Increased human complement pathway regulatory protein gene dose is associated with increased endothelial expression and prolonged survival during ex‐vivo perfusion of GTKO pig lungs with human blood

INTRODUCTION Expression of human complement pathway regulatory proteins (hCPRP's) such as CD46 or CD55 has been associated with improved survival of pig organ xenografts in multiple different models. Here we evaluate the hypothesis that an increased human CD46 gene dose, through homozygosity or additional expression of a second hCPRP, is associated with increased protein expression and with improved protection from injury when GTKO lung xenografts are perfused with human blood. METHODS Twenty three GTKO lungs heterozygous for human CD46 (GTKO.heteroCD46), 10 lungs homozygous for hCD46 (GTKO.homoCD46), and six GTKO.homoCD46 lungs also heterozygous for hCD55 (GTKO.homoCD46.hCD55) were perfused with human blood for up to 4 h in an ex vivo circuit. RESULTS Relative to GTKO.heteroCD46 (152 min, range 5-240; 6/23 surviving at 4 h), survival was significantly improved for GTKO.homoCD46 (>240 min, range 45-240, p = .034; 7/10 surviving at 4 h) or GTKO.homoCD46.hCD55 lungs (>240 min, p = .001; 6/6 surviving at 4 h). Homozygosity was associated with increased capillary expression of hCD46 (p < .0001). Increased hCD46 expression was associated with significantly prolonged lung survival (p = .048),) but surprisingly not with reduction in measured complement factor C3a. Hematocrit, monocyte count, and pulmonary vascular resistance were not significantly altered in association with increased hCD46 gene dose or protein expression. CONCLUSION Genetic engineering approaches designed to augment hCPRP activity - increasing the expression of hCD46 through homozygosity or co-expressing hCD55 with hCD46 - were associated with prolonged GTKO lung xenograft survival. Increased expression of hCD46 was associated with reduced coagulation cascade activation, but did not further reduce complement activation relative to lungs with relatively low CD46 expression. We conclude that coagulation pathway dysregulation contributes to injury in GTKO pig lung xenografts perfused with human blood, and that the survival advantage for lungs with increased hCPRP expression is likely attributable to improved endothelial thromboregulation.

[1]  R. Pierson,et al.  Effects of human TFPI and CD47 expression and selectin and integrin inhibition during GalTKO.hCD46 pig lung perfusion with human blood , 2022, Xenotransplantation.

[2]  R. Pierson,et al.  hEPCR.hTBM.hCD47.hHO‐1 with donor clodronate and DDAVP treatment improves perfusion and function of GalTKO.hCD46 porcine livers perfused with human blood , 2022, Xenotransplantation.

[3]  R. Pierson,et al.  Human erythrocyte fragmentation during ex‐vivo pig organ perfusion , 2022, Xenotransplantation.

[4]  R. Pierson,et al.  Humanized von Willebrand factor reduces platelet sequestration in ex vivo and in vivo xenotransplant models , 2021, Xenotransplantation.

[5]  R. Pierson,et al.  Pig‐to‐baboon lung xenotransplantation: Extended survival with targeted genetic modifications and pharmacologic treatments , 2021, American journal of transplantation : official journal of the American Society of Transplantation and the American Society of Transplant Surgeons.

[6]  Z. Kozovska,et al.  CRISPR: History and perspectives to the future. , 2021, Biomedicine & pharmacotherapy = Biomedecine & pharmacotherapie.

[7]  E. Wolf,et al.  Pig-to-non-human primate heart transplantation: The final step toward clinical xenotransplantation? , 2020, The Journal of heart and lung transplantation : the official publication of the International Society for Heart Transplantation.

[8]  C. Qin,et al.  Xenotransplantation: Current Status in Preclinical Research , 2020, Frontiers in Immunology.

[9]  R. Pierson,et al.  Thromboxane and histamine mediate PVR elevation during xenogeneic pig lung perfusion with human blood , 2018, Xenotransplantation.

