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Query: EC:3.1.1.34 (
lipoprotein lipase
)
7,025
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Lipoprotein(a),
Lp(a)
, is found in the extracellular matrix in atherosclerotic plaques, but with a different localization than LDL. A two-compartment system, with a monolayer of endothelial cells forming a barrier, was used to compare the transport, cell binding, and retention of
Lp(a)
and LDL into the subendothelial matrix. Baseline values for transport and retention of
Lp(a)
and LDL were not significantly different. Incubation with
lipoprotein lipase
or sphingomyelinase caused modest and similar increases in transport and retention of the two lipoproteins. In contrast, incubation with phospholipase A2 (PLA2) resulted in a marked (4-fold) increase in retention of
Lp(a)
on the subendothelial matrix, but a lesser (2-fold) increase in LDL retention. Moreover, PLA2 treatment of
Lp(a)
enhanced its binding to individual matrix proteins (fibronectin, laminin, or collagen) by 4-10 times above that of LDL. The enzymatic activity of PLA2 was responsible for its effect on
Lp(a)
binding. The lysine binding sites of
Lp(a)
contributed to the increased binding of PLA2-modified
Lp(a)
to the matrix, and the enhanced lysine binding functions of PLA2-modified
Lp(a)
was demonstrated by two independent approaches. Thus, PLA2 modification leads to enhanced interactions of lipoproteins with the extracellular matrix, and this effect is more pronounced with
Lp(a)
.
...
PMID:Phospholipase A2 modification enhances lipoprotein(a) binding to the subendothelial matrix. 953 Oct 56
Coronary heart disease (CHD) has been considered as a multifactorial disorder with the involvement of both environmental and genetic factors. The advent of tools to investigate individual variability of DNA has allowed us to perform the association studies of candidate genes. However, an association between genetic trait and phenotypic variations is not easy to demonstrate and several reported association between genetic markers and risk factors or overt CHD have gone unconfirmed. It should not be assumed that for a given genetic trait, the impact on risk will be similar in all populations. In particular, most studies of the molecular bases of CHD have involved Caucasian subjects, so much more work with the Korean population is needed before genetic testing for susceptibility to CHD can be offered to Koreans as a clinical service. In this review, we discuss two aspects of the molecular bases of CHD: i) Molecular bases of the candidate gene related to lipoprotein metabolism including apolipoprotein AI-CIII-AIV gene duster, apolipoprotein B, apolipoprotein E-CI-CII gene cluster,
apolipoprotein(a)
, LDL receptors,
lipoprotein lipase
, cholesteryl ester transfer protein, and apo B editing protein; ii) Molecular bases of the candidate gene related to thrombotic and other factors including fibrinogen, factor VII, plasminogen activator inhibitor 1, homocysteine, stromelysin, paraoxonase, and angiotensin converting enzyme. Studies involving the Korean population, especially those performed by our teams, are also summarized.
...
PMID:Molecular bases of coronary heart disease in Koreans. 953 12
The pathogenicity of lipoprotein(a) [
Lp(a)
] as a risk factor for cardiovascular disease may depend upon its lysine binding sites (LBS) which impart unique functions to
Lp(a)
not shared with low density lipoprotein. Biologically relevant modifications of
Lp(a)
were tested for alterations of LBS activity using two previously described functional assays, a LBS-
Lp(a)
immunoassay and a lysine-Sepharose bead assay. In the LBS-
Lp(a)
immunoassay, minimal changes in the LBS activity of
Lp(a)
were observed after modification with
lipoprotein lipase
, sphingomyelinase, or phospholipase C. In contrast, a significant (p<0.003) increase in the LBS activity of
Lp(a)
occurred after phospholipase A2 (PLA2) treatment, and this increase was confirmed using the lysine-Sepharose bead assay. The increase depended upon the release of fatty acids from
Lp(a)
by PLA2. A decrease in the LBS activity of
Lp(a)
occurred after oxidation of
Lp(a)
with 2,2'-azobis(2-amidinopropane) dihydrochloride (AAPH) (44% decrease), but CuSO4 oxidation increased LBS activity (210%). N-acetylcysteine (NAC) treatment of
Lp(a)
decreased (48%) LBS activity while homocysteine treatment had no (89%) effect. Thus, modification of phospholipids and protein moieties can alter the LBS-activity of
Lp(a)
. Such enzymatic and chemical modifications may contribute to the variability in LBS function of
Lp(a)
seen within the population.
...
