD8+ T cells in class II-, CD4+ mice prolonged graft survival to about 70 days. Depletion of CD4+ T cells from these mice further prolonged xenograft survival to about 100 days. CONCLUSIONS: These results suggest that the rejection of pig islets by mice initially depends on a CD4 dependent indirect response. The CD4 direct response also contributes to graft destruction. CD8+ T cells also participate in graft destruction, albeit weakly.