Abstract
Low density lipoprotein (LDL) particles can undergo fusion in the arterial intima, where they are bound to proteoglycans. Here we studied the effect of human arterial proteoglycans on proteolytic fusion of LDL in vitro. For this purpose, an assay was devised based on fluorescence resonance energy transfer that allowed continuous monitoring of fusion of proteoglycan-bound LDL particles. We found that addition of human arterial proteoglycans markedly increased the rate of proteolytic fusion of LDL. The glycosaminoglycans isolated from the proteoglycans also increased the rate of fusion, demonstrating that this effect was produced by the negatively charged sulfated polysaccharides in the proteoglycans. Furthermore, heparin, chondroitin 6-sulfate, and dextran sulfate, three commercially available sulfated polysaccharides, also increased the rate of LDL fusion, with heparin and chondroitin 6-sulfate being as effective as and dextran sulfate more effective than human proteoglycans. The ability of the sulfated polysaccharides to increase the rate of proteolytic fusion of LDL depended critically on their ability to form insoluble complexes with LDL, which, in turn, resulted in an increased rate of LDL proteolysis and, in consequence, in an increased rate of LDL fusion. The results reveal a novel mechanism regulating LDL fusion and point to the potentially important role of arterial proteoglycans in the generation of LDL-derived lipid droplets in the arterial intima during atherogenesis.
Highlights
Human atherosclerosis is characterized by an initial accumulation of lipid in the extracellular matrix of the arterial intima in the form of lipid droplets and vesicles [1, 2]
Size-exclusion chromatography of low density lipoprotein (LDL) particles proteolyzed for 48 h (Fig. 2) showed that the large particles that eluted in the void volume of the column displayed a high resonance energy transfer (RET), which gradually decreased toward the fractions containing native-sized LDL, which displayed a RET similar to that of native LDL particles (Fig. 1)
Why is the rate of proteolytic fusion of LDL increased in the presence of PGs or GAGs? Their addition to a system containing both LDL and ␣-chymotrypsin was found to lead to two parallel phenomena: (i) formation of insoluble complexes between LDL and PGs or GAGs and (ii) an increased rate of LDL proteolysis
Summary
Human atherosclerosis is characterized by an initial accumulation of lipid in the extracellular matrix of the arterial intima in the form of lipid droplets and vesicles [1, 2]. We incorporated Pyr10CE and BODIPY-CE into the core lipids of different samples of LDL particles and studied the effect of ␣-chymotrypsin on LDL fusion in a mixture of the two LDL preparations by measuring RET.
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