Autoradiographic analysis of the distribution of 125I-tyramine-cellobiose-LDL in atherosclerotic lesions of the WHHL rabbit

Association of apo B lipoproteins with arterial proteoglycans: pathological significance and molecular basis

Retention of apo B-100 lipoproteins, low density lipoprotein (LDL) and probably lipoprotein(a), Lp(a), by intima proteoglycans (PGs) appears to increase the residence time needed for their structural, hydrolytic and oxidative modifications. If the rate of LDL entry exceeds the tissue capacity to eliminate the modified products, this process may be a contributor to atherogenesis and lesion advancement. LDL binds to PGs of the intima, by association of specific positive segments of the apo B-100 with the negatively-charged glycosaminoglycans (GAGs) made of chondroitin sulfate (CS), dermatan sulfate (DS) and probably heparan sulfate (HS). Small, dense LDL has a higher affinity for CS-PGs than large buoyant particles, probably because they expose more of the segments binding the GAGs than larger LDL. PGs cause irreversible structural alterations of LDL that potentiate hydrolytic and oxidative modifications. These alterations also increase LDL uptake by macrophages and smooth muscle cells. These in vitro data suggest that part of the atherogenicity of LDL may depend on its tendency to form complexes with arterial PGs in vivo. Ex vivo results support this hypothesis. Subjects with coronary heart disease have LDL with significantly higher affinity for arterial PGs. This is also a characteristic of subjects with the atherogenic lipoprotein phenotype, with high levels of small, dense LDL. The LDL-PG affinity, however can be modified by dietary or pharmacological interventions that change the composition and size of LDL. Lesion-prone intima contain PGs with a high affinity for LDL. Increased LDL entrapment at these sites may be a key step in a cyclic atherogenic process.

Proteoglycans in macrophages: characterization and possible role in the cellular uptake of lipoproteins

The murine macrophage cell line J774 was incubated with [35S]sulphate. The cell-associated 35S-labelled macromolecules were shown to be proteoglycans and glycosaminoglycans in similar amounts. The possible presence of cell-surface proteoglycans was investigated by incubating [35S]sulphate-labelled cells with trypsin for 15 min. The released material contained approx. 70% free glycosaminoglycan chains and 30% proteoglycans. The latter component was demonstrated by HNO2 treatment to contain heparan sulphate. In the total cell fraction not treated with trypsin a small but significant portion was shown to be chondroitin sulphate proteoglycan. The cell-associated glycosaminoglycans contained both chondroitin sulphate and heparan sulphate. To investigate possible biological functions of cell-surface proteoglycans in macrophages, cells were incubated with NaClO3 to inhibit sulphation of proteoglycans and beta-d-xyloside to abrogate proteoglycan expression. The uptake of oxidized 125I-tyraminylcellobiose-labelled low-density lipoprotein (125I-TC-LDL) was typically two to three times higher than that of native 125I-TC-LDL in untreated J774 cells. The cellular uptake at 37 degreesC of native 125I-TC-LDL was decreased 25% after both NaClO3 and xyloside treatment, whereas the uptake of oxidized 125I-TC-LDL was decreased 35% after both types of treatment. The mRNA levels for the scavenger receptor A-II and the LDL receptor were not affected by NaClO3 or xyloside treatment. Furthermore, fluid-phase endocytosis, measured as uptake of horseradish peroxidase, and receptor-mediated endocytosis, measured as uptake of 125I-TC-ovalbumin, were not affected by NaClO3 treatment of J774 cells. Removal of cell-surface chondroitin sulphate with chondroitinase ABC decreased only the binding of native 125I-TC-LDL, whereas removal of heparan sulphate with heparitinase decreased the binding of both oxidized and native 125I-TC-LDL. Addition of lipoprotein lipase increased the uptake of oxidized 125I-TC-LDL 1.7 times and the uptake of native 125I-TC-LDL 2.1 times. The binding of the former was more sensitive to NaClO3 treatment than the latter. The results presented support the notion that some of the uptake pathways for lipoproteins in the foam-cell-forming macrophages depend on the presence of cell-surface heparan sulphate and chondroitin sulphate.

Localization of lipoprotein in pre- and post-transition atherosclerotic lesions following short-term incubation with [125I]LDL

Ultrastructural autoradiography has been used to test the hypothesis that atherosclerotic regions of vessels differ with respect to lipoprotein uptake and localization. White Carneau pigeons, in which the prevalence and localization of aortic lesions are highly predictable, were fed a 0.25% cholesterol-supplemented diet to accelerate atherosclerosis. One hour prior to necropsy the birds were given a single intravenous injection of homologous [125I]LDL (low-density lipoprotein). Plasma die-away and tissue distribution of label were determined, and after the birds had been killed, the aortas, spleen and liver were processed for electron microscope autoradiography. Initial [125I]LDL uptake was rapid, with 35% of the label removed within 30 min. Predominant accumulation was in the liver, followed by the lung, kidney, the spleen and the aorta, in which the [125I]LDL level was approximately 4% that of the liver. Autoradiographic analysis documented hepatocyte (33%) and Kupffer cell (19.9%) localization in the liver and reticuloendothelial cell (57.4%) localization in the spleen. The aortic analysis involved serially sectioned lesions for direct comparison of non-lesion, lesion/non-lesion interface (edge) and deep lesion regions. Analysis of 2275 silver grains documented a ten-fold increase in LDL accumulation at the lesion edge (as compared to adjacent non-lesion) where macrophage foam cells contained more than 70% of the label. The other 30% was distributed equally among endothelium, the intimal matrix and smooth muscle cells. This distribution changed with more complex (deeper) lesions, although grain density in the complex lesions was comparable to the edge. In the complex regions, macrophage foam cell grains were reduced to 37%, whereas smooth muscle cell (22%) and the extracellular matrix (24%) label were both increased. These studies substantiate enhanced accumulation of lipoprotein specifically at lesion sites in the aorta and demonstrate a shift from macrophage localization at the developing edge to smooth muscle cell and the extracellular matrix in more complex deeper lesions.

