Xin Xiao Zheng

Mouse Hind Limb Transplantation: A New Composite Tissue Allotransplantation Model Using Nonsuture Supermicrosurgery

Background. The development of microsurgical techniques has facilitated the establishment of vascularized composite tissue transplant models in small mammals. Because the mouse would be the ideal model to study various composite tissue allotransplantation (CTA)-related problems, we designed two new surgical techniques for orthotopic (ORT) and heterotopic (HET) hind limb transplantation. Methods. BALB/c hind limbs were transplanted to BALB/c or C57BL6 recipients using a nonsuture cuff technique. ORT: donor femoral vessels were anastomosed to recipient femoral vessels, the sciatic nerve approximated end-to-end and osteosynthesis was performed using an intramedullary rod. HET/cervical: Donor femoral vessels of a reduced size osteomyocutaneous hind limb CTA were anastomosed to recipient common carotid artery and external jugular vein without nerve approximation. Results. Both procedures could be performed with a high success rate (ORT: 62%; HET: 90%). Donor operation lasted for 100±12 min and recipient operation 114±27 min (ORT) and 54±16 min (HET). Complication rates in terms of bleeding, and thrombosis at the cuff side was slightly higher in the ORT group. All syngeneic grafts survived long term (>100 days). FK506 (2 mg/kg) significantly prolonged graft survival (87±22 days) when compared with untreated controls (6±1 day). Functional evaluation of ORT grafts by means of video gait kinematics and CatWalk analysis revealed specific differences of gait parameters when compared with nontransplanted controls (P<0.05). Conclusions. The ORT hind limb transplant model seems to be best suited to study functional outcome and nerve regeneration in CTA. The technically less demanding HET/cervical model may be used to investigate basic immunology and clinically relevant questions related to acute and chronic rejection, and ischemia reperfusion injury in reconstructive transplantation.

Perspectives on the Use of Mesenchymal Stem Cells in Vascularized Composite Allotransplantation

Reconstructive transplantation has emerged as clinical reality over the past decade. Long-term graft acceptance has been feasible in extremity and facial vascularized composite allotransplantation (VCA) under standard immunosuppression. Minimizing overall burden of lifelong immunosuppression is key to wider application of these non-life saving grafts. Allograft tolerance is the holy grail of many cell-based immunomodulatory strategies. Recent protocols using mesenchymal stem cells from bone marrow and adipose tissue offer promise and potential in VCA. This article provides an overview of the experimental basis, the scientific background and clinical applications of stem cell-based therapies in the field of reconstructive allotransplantation.

Review of the Early Diagnoses and Assessment of Rejection in Vascularized Composite Allotransplantation

The emerging field of vascular composite allotransplantation (VCA) has become a clinical reality. Building upon cutting edge understandings of transplant surgery and immunology, complex grafts such as hands and faces can now be transplanted with success. Many of the challenges that have historically been limiting factors in transplantation, such as rejection and the morbidity of immunosuppression, remain challenges in VCA. Because of the accessibility of most VCA grafts, and the highly immunogenic nature of the skin in particular, VCA has become the focal point for cross-disciplinary approaches to developing novel approaches for some of the most challenging immunological problems in transplantation, particularly the early diagnoses and assessment of rejection. This paper provides a historically oriented introduction to the field of organ transplantation and the evolution of VCA.

Investigation of Antibody-Mediated Rejection in Composite Tissue Allotransplantation in a Rat Limb Transplant Model

BACKGROUND Despite the widely accepted implication of antidonor antibodies and complement in solid organ transplantation, their role in reconstructive allotransplantation is not clear. The aim of this study was to analyze the humoral immune response using a rat orthotopic limb transplantation model. METHODS We used the Brown Norway to Lewis rat orthotopic hind-limb transplant model: Group 1, isografts; group 2, allografts with daily continuous cyclosporine treatment to prevent acute rejection; and group 3, allografts undergoing multiple episodes of acute rejection. Samples were taken at 30, 60, and 90 days. Serum was analyzed by FACS for antidonor antibodies. Tissue deposition of antibodies and complement was investigated by immunofluorescence. RESULTS By day 90, animals in group 3 had undergone 19 (+/-3.2) acute rejection episodes. There was no difference in the occurrence of serum antidonor antibodies between the three groups at any time point. However, at 90 days, anti-third-party antibodies were significantly greater among group 3. There was no difference in antibody or complement deposition in muscles between the 3 groups. CONCLUSION Despite the increased antibody against a third party after multiple rejection episodes in this animal model, there was no clear evidence of an antibody-mediated alloresponse in limb transplantation.

