Hum Reprod. 2025 Apr 02. pii: deaf050. [Epub ahead of print]
STUDY QUESTION: Is preimplantation genetic testing for mitochondrial DNA (mtDNA) disorders (PGT-mt) feasible at early compaction and blastocyst stages?
SUMMARY ANSWER: Pathogenic mtDNA variants segregate evenly among cell types and various lineages of a given embryo during preimplantation development, supporting the relevance of genetic analyses performed on Day 4 blastomere and on Day 5 or 6 trophectoderm (TE) samples.
WHAT IS KNOWN ALREADY: PGT-mt is validated at cleavage stage (Day 3 of development). However, its feasibility at later stages is questionable, as little is known regarding the segregation of pathogenic mtDNA variants during preimplantation development. Since mtDNA replication is silenced until the blastocyst stage (Day 5 or 6), uneven mtDNA segregation between preimplantation embryo cellular lineages known as a 'bottleneck' effect, cannot be excluded, posing a challenge for PGT-mt.
STUDY DESIGN, SIZE, DURATION: We analyzed 112 'mito' embryos carrying pathogenic mtDNA variants and 28 control embryos with mtDNA polymorphism. Heteroplasmy levels were assessed in single cells of the TE, in different parts of blastocysts (inner cell mass and TE), and at three time points of development, namely cleavage (Day 3), early compaction (Day 4), and blastocyst stages (Day 5 or 6).
PARTICIPANTS/MATERIALS, SETTING, METHODS: As part of clinical PGT, a blastomere biopsy was performed at cleavage or early compaction stages (Day 3 or 4) on 112 'mito' and 21/28 control embryos. Further analysis was carried out at Day 5 or 6 on 51 embryos deemed unsuitable for uterine transfer and donated to research. Heteroplasmy levels were determined by semi-quantitative PCR amplification of (i) the mtDNA pathogenic variants with additional enzymatic digestion or (ii) the mtDNA polymorphic hypervariable region 2.
MAIN RESULTS AND THE ROLE OF CHANCE: Here, we first show that mtDNA variants segregate evenly among blastomeres during early compaction (Day 4), supporting the feasibility of PGT-mt at this stage. We also found that mtDNA ratios remain stable between cleavage and blastocyst stages. Yet, the substantial variation of heteroplasmy levels occurring among single TE cells in 1/8 embryos suggests that PGT is only feasible when at least 5-10 cells are collected by standard TE biopsy.
LIMITATIONS, REASONS FOR CAUTION: This study sheds light on mtDNA segregation in human preimplantation embryo development. Its limitation lies in the scarcity of the material and the small number of embryos carrying a specific pathogenic mtDNA variant. Furthermore, the study of single cells from TE was performed on control embryos only.
WIDER IMPLICATIONS OF THE FINDINGS: By supporting the relevance of blastocyst biopsy in the context of PGT for pathogenic mtDNA variants, this study contributes to the general trend of postponing the biopsy to later stages of embryonic development. However, particular attention should be paid to the number of TE cells tested. Due to the potential variation of mutant load during in utero development, a control amniocentesis for evolutive pregnancies following the transfer of heteroplasmic embryos is still recommended.
STUDY FUNDING/COMPETING INTEREST(S): This work was funded by 'Association Française contre les Myopathies/AFM Téléthon' (22112, 24317, 28525); and EUR G.E.N.E. (No. ANR-17-EURE-0013). The authors have no competing interests to declare.
TRIAL REGISTRATION NUMBER: N/A.
Keywords: heteroplasmy; human preimplantation embryo; mitochondria; mitochondrial DNA; morula biopsy; mtDNA segregation; pathogenic mtDNA variants; preimplantation genetic testing; trophectoderm biopsy