Macrophage signaling and function are regulated by distinct sterol biochemistries.

Membranes require continuous reorganization of lipid components, including sterols, to dynamically alter their rigidity to deform and bend during scission events which occur during fundamental cellular functions such as endocytosis. While diseases of cholesterol biosynthesis result in reduced cellular cholesterol and accumulation of precursor sterols, limited studies have addressed the intracellular consequences of disease-associated sterol changes on the ability of eukaryotic cellular membranes to function and signal normally. Here, we utilized bone marrow-derived macrophages (BMDMs) to investigate how altered sterol content impacts macrophage signaling and membrane function. Through pharmacological inhibition of cholesterol biosynthetic enzymes, reduced cholesterol and increased levels of disease-associated sterol intermediates coincided with reduced expression of cell surface proteins and impaired macropinocytosis. Macropinocytic activity was sensitive to both reduced plasma membrane cholesterol and sterols containing functional groups substituted for the C3 hydroxyl group. Transcriptomic analyses of cholesterol-inhibited BMDMs revealed alterations in immune and chemokine signaling pathways. Decreased cholesterol was also associated with dysregulated vesicular sorting pathways and elevated expression of endosomal/lysosomal markers. Disrupted endosome expression and impaired macropinocytosis was also observed in BMDMs from mouse models of the cholesterol biosynthesis disorder Smith-Lemli-Opitz syndrome (SLOS). Our findings detail an important connection between sterol imbalance, membrane dynamics, and immune cell function.