Macrophages possess a number of mechanisms to regulate the balance between cholesterol? uptake/synthesis and export. Of major importance are transport mechanisms that promote the efflux of? excess cholesterol to extracellular acceptors. The removal of excess cholesterol is critical in the vessel wall,? where macrophage uptake of lipoprotein-derived lipid can lead to a pathological cholesterol load in the? absence of sufficient removal systems. Two members of the ATP binding cassette (ABC) superfamily of? transmembrane transporters, ABCA1 and ABCG1, play critical roles in preventing cholesterol lipid? accumulation in macrophages. Extensive studies have shown that ABCA1 promotes efflux of both? cholesterol and phospholipids to lipid-poor apolipoproteins, in particular, apoA-l. In contrast, ABCG1 appears? to promote efflux by redistributing intracellular cholesterol to plasma membrane domains accessible for? removal by HDL, but not lipid-poor apoA-l. Thus, factors that affect the lipidated state of apoA-l may? modulate the activity of these two transporters. During inflammation, HDL undergoes extensive remodeling? that leads to the generation of particles that are significantly altered in size, charge, and apolipoprotein and? lipid content. These alterations are primarily brought about by the acute phase reactants serum amyloid A? (SAA) and Group IIA secretory phospholipase A2. Accumulating evidence from multiple laboratories,? including ours, has established that SAA, either delivered as acute phase HDL or in a lipid-free form, can? enhance macrophage cholesterol efflux. In Preliminary Data, we provide evidence that in the presence of? cholesterol ester transfer protein, phospholipid depletion of HDL particles by Group IIA sPLA2 can lead to the? generation of small, lipid-depleted HDL particles.
We aim to show that a major consequence of the acute? phase response is an increase in the mobilization of cholesterol from the periphery, and an accelerated rate? of macrophage reverse cholesterol transport. We hypothesize that SAA and sPLA2 promote macrophage? lipid efflux by modifying HDL acceptors and through direct interactions with macrophage cells. To test this? hypothesis, we propose the following Specific Aims: 1) To demonstrate that inflammation-induced? remodeling of HDL generates substrates that enhance ABCA1 and ABCG1-dependent efflux; 2) To? investigate the mechanism(s) by which SAA and sPLA2 promote macrophage cholesterol efflux; and 3) To? test the hypothesis that SAA protects against atherosclerotic lipid accumulation through an ABCA1 and/or? ABCG1 -dependent mechanism.
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