Saturated lipid stress attenuates mitochondrial genome synthesis in human cells

Fatty acids are trafficked between organelles to support membrane biogenesis and act as signaling molecules to rewire cellular metabolism in response to starvation, overnutrition, and environmental cues. Mitochondria are key cellular energy converters that harbor their own multi-copy genome critical to metabolic control. In homeostasis, mitochondrial DNA (mtDNA) synthesis is coupled to mitochondrial membrane expansion and division at sites of contact with the endoplasmic reticulum (ER). Here, we provide evidence from cultured hepatocytes that mtDNA synthesis and lipid droplet biogenesis occur at spatially and functionally distinct ER-mitochondria membrane contact sites. We find that, during saturated lipid stress, cells pause mtDNA synthesis and mitochondrial network expansion secondary to rerouted fatty acid trafficking through the ER and lipid droplet biogenesis, coincident with a defect in soluble protein import to the ER lumen. The relative composition of fatty acid pools available to cells is critical, as monounsaturated fatty acid supplementation rescued both ER proteostasis and mtDNA synthesis, even in the presence of excess saturated fat. We propose that shutoff of mtDNA synthesis conserves mtDNA-to-mitochondrial network scaling until cells can regain ER homeostasis.