Proteomic Analysis of ABCA1-Null Macrophages Reveals a Role for Stomatin-Like Protein-2 in Raft Composition and Toll-Like Receptor Signaling

Lipid rafts are cholesterol-enriched membrane microdomains, thought to be present in all cells, that concentrate and organize cell-surface signal transduction events in several signaling cascades, including those of the Toll-like receptors (TLRs) (1). The selectivity of rafts for particular proteins, and, consequently, the signal strength of pathways initiating from ligated raft-resident receptors, are thought to derive in large part from the high cholesterol content of raft microdomains (2–4). In vitro, altering raft cholesterol of living cells downward or upward with chemical tools (e.g. cyclodextrins) leads to parallel changes in raft protein abundance (3, 4). The relevance of cholesterol-driven alterations in the raft proteome to disease is suggested by reports that hypercholesterolemia cholesterol-loads macrophage rafts and amplifies their responsiveness to lipopolysaccharide (LPS) (3, 4). Proteomic strategies have recently been applied to raft isolates from a variety of cell types, aiming to better understand the identity of proteins tonically present in rafts, as well as proteins dynamically recruited to rafts upon cell stimulation (2, 5–8). To date, however, most reports have used cell lines of uncertain physiological relevance. In addition, although raft cholesterol levels are regulated in vivo by intracellular cholesterol trafficking (1), no reports to date have sought to define how the raft proteome is physiologically regulated by cholesterol trafficking proteins. ATP binding cassette (ABC) A1, a member of the ABC transporter superfamily, plays a key role in regulating levels of cholesterol in macrophages and other cells via promoting efflux of cellular cholesterol to extracellular acceptors, in particular lipid-free apolipoprotein (apo) A-I (9). The importance of ABCA11 to human health is clearly illustrated by Tangier disease, a rare ABCA1 mutation syndrome typified by severe HDL deficiency, widespread macrophage foam cells, and premature atherosclerosis (10). In addition, the large number of common ABCA1 polymorphisms that have been associated with human cardiovascular disease (10) suggest a broad-spanning impact of ABCA1 on human health. It remains somewhat controversial whether ABCA1-effluxed cholesterol derives from raft or extra-raft membranes (11). Nonetheless, both human Tangier disease cells and ABCA1-null murine macrophages have been shown to have greatly expanded lipid rafts that contain increased cholesterol and increased TLR4 (12, 13). These changes are associated with enhanced responsiveness to LPS that can be reversed by cholesterol depletion (13–15). Collectively, these findings indicate that ABCA1 may regulate the raft proteome and innate immune response through control of raft cholesterol. However, no proteomic analysis of rafts from ABCA1-deficient cells has been reported to date. Herein, we report a proteomic analysis of raft isolates from naive and LPS-stimulated Abca1+/+ and Abca1−/− primary murine macrophages. Unexpectedly, we found that ABCA1 deletion and LPS stimulation induced many similar changes in the raft proteome. Stomatin-like protein 2 (SLP-2), a lesser known member of the stomatin-prohibitin-flotillin-HflK/C (SPFH) family of membrane scaffolding proteins, was unique among SPFH proteins in being robustly up-regulated in rafts of unstimulated Abca1−/− cells compared with Abca1+/+ counterparts. We found that rafts of SLP-2 knockdown cells were abnormal, displaying increased binding of cholera toxin subunit B—a probe for the raft-specific ganglioside GM1—but markedly decreased protein, including flotillins-1 and -2, and CD14. Whereas SLP-2 silencing did not compromise ABCA1-dependent cholesterol efflux, it reduced macrophage responsiveness to LPS and multiple additional TLR ligands. Taken together, we report that ABCA1 regulates the macrophage raft proteome and identify SLP-2 as a novel ABCA1-dependent regulator of raft composition that controls the innate immune response.