TY - JOUR
T1 - Segregation of mitochondrial DNA heteroplasmy through a developmental genetic bottleneck in human embryos
AU - Floros, Vasileios I.
AU - Pyle, Angela
AU - DIetmann, Sabine
AU - Wei, Wei
AU - Tang, Walfred W.C.
AU - Irie, Naoko
AU - Payne, Brendan
AU - Capalbo, Antonio
AU - Noli, Laila
AU - Coxhead, Jonathan
AU - Hudson, Gavin
AU - Crosier, Moira
AU - Strahl, Henrik
AU - Khalaf, Yacoub
AU - Saitou, Mitinori
AU - Ilic, Dusko
AU - Surani, M. Azim
AU - Chinnery, Patrick F.
N1 - Publisher Copyright:
© 2018 The Authors 2017, under exclusive licence to Macmillan Publishers Limited, part of Springer Nature.
PY - 2018/2/1
Y1 - 2018/2/1
N2 - Mitochondrial DNA (mtDNA) mutations cause inherited diseases and are implicated in the pathogenesis of common late-onset disorders, but how they arise is not clear 1,2 . Here we show that mtDNA mutations are present in primordial germ cells (PGCs) within healthy female human embryos. Isolated PGCs have a profound reduction in mtDNA content, with discrete mitochondria containing ~5 mtDNA molecules. Single-cell deep mtDNA sequencing of in vivo human female PGCs showed rare variants reaching higher heteroplasmy levels in late PGCs, consistent with the observed genetic bottleneck. We also saw the signature of selection against non-synonymous protein-coding, tRNA gene and D-loop variants, concomitant with a progressive upregulation of genes involving mtDNA replication and transcription, and linked to a transition from glycolytic to oxidative metabolism. The associated metabolic shift would expose deleterious mutations to selection during early germ cell development, preventing the relentless accumulation of mtDNA mutations in the human population predicted by Muller's ratchet. Mutations escaping this mechanism will show shifts in heteroplasmy levels within one human generation, explaining the extreme phenotypic variation seen in human pedigrees with inherited mtDNA disorders.
AB - Mitochondrial DNA (mtDNA) mutations cause inherited diseases and are implicated in the pathogenesis of common late-onset disorders, but how they arise is not clear 1,2 . Here we show that mtDNA mutations are present in primordial germ cells (PGCs) within healthy female human embryos. Isolated PGCs have a profound reduction in mtDNA content, with discrete mitochondria containing ~5 mtDNA molecules. Single-cell deep mtDNA sequencing of in vivo human female PGCs showed rare variants reaching higher heteroplasmy levels in late PGCs, consistent with the observed genetic bottleneck. We also saw the signature of selection against non-synonymous protein-coding, tRNA gene and D-loop variants, concomitant with a progressive upregulation of genes involving mtDNA replication and transcription, and linked to a transition from glycolytic to oxidative metabolism. The associated metabolic shift would expose deleterious mutations to selection during early germ cell development, preventing the relentless accumulation of mtDNA mutations in the human population predicted by Muller's ratchet. Mutations escaping this mechanism will show shifts in heteroplasmy levels within one human generation, explaining the extreme phenotypic variation seen in human pedigrees with inherited mtDNA disorders.
UR - http://www.scopus.com/inward/record.url?scp=85040700724&partnerID=8YFLogxK
U2 - 10.1038/s41556-017-0017-8
DO - 10.1038/s41556-017-0017-8
M3 - Article
C2 - 29335530
AN - SCOPUS:85040700724
SN - 1465-7392
VL - 20
SP - 144
EP - 151
JO - Nature Cell Biology
JF - Nature Cell Biology
IS - 2
ER -