A lipid in transit - the journey of cholesterol into the heart of mitochondrial research.

Mitochondrial cholesterol biology in non-steroidogenic tissues remains understudied in cell science. Although detecting cholesterol in mitochondria is challenging due to isolation difficulties, studies using mitoplasts (mitochondria stripped of their outer membrane) and imaging approaches confirm its presence in the inner mitochondrial membrane. Through analysis of published evidence and first-principles reasoning, we advance a model of cholesterol trafficking into and out of mitochondria via phospholipids at mitochondria-associated membranes (MAMs), challenging the traditional view of protein-driven transport. In this model, cholesterol enters mitochondria alongside phosphatidylserine and exits with phosphatidylethanolamine - either unchanged or in a hydroxylated form after modification by the enzyme CYP27A1. Strong cholesterol-phospholipid binding energies, ∼17 kcal/mol (71.128 kJ/mol), support this lipid-mediated mechanism, suggesting it complements protein-based pathways. Future research should explore how these mechanisms collaborate to regulate mitochondrial cholesterol trafficking. By rethinking cholesterol dynamics, we raise the possibility that cholesterol plays a larger role in mitochondrial biology, influencing membrane-dependent functions like cristae structure, respiratory efficiency and inter-organelle communication. This Perspective also highlights the potential of mitochondria to regulate both dietary and endogenous cholesterol flux and homeostasis across the cell.