Immunological and functional features of decellularized xenogeneic heart valves after transplantation into GGTA1-KO pigs.

Decellularization of xenogeneic heart valves might lead to excellent regenerative implants, from which many patients could benefit. However, this material carries various xenogeneic epitopes and thus bears a considerable inherent immunological risk. Here, we investigated the regenerative and immunogenic potential of xenogeneic decellularized heart valve implants using pigs deficient for the galactosyltransferase gene (GGTA1-KO) as novel large animal model. Decellularized aortic and pulmonary heart valves obtained from sheep, wild-type pigs or GGTA1-KO pigs were implanted into GGTA1-KO pigs for 3, or 6 months, respectively. Explants were analyzed histologically, immunhistologically (CD3, CD21 and CD172a) and anti-αGal antibody serum titers were determined by ELISA. Xenogeneic sheep derived implants exhibited a strong immune reaction upon implantation into GGTA1-KO pigs, characterized by massive inflammatory cells infiltrates, presence of foreign body giant cells, a dramatic increase of anti-αGal antibody titers and ultimately destruction of the graft, whereas wild-type porcine grafts induced only a mild reaction in GGTA1-KO pigs. Allogeneic implants, wild-type/wild-type and GGTA1-KO/GGTA1-KO valves did not induce a measurable immune reaction. Thus, GGTA1-KO pigs developed a 'human-like' immune response toward decellularized xenogeneic implants showing that immunogenicity of xenogeneic implants is not sufficiently reduced by decellularization, which detracts from their regenerative potential.

[1]  D. Sachs,et al.  Antibody reactivity with new antigens revealed in multi‐transgenic triple knockout pigs may cause early loss of pig kidneys in baboons , 2020, Xenotransplantation.

[2]  A. Haverich,et al.  Toward acellular xenogeneic heart valve prostheses: Histological and biomechanical characterization of decellularized and enzymatically deglycosylated porcine pulmonary heart valve matrices , 2020, Xenotransplantation.

[3]  J. Pepper,et al.  Early results from a prospective, single-arm European trial on decellularized allografts for aortic valve replacement: the ARISE study and ARISE Registry data , 2020, European journal of cardio-thoracic surgery : official journal of the European Association for Cardio-thoracic Surgery.

[4]  A. Haverich,et al.  Decellularization combined with enzymatic removal of N‐linked glycans and residual DNA reduces inflammatory response and improves performance of porcine xenogeneic pulmonary heart valves in an ovine in vivo model , 2019, Xenotransplantation.

[5]  E. Wolf,et al.  Viable pigs after simultaneous inactivation of porcine MHC class I and three xenoreactive antigen genes GGTA1, CMAH and B4GALNT2 , 2019, Xenotransplantation.

[6]  R. Colvin,et al.  The pathology of solid organ xenotransplantation. , 2019, Current opinion in organ transplantation.

[7]  G. Stellin,et al.  A European study on decellularized homografts for pulmonary valve replacement: initial results from the prospective ESPOIR Trial and ESPOIR Registry data† , 2019, European journal of cardio-thoracic surgery : official journal of the European Association for Cardio-thoracic Surgery.

[8]  E. Wolf,et al.  Consistent success in life-supporting porcine cardiac xenotransplantation , 2018, Nature.

[9]  Rongfeng Li,et al.  Antigenicity of tissues and organs from GGTA1/CMAH/β4GalNT2 triple gene knockout pigs. , 2018, Journal of biomedical research.

[10]  Carlijn V. C. Bouten,et al.  Can We Grow Valves Inside the Heart? Perspective on Material-based In Situ Heart Valve Tissue Engineering , 2018, Front. Cardiovasc. Med..

[11]  HaverichAxel,et al.  *Six-Year-Old Sheep as a Clinically Relevant Large Animal Model for Aortic Valve Replacement Using Tissue-Engineered Grafts Based on Decellularized Allogenic Matrix , 2017 .

[12]  A. Tector,et al.  The Resurgence of Xenotransplantation , 2017, American journal of transplantation : official journal of the American Society of Transplantation and the American Society of Transplant Surgeons.

