Avneesh K. Singh

Chimeric 2C10R4 anti-CD40 antibody therapy is critical for long-term survival of GTKO.hCD46.hTBM pig-to-primate cardiac xenograft

Preventing xenograft rejection is one of the greatest challenges of transplantation medicine. Here, we describe a reproducible, long-term survival of cardiac xenografts from alpha 1-3 galactosyltransferase gene knockout pigs, which express human complement regulatory protein CD46 and human thrombomodulin (GTKO.hCD46.hTBM), that were transplanted into baboons. Our immunomodulatory drug regimen includes induction with anti-thymocyte globulin and αCD20 antibody, followed by maintenance with mycophenolate mofetil and an intensively dosed αCD40 (2C10R4) antibody. Median (298 days) and longest (945 days) graft survival in five consecutive recipients using this regimen is significantly prolonged over our recently established survival benchmarks (180 and 500 days, respectively). Remarkably, the reduction of αCD40 antibody dose on day 100 or after 1 year resulted in recrudescence of anti-pig antibody and graft failure. In conclusion, genetic modifications (GTKO.hCD46.hTBM) combined with the treatment regimen tested here consistently prevent humoral rejection and systemic coagulation pathway dysregulation, sustaining long-term cardiac xenograft survival beyond 900 days.

B‐Cell Depletion Extends the Survival of GTKO.hCD46Tg Pig Heart Xenografts in Baboons for up to 8 Months

Xenotransplantation of genetically modified pig organs offers great potential to address the shortage of human organs for allotransplantation. Rejection in Gal knockout (GTKO) pigs due to elicited non‐Gal antibody response required further genetic modifications of donor pigs and better control of the B‐cell response to xenoantigens. We report significant prolongation of heterotopic alpha Galactosyl transferase “knock‐out” and human CD46 transgenic (GTKO.hCD46Tg) pig cardiac xenografts survival in specific pathogen free baboons. Peritransplant B‐cell depletion using 4 weekly doses of anti‐CD20 antibody in the context of an established ATG, anti‐CD154 and MMF‐based immunosuppressive regimen prolonged GTKO.hCD46Tg graft survival for up to 236 days (n = 9, median survival 71 days and mean survival 94 days). B‐cell depletion persisted for over 2 months, and elicited anti‐non‐Gal antibody production remained suppressed for the duration of graft follow‐up. This result identifies a critical role for B cells in the mechanisms of elicited anti‐non‐Gal antibody and delayed xenograft rejection. Model‐related morbidity due to variety of causes was seen in these experiments, suggesting that further therapeutic interventions, including candidate genetic modifications of donor pigs, may be necessary to reduce late morbidity in this model to a clinically manageable level.

Genetically Engineered Pigs And Target Specific Immunomodulation Provide Significant Graft Survival And Hope For Clinical Cardiac Xenotransplantation

OBJECTIVES Cardiac transplantation and available mechanical alternatives are the only possible solutions for end-stage cardiac disease. Unfortunately, because of the limited supply of human organs, xenotransplantation may be the ideal method to overcome this shortage. We have recently seen significant prolongation of heterotopic cardiac xenograft survival from 3 to 12 months and beyond. METHODS Hearts from genetically engineered piglets that were alpha 1-3 galactosidase transferase knockout and expressed the human complement regulatory gene, CD46 (groups A-C), and the human thrombomodulin gene (group D) were heterotropically transplanted in baboons treated with antithymocyte globulin, cobra venom factor, anti-CD20 antibody, and costimulation blockade (anti-CD154 antibody [clone 5C8]) in group A, anti-CD40 antibody (clone 3A8; 20 mg/kg) in group B, clone 2C10R4 (25 mg/kg) in group C, or clone 2C10R4 (50 mg/kg) in group D, along with conventional nonspecific immunosuppressive agents. RESULTS Group A grafts (n = 8) survived for an average of 70 days, with the longest survival of 236 days. Some animals in this group (n = 3) developed microvascular thrombosis due to platelet activation and consumption, which resulted in spontaneous hemorrhage. The median survival time was 21 days in group B (n = 3), 80 days in group C (n = 6), and more than 200 days in group D (n = 5). Three grafts in group D are still contracting well, with the longest ongoing graft survival surpassing the 1-year mark. CONCLUSIONS Genetically engineered pig hearts (GTKOhTg.hCD46.hTBM) with modified targeted immunosuppression (anti-CD40 monoclonal antibody) achieved long-term cardiac xenograft survival. This potentially paves the way for clinical xenotransplantation if similar survival can be reproduced in an orthotopic transplantation model.

