Michael Thormann

Xenografted Islet Cell Clusters From INSLEA29Y Transgenic Pigs Rescue Diabetes and Prevent Immune Rejection in Humanized Mice

Islet transplantation is a potential treatment for type 1 diabetes, but the shortage of donor organs limits its routine application. As potential donor animals, we generated transgenic pigs expressing LEA29Y, a high-affinity variant of the T-cell costimulation inhibitor CTLA-4Ig, under the control of the porcine insulin gene promoter. Neonatal islet cell clusters (ICCs) from INSLEA29Y transgenic (LEA-tg) pigs and wild-type controls were transplanted into streptozotocin-induced hyperglycemic NOD-scid IL2Rγnull mice. Cloned LEA-tg pigs are healthy and exhibit a strong β-cell–specific transgene expression. LEA-tg ICCs displayed the same potential to normalize glucose homeostasis as wild-type ICCs after transplantation. After adoptive transfer of human peripheral blood mononuclear cells, transplanted LEA-tg ICCs were completely protected from rejection, whereas reoccurrence of hyperglycemia was observed in 80% of mice transplanted with wild-type ICCs. In the current study, we provide the first proof-of-principle report on transgenic pigs with β-cell–specific expression of LEA29Y and their successful application as donors in a xenotransplantation model. This approach may represent a major step toward the development of a novel strategy for pig-to-human islet transplantation without side effects of systemic immunosuppression.

Cotransfection of Vascular Endothelial Growth Factor-A and Platelet-Derived Growth Factor-B Via Recombinant Adeno-Associated Virus Resolves Chronic Ischemic Malperfusion Role of Vessel Maturation

OBJECTIVES We set out to investigate the ability of cardiotropic adeno-associated viral vector (AAV2.9 = recombinant adeno-associated virus [rAAV]) to induce prolonged expression of vascular endothelial growth factor (VEGF)-A and platelet-derived growth factor (PDGF)-B in a rabbit hindlimb ischemia model and a pig model of hibernating myocardium. BACKGROUND Gene therapy to induce angiogenesis and arteriogenesis has produced mixed results. However, long-acting viruses, such as rAAV, as well as combined induction of angiogenesis and vessel maturation might extend the therapeutic potential. METHODS In rabbits, 0.5 x 10(11) particles rAAV.VEGF-A with or without 1 x 10(12) particles rAAV.PDGF-B were retroinfused at day 7 after femoral artery excision. At days 7 and 35, collateral counts and perfusion were determined, each value given as the day 35/day 7 ratio. Capillary-to-muscle fiber ratio was determined at day 35. In pigs, implantation of a reduction stent graft into the circumflex artery led to complete occlusion at day 28. At this time point, retroinfusion of rAAV.VEGF-A (1 x 10(13) particles), rAAV.VEGF-A/PDGF-B (2 x 10(12) and 4 x 10(12) particles, respectively) or mock transfection was performed. Ejection fraction and left ventricular end-diastolic pressure were assessed at days 28 and 56. RESULTS In rabbits, rAAV.VEGF-A strongly induced angiogenesis (capillary-to-muscle fiber ratio; 1.67 +/- 0.09 vs. 1.32 +/- 0.11 in rAAV.LacZ-treated limbs, p < 0.05), but not collateral growth (125 +/- 7% vs. 106 +/- 7%, p = NS) or perfusion (136 +/- 12% vs. 107 +/- 9%, p = NS). With VEGF-A/PDGF-B cotransfection, collateral growth increased to 146 +/- 9%, perfusion to 163 +/- 8% of the respective day 7 value (p < 0.05). In the pig model, retroinfusion of rAAV.VEGF-A/PDGF-B increased regional myocardial blood flow reserve from 101 +/- 4% (rAAV.Mock) to 129 +/- 8% (p < 0.05), based on collateral growth (3.2 +/- 0.3 in rAAV.Mock vs. 9.0 +/- 0.4 in rAAV.VEGF-A/PDGF-B, p < 0.05), whereas rAAV.VEGF-A did not alter flow reserve (112 +/- 7%) or collateral count (5.2 +/- 0.7). rAAV.VEGF-A/PDGF-B improved ejection fraction (55 +/- 5% vs. 34 +/- 3% in rAAV.Mock, p < 0.05) unlike rAAV.VEGF-A (37 +/- 2%). CONCLUSIONS Retroinfusion of rAAV.VEGF-A alone induces angiogenesis, but fails to enhance collateralization and perfusion, unless PDGF-B is cotransfected. In addition to neovascularization, rAAV.VEGF-A/PDGF-B improves regional and global myocardial function in hibernating myocardium.

First experience with heterotopic thoracic pig-to-baboon cardiac xenotransplantation

Bauer A, Postrach J, Thormann M, Blanck S, Faber C, Wintersperger B, Michel S, Abicht J‐M, Christ F, Schmitz C, Schmoeckel M, Reichart B, Brenner P. First experience with heterotopic thoracic pig‐to‐baboon cardiac xenotransplantation.
Xenotransplantation 2010; 17: 243–249.

Pre‐clinical heterotopic intrathoracic heart xenotransplantation: a possibly useful clinical technique

As a step towards clinical cardiac xenotransplantation, our experimental heterotopic intrathoracic xenotransplantation model offers a beating and ejecting donor heart while retaining the recipient′s native organ as a backup in case of graft failure. Clinically applicable immunosuppressive regimens (IS) were investigated first, then treatments known to be effective in hypersensitized patients or those with recalcitrant rejection reactions.

