UMLS:C0004153 - FACTA Search

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Query: UMLS:C0004153 (atherosclerosis)
77,401 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Apoprotein(a), (apo[a]), the specific antigen of lipoprotein(a) (Lp[a]), consists of structural domains (a serine protease unit, kringles 4 and 5) with marked homology to those of the corresponding domains in plasminogen. In this study, we have investigated the impact of this unique structural mimicry on the binding and activation of plasminogen by fibrin-bound tissue-type plasminogen activator at the plasma-fibrin interface. We found that the total amount of plasmin generated on the surface of fibrin was decreased in the presence of high concentrations of Lp(a): 197 +/- 65 fmol in plasmas with greater than 60 mg/dl Lp(a) versus 287 +/- 112 fmol in control plasmas. A similar effect was also apparent in the corresponding euglobulin fractions (554 +/- 169 fmol versus 754 +/- 310 fmol), the latter lacking the plasminogen-binding proteins alpha 2-antiplasmin and histidine-rich glycoprotein, but containing Lp(a). The difference between plasma samples was significant (p less than 0.05) as calculated from the percent decrease in plasmin generated from plasmas with high levels of Lp(a) relative to that generated in the paired controls with low Lp(a) levels. The involvement of Lp(a) was verified in a reconstituted system consisting of normal human plasma supplemented with 100 mg/dl of either purified Lp(a) or low density lipoprotein. Lp(a) produced a decrease of 30% in the generation of plasmin (180 fmol versus 255 fmol in plasma, and 485 fmol versus 705 fmol in the euglobulin fraction). Moreover, using a radiolabeled sheep antibody against human apo(a), we were able to demonstrate the binding of 40 fmol Lp(a) to fibrin during ongoing plasminogen activation. These results indicate that Lp(a) impairs the binding of plasminogen to fibrin and thereby decreases the generation of plasmin by occupying C-terminal lysine residues unveiled on the fibrin surface by plasmin degradation as recently reported (Circulation 1990;82[suppl III]:III-92). In consequence, impairment of fibrinolysis and accumulation of Lp(a) at sites of vascular injury may occur, factors that may be important in the development of atherosclerosis and associated thrombosis.
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PMID:Lipoprotein(a) impairs generation of plasmin by fibrin-bound tissue-type plasminogen activator. In vitro studies in a plasma milieu. 182 91

Thrombotic occlusion is the major cause of myocardial infarction (MI), and fibrin accumulation appears to play a significant role in development of atherosclerotic lesions. Any factor that reduces the lysis of fibrin may thus increase the risk of MI, and it has been suggested that this accounts for the atherogenicity of the lipoprotein variant Lp(a). The characteristic feature of Lp(a) is an apoprotein which is homologous with part of the plasminogen molecule, and experiments in vitro suggest that it interferes with uptake and activation of plasminogen on cell surfaces and fibrin. The presence of Lp(a) also seemed to offer an explanation for the apparent absence of plasminogen from 70-80% of intimal samples. We have compared the levels of Lp(a) and plasminogen in normal intima and atherosclerotic lesions. In aortic intima there was no relation between Lp(a) and plasminogen, which was absent in some samples with no Lp(a), and present in others with high levels. In intravascular thrombi plasminogen was present at a rather constant concentration (16.3 +/- 4.6 micrograms/100 mg wet tissue), whereas Lp(a) varied over a 100 fold range (0-104 micrograms/100 mg). Plasminogen binds to fibrin and is activated on the fibrin clot, so levels in extracts may not fully represent Lp(a)/plasminogen interactions. After extraction the residual tissues and thrombi were treated with 1 M epsilon-aminocaproic acid (epsilon-aca) to elute lysine-bound components. Lp(a) was eluted from all but one intimal sample, confirming previous findings on its binding to fibrin in lesions, but there was no relation between the amounts of Lp(a) and plasminogen in the tissue eluates. Paradoxically, in the thrombi there was a weak positive correlation between Lp(a) and plasminogen in epsilon-aca eluates (r = 0.504, P = 0.05). These results do not support the hypothesis that Lp(a) displaces plasminogen in vivo, but the large amount of Lp(a) eluted by epsilon-aca suggests that its atherogenicity resides in preferential binding to fibrin, leading to increased lipid accumulation in lesions.
Atherosclerosis 1991 Aug
PMID:Does lipoprotein(a) (Lp(a)) complete with plasminogen in human atherosclerotic lesions and thrombi? 183 24

