BACKGROUND: Acute humoral xenograft rejection (AHXR) is an important barrier to xenograft survival. Human tumor necrosis factor-α (hTNF-α) is one of the essential mediators of AHXR and induces activation of porcine endothelial cells (PECs), resulting in upregulation of major histocompatibility complex molecules, adhesion molecules, and proinflammatory chemokines. We investigated whether introduction of a soluble human tumor necrosis factor receptor I-Fc (shTNFRI-Fc) fusion gene can suppress activation of PECs and, more importantly, produced shTNFRI-Fc transgenic pigs. METHODS: The shTNFRI-Fc gene expression vector was constructed and inserted into PECs. The inhibitory effects of shTNFRI-Fc were tested by luciferase assay, reverse-transcriptase polymerase chain reaction, and flow cytometry. A shTNFRI-Fc transgenic pig was generated by somatic cell nuclear transfer. The expression of shTNFRI-Fc in the transgenic pig was evaluated by PCR, western blot, enzyme-linked immunosorbent assay, and immunohistochemistry. The inhibitory effects of shTNFRI-Fc in the serum obtained from the transgenic pig were also tested. RESULTS: In comparison with control green fluorescent protein, shTNFRI-Fc protein showed much stronger inhibitory effects on NF-κB activation in the HEK293-NF-κB-luciferase reporting cell line, expression of chemokines and adhesion molecules in PECs, and TNF-α-mediated cytotoxicity. We successfully generated shTNFRI-Fc transgenic pig. Sera obtained from the transgenic pig inhibited induction of chemokines, and E-selectin in PECs stimulated with Human TNF-α. CONCLUSIONS: We have generated transgenic pigs producing shTNFRI-Fc protein that can inhibit TNF-α-mediated activation of PECs. Because TNF-α is an important mediator of xenograft rejection, the use of xenografts that can produce shTNFRI-Fc proteins de novo could be an effective approach in overcoming a considerable component of the xenograft rejection process, especially AHXR.
BACKGROUND: Acute humoral xenograft rejection (AHXR) is an important barrier to xenograft survival. Humantumornecrosis factor-α (hTNF-α) is one of the essential mediators of AHXR and induces activation of porcine endothelial cells (PECs), resulting in upregulation of major histocompatibility complex molecules, adhesion molecules, and proinflammatory chemokines. We investigated whether introduction of a soluble humantumornecrosis factor receptor I-Fc (shTNFRI-Fc) fusion gene can suppress activation of PECs and, more importantly, produced shTNFRI-Fc transgenic pigs. METHODS: The shTNFRI-Fc gene expression vector was constructed and inserted into PECs. The inhibitory effects of shTNFRI-Fc were tested by luciferase assay, reverse-transcriptase polymerase chain reaction, and flow cytometry. A shTNFRI-Fc transgenic pig was generated by somatic cell nuclear transfer. The expression of shTNFRI-Fc in the transgenic pig was evaluated by PCR, western blot, enzyme-linked immunosorbent assay, and immunohistochemistry. The inhibitory effects of shTNFRI-Fc in the serum obtained from the transgenic pig were also tested. RESULTS: In comparison with control green fluorescent protein, shTNFRI-Fc protein showed much stronger inhibitory effects on NF-κB activation in the HEK293-NF-κB-luciferase reporting cell line, expression of chemokines and adhesion molecules in PECs, and TNF-α-mediated cytotoxicity. We successfully generated shTNFRI-Fc transgenic pig. Sera obtained from the transgenic pig inhibited induction of chemokines, and E-selectin in PECs stimulated with Human TNF-α. CONCLUSIONS: We have generated transgenic pigs producing shTNFRI-Fc protein that can inhibit TNF-α-mediated activation of PECs. Because TNF-α is an important mediator of xenograft rejection, the use of xenografts that can produce shTNFRI-Fc proteins de novo could be an effective approach in overcoming a considerable component of the xenograft rejection process, especially AHXR.
Authors: Geon A Kim; Eun Mi Lee; Bumrae Cho; Zahid Alam; Su Jin Kim; Sanghoon Lee; Hyun Ju Oh; Jong Ik Hwang; Curie Ahn; Byeong Chun Lee Journal: Transgenic Res Date: 2018-12-14 Impact factor: 2.788
Authors: David K C Cooper; Burcin Ekser; Christopher Burlak; Mohamed Ezzelarab; Hidetaka Hara; Leela Paris; A Joseph Tector; Carol Phelps; Agnes M Azimzadeh; David Ayares; Simon C Robson; Richard N Pierson Journal: Xenotransplantation Date: 2012 May-Jun Impact factor: 3.907
Authors: Yonglun Luo; Lin Lin; Lars Bolund; Thomas G Jensen; Charlotte Brandt Sørensen Journal: J Inherit Metab Dis Date: 2012-03-28 Impact factor: 4.982
Authors: Geon A Kim; Eun Mi Lee; Jun-Xue Jin; Sanghoon Lee; Anukul Taweechaipaisankul; Jong Ik Hwang; Zahid Alam; Curie Ahn; Byeong Chun Lee Journal: Transgenic Res Date: 2017-05-28 Impact factor: 2.788
Authors: Sol Ji Park; Bumrae Cho; Ok Jae Koo; Hwajung Kim; Jung Taek Kang; Sunghoon Hurh; Su Jin Kim; Hye Jung Yeom; Joonho Moon; Eun Mi Lee; Ji Yei Choi; Ju Ho Hong; Goo Jang; Joing-Ik Hwang; Jaeseok Yang; Byeong Chun Lee; Curie Ahn Journal: Transgenic Res Date: 2014-02-05 Impact factor: 2.788
Authors: Hye-Jung Yeom; Ok Jae Koo; Jaeseok Yang; Bumrae Cho; Jong-Ik Hwang; Sol Ji Park; Sunghoon Hurh; Hwajung Kim; Eun Mi Lee; Han Ro; Jung Taek Kang; Su Jin Kim; Jae-Kyung Won; Philip J O'Connell; Hyunil Kim; Charles D Surh; Byeong-Chun Lee; Curie Ahn Journal: PLoS One Date: 2012-10-05 Impact factor: 3.240
Authors: Ok Jae Koo; Seung-Kwon Ha; Sol Ji Park; Hee Jung Park; Su Jin Kim; Daekee Kwon; Jung Taek Kang; Joon Ho Moon; Eun Jung Park; Goo Jang; Byeong Chun Lee Journal: J Vet Sci Date: 2015-01-30 Impact factor: 1.672