One-year heterotopic cardiac xenograft survival in a pig to baboon model.

We have now demonstrated that the heterotopic pig cardiac xenograft survival in a baboon can exceed 1 year by utilizing porcine hearts with customized genetics (alpha galactosyl transferase gene knock out [GTKO] to eliminate alpha Gal antibody-mediated rejection, transgenic expression of human complement regulatory protein [hCD46] to inhibit complement activation and human thrombomodulin molecules [hTBM] to prevent coagulation) (Revivicor, Inc., Blacksburg, VA) and an immunomodulatory treatment regimen consisting of co-stimulation blockade by a primatized anti-CD40 antibody (clone 2C10R4; 50mg/kg/weekly), anti-CD20 antibody (19mg/kg on days 14, 7, 0 and 7), antithymocyte globulin (5mg/kg on days 2 and 1), mycophenolate mofetil (20mg/kg twice a day) and steroids (2mg/kg tapered off in 4–6 weeks). Graft survival of all five animals in this group is shown in Table 1.

Characterization and expansion of baboon CD4+CD25+ Treg cells for potential use in a non-human primate xenotransplantation model.

Abstract:  Background:  It is well established that CD4+CD25+ regulatory T (Treg) cells can modulate allogeneic immune responses. Xenotransplantation, proposed as a means to address the critical shortage of human organs, may also benefit from similar approaches to avert rejection. Baboons are a preferred preclinical animal model for xenogeneic organ transplantation experiments, and the characterization of baboon Treg cells will be beneficial to future tolerance studies in this animal model.

Role of anti‐CD40 antibody‐mediated costimulation blockade on non‐Gal antibody production and heterotopic cardiac xenograft survival in a GTKO.hCD46Tg pig‐to‐baboon model

Recently, we have shown that an immunosuppression regimen including costimulation blockade via anti‐CD154 antibody significantly prolongs the cardiac xenograft survival in a GTKO.hCD46Tg pig‐to‐baboon heterotopic xenotransplantation model. Unfortunately, many coagulation disorders were observed with the use of anti‐CD154 antibody, and recipient survival was markedly reduced by these complications.

Early graft failure of GalTKO pig organs in baboons is reduced by expression of a human complement pathway-regulatory protein

We describe the incidence of early graft failure (EGF, defined as loss of function from any cause within 3 days after transplant) in a large cohort of GalTKO pig organs transplanted into baboons in three centers, and the effect of additional expression of a human complement pathway‐regulatory protein, CD46 or CD55 (GalTKO.hCPRP). Baboon recipients of life‐supporting GalTKO kidney (n = 7) or heterotopic heart (n = 14) grafts received either no immunosuppression (n = 4), or one of several partial or full immunosuppressive regimens (n = 17). Fourteen additional baboons received a GalTKO.hCPRP kidney (n = 5) or heart (n = 9) and similar treatment regimens. Immunologic, pathologic, and coagulation parameters were measured at frequent intervals. EGF of GalTKO organs occurred in 9/21 baboons (43%). hCPRP expression reduced the GalTKO EGF incidence to 7% (1/14; P < 0.01 vs. GalTKO alone). At 30 mins, complement deposits were more intense in organs in which EGF developed (P < 0.005). The intensity of peri‐transplant platelet activation (as β‐thromboglobulin release) correlated with EGF, as did the cumulative coagulation score (P < 0.01). We conclude that (i) the transgenic expression of a hCPRP on the vascular endothelium of a GalTKO pig reduces the incidence of EGF and reduces complement deposition, (ii) complement deposition and platelet activation correlate with early GalTKO organ failure, and (iii) the expression of a hCPRP reduces EGF but does not prevent systemic coagulation activation. Additional strategies will be required to control coagulation activation.

