Study of the effect of mitochondrial DNA amount on embryonic development: implications for fertility and mitochondrial inheritance

The mammalian mitochondrial DNA (mtDNA) is composed by only about 16,500 base pairs, is exclusively inherited from the mother, and encodes 13 polypeptides essential for mitochondrial function. Hundreds to thousands mtDNA copies are found in somatic cells depending on the energetic requirement of the tissue. However, oocytes contain more than 150,000 copies, at least an order of magnitude greater than most somatic cells. Moreover, since replication of mtDNA is downregulated during early development, the mtDNA content per cell decreases after each cell cycle. Therefore, mtDNA copy number in oocytes should be enough to support the energetic requirement of embryonic cells until mtDNA replication to be restablished. Considering there is a wide variability of mtDNA copy number among oocytes and there are reports showing a link between infertility and oocyte mtDNA copy number, the content of mtDNA could be used to select embryos more competent to develop. To test this hypothesis we used the bovine as an experimental model since its embryonic development is more similar to human than the murine is. Therefore, in a first experiment bovine oocytes derived from follicles of different sizes were used. Oocytes obtained from small follicles, known to be less competent to develop into blastocysts, contained less mtDNA than those originated from larger follicles. However, due to the high variability in copy number, in a second experiment a more accurate approach was examined in which parthenogenetic one-cell embryos were biopsied to measure their mtDNA content and then cultured to assess development capacity. Contrasting with previous findings, mtDNA copy number in biopsies was not different between competent and incompetent embryos, indicating that mtDNA content is not related to early developmental competence. To further examine the importance of mtDNA on development, one-cell embryos were partially depleted of over than 60% of their mtDNA by centrifugation followed by the removal of the mitochondrial-enriched cytoplasmic fraction. Surprisingly, depleted embryos developed normally into blastocysts, which contained mtDNA copy numbers similar to non-manipulated controls. Development in depleted embryos was accompanied by an increase in the expression of genes (TFAM and NRF1) controlling mtDNA replication and transcription, indicating an intrinsic ability to restore the content of mtDNA at the blastocyst stage. In conclusion, competent bovine embryos are able to regulate their mtDNA content at the blastocyst stage regardless of the copy numbers present in oocytes. These findings are in disagreement with that reported for mice, highlighting the need for studies using species more similar to human before the clinical use of mtDNA as a diagnostic tool in woman fertility. Moreover, these findings are important to manipulate mitochondrial inheritance and, therefore, to prevent transmission of important disorders caused by mtDNA mutations (AU)