Litcius/Paper detail

Increased mtDNA mutation frequency in oocytes causes epigenetic alterations and embryonic defects

Longsen Han, Yujia Chen, Ling Li, Chao Ren, Haichao Wang, Xinghan Wu, Juan Ge, Wenjie Shu, Minjian Chen, Qiang Wang

2022National Science Review21 citationsDOIOpen Access PDF

Abstract

Abstract Mitochondria are essential for female reproductive processes, yet the function of mitochondrial DNA (mtDNA) mutation in oocytes remains elusive. By employing an mtDNA mutator (Polgm) mouse model, we found the fetal growth retardation and placental dysfunction in post-implantation embryos derived from Polgm oocytes. Remarkably, Polgm oocytes displayed the global loss of DNA methylation; following fertilization, zygotic genome experienced insufficient demethylation, along with dysregulation of gene expression. Spindle–chromosome exchange experiment revealed that cytoplasmic factors in Polgm oocytes are responsible for such a deficient epigenetic remodeling. Moreover, metabolomic profiling identified a significant reduction in the α-ketoglutarate (αKG) level in oocytes from Polgm mice. Importantly, αKG supplement restored both DNA methylation state and transcriptional activity in Polgm embryos, consequently preventing the developmental defects. Our findings uncover the important role of oocyte mtDNA mutation in controlling epigenetic reprogramming and gene expression during embryogenesis. αKG deserves further evaluation as a potential drug for treating mitochondrial dysfunction-related fertility decline.

Topics & Concepts

BiologyEpigeneticsMitochondrial DNAReprogrammingDNA methylationGeneticsMaternal to zygotic transitionOocyteDNA demethylationEmbryoMitochondrionMitochondrial biogenesisEmbryogenesisAndrologyGeneZygoteCell biologyGene expressionMedicineEpigenetics and DNA MethylationReproductive Biology and FertilityBirth, Development, and Health