Xenotransplantation using transgenic pigs as an organ source is a promising strategy to overcome shortage of human organ for transplantation. Various genetic modifications have been tried to ameliorate xenograft rejection. In the present study we assessed effect of transgenic expression of human heme oxygenase-1 (hHO-1), an inducible protein capable of cytoprotection by scavenging reactive oxygen species and preventing apoptosis caused by cellular stress during inflammatory processes, in neonatal porcine islet-like cluster cells (NPCCs). Transduction of NPCCs with adenovirus containing hHO-1 gene significantly reduced apoptosis compared with the GFP-expressing adenovirus control after treatment with either hydrogen peroxide or hTNF-α and cycloheximide. These protective effects were diminished by co-treatment of hHO-1 antagonist, Zinc protoporphyrin IX. We also generated transgenic pigs expressing hHO-1 and analyzed expression and function of the transgene. Human HO-1 was expressed in most tissues, including the heart, kidney, lung, pancreas, spleen and skin, however, expression levels and patterns of the hHO-1 gene are not consistent in each organ. We isolate fibroblast from transgenic pigs to analyze protective effect of the hHO-1. As expected, fibroblasts derived from the hHO-1 transgenic pigs were significantly resistant to both hydrogen peroxide damage and hTNF-α and cycloheximide-mediated apoptosis when compared with wild-type fibroblasts. Furthermore, induction of RANTES in response to hTNF-α or LPS was significantly decreased in fibroblasts obtained from the hHO-1 transgenic pigs. These findings suggest that transgenic expression of hHO-1 can protect xenografts when exposed to oxidative stresses, especially from ischemia/reperfusion injury, and/or acute rejection mediated by cytokines. Accordingly, hHO-1 could be an important candidate molecule in a multi-transgenic pig strategy for xenotransplantation.
Generation of transgenic pigs for xenotransplantation is one of the most promising technologies for resolving organ shortages. Human heme oxygenase-1 (hHO-1/HMOX1) can protect transplanted organs by its strong anti-oxidative, anti-apoptotic, and anti-inflammatory effects. Soluble human TNFRI-Fc (shTNFRI-Fc) can inhibit the binding of human TNF-α (hTNF-α) to TNF receptors on porcine cells, and thereby, prevent hTNF-α-mediated inflammation and apoptosis. Herein, we successfully generated shTNFRI-Fc-F2A-HA-hHO-1 transgenic (TG) pigs expressing both shTNFRI-Fc and hemagglutinin-tagged-human heme oxygenase-1 (HA-hHO-1) by using an F2A self-cleaving peptide. shTNFRI-Fc and HA-hHO-1 transgenes containing the F2A peptide were constructed under the control of the CAG promoter. Transgene insertion and copy number in the genome of transgenic pigs was confirmed by polymerase chain reaction (PCR) and Southern blot analysis. Expressions of shTNFRI-Fc and HA-hHO-1 in TG pigs were confirmed using PCR, RT-PCR, western blot, ELISA, and immunohistochemistry. shTNFRI-Fc and HA-hHO-1 were expressed in various organs, including the heart, lung, and spleen. ELISA assays detected shTNFRI-Fc in the sera of TG pigs. For functional analysis, fibroblasts isolated from a shTNFRI-Fc-F2A-HA-hHO-1 TG pig (i.e., #14; 1 × 10(5) cells) were cultured with hTNF-α (20 ng/mL) and cycloheximide (10 μg/mL). The viability of shTNFRI-Fc-F2A-HA-hHO-1 TG pig fibroblasts was significantly higher than that of the wild type (wild type vs. shTNFRI-Fc-F2A-HA-hHO-1 TG at 24 h, 31.6 ± 3.2 vs. 60.4 ± 8.3 %, respectively; p < 0.05). Caspase-3/-7 activity of the shTNFRI-Fc-F2A-HA-hHO-1 TG pig fibroblasts was lower than that of the wild type pig fibroblasts (wild type vs. shTNFRI-Fc-F2A-HA-hHO-1 TG at 12 h, 812,452 ± 113,078 RLU vs. 88,240 ± 10,438 RLU, respectively; p < 0.05). These results show that shTNFRI-Fc and HA-hHO-1 TG pigs generated by the F2A self-cleaving peptide express both shTNFRI-Fc and HA-hHO-1 molecules, which provides protection against oxidative and inflammatory injury. Utilization of the F2A self-cleaving peptide is a promising tool for generating multiple TG pigs for xenotransplantation.
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: With the introduction of the a1, 3-galactosyltransferase gene-knockout (GT-KO) pig and its pivotal role in preventing hyperacute rejection (HAR), coagulation remains a considerable obstacle yet to be overcome in order to provide long-term xenograft survival. Thrombomodulin (TBM) plays a critical anticoagulant and anti-inflammatory role in its part of the protein C pathway. Many studies have demonstrated the strong anticoagulant effects of TBM in xenotransplantation, but its complement regulatory effects have not been appropriately examined. Here, we investigate whether TBM can regulate complement activation as well as coagulation in response to xenogeneic stimuli. Methods: We transfected porcine endothelial cells (MPN-3) with adenovirus vectors containing the human TBM gene (ad-hTBM), or a control gene containing GFP (ad-GFP). The expression level of ad-hTBM was measured by flow cytometry. To confirm the anticoagulant effect of TBM, coagulation time was measured after treatment with recalcified human plasma in adhTBM-transfected MPN-3, and a thrombin activity assay was performed after treatment with 50% human serum in ad-hTBM-infected MPN-3. Results: Thrombin generation was significantly decreased in a dosedependent manner in ad-TBM group, and coagulation time was increased in the ad-hTBM group when compared to the ad-GFP group. Complement-dependent serum toxicity assays were performed after treatment with 20% human serum or heat-inactivated human serum by LDH assay. Complement-dependent toxicity was significantly attenuated in the ad-hTBM group, but complement-independent toxicity was not attenuated in the ad-hTBM group. These results suggest that human thrombomodulin (hTBM) has complement regulatory effects as well as anticoagulant effects. To further investigate the mechanisms of complement regulation by hTBM, we deleted the EGF5, 6 domains that are involved in thrombin generation or the lectin-like domain involved in inflammation of TBM and functional tests were performed using these modified forms. We showed that the EGF5, 6 domain of TBM principally inhibits complement activation rather than the lectin domain. Conclusion: The EGF5, 6 domains of TBM appear to be the major domains for down-regulating the complement system rather than the lectin-like domain during xenogenic stimuli. The role of EGF5, 6 domains of hTBM may be due to inhibition of thrombin as thrombin can cleave C3a and C5a directly and hTBM may also be involved in complement regulation. Clearly then human TBM has complement regulatory effects as well as anticoagulant effects in xeno-immune response, and it is a promising target for attenuating xenograft rejection.
We showed that IgG-mediated CDC was detected in Neu5Gc-overexpressed HEK293 cells incubated with human sera; however, this antibody reactivity to Neu5Gc was highly variable among individuals. Our results suggest that additional modifications to the CMAH gene should be considered for widespread use of pig organs for human transplants.
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