Previous studies have shown that nonenzymatic glycosylation of high-density lipoprotein (HDL) inhibits high-affinity binding to cultured cells and the candidate HDL-receptor protein. Because binding of HDL to its receptor is required for HDL-receptor-mediated cholesterol efflux from cells, we hypothesized that glycosylated HDL3 would have reduced ability to remove cholesterol from cells. HDL3 was glycosylated in vitro to achieve up to 40-50% reductions in free-lysine residues. Glycosylated HDL3 had a slightly greater ability than control HDL3 to sequester cholesterol directly from the plasma membrane, as predicted by changes in lipid composition. This process is independent of HDL-receptor binding and should not be influenced by reduced binding of HDL3. In contrast, efflux of intracellular cholesterol from cells, which is HDL-receptor dependent, was reduced 25-40%. The ability of glycosylated HDL3 to diminish cholesterol esterification was significantly reduced, indicating reduced net cholesterol efflux. Steady-state efflux of LDL-derived cholesterol was also markedly reduced. These findings suggest that nonenzymatically glycosylated HDL is functionally abnormal and might contribute to the accelerated development of atherosclerosis in patients with diabetes mellitus.
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PMID:Nonenzymatic glycosylation of HDL and impaired HDL-receptor-mediated cholesterol efflux. 184 86

Endothelial cells play a critical role in thromboregulation by controlling the assembly of fibrinolytic constituents on the membrane. The assembly system illustrated in FIGURE 6 is characterized by the binding of circulating glu-plasminogen to a membrane receptor (Pathway 1). A membrane-associated protease (possibly plasmin) converts the inactive zymogen into a catalytically more efficient zymogen lys-plasminogen (Pathway 2). T-PA binds to a specific receptor, retains its catalytic activity, and is protected from its natural inhibitor PAI-1. The membrane provides a favorable environment for plasmin generation (Pathway 3) at the vessel surface and contributes to the maintenance of a physiological nonthrombogenic state. The immobilization and surface activation of plasminogen provides an important mechanism for localizing proteolytic activity at the surface of other cells such as macrophages and tumor cells. Lp(a), a plasminogen-like lipoprotein, by competing at the endothelial surface for plasminogen binding down-regulates endothelial cell plasmin generation and may thus promote localized thrombogenesis that over a period of time contributes to progressive atherosclerosis.
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PMID:Endothelial cell fibrinolytic assembly. 190 39

The plasma concentration of lipoprotein (a) (Lp(a] varies widely in humans, and elevated concentrations of this lipoprotein are correlated with progression of atherosclerosis. Structural studies of Lp(a) have revealed that it is a low density lipoprotein (LDL)-like particle containing a unique glycoprotein, apo(a), which shares extensive homology with plasminogen. The apo(a) portion of Lp(a) binds to the carboxy-terminal heparin-binding domain of fibronectin. Incubation of Lp(a) or isolated apo(a) with fibronectin results in proteolytic cleavage of fibronectin which is, as visualized by gel electrophoresis and immunoblotting, distinct from that caused by plasmin or kallikrein. The proteolytic activity of apo(a) is of serine proteinase-type and displays specificity for arginine rather than lysine bonds. The molecular mechanism(s) underlying the association between Lp(a) and atherosclerosis remains an enigma.
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PMID:Interaction of lipoprotein(a) with fibronectin and its potential role in atherogenesis. 214 25

Nonenzymatic glycosylation of plasma proteins may contribute to the excess risk of developing atherosclerosis in patients with diabetes mellitus. Because high-density lipoprotein (HDL) is believed to protect against atherosclerosis and is glycosylated at increased levels in diabetic individuals, the effects of nonenzymatic glycosylation of HDL3 on binding of HDL3 to cultured fibroblasts and to the candidate HDL-receptor protein were examined. HDL3 was glycosylated in vitro with glucose alone or in combination with sodium cyanoborohydride. With this catalyst, up to 40-50% of the lysine residues could be glycosylated, resulting in a progressive drop to nearly 60% in high-affinity binding to cultured fibroblasts at 4 degrees C. Binding to the 110,000-Mr candidate HDL-receptor protein was reduced by almost 75%. At levels of HDL glycosylation equivalent to the 3-5% observed in diabetes, high-affinity binding to fibroblasts at 4 degrees C was diminished by up to 15-20%. Binding kinetic studies paradoxically suggested that glycosylated HDL3 binds with higher affinity to a reduced number of binding sites. The findings in this study suggest that nonenzymatically glycosylated HDL may be functionally abnormal and might contribute to the development of atherosclerosis in patients with diabetes mellitus.
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PMID:Nonenzymatic glycosylation of HDL resulting in inhibition of high-affinity binding to cultured human fibroblasts. 217 Feb 16