PMID:Enzymatic and chemical modifications of lipoprotein(a) selectively alter its lysine-binding functions. 959 30
Acetylcholine (Ach)-induced vascular relaxation is mediated by nitric oxide released from the endothelium. Hence, impaired Ach-induced relaxation reflects endothelial dysfunction. The action of
lipoprotein lipase
on chylomicrons and very low density lipoproteins produces remnant lipoproteins (RLP) rich in triglycerides (TG), cholesterol (C) and apolipoprotein E (apo E). Apo E on RLP serves as a ligand for uptake of RLP by macrophages, endothelial cells and other cells expressing the LDL receptor or the remnant receptor; uptake of RLP by vascular wall cells can promote atherosclerosis. Serum C, TG,
Lp(a)
, apo E, apo A-I, apo B, HDL-C and RLP-C were measured in 652 patients who underwent diagnostic coronary angiography. Of these, 48 (32 males and 16 females, age 59 +/- 10 years) were suspected of having ischaemic heart disease because they had chest pain, but without angiographic evidence of atherosclerotic coronary artery disease defined as a discrete stenosis or intimal irregularity, and without any other known underlying heart disease. These were selected for acetylcholine provocation test in the left coronary artery. Nineteen of 48 patients had high RLP-C ( > or = 5 mg/dl, mean 8.7 +/- 3.1 mg/dl), 29 had normal RLP-C ( < or = 5 mg/dl, mean 2.4 +/- 0.4 mg/dl, P < 0.0001). The percent change (-, constriction, or +, dilation) in coronary artery diameter after intracoronary injection of Ach was smaller in the high RLP-C group, compared with the normal RLP-C group thus, in the left anterior descending artery, -33 +/- 23 vs -8 +/- 25 in the proximal segment (P <0.01), -30 +/- 37 vs -3 +/- 29 in the mid segment (P < 0.01), -17 +/- 47 vs 16 +/- 43 in the distal segment (P < 0.001); in the left circumflex artery, -29 +/- 46 vs -9 +/- 28 in the proximal segment (P < 0.01), -29 +/- 43 vs -5 +/- 34 in the mid segment (P < 0.01), -26 +/- 43 vs 10 +/- 31 in the distal segment (P < 0.001). There were no significant differences in other lipid levels. These results suggest that there is an association between high serum RLP-C and coronary vascular endothelial cell dysfunction and that RLP-C may be taken as a marker of early stage coronary artery atherosclerosis not detectable by angiography.
...
PMID:Impaired endothelium-dependent acetylcholine-induced coronary artery relaxation in patients with high serum remnant lipoprotein particles. 971 43
The trapping of apolipoprotein (apo)B containing lipoproteins within the arterial subendothelial matrix (ECM) is an early event in atherosclerosis. When
lipoprotein lipase
, a constituent of the ECM, is prebound to ECM both LDL and oxidized LDL binding is greatly enhanced. In this study we compared the binding of lipoprotein(a) (
Lp(a)
), a lipoprotein correlated with atherosclerosis and restenosis, to ECM in the presence of varying concentrations of LPL. Without LPL,
Lp(a)
binding was low and non-saturable. In the presence of LPL,
Lp(a)
retention increased from 2.7 x 10(-7) to 1.13 x 10(-4) nmoles. Scatchard analysis demonstrated that the affinities of both
Lp(a)
and LDL to lipase were similar. In competition experiments, LDL, apoE, polymers of lysine and arginine were all capable of preventing the lipase specific [125I]
Lp(a)
retention. However, neither collagen nor fibronectin were capable of blocking or displacing [125I]
Lp(a)
from the lipase bound to ECM. In a separate set of experiments, when ECM was not saturated with lipase, both fibronectin and collagen (at 10-fold protein excess) prevented approximately 40% of total [125I]
Lp(a)
retention to ECM. These data suggest, in the absence of lipase, apo(a) may regulate the binding of
Lp(a)
to ECM. Whereas, lipase enhanced the binding of
Lp(a)
to ECM, most probably through the apoB moiety of the
Lp(a)
particle.
...
PMID:Lipoprotein lipase greatly enhances the retention of lipoprotein(a) to endothelial cell-matrix. 992 May 9
Among the risk factors for coronary atherosclerosis, elevated LDL-C level is best known. The action of
lipoprotein lipase
on triglyceride-rich lipoproteins produces remnant lipoprotein particles enriched in cholesterol and apolipoprotein E (apo E). Apo E serves as the ligand for uptake of remnant lipoproteins via the LDL-receptor or the remnant receptor. In this study, postmortem plasma total cholesterol, triglycerides (TG), VLDL-C, HDL-C, lipoprotein (a) [
Lp(a)
] and remnant-like lipoprotein particles (RLP)-cholesterol, RLP-TG, apolipoproteins B, C III and E were measured, together with LDL-C to assess their potential contribution to the severity of coronary and aortic atherosclerosis of the 197 cases of sudden death (132 cardiac death and 65 non-cardiac death). In all cases, the severity of coronary atherosclerosis was determined at postmortem pathological examination. RLP-cholesterol (RLP-C) and LDL-C concentrations were significantly higher in cases with advanced coronary atherosclerosis compared with those without coronary atherosclerosis; respective median values were 13.5 vs 8.4 mg/dl (P < 0.001) and 140 vs 115 mg/dl (P < 0.05). RLP-C levels were more strongly correlated with the severity score of coronary atherosclerosis than LDL-C.
...
PMID:Association of plasma triglyceride-rich lipoprotein remnants with coronary atherosclerosis in cases of sudden cardiac death. 1003 Mar 82
Hyperlipidemia in the nephrotic syndrome results from increased synthesis and decreased catabolism of lipoproteins. The contribution of each to establishing blood lipid levels is unknown. Increased triglyceride rich lipoprotein concentration, very low density lipoprotein (VLDL) and intermediate density lipoprotein (IDL) primarily results from decreased clearance. This defect is due in part to reduced
lipoprotein lipase
(
LPL
) on the vascular endothelium resulting either from decreased synthesis or inadequate binding of this enzyme to endothelial surfaces. In contrast, both low density lipoprotein (LDL) and lipoprotein(a) [
Lp(a)
] concentrations are increased. Unlike the case of albumin or transferrin, or apoA-I in the rat, LDL apoB 100 synthesis is not related to that of albumin, suggesting a different mechanism of regulation or a response to a stimulus that is not the same as that augmenting the synthesis of nonlipoproteins. Evidence is presented for synthesis of LDL through a mechanism that bypasses the normal delipidation pathway that requires a VLDL precursor for LDL formation. HDL concentration is normal but maturation is impaired leading to a shift from the larger HDL2 to the smaller HDL3, a variant that is less effective as a transporter of the
LPL
cofactor apolipoprotein C II.
...
PMID:New insights into lipid metabolism in the nephrotic syndrome. 1041 29
A preponderance of dense low density lipoprotein (LDL) particles is associated with an increased risk of coronary heart disease. It has been shown that dense LDL levels can be modified by diet. We investigated the contribution of polymorphisms in the genes for apolipoprotein (apo) B, apo AIV,
lipoprotein lipase
(
LPL
) and cholesterol ester transfer protein (CETP) to variation in the changes in plasma concentrations of dense LDL between a high saturated and a high polyunsaturated fatty acid diet. A total of 46 freeliving individuals (19 men and 27 women) completed a crossover trial with two dietary interventions of 4 weeks each, a high saturated fat diet (providing 21% energy from saturated fat and 3% energy from polyunsaturated fat) and a high polyunsaturated fat diet (providing 11% energy as saturated fat and 10% energy as polyunsaturated fat). Overall, the change in dense LDL between the saturated and polyunsaturated fat period was 0.17+/-0.33 mmol/L and this change was similar in men and women. Of the polymorphisms studied only variation in the apo AIV gene causing the substitution of histidine for glutamine at position 360 (Q360H) was associated with significant differences in the change in dense LDL concentration. Apo AIV Q/H individuals (n=6) showed a three-fold greater change in dense LDL cholesterol unadjusted for
Lp(a)
levels than Q/Q individuals (0.46+/-0.27 versus 0.12+/-0.31 mmol/L, p=0.02). The greater decrease in dense LDL cholesterol with an increase in polyunsaturated fat seen in those with the apo AIV H360 variant, who represent roughly 10% of the general population, suggests that they may benefit most from a PUFA rich lipid lowering diet.
...
PMID:Genetic factors associated with response of LDL subfractions to change in the nature of dietary fat. 1072 89
beta(2)-glycoprotein I (beta(2)-GPI=apolipoprotein H) is an important autoantigen in patients with the antiphospholipid syndrome. It also plays a role in lipoprotein metabolism, such as anti-atherogenic property, triglyceride removal, and enhancement of
lipoprotein lipase
. Serum beta(2)-GPI concentration of 812 apparently healthy Japanese individuals was measured by sandwich EIA. Two families with complete beta(2)-GPI deficiency were identified. In one family, all affected had increased serum LDL-cholesterol levels or smaller particle sizes of LDL, while the other had no apparent abnormality in lipid metabolism. Individuals investigated had no history of thrombosis or overt abnormalities in hemostatic tests. A thymine corresponding to position 379 of the beta(2)-GPI cDNA was deleted in every beta(2)-GPI deficient individual. The incidence of this heterozygous deficiency determined by RFLP was 6. 3% in Japanese and none in Caucasians. Heterozygotes had significantly lower concentrations of serum beta(2)-GPI than did those without the mutation, yet no significantly different lipid profiles, such as total cholesterol, triglyceride, HDL-cholesterol, LDL-cholesterol, apoA-I, apoB and
Lp(a)
, were observed. A low concentration of beta(2)-GPI seemed not to be associated with apparent abnormality in lipoprotein metabolism.
...
PMID:beta(2)-glycoprotein I deficiency: prevalence, genetic background and effects on plasma lipoprotein metabolism and hemostasis. 1099 61
Although molecular cardiology is a relative young discipline, the impact of the new techniques on diagnosis and therapy in cardiovascular disease are extensive. Our insight into pathophysiological mechanisms is rapidly expanding and is changing our understanding of cardiovascular disease radically and irrevocably. Molecular cardiology has many different aspects. In this paper the importance of molecular cardiology and genetics for every day clinical practice are briefly outlined. It is expected that in the genetic predisposition for atherosclