Mitochondrial metabolic imbalance drives diploidization in mouse haploid embryonic stem cells via NADPH overload

A hallmark of mammals is a diploid genome. Despite constraints from dosage compensation and imprinting, haploid embryonic stem cells can be established. However, rapid diploidization is observed in such cultures from mice, rats, and humans, limiting their use and indicating counterselection of a haploid genome. Here, we use metabolic profiling to discover that diploidization is triggered by an imbalance that arises from a smaller cytoplasmic volume and increased mitochondrial density. Reduced respiration causes a change in redox potential, leading to increased NADPH. Conversely, we demonstrate that NADPH oxidation in the mitochondria is sufficient to stabilize the haploid genome. We further show that the redox change leads to reduced AURORA kinase activation on chromosomes, connecting metabolic state to mitotic regulation. Our data, therefore, identify a mitochondrial–nuclear metabolic imbalance as the root cause of diploidization, and connect redox dysregulation to karyotypic instability.