BACKGROUND: Organs from transgenic animals with high-level endothelial expression of the human complement regulatory factors CD55 and CD59 are significantly protected from human complement-mediated injury. Elimination or reduction of the major xenoepitope alphaGal, achieved by knocking out the alpha1,3-galactosyltransferase gene (Gal KO) or expressing human alpha1,2-fucosyltransferase (H transferase or HTF), also affords protection, although to a lesser degree. In this study, we examined whether the protection provided by strong CD55 and CD59 expression can be augmented by the Gal KO or HTF modifications. METHODS: Hearts from four groups of mice (wild type, CD55/CD59, CD55/CD59/HTF, and CD55/CD59/Gal KO) were perfused ex vivo with 40% human plasma. Mean heart work for each group was compared over a 60-min period. RESULTS: Wild-type hearts ceased to function effectively within 15 min of plasma addition. CD55/CD59 hearts displayed prolonged survival and maintained approximately 10% maximum work at the end of perfusion. Introduction of Gal KO or HTF onto the CD55/CD59 background resulted in a further prolongation, with work maintained at 20-30% of the maximum level. CONCLUSIONS: We used an ex vivo model to demonstrate that eliminating alphaGal expression further prolongs the function of mouse hearts expressing high levels of CD55 and CD59. In addition, we showed that reducing alphaGal by expressing HTF is equally as effective in prolonging CD55/CD59 heart function as knocking out Gal transferase, thus providing a feasible strategy for translating these advances to the pig.
BACKGROUND: Organs from transgenic animals with high-level endothelial expression of the human complement regulatory factors CD55 and CD59 are significantly protected from human complement-mediated injury. Elimination or reduction of the major xenoepitope alphaGal, achieved by knocking out the alpha1,3-galactosyltransferase gene (Gal KO) or expressing humanalpha1,2-fucosyltransferase (H transferase or HTF), also affords protection, although to a lesser degree. In this study, we examined whether the protection provided by strong CD55 and CD59 expression can be augmented by the Gal KO or HTF modifications. METHODS: Hearts from four groups of mice (wild type, CD55/CD59, CD55/CD59/HTF, and CD55/CD59/Gal KO) were perfused ex vivo with 40% human plasma. Mean heart work for each group was compared over a 60-min period. RESULTS: Wild-type hearts ceased to function effectively within 15 min of plasma addition. CD55/CD59 hearts displayed prolonged survival and maintained approximately 10% maximum work at the end of perfusion. Introduction of Gal KO or HTF onto the CD55/CD59 background resulted in a further prolongation, with work maintained at 20-30% of the maximum level. CONCLUSIONS: We used an ex vivo model to demonstrate that eliminating alphaGal expression further prolongs the function of mouse hearts expressing high levels of CD55 and CD59. In addition, we showed that reducing alphaGal by expressing HTF is equally as effective in prolonging CD55/CD59 heart function as knocking out Gal transferase, thus providing a feasible strategy for translating these advances to the pig.
Authors: B Charreau; S Ménoret; L Tesson; A Azimzadeh; M Audet; P Wolf; R Marquet; C Verbakel; J Ijzermans; P Cowan; M Pearse; A d'Apice; J P Soulillou; I Anegon Journal: Mol Med Date: 1999-09 Impact factor: 6.354
Authors: W E Walsh; B E Anderson; D Ivancic; Z Zhang; J P Piccini; T G Rodgers; W Pao; J P Fryer Journal: Immunology Date: 2000-12 Impact factor: 7.397
Authors: Joseph Sushil Rao; Nora Hosny; Ramesh Kumbha; Raza Ali Naqvi; Amar Singh; Zachary Swanson; Heather Levy; Anders W Matson; Magie Steinhoff; Nicole Forneris; Eric Walters; Bernhard J Hering; Christopher Burlak Journal: Front Immunol Date: 2021-09-09 Impact factor: 7.561