[10]  R. Pierson,et al.  Interleukin‐8 mediates neutrophil‐endothelial interactions in pig‐to‐human xenogeneic models , 2018, Xenotransplantation.

[11]  Dana Carroll,et al.  Genome Editing: Past, Present, and Future
 , 2017, The Yale journal of biology and medicine.

[12]  R. Pierson,et al.  The role of sialic acids in the immune recognition of xenografts , 2017, Xenotransplantation.

[13]  D. Shriner,et al.  Human Germline Genome Editing. , 2017, American journal of human genetics.

[14]  R. F. Hoyt,et al.  Chimeric 2C10R4 anti-CD40 antibody therapy is critical for long-term survival of GTKO.hCD46.hTBM pig-to-primate cardiac xenograft , 2016, Nature Communications.

[15]  J. D. Watson,et al.  Human Genome Project: Twenty-five years of big biology , 2015, Nature.

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

[17]  J. Doudna,et al.  The new frontier of genome engineering with CRISPR-Cas9 , 2014, Science.

[18]  D. Ayares,et al.  Expression of Human CD46 Modulates Inflammation Associated With GalTKO Lung Xenograft Injury , 2014, American journal of transplantation : official journal of the American Society of Transplantation and the American Society of Transplant Surgeons.

[19]  Ashutosh Kumar Singh,et al.  B‐Cell Depletion Extends the Survival of GTKO.hCD46Tg Pig Heart Xenografts in Baboons for up to 8 Months , 2012, American journal of transplantation : official journal of the American Society of Transplantation and the American Society of Transplant Surgeons.

[20]  D. Sachs,et al.  Absence of Gal epitope prolongs survival of swine lungs in an ex vivo model of hyperacute rejection , 2011, Xenotransplantation.

[21]  H. Ohdan,et al.  Deficiency of N‐glycolylneuraminic acid and Galα1‐3Galβ1‐4GlcNAc epitopes in xenogeneic cells attenuates cytotoxicity of human natural antibodies , 2010, Xenotransplantation.

[22]  R. Pierson,et al.  Life-supporting function of genetically modified swine lungs in baboons. , 2007, The Journal of thoracic and cardiovascular surgery.

[23]  C. Harris,et al.  ‘‘Homologous restriction’’ in complement lysis: roles of membrane complement regulators , 2005, Xenotransplantation.

[24]  B. Loveland,et al.  Characterization of a CD46 transgenic pig and protection of transgenic kidneys against hyperacute rejection in non‐immunosuppressed baboons , 2004, Xenotransplantation.

[25]  S. H. A. Chen,et al.  Production of α1,3-Galactosyltransferase-Deficient Pigs , 2002, Science.

[26]  John D Lambris,et al.  Role of Membrane Cofactor Protein (CD46) in Regulation of C4b and C3b Deposited on Cells1 , 2002, The Journal of Immunology.

[27]  R. Pierson,et al.  Thromboxane mediates pulmonary hypertension and lung inflammation during hyperacute lung rejection. , 2001, Journal of applied physiology.

[28]  I. Wilmut,et al.  "Viable Offspring Derived from Fetal and Adult Mammalian Cells" (1997), by Ian Wilmut et al. , 2014 .

[29]  J. Atkinson,et al.  SEPARATION OF SELF FROM NON‐SELF IN THE COMPLEMENT SYSTEM: A ROLE FOR MEMBRANE COFACTOR PROTEIN AND DECAY ACCELERATING FACTOR , 1991, Clinical and experimental immunology.

[30]  J. Atkinson,et al.  Functional properties of membrane cofactor protein of complement. , 1989, The Biochemical journal.

[31]  G. Blancho,et al.  Corneal Xenotransplantation: Anterior Lamellar Keratoplasty. , 2020, Methods in molecular biology.

[32]  R. Bottino,et al.  Pig-to-Macaque Islet Xenotransplantation. , 2020, Methods in molecular biology.

[33]  R. Pierson,et al.  Hyperacute rejection is attenuated in GalT knockout swine lungs perfused ex vivo with human blood. , 2005, Transplantation proceedings.