Rapamycin Promotes the Enrichment of CD4+CD25hiFoxP3+ T Regulatory Cells From Naïve CD4+ T Cells of Baboon That Suppress Antiporcine Xenogenic Response In Vitro

The CD4(+)CD25(+)FoxP3(+) regulatory T (Treg) cells play an important role in regulating the immune response. These Treg cells are present in peripheral blood and lymphoid organs and have a high potential for immunotherapy in clinics. Adoptive cell transfer therapy using CD4(+)CD25(+) cells has been shown to prevent autoimmune diseases and has also induced transplant tolerance in mice. Treg cells low frequency in peripheral blood will necessitate its ex vivo expansion to enable adaptive immunotherapy. Recently, it has been reported that rapamycin, an immunosuppressive agent, inhibits T-cell proliferation while selectively increasing the number of Treg cells. Based on this additional mode of action, rapamycin can be used to expand Treg cells for ex vivo cellular therapy in T-cell-mediated diseases and in transplantation. We have reported the ex vivo expansion of baboon Treg cells, using irradiated pig peripheral blood mononuclear cell (PBMC) and interleukin (IL)-2, and have demonstrated the suppression of autologus CD4(+)CD25(neg) T-cell proliferation in response to pig PBMCs. In the present study, we have expanded baboon CD4(+) T cells in the presence or absence of rapamycin (0.1-10 nmol/L) using irradiated pig PBMCs and IL-2 to enrich the regulatory T cells. CD4(+)CD25(+)FoxP3(+) Treg cells were increased up to 2 times in the presence of rapamycin versus without rapamycin in vitro. However, a higher dose of rapamycin (> or = 10 nmol/L) considerably decreases the number of Treg cells. Furthermore, purified CD4(+)CD25(+) Treg cells enriched from CD4(+) cells in the presence of rapamycin were able to suppress the baboon anti-porcine xenogeneic immune responses in vitro up to 93% at a 1:1 ratio (Treg cells:T effector cells) and suppression ability exists even at a 1:256 ratio, whereas freshly isolated natural Treg cells suppress only 70% at 1:1 and lose their suppressive ability (>50%) at 1:16. Our results demonstrate that the addition of rapamycin to the culture enriches the Treg phenotype and induces functional regulatory T cells. This method may allow the production of large numbers of regulatory cells for the preclinical testing of Treg cell therapy in a non-human primate model.

Regulatory T cells enhance mesenchymal stem cell survival and proliferation following autologous cotransplantation in ischemic myocardium

OBJECTIVES We sought to investigate if autologous freshly isolated regulatory T cells (Tregs) provide a protective and supportive role when cotransplanted with mesenchymal stem cells (MSCs). METHODS In a porcine model of chronic ischemia, autologous MSCs were isolated and expanded ex vivo for 4 weeks. Autologous Treg cells were freshly isolated from 100 mL peripheral blood and purified by fluorescence-activated cell sorting. MSCs and Treg cells were then cotransplanted into the chronic ischemic myocardium of Yorkshire pigs by direct intramyocardial injection (1.2 × 10(8) MSCs plus an average of 1.5 million Treg cells in 25 injection sites). Animals were killed 6 weeks postinjection to study the fate of the cells and compare the effect of combined MSCs + Treg cells transplantation versus MSCs alone. RESULTS The coinjection of MSCs along with Tregs was safe and no deleterious side effects were observed. Six weeks after injection of the cell combination, spherical MSCs clusters with thin layer capsules were found in the injected areas. In animals treated with MSCs only, the MSC clusters were less organized and not encapsulated. Immunofluorescent staining showed CD25+ cells among the CD90+ (MSC marker) cells, suggesting that the injected Treg cells remained present locally, and survived. Factor VIII+ cells were also prevalent suggesting new angiogenesis. We found no evidence that coinjections were associated with the generation of cardiac myocytes. CONCLUSIONS The cotransplantation of Treg cells with MSCs dramatically increased the MSC survival rate, proliferation, and augmented their role in angiogenesis, which suggests a new way for future clinical application of cell-based therapy.

Ex-vivo expanded baboon CD4+ CD25 Hi Treg cells suppress baboon anti-pig T and B cell immune response.

Singh AK, Seavey CN, Horvath KA, Mohiuddin MM. Ex‐vivo expanded baboon CD4+ CD25Hi Treg cells suppress baboon anti‐pig T and B cell immune response. Xenotransplantation 2012; 19: 102–111.