| Literature DB >> 31427818 |
Tobias Deuse1, Xiaomeng Hu1,2,3, Sean Agbor-Enoh4,5, Martina Koch6, Matthew H Spitzer7,8,9, Alessia Gravina1,3, Malik Alawi10, Argit Marishta5, Bjoern Peters11, Zeynep Kosaloglu-Yalcin11, Yanqin Yang5, Raja Rajalingam12, Dong Wang1,2,3, Bjoern Nashan6, Rainer Kiefmann13, Hermann Reichenspurner2,3, Hannah Valantine5, Irving L Weissman14, Sonja Schrepfer15,16,17,18.
Abstract
The utility of autologous induced pluripotent stem cell (iPSC) therapies for tissue regeneration depends on reliable production of immunologically silent functional iPSC derivatives. However, rejection of autologous iPSC-derived cells has been reported, although the mechanism underlying rejection is largely unknown. We hypothesized that de novo mutations in mitochondrial DNA (mtDNA), which has far less reliable repair mechanisms than chromosomal DNA, might produce neoantigens capable of eliciting immune recognition and rejection. Here we present evidence in mice and humans that nonsynonymous mtDNA mutations can arise and become enriched during reprogramming to the iPSC stage, long-term culture and differentiation into target cells. These mtDNA mutations encode neoantigens that provoke an immune response that is highly specific and dependent on the host major histocompatibility complex genotype. Our results reveal that autologous iPSCs and their derivatives are not inherently immunologically inert for autologous transplantation and suggest that iPSC-derived products should be screened for mtDNA mutations.Entities:
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Year: 2019 PMID: 31427818 DOI: 10.1038/s41587-019-0227-7
Source DB: PubMed Journal: Nat Biotechnol ISSN: 1087-0156 Impact factor: 54.908