Biologics and Donor Bone Marrow Cells for Targeted Immunomodulation in Vascularized Composite Allotransplantation: A Translational Trial in Swine

INTRODUCTION Bone marrow (BM) infusion following organ transplantation is a prerequisite for potential donor-antigen-specific tolerance induction. We developed a preclinical swine model to determine the optimal dose of BM cells to achieve microchimerism. Furthermore, induction therapy was optimized by augmenting the BM infusion with biologics in the form of costimulatory blockade: cytotoxic T-lymphocyte antigen 4 immunoglobulin (CTLA4-Ig). MATERIALS AND METHODS Yucatan miniature swine (n = 12) underwent total body and thymic irradiation for cytodepletion. Animal groups received 15, 30, or 60 million cells per kilogram of whole unmodified BM. The optimal dose of BM cell infusion (BMT) was then applied to subsequent experiments evaluating the addition of CTLA4lg. Group 1 (control) received no treatment. Group 2 received FK506 only; group 3 received irradiation, BMT, and FK506; group 4 received FK506 and CTLA4-lg. RESULTS Microchimerism was established in all animals after BM cell infusion; at postoperative day 9, it was significantly increased for 60 million cells per kilogram (P = .0001). Transplanted animals in group 1 rejected the allograft 5 to 8 days after transplantation. Group 2 rejected the allograft (skin and muscle) 30 to 32 days after transplantation (2 days after cessation of immunosuppression). Group 3 rejected the skin portion of the allograft at 50, 52, and 53 days posttransplant. Remaining allograft components (muscle, bone, nerve, vessel) survived indefinitely. Group 4 animals demonstrated significantly prolonged muscle survival beyond 150 days posttransplant; the skin component survived past 150 days in two of three animals. Skin and muscle histology in all long-term surviving animals were normal. CONCLUSIONS BM cell infusion with 60 million cells per kilogram results in stable levels of microchimerism. The addition of costimulatory blockade (CTLA4lg) prolonged allograft skin survival and overall graft survival. Such targeted immunomodulatory protocols might facilitate immune tolerance and eliminate the need for multidrug immunosuppression to maintain graft survival after vascularized composite allotransplantation.

Combined Administration of a Mutant TGF-β1/Fc and Rapamycin Promotes Induction of Regulatory T Cells and Islet Allograft Tolerance

The critical roles of TGF-β in the reciprocal differentiation of tolerance-promoting CD4+Foxp3+ regulatory T cells (Tregs) and proinflammatory Th17 effector cells affect alloimmune reactivity and transplant outcome. We reasoned that a strategy to harness TGF-β and block proinflammatory cytokines would inhibit the differentiation of Th17 cells and strengthen the cadre of Tregs to promote tolerance induction and long-term allograft survival. In this study, we report the development of a long-lasting autoactive human mutant TGF-β1/Fc fusion protein that acts in conjunction with rapamycin to inhibit T cell proliferation and induce the de novo generation of Foxp3+ Treg in the periphery, while at the same time inhibiting IL-6–mediated Th17 cell differentiation. Short-term combined treatment with TGF-β1/Fc and rapamycin achieved long-term pancreatic islet allograft survival and donor-specific tolerance in a mouse model. This effect was accompanied by expansion of Foxp3+ Tregs, enhanced alloantigen-specific Treg function, and modulation of transcript levels of Foxp3, IL-6, and IL-17. Our strategy of combined TGF-β1/Fc and rapamycin to target the IL-6–related Tregs and Th17 signaling pathways provides a promising approach for inducing transplant tolerance and its clinical application.

Site-Specific Immunosuppression in Vascularized Composite Allotransplantation: Prospects and Potential

Skin is the most immunogenic component of a vascularized composite allograft (VCA) and is the primary trigger and target of rejection. The skin is directly accessible for visual monitoring of acute rejection (AR) and for directed biopsy, timely therapeutic intervention, and management of AR. Logically, antirejection drugs, biologics, or other agents delivered locally to the VCA may reduce the need for systemic immunosuppression with its adverse effects. Topical FK 506 (tacrolimus) and steroids have been used in clinical VCA as an adjunct to systemic therapy with unclear beneficial effects. However, there are no commercially available topical formulations for other widely used systemic immunosuppressive drugs such as mycophenolic acid, sirolimus, and everolimus. Investigating the site-specific therapeutic effects and efficacy of systemically active agents may enable optimizing the dosing, frequency, and duration of overall immunosuppression in VCA with minimization or elimination of long-term drug-related toxicity.

