Human CD55 Expression Blocks Hyperacute Rejection and Restricts Complement Activation in Gal Knockout Cardiac Xenografts

McGregor, Christopher G.A.; Ricci, Davide; Miyagi, Naoto; Stalboerger, Paul G.; Du, Zeji; Oehler, Elise A.; Tazelaar, Henry D.; Byrne, Guerard W.

doi:10.1097/tp.0b013e3182472850

Cited by 98 publications

(107 citation statements)

References 23 publications

(30 reference statements)

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“…Expression of multiple hCRPs increases in vitro resistance to complement mediated lysis assays, however, in hCXTx a prospective comparison of single (CD55) and double (CD55:CD46) transgenic donors found no additional survival benefit from the double transgenic donor hearts [50]. In the GTKO background a head-to-head comparisons of GTKO and GTKO:CD55 donors transplanted under identical immune suppression regimens shows GTKO:CD55 donor hearts have improved complement regulation and prevent early graft failure but do not prolong graft survival [51]. The early protective effects of hCRP expression in hCXTx was recently confirmed by an aggregate analysis of GTKO, GTKO:CD55 or GTKO:CD46 transplants from three transplant centers [26].…”

Section: Genetic Modifications Of Donorsmentioning

confidence: 99%

Current status of pig heart xenotransplantation

Mohiuddin

Reichart

Byrne

et al. 2015

International Journal of Surgery

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Significant progress in understanding and overcoming cardiac xenograft rejection using a clinically relevant large animal pig-to-baboon model has accelerated in recent years. This advancement is based on improved immune suppression, which attained more effective regulation of B lymphocytes and possibly newer donor genetics. These improvements have enhanced heterotopic cardiac xenograft survival from a few weeks to over 2 years, achieved intrathoracic heterotopic cardiac xenograft survival of 50 days and orthotopic survival of 57 days. This encouraging progress has rekindled interest in xenotransplantation research and refocused efforts on preclinical orthotopic cardiac xenotransplantation.

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Section: Genetic Modifications Of Donorsmentioning

confidence: 99%

Current status of pig heart xenotransplantation

Mohiuddin

Reichart

Byrne

et al. 2015

International Journal of Surgery

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“…The combination, therefore, of a graft from a pig that does not express the important Gal epitopes, but does express one or more human complement-regulatory proteins provides considerable protection against the primate innate immune response [21,22]. If, in addition, an effective immunosuppressive regimen is administered that prevents a T cell response to the graft, then prolonged graft survival has been obtained [23-29].…”

Section: Pig-to-primate Organ Transplantationmentioning

confidence: 99%

Recent advances in understanding xenotransplantation: implications for the clinic

Cooper

Bottino

2015

Expert Review of Clinical Immunology

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Summary The results of organ and cell allotransplantation continue to improve, but the field remains limited by a lack of deceased donor organs. Xenotransplantation, e.g., between pig and human, offers unlimited organs and cells for clinical transplantation. The immune barriers include a strong innate immune response in addition to the adaptive T cell response. The innate response has largely been overcome by the transplantation of organs from pigs with genetic modifications that protect their tissues from this response. T cell-mediated rejection can be controlled by immunosuppressive agents that inhibit costimulation. Coagulation dysfunction between the pig and primate remains problematic but is being overcome by the transplantation of organs from pigs that express human coagulation-regulatory proteins. The remaining barriers will be resolved by the introduction of novel genetically-engineered pigs. Limited clinical trials of pig islet and corneal transplantation are already underway.

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“…A combination of complement regulatory transgenes and GGTA1 gene inactivation can effectively control hyperacute rejection (Van Denderen et al, 1997;McGregor et al, 2012). Although the complement system and coagulation system are closely connected (Amara et al, 2010), additional genes regulating the coagulation system are necessary to inhibit AVR and AHXR.…”

Section: Antithrombotic Genesmentioning

confidence: 99%

“…To provide further protection in vivo, the GGTA1 gene was subsequently inactivated. The combination of complement regulatory genes with GGTA1 knockout has already shown to very efficiently prolong xenograft survival (Van Denderen et al, 1997;McGregor et al, 2012). To facilitate transplantation into human patients, the gene CMAH, responsible for the major non-Gal antigen Neu5Gc will be inactivated.…”

Section: Multi-transgenic Animalsmentioning

confidence: 99%

Multi‐transgenic pigs for xenotransplantation

Fischer

Kraner-Scheiber

Flisikowski

et al. 2013

Xenotransplantation

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Genetically modified pigs offer a solution to the severe shortage of organs available for human transplantation. Inactivation of the α1,3‐galactosyltransferase gene, responsible for α1,3‐Gal epitope synthesis (1–2) was a major breakthrough and essentially solved the problem of hyperacute rejection. However, further modifications of donor pigs are required to enable long term xenograft survival. These include expression of complement regulatory, antithrombotic, endothelium protective and immuno‐regulatory transgenes. Current evidence indicates that complement regulator transgenes, such as CD46 and CD55, must be expressed at least fivefold more than their human endogenous equivalent to effectively protect grafted tissue (3). To explore means of achieving high expression, we produced a series of BAC‐ and PAC‐vector constructs containing different sized genomic complement regulatory genes, from 70 to 190 kb, under the control of endogenous or CAGGs (CMV enhancer chicken β actin) promoter sequences. Using these vectors we obtained high levels of CD46 and CD55 expression in vitro. To prepare multi‐transgene “packages” for introduction into animals, the most effective constructs were combined with one or two further xenoprotective transgenes, including A20 (4), HO‐1 (5), thrombomodulin (6) and CTLA4‐Ig (LEA 29Y). In cotransfection experiments single cell clones expressing up to five different xenogenes could be detected. Achieving desired levels of transgene expression in an animal is not only a function of the transgene construct, but also of the location at which it integrates. Position effect variation in expression of random transgenes is well‐documented. Transgene placement by gene targeting at a permissive locus offers a useful means of achieving reliable transgene expression. In mice the ROSA26 locus is widely used to support ubiquitous expression of inserted transgenes (7–8). Murine ROSA26 encodes no functional genes and extensive gene targeting of this locus has not led to deleterious effects on development or physiology (9). To enable a similar approach in pigs, we recently identified a strong candidate for the porcine ROSA26 locus. Gene targeted placement of a neomycin reporter gene construct under the control of the ROSA26 promoter showed expression in all examined porcine tissues of all three germ layers. This strongly suggests that porcine ROSA 26 may resemble the murine locus as a suitably permissive site for transgene expression. We are currently proceeding with gene targeting to place various xenoprotective transgene constructs at this locus. References: 1. Dai Y, Vaught TD, Boone J et al. Targeted disruption of the alpha1,3‐ galactosyltransferase gene in cloned pigs. Nat Biotechnol 2002; 20: 251–255. 2. Lai L, Kolber‐Simonds D, Park K et al. Production of alpha‐1,3‐galactosyltransferase knockout pigs by nuclear transfer cloning. Science 2002; 295: 1089–1092. 3. Miyagawa S, Fukuta D, Kitano E et al. Effect of tandem forms of DAF(CD55) on complement‐mediated xenogeneic cell lysis. Xenotransplantation 20...

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Human CD55 Expression Blocks Hyperacute Rejection and Restricts Complement Activation in Gal Knockout Cardiac Xenografts

Cited by 98 publications

References 23 publications

Current status of pig heart xenotransplantation

Current status of pig heart xenotransplantation

Recent advances in understanding xenotransplantation: implications for the clinic

Multi‐transgenic pigs for xenotransplantation

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