Oxidative modification of LDL is accompanied by a number of compositional and structural changes, including increased electrophoretic mobility, increased density, fragmentation of apolipoprotein B, hydrolysis of phosphatidylcholine, derivatization of lysine amino groups, and generation of fluorescent adducts due to covalent binding of lipid oxidation products to apo B. In addition, oxidation of LDL has been shown to result in numerous changes in its biologic properties that could have pathogenetic importance, including accelerated uptake in macrophages, cytotoxicity, and chemotactic activity for monocytes. The present article summarizes very recent developments related to the mechanism of oxidation of LDL by cells, receptor-mediated uptake of oxidized LDL in macrophages, the mechanism of phosphatidylcholine hydrolysis during LDL oxidation, and other biologic actions of oxidized LDL including cytotoxicity, altered eicosanoid metabolism, and effects on the secretion of growth factors and chemotactic factors. In addition, this review will examine the evidence for the presence of oxidized LDL in vivo and the evidence that oxidized LDL plays a pathogenetic role in atherosclerosis.
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PMID:Role of oxidatively modified LDL in atherosclerosis. 222 30

It has been proposed that low density lipoprotein (LDL) must undergo oxidative modification before it can give rise to foam cells, the key component of the fatty streak lesion of atherosclerosis. Oxidation of LDL probably generates a broad spectrum of conjugates between fragments of oxidized fatty acids and apolipoprotein B. We now present three mutually supportive lines of evidence for oxidation of LDL in vivo: (i) Antibodies against oxidized LDL, malondialdehyde-lysine, or 4-hydroxynonenal-lysine recognize materials in the atherosclerotic lesions of LDL receptor-deficient rabbits; (ii) LDL gently extracted from lesions of these rabbits is recognized by an antiserum against malondialdehyde-conjugated LDL; (iii) autoantibodies against malondialdehyde-LDL (titers from 512 to greater than 4096) can be demonstrated in rabbit and human sera.
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PMID:Low density lipoprotein undergoes oxidative modification in vivo. 246 52

The extent of glycation in pieces of human aorta was estimated by determining the content of furosine, which is derived from fructose-lysine through acid hydrolysis. Glycation of human aorta was found to increase with advancing age. A significant positive correlation was found between the degree of atherosclerosis and the furosine level in the aorta in subjects over 60 years of age. Furthermore, the furosine level in the aortae of diabetic patients was significantly higher than that in normal subjects of the same age. These results suggest not only that glycation in the aorta may increase with aging and with the development of arteriosclerosis, but also that diabetes may be related as well to premature aging as to arteriosclerosis.
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PMID:Age- and diabetes-accelerated glycation in the human aorta. 250 75

Endothelial cells play a critical role in thromboregulation by virtue of a surface-connected fibrinolytic system. Cultured endothelial cells synthesize and secrete tissue-type plasminogen activator (t-PA) which can bind to at least two discrete sites on the cell surface. These binding sites preserve the catalytic activity of t-PA and protect it from its physiological inhibitor (PAI-1). N-terminal glutamic acid plasminogen (Glu-PLG), the main circulating fibrinolytic zymogen, also interacts specifically with the endothelial cell surface. Binding is associated with a 12-fold increase in catalytic efficiency of plasmin generation by t-PA which may reflect conversion of Glu-PLG to its plasmin-modified form, N-terminal lysine plasminogen (Lys-PLG). Lipoprotein(a) is an atherogenic lipoprotein particle which contains the plasminogen-like apolipoprotein(a) bound to low density lipoprotein. We report here that lipoprotein(a) interferes with endothelial cell fibrinolysis by inhibiting plasminogen binding and hence plasmin generation. In addition, we demonstrate lipoprotein(a) accumulation in atherosclerotic lesions. These findings may provide a link between impaired cell surface fibrinolysis and progressive atherosclerosis.
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PMID:Lipoprotein(a) modulation of endothelial cell surface fibrinolysis and its potential role in atherosclerosis. 252 66

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