Abstract
Mammalian mitochondrial DNA (mtDNA) inheritance differs fundamentally from nuclear inheritance owing to exclusive maternal transmission, high mutation rate, and lack of recombination. Two key mechanisms shape this inheritance: the bottleneck, which drives stochastic transmission of maternal mtDNA variants, and purifying selection, which actively removes mutant mtDNA. Whether these mechanisms interact has been unresolved. To address this question, we generated a series of mouse models with random mtDNA mutations alongside alleles altering mtDNA copy number or decreasing autophagy. We demonstrate that tightening the mtDNA bottleneck increases heteroplasmic variance between individuals, causing lower mutational burden and nonsynonymous-to-synonymous ratios. In contrast, reduced autophagy weakens purifying selection, leading to decreased interoffspring heteroplasmic variance and increased mutational burden with higher nonsynonymous-to-synonymous ratios. These findings provide experimental evidence that the mtDNA bottleneck size modulates the efficacy of purifying selection. Our findings yield fundamental insights into the processes governing mammalian mtDNA transmission with direct implications for the origin and propagation of mtDNA mutations causing human disease.