Adeno-associated viral vector 2.9 thymosin ß4 application attenuates rejection after heart transplantation: results of a preclinical study in the pig.

Background Graft survival is the most important factor for morbidity and mortality in cardiac transplantation. Improved immunosuppression significantly reduced early graft rejection. However, acute rejection may predispose to chronic rejection. Targeting both phases of the recipient’s immune-reactivity by means of long-acting recombinant adeno-associated viral vectors (AAVs) encoding anti-inflammatory and cardioprotective factors appears to be a promising therapeutic approach. We investigate thymosin ß4 (Tß4) possessing anti-inflammatory and prosurvival abilities, as a means for pretransplant gene therapy. Methods Heterotopic, abdominal transplantation of cardiac allografts into landrace or into Munich mini pigs (n=5 per group) was performed. Transplants were transduced with AAV2.9 before transplantation by means of in situ perfusion of the donor organ. Vascuar endothelial growth factor and AAV2.9.Tß4 or AAV2.9.LacZ were added to the autologous blood used for perfusing the grafts for a period of 45 min. Immunosuppression was applied for 10 days after the operation. Transgene expression, capillary density, graft function, survival, and rejection were assessed. Results The AAV2.9 transduction induced robust overexpression of the transgene. In addition, Tß4 ameliorated inflammation, necrosis, vascular reaction (acute rejection) and in parallel improved capillary density. In addition, graft survival was significantly prolonged (10±3 days AAV2.9.LacZ vs. 31±4 days AAV2.9.Tß4). In the mini pig model, regional myocardial function of the grafts was improved by Tß4 transduction compared to LacZ (9.1%±0.9% subendocardial segment shortening in AAV2.9.LacZ vs. 15.8%±2.3% in AAV2.9.Tß4). Conclusion In situ AAV2.9-mediated gene transfer of thymosin &bgr;4 attenuated graft rejection in a heterotopic heart transplantation model. Perioperative cardioprotection by means of gene therapy might improve graft survival in cardiac allotransplantation.

Discordant cardiac xenotransplantation: broadening the horizons

a Transregio Collaborative Research Center 127, Ludwig-Maximilians University, Munich, Germany b Department of Cardiovascular Surgery, Ludwig-Maximilians University, Munich, Germany c Revivicor, Blacksburg, VA, USA d Living Cell Technologies, Auckland, New Zealand e Chair of Livestock Biotechnology, Weihenstephan, Technical University, Munich, Germany f Department of Anaesthesiology and Intensive Medicine, Ludwig-Maximilians University, Munich, Germany

Angiogenetic Potential of Ad2/Hif-1α/Vp16 after Regional Application in a Preclinical Pig Model of Chronic Ischemia

UNLABELLED Hif-1α, a master regulator of ischemia-responsive gene induction, controls pro-angiogenic gene expression of VEGF-A, flt-1, IGF-1 and erythropoietin, rendering its overexpression an attractive tool for therapeutic neovascularization. Utilizing an adenoviral vector system, we investigated the efficacy of selective pressure-regulated venous retroinfusion of an enhanced Hif-1α mutant (Hif-1α/VP16) in a randomized investigator-blinded study. METHODS Pigs were subjected to percutaneous implantation of a reduction-stent into the circumflex artery, leading to progressive stenosis and complete occlusion at day 28. Selective pressure-regulated retroinfusion of the great cardiac vein was performed at day 28 for regional delivery of either saline or empty vector or Ad2/Hif-1α/VP16. Collateral growth and global myocardial function were obtained by fluoroscopy, whereas regional blood flow and regional myocardial function were assessed by fluorescent microsphere analysis and sonomicrometry, respectively. Capillary density in the ischemic myocardium was analyzed by PECAM-1 staining. RESULTS Compared to saline and Ad empty vector controls, overexpression of Hif-1α in the ischemic region induced an increase of small (capillary) and large (collateral) vessels, resulting in an improved perfusion of the ischemic myocardium. Concomitantly, an ischemia induced loss of myocardial function (hibernating myocardium) was resolved only after transfection with the Hif 1-α transgene, but not the empty vector or saline control. CONCLUSION Retroinfusion of Ad2/Hif-1α/VP16, combining a master pro-angiogenic protein with regional myocardial application, may offer an efficient approach to cardiac gene therapy of chronic ischemic cardiomyopathy.

THE WORLDWIDE FIRST MODEL WITH HETEROTOPIC THORACIC XENOGENEIC HEART TRANSPLANTATION COMPARED WITH THE HETEROTOPIC ABDOMINAL TECHNIQUE: 800

P. Brenner1, J. Postrach1, A. Bauer2, M. Thormann1, M. Loewenthal1, S. Blanck1, S. Michel1, B. Wintersperger3, K. Sotlar4, C. Schmitz1, M. Schmoeckel5, B. Reichart2 1Dept. Of Cardiac Surgery, Clinic of Grosshadern of the LudwigMaximilians-University Munich, Munich/GERMANY, 2Dept. Of Anestesiology, Clinic of Grosshadern of the Ludwig-MaximiliansUniversity Munich, Munich/GERMANY, 3Dept. Of Radiology, Clinic of Grosshadern of the Ludwig-Maximilians-University Munich, Munich/ GERMANY, 4Dept. Of Pathology, Clinic of Grosshadern of the LudwigMaximilians-University Munich, Munich/GERMANY, 5, Asclepios Clinic St. Georg, Hamburg/GERMANY