BACKGROUND: Hyperacute rejection of discordant xenografts is dependent on activation of the complement system of the recipient. Transgenic expression of recipient complement regulatory factors in donor tissue has proved to be a promising approach to dealing with hyperacute rejection, although the relationship between the level of complement regulatory factor expression and the degree of protection is not well established. Here, we examine this relationship using CD59 transgenic mouse hearts in an ex vivo model of xenograft rejection. METHODS: The level of expression of CD59 in two lines of transgenic mice, in which CD59 is expressed under the control of either the murine H2Kb (MHC class I) promoter (line CA-17) or the endothelium-specific human intercellular adhesion molecule-2 promoter (line 237-7), was compared by immunohistochemistry and flow cytometry. Hearts from both groups and wild-type controls were perfused ex vivo with human plasma, and mean heart work for each group was compared over a 60-min period. RESULTS: CD59 expression on cardiac endothelial cells isolated from homozygous CA-17 mice was 25- to 30-fold lower than that on cardiac endothelial cells from heterozygous 237-7 mice. CA-17 hearts perfused with 6% human plasma exhibited a reduction in deposition of the membrane attack complex, but not a prolongation of function, compared with nontransgenic mouse hearts. In contrast, 237-7 hearts showed significantly prolonged function during perfusion with 20% plasma. CONCLUSIONS: High-level endothelial-specific expression of CD59 was effective in prolonging the function of mouse hearts perfused with 20% human plasma, whereas low-level, broader expression did not provide protection from 6% plasma.
BACKGROUND: Hyperacute rejection of discordant xenografts is dependent on activation of the complement system of the recipient. Transgenic expression of recipient complement regulatory factors in donor tissue has proved to be a promising approach to dealing with hyperacute rejection, although the relationship between the level of complement regulatory factor expression and the degree of protection is not well established. Here, we examine this relationship using CD59 transgenic mouse hearts in an ex vivo model of xenograft rejection. METHODS: The level of expression of CD59 in two lines of transgenic mice, in which CD59 is expressed under the control of either the murineH2Kb (MHC class I) promoter (line CA-17) or the endothelium-specific human intercellular adhesion molecule-2 promoter (line 237-7), was compared by immunohistochemistry and flow cytometry. Hearts from both groups and wild-type controls were perfused ex vivo with human plasma, and mean heart work for each group was compared over a 60-min period. RESULTS:CD59 expression on cardiac endothelial cells isolated from homozygous CA-17 mice was 25- to 30-fold lower than that on cardiac endothelial cells from heterozygous 237-7 mice. CA-17 hearts perfused with 6% human plasma exhibited a reduction in deposition of the membrane attack complex, but not a prolongation of function, compared with nontransgenic mouse hearts. In contrast, 237-7 hearts showed significantly prolonged function during perfusion with 20% plasma. CONCLUSIONS: High-level endothelial-specific expression of CD59 was effective in prolonging the function of mouse hearts perfused with 20% human plasma, whereas low-level, broader expression did not provide protection from 6% plasma.
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: Gongxiong Wu; Weiguo Hu; Aliakbar Shahsafaei; Wenping Song; Martin Dobarro; Galina K Sukhova; Rod R Bronson; Guo-Ping Shi; Russell P Rother; Jose A Halperin; Xuebin Qin Journal: Circ Res Date: 2009-01-08 Impact factor: 17.367
Authors: Sharon J Harrison; Angelo Guidolin; Renate Faast; Lesley A Crocker; Chris Giannakis; Anthony J F D'Apice; Mark B Nottle; Ian Lyons Journal: Transgenic Res Date: 2002-04 Impact factor: 2.788