[13]  A. Haverich,et al.  Effects of combined cryopreservation and decellularization on the biomechanical, structural and biochemical properties of porcine pulmonary heart valves. , 2016, Acta biomaterialia.

[14]  H. Niemann,et al.  Efficient production of biallelic GGTA1 knockout pigs by cytoplasmic microinjection of CRISPR/Cas9 into zygotes , 2016, Xenotransplantation.

[15]  H. Niemann,et al.  Decellularized GGTA1-KO pig heart valves do not bind preformed human xenoantibodies , 2016, Basic Research in Cardiology.

[16]  Jeffrey M Perkel,et al.  Xenotransplantation makes a comeback , 2016, Nature Biotechnology.

[17]  A. Haverich,et al.  No evidence for αGal epitope transfer from media containing FCS onto human endothelial cells in culture , 2015, Xenotransplantation.

[18]  Samir Sarikouch,et al.  Successful matrix guided tissue regeneration of decellularized pulmonary heart valve allografts in elderly sheep. , 2015, Biomaterials.

[19]  M. Tector,et al.  Evaluation of human and non‐human primate antibody binding to pig cells lacking GGTA1/CMAH/β4GalNT2 genes , 2015, Xenotransplantation.

[20]  S. Soker,et al.  Semi‐xenotransplantation: the regenerative medicine‐based approach to immunosuppression‐free transplantation and to meet the organ demand , 2015, Xenotransplantation.

[21]  L. Griffiths,et al.  Immunogenicity in xenogeneic scaffold generation: antigen removal vs. decellularization. , 2014, Acta biomaterialia.

[22]  Giacomo Pongiglione,et al.  Early and late failure of tissue-engineered pulmonary valve conduits used for right ventricular outflow tract reconstruction in patients with congenital heart disease. , 2012, European journal of cardio-thoracic surgery : official journal of the European Association for Cardio-thoracic Surgery.

[23]  Yolanda Santiago,et al.  Efficient generation of a biallelic knockout in pigs using zinc-finger nucleases , 2011, Proceedings of the National Academy of Sciences.

[24]  S. Dittrich,et al.  Early failure of xenogenous de-cellularised pulmonary valve conduits--a word of caution! , 2010, European journal of cardio-thoracic surgery : official journal of the European Association for Cardio-thoracic Surgery.

[25]  M. Stelzmüller,et al.  IgG deposition and activation of the classical complement pathway involvement in the activation of human granulocytes by decellularized porcine heart valve tissue. , 2008, Biomaterials.

[26]  Artur Lichtenberg,et al.  Preclinical Testing of Tissue-Engineered Heart Valves Re-Endothelialized Under Simulated Physiological Conditions , 2006, Circulation.

[27]  E. Wolner,et al.  Presence and elimination of the xenoantigen gal (alpha1, 3) gal in tissue-engineered heart valves. , 2005, Tissue engineering.

[28]  E Wolner,et al.  Early failure of the tissue engineered porcine heart valve SYNERGRAFT in pediatric patients. , 2003, European journal of cardio-thoracic surgery : official journal of the European Association for Cardio-thoracic Surgery.

[29]  D. Sudan,et al.  Heart Xenograft Survival With Chimeric Pig Donors and Modest Immune Suppression , 2003, Annals of surgery.

[30]  M. Tanemura,et al.  Differential immune response to carbohydrate epitopes on allo- and xenografts: implications for accommodation. , 2000, Transplantation proceedings.

[31]  A. Edge,et al.  ENZYMATIC REMOVAL OF ALPHA‐GALACTOSYL EPITOPES FROM PORCINE ENDOTHELIAL CELLS DIMINISHES THE CYTOTOXIC EFFECT OF NATURAL ANTIBODIES , 1995, Transplantation.

[32]  D. Buttle,et al.  Improved quantitation and discrimination of sulphated glycosaminoglycans by use of dimethylmethylene blue. , 1986, Biochimica et biophysica acta.

[33]  H. Stegemann,et al.  Determination of hydroxyproline. , 1967, Clinica chimica acta; international journal of clinical chemistry.