A comparison of the antiatherogenic effects of probucol and of a structural analogue of probucol in low density lipoprotein receptor-deficient rabbits

The efficacies of probucol and a close structural analogue as antioxidants in the prevention of atherogenesis in LDL receptor-deficient rabbits were compared. The antioxidant potency of the analogue in vitro was equal to that of probucol. Its biological availability was much greater: almost comparable concentrations in total plasma were achieved by feeding 1% probucol (wt/wt) and 0.05% analogue (wt/wt). Total plasma concentrations were comparable, but the concentration of probucol within the LDL fraction was about twice that of the analogue. Probucol slowed lesion progression by almost 50%, confirming earlier reports; the analogue, however, showed no detectable inhibitory effect on atherogenesis. Resistance of LDL to oxidation was measured at the end of the study by incubating it with Cu2+ and measuring the rate of diene conjugation. Probucol prolonged diene conjugation lag time from the control value of 130 min to values > 1,000 min. The analogue approximately tripled the lag time (mean, 410 min) and yet failed to slow the atherogenic process. The results suggest that LDL resistance to oxidation must reach some threshold level before there is significant protection against atherogenesis. However, probucol has additional biological effects, possibly not shared by the analogue, that could contribute to its antiatherogenic potential.

Low density lipoproteins bind more to type I and III collagens by negative charge-dependent mechanisms than to type IV and V collagens

The accumulation of low density lipoprotein (LDL) in the arterial intima is an important characteristic of atherosclerosis. We investigated the mechanisms by which LDL binds to different types of collagen. The binding activities of 125I-labeled human native LDL (nLDL) and copper-oxidized LDL (oxLDL) with different collagen gels prepared in type I collagen-based mixtures with types I, III, IV and V (I+I, I+III, I+IV and I+V, respectively) were examined. A concentration of 20 micrograms LDL protein/150 micrograms collagen/well was used. The diffusion of both nLDL and oxLDL into the collagen gels reached an equilibrium after 48 h. All of the collagen gels showed the same rates of diffusion with both LDLs. The binding activities of oxLDL were significantly greater than those of nLDL (P < 0.001%), while the binding activities for both LDLs followed the order I+I and I+III > I+V > I+IV. However, the increased binding rate of oxLDL compared to nLDL was 1.66 for I+IV, 1.50 for I+V, 1.33 for I+I and 1.19 for I+III. When a 10-fold higher dose of NaCl (1 M) was added to the oxLDL medium, the binding rate of oxLDL was reduced (rate of reduction: 52% (I+I), 48% (I+III), 35% (I+IV), 13% (I+V)). These results suggest that oxLDL binds more to type I and III collagens by negative charge-dependent mechanisms than to type IV and V collagens. Therefore, types I and III collagens may play an important role in trapping LDL, especially oxLDL. Therefore, oxidatively modified LDL may contribute to atherogenesis due to its longer retention in the arterial wall.

Lipoprotein (a) displays increased accumulation compared with low-density lipoprotein in the murine arterial wall

Lipoprotein (a) (Lp(a)) is known to be an independent risk factor for cardiovascular disease, but the mechanisms by which it contributes to this disease remain unclear. Current evidence indicates that the closely related plasma particle, low-density lipoprotein (LDL), may initiate atherosclerosis through deposition in the arterial wall. This study has compared the ability of both lipoproteins to enter and accumulate within the arterial wall. Experiments were conducted in vivo with animals from two strains of mice: C57BL/6 mice, which develop fatty streak lesions upon challenge by a high-fat diet, and C3H/HeJ mice, which are resistant to lesion formation. Animals from both strains were maintained up to 16 weeks either on chow or high-fat diet. The mice were intravenously injected with 125I-labeled human Lp(a) or 125I-labeled human LDL in equimolar amounts and the lipoprotein allowed to circulate in vivo for 2 or 24 h. Transverse sections of the aortic root including sites of predilection for lesion formation at the commissures of the valve were prepared and examined after autoradiography. The autoradiographic grains over lesions and histologically uninvolved areas were enumerated and compared after normalization. Both Lp(a) and LDL demonstrated nearly ten times greater accumulation in lesions compared with histologically uninvolved areas from C57BL/6 mice. Analyses of histologically uninvolved areas from both strains of mice showed a significantly higher accumulation of Lp(a) than LDL. Finally, significantly higher accumulations of both Lp(a) and LDL occurred in the histologically uninvolved intima and subintima of lesion-prone C57BL/6 mice as compared with lesion-resistant C3H/HeJ mice after 5 weeks on the diets. We propose that enhanced accumulation of Lp(a) in the arterial wall accounts, in part, for the increased risk of cardiovascular disease.