Vascularized Osteomyocutaneous Allografts Are Permissive to Tolerance by Induction‐Based Immunomodulatory Therapy

Vascularized composite allografts (VCAs) are unique among transplanted organs in that they are composed of multiple tissues with disparate antigenic and immunologic properties. As the predominant indications for VCAs are non‐life‐threatening conditions, there is an immediate need to develop tolerance induction strategies and to elucidate the mechanisms of VCA rejection and tolerance using VCA‐specific animal models. In this study, we explore the effects of in vitro induced donor antigen‐specific CD4−CD8− double negative (DN) Treg‐based therapy, in a fully MHC mismatched mouse VCA such as a vascularized osteomyocutaneous as compared to a non‐VCA such as a full thickness skin (FTS) transplantation model to elucidate the unique features of VCA rejection and tolerance. We demonstrate that combined therapy with antigen‐induced CD4 derived DN Tregs and a short course of anti‐lymphocyte serum, rapamycin and IL‐2/Fc fusion protein results in donor‐specific tolerance to VCA, but not FTS allografts. Macrochimerism was detected in VCA but not FTS allograft recipients up to >60 days after transplantation. Moreover, a significant increase of CD4+Foxp3+ Tregs was found in the peripheral blood of tolerant VCA recipients. These data suggest that VCA are permissive to tolerance induced by DN Treg‐based induction therapy.

Adoptive cell therapy using antigen-specific CD4−CD8− T regulatory cells to prevent autoimmune diabetes and promote islet allograft survival in NOD mice

Aims/hypothesisA new differentiation pathway for CD4−CD8− (DN) T cells has recently been identified that exhibits the potent function of peripheral converted DN T cells in suppressing immune responses and provides the potential to treat autoimmune diseases. The aim of this study was to determine if the DN T cells converted from CD4+ T cells of NOD mice retain the antigen-specific regulatory capacity and prevent autoimmune diabetes in vivo. We also sought to determine if the combination of DN T cells with rapamycin promotes islet allograft survival in autoimmune diabetic NOD recipients.MethodsNOD CD4+ T cells were converted to DN T cells in an in vitro mixed-lymphocyte reaction, with or without GAD65 peptide, as previously reported. The antigen-specific DN T cells were adoptively transferred to NOD/SCID mice, new-onset diabetic NOD mice or islet-allograft-recipient NOD mice as the part of cell-based therapy. The development of diabetes and allograft survival was assessed by monitoring blood glucose levels.ResultsNOD CD4+ T cells were converted in vitro to DN T cells at a rate of 50% and expressed unique cell features. The DN T cells from NOD donors blocked autoimmunity and prevented diabetes in NOD models, and these effects were even greater for GAD65-peptide-primed DN T cells. DN T cells acted in conjunction with rapamycin to suppress alloantigen-triggered T cell proliferation, promoted apoptosis and prolonged islet allograft survival in NOD recipients.Conclusions/interpretationAdministration of the islet beta cell antigen-specific DN T cells can prevent the development of autoimmune diabetes and promote islet allograft survival in NOD mice.

Combined Anti-CD154/CTLA4Ig Costimulation Blockade-Based Therapy Induces Donor-Specific Tolerance to Vascularized Osteomyocutaneous Allografts

Tolerance induction by means of costimulation blockade has been successfully applied in solid organ transplantation; however, its efficacy in vascularized composite allotransplantation, containing a vascularized bone marrow component and thus a constant source of donor‐derived stem cells, remains poorly explored. In this study, osteomyocutaneous allografts (alloOMCs) from Balb/c (H2d) mice were transplanted into C57BL/6 (H2b) recipients. Immunosuppression consisted of 1 mg anti‐CD154 on day 0, 0.5 mg CTLA4Ig on day 2 and rapamycin (RPM; 3 mg/kg per day from days 0–7, then every other day for 3 weeks). Long‐term allograft survival, donor‐specific tolerance and donor–recipient cell trafficking were evaluated. Treatment with costimulation blockade plus RPM resulted in long‐term graft survival (>120 days) of alloOMC in 12 of 15 recipients compared with untreated controls (median survival time [MST] ≈10.2 ± 0.8 days), RPM alone (MST ≈33 ± 5.5 days) and costimulation blockade alone (MST ≈45.8 ± 7.1 days). Donor‐specific hyporesponsiveness in recipients with viable grafts was demonstrated in vitro. Evidence of donor‐specific tolerance was further assessed in vivo by secondary donor‐specific skin graft survival and third‐party graft rejection. A significant increase of Foxp3+ regulatory T cells was evident in tolerant animals. Donor cells populated peripheral blood, thymus, and both donor and recipient bone marrow. Consequently, combined anti‐CD154/CTLA4Ig costimulation blockade‐based therapy induces donor‐specific tolerance in a stringent murine alloOMC transplant model.