The final obstacle to successful pre‐clinical xenotransplantation?

Yamamoto, Takayuki; Hara, Hidetaka; Iwase, Hayato; Jagdale, Abhijit; Bikhet, Mohamed H; Morsi, Mahmoud; Cui, Yehua; Nguyen, Huy Quoc; Wang, Zheng‐Yu; Anderson, Douglas J.; Foote, Jeremy B.; Schuurman, Henk‐Jan; Ayares, David; Eckhoff, Devin E.; Cooper, David K. C.

doi:10.1111/xen.12596

Cited by 36 publications

(45 citation statements)

References 28 publications

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“…The scientific community has published requirements on efficacy data to support a clinical trial application, that is, for porcine islets 68 and cornea 69 in recent years, and already in 2000 for a porcine heart 70 . It should be realized in this discussion that studies in animal species have their limitations to translation to the human species; some examples are the complications in long‐term survival of a porcine islet product in diabetic monkeys 71 and incompatibility between non‐human primates and humans regarding expression of some carbohydrate xeno‐antigens 72 . Regulatory agencies do not prescribe which animal models including species combinations need to be used; most often, pivotal transplantation experiments are conducted in a life‐supporting situation, for example, for a kidney in animals after bilaterally nephrectomy.…”

Section: Conclusion and Perspectivementioning

confidence: 99%

Solid organ xenotransplantation at the interface between research and clinical development: Regulatory aspects

Schuurman¹,

Hoogendoorn

2020

Xenotransplantation

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During the last years, progress has been made in survival and function of pig‐to‐non‐human primate organ xenotransplantation using organs from genetically modified pigs and immunosuppression regimens that are clinically acceptable. This, together with increased insights into a low risk of pig‐to‐human transmission of porcine endogenous retrovirus, has opened the perspective of starting with first‐in‐human trials with xenogeneic organs. The regulatory path to clinical development is complex. Unlike an organ from human donors, an organ from pigs, either genetically modified or wild‐type pigs, is considered a medicinal product for human use and hence is under regulatory oversight, in the United States by the Food and Drug Administration and in Europe by the national competent authorities of the member states as well as the European Medicines Agency. Related to the status of medicinal product, “(current) good practices” apply in the process of generating a xenogeneic organ through to the transplantation into a patient and life‐long follow‐up. In addition, guidances for xenotransplantation products and genetically modified organisms do apply as well. This commentary focuses on regulatory aspects of transplantation of organs from genetically modified pigs into humans, with the intention to facilitate the interactions between regulatory agencies and institutions (sponsors) in research and clinical development of these organs, to support the perspective of speeding up the process with a proper entry in clinical application, to fill an unmet medical need in patients with end‐stage organ disease.

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Section: Conclusion and Perspectivementioning

confidence: 99%

Solid organ xenotransplantation at the interface between research and clinical development: Regulatory aspects

Schuurman¹,

Hoogendoorn

2020

Xenotransplantation

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“…Yamamoto et al comment on relevance of antibody binding in humans and primates with regard to the production of natural antibodies directed at novel xenoantigens. The T‐cell proliferative response to α1,3‐galactosyltransferase gene knockout (GTKO) pig peripheral blood mononuclear cells (PBMCs) is reduced when compared to wild‐type pig PBMCs, while the deletion of expression of all three glycans does not further reduce the proliferative response 3 . However, baboons and old‐world monkeys contain antibodies that bind to RBCs from TKO pigs 4 due to the hypothetical fourth xenoantigen.…”

Section: Commentariesmentioning

confidence: 99%

“…However, baboons and old‐world monkeys contain antibodies that bind to RBCs from TKO pigs 4 due to the hypothetical fourth xenoantigen. Therefore, kidneys and hearts from TKO pigs would not show antibody‐mediated injury when transplanted into humans while the T‐cell response suppressed by blockade of CD40‐CD154 co‐stimulation pathway, while binding of baboon natural antibodies to donor pig (CMAH deleted) activates the complement cascade and results in high serum cytotoxicity irrespective to the binding potential 3‐9 . The authors point out that post‐transplant production of antibody toward the fourth xenoantigen is likely to result in chronic antibody‐mediated rejection.…”

Section: Commentariesmentioning

confidence: 99%

“…The authors point out that post‐transplant production of antibody toward the fourth xenoantigen is likely to result in chronic antibody‐mediated rejection. The obstacle of the fourth antigen may be overcome experimentally either when the xenoantigen is absent in case of additional gene editing, ex‐vivo perfusion of TKO organs with human blood to absorb antibody, or through further investigation by transplantation into brain‐dead human or New world monkey recipients 3 …”

Section: Commentariesmentioning

confidence: 99%

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Xenotransplantation literature update for September – October 2020

Rao

Burlak

2020

Xenotransplantation

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“…2-4 Therefore, successful pig heart or kidney transplantation in baboons may be more problematic than in a clinical trial. 4 The expression of one or more human complement-regulatory proteins, for example, CD46 and CD55, reduced early graft failure in GTKO pig-to-baboon transplant models. 5,6 However, it is unclear whether expression of additional human transgenes will suppress complement-dependent cytotoxicity (CDC) of TKO pig cells.…”

mentioning

confidence: 99%

The problem of the “4th xenoantigen” after pig organ transplantation in non‐human primates may be overcome by expression of human “protective” proteins

Yamamoto

Hara

Ayares³

et al. 2020

Xenotransplantation

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The problem of the "4th xenoantigen" after pig organ transplantation in non-human primates may be overcome by expression of human "protective" proteins Triple-knockout (TKO) pigs, in which all three-known carbohydrate xenoantigens are deleted, are now available for xenotransplantation research. Multiple human transgenes have been expressed in TKO pigs, all of which are aimed at protecting the cells from the human immune response. Many human sera demonstrate no or minimal antibody binding to, and little or no cytotoxicity of, cells from these pigs. 1 However, baboons and other Old World non-human primates have antibodies against TKO pig cells, apparently directed to a fourthxenoantigen that appears to be exposed after deletion of expression of N-glycolylneuraminic acid (CMAH-KO). 2-4 Therefore, successful pig heart or kidney transplantation in baboons may be more problematic than in a clinical trial. 4 The expression of one or more human complement-regulatory proteins, for example, CD46 and CD55, reduced early graft failure in GTKO pig-to-baboon transplant models. 5,6 However, it is unclear whether expression of additional human transgenes will suppress complement-dependent cytotoxicity (CDC) of TKO pig cells. Here, we briefly report that expression of several human "protective" proteins inhibits baboon serum CDC of TKO pig cells.Briefly, peripheral blood mononuclear cells (PBMCs) were obtained from (a) α1,3-galactosyltransferase gene-knockout (GTKO) and (b) TKO pigs (neither of which expressed any human "protective" transgenes), and from (c) GTKO/CD46/CD55 and (d) TKO/ CD46/CD55/CD47/HO-1 pigs (Revivicor), as previously described. 3 The expression of CD46, CD55, CD47, and HO-1 was confirmed by immunohistochemistry and Western blot. Sera were obtained from eight baboons (Michale E Keeling Center, MD Anderson Cancer Center) and stored at − 80°C. When required, decomplementation was carried out by heat inactivation for 30 minutes at 56°C. Baboon serum IgM and IgG binding to pig PBMCs, and baboon serum CDC to pig PBMCs (at a serum concentration of 25%), were measured as previously described. 3 Data acquisition was performed with a flow cytometer (LSRII, Becton Dickinson). Binding of IgM and IgG was reported as the relative geometric mean (rGM), calculated by dividing the geometric mean fluorescence for each sample by that of the negative control, as previously described. 3Mean CDC of GTKO pig cells (58%) was significantly greater than of GTKO/CD46/CD55 pig cells (33%) (P < .05; Figure 1A), but was not significantly different from that of TKO cells (41%; Figure 1C).CDC of TKO/CD46/CD55/CD47/HO-1 pig cells was almost totally suppressed (5%) and was significantly less than of TKO pig cells (41%) (P < .01), even though the binding of baboon serum IgM to TKO/CD46/CD55/CD47/HO-1 pig cells was slightly greater (though not significantly different) than to TKO pig cells (Figure 1B).These results suggest that the additional expression of CD47 and HO-1 on pig cells may have had a protective effect, probably though expression o...

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The final obstacle to successful pre‐clinical xenotransplantation?

Cited by 36 publications

References 28 publications

Solid organ xenotransplantation at the interface between research and clinical development: Regulatory aspects

Solid organ xenotransplantation at the interface between research and clinical development: Regulatory aspects

Xenotransplantation literature update for September – October 2020

The problem of the “4th xenoantigen” after pig organ transplantation in non‐human primates may be overcome by expression of human “protective” proteins

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