Enhanced macrophage degradation of biologically modified low density lipoprotein.

Abstract: Low density lipoprotein (LDL) conditioned by incubation in the presence of rabbit aortic or human umbilical vein endothelial cells (endothelial cell-modified LDL) was degraded by macrophages three to five times more rapidly than LDL incubated in the absence of cells (control LDL). This enhanced degradation occurred mostly via a high affinity, saturable pathway related to the pathway for macrophage uptake of acetylated LDL. Conditioning LDL with cultured aortic smooth muscle cells had a qualitatively similar bu… Show more

“…Our results show that incubation of LDL in serum-free medium with human umbilical vein EC or bovine aortic SMC, but not human fibroblasts or bovine aortic EC, resulted in a modified LDL with increased electrophoretic mobility. These findings are in general agreement with the results of Henriksen et al 8 " 10 Like these authors, 10 we observed that the electrophoretic mobility change was accompanied by a variable decrease in the LDL sterol. A decreased total cholesterol/protein ratio of up to 20% was observed after 48 hours of incubation of LDL with human umbilical vein EC or bovine SMC.…”

“…The purpose of the spin was to reisolate LDL. A solvent density of 1.100 was used to collect LDL that might have increased in density as indicated by Henriksen, et al 9 ' 10 The reisolated LDL was then assayed for cholesterol, protein, TBARS, electrophoretic mobility, and cytotoxicity.…”

“…5 Although oxygen-free radicals such as these have been implicated as effectors of tissue damage, 6 ' 7 the toxic action of oxidized LDL is effected by an oxidized lipid producad by free radicals rather than by free radicals generated during propagation of the oxidation reaction. 5 Henriksen, et al 8 " 10 have reported that cultured human umbilical vein endothelial cells (EC) and vascular smooth muscle cells (SMC), but not human fibroblasts or bovine aortic EC, can modify LDL. The changes in LDL produced by incubation with human umbilical vein EC and SMC include increased anodic electrophoretic mobility, a reduced ratio of total cholesterol to protein, and increased degradation by macrophages.…”

“…The changes in LDL produced by incubation with human umbilical vein EC and SMC include increased anodic electrophoretic mobility, a reduced ratio of total cholesterol to protein, and increased degradation by macrophages. 8 " 10 Bowman et al 11 have reported that pulmonary artery EC, but not lung fibroblasts, produce superoxide anion in vitro. Since superoxide anion appeared to be involved in spontaneous oxidation of LDL during its isolation, 5 we chose to determine whether cultured EC and SMC could oxidize LDL and render it cytotoxic and to identify the relationship between oxidation and certain other EC modifications of LDL, including the changes in electrophoretic mobility and the decreased steroi content reported by Henriksen et al prepared from citrated bovine whole-blood serum.…”

Endothelial and smooth muscle cells alter low density lipoprotein in vitro by free radical oxidation.

“…Our results show that incubation of LDL in serum-free medium with human umbilical vein EC or bovine aortic SMC, but not human fibroblasts or bovine aortic EC, resulted in a modified LDL with increased electrophoretic mobility. These findings are in general agreement with the results of Henriksen et al 8 " 10 Like these authors, 10 we observed that the electrophoretic mobility change was accompanied by a variable decrease in the LDL sterol. A decreased total cholesterol/protein ratio of up to 20% was observed after 48 hours of incubation of LDL with human umbilical vein EC or bovine SMC.…”

“…The purpose of the spin was to reisolate LDL. A solvent density of 1.100 was used to collect LDL that might have increased in density as indicated by Henriksen, et al 9 ' 10 The reisolated LDL was then assayed for cholesterol, protein, TBARS, electrophoretic mobility, and cytotoxicity.…”

“…5 Although oxygen-free radicals such as these have been implicated as effectors of tissue damage, 6 ' 7 the toxic action of oxidized LDL is effected by an oxidized lipid producad by free radicals rather than by free radicals generated during propagation of the oxidation reaction. 5 Henriksen, et al 8 " 10 have reported that cultured human umbilical vein endothelial cells (EC) and vascular smooth muscle cells (SMC), but not human fibroblasts or bovine aortic EC, can modify LDL. The changes in LDL produced by incubation with human umbilical vein EC and SMC include increased anodic electrophoretic mobility, a reduced ratio of total cholesterol to protein, and increased degradation by macrophages.…”

“…The changes in LDL produced by incubation with human umbilical vein EC and SMC include increased anodic electrophoretic mobility, a reduced ratio of total cholesterol to protein, and increased degradation by macrophages. 8 " 10 Bowman et al 11 have reported that pulmonary artery EC, but not lung fibroblasts, produce superoxide anion in vitro. Since superoxide anion appeared to be involved in spontaneous oxidation of LDL during its isolation, 5 we chose to determine whether cultured EC and SMC could oxidize LDL and render it cytotoxic and to identify the relationship between oxidation and certain other EC modifications of LDL, including the changes in electrophoretic mobility and the decreased steroi content reported by Henriksen et al prepared from citrated bovine whole-blood serum.…”

Endothelial and smooth muscle cells alter low density lipoprotein in vitro by free radical oxidation.

“…It has been demonstrated in vitro, however, that LDL can be oxidised by the main cells present in atherosclerotic lesions, namely endothelial cells [3], smooth muscle cells [4], monocyte-macrophages [5 7] and lymphocytes [8]. Most workers find that LDL oxidation by cells requires the presence of transition metal ions, usually iron [7,9], but copper ions will also catalyse the oxidation [9,10].…”

Transition metal ions within human atherosclerotic lesions can catalyse the oxidation of low density lipoprotein by macrophages

Antioxidants and the Prevention of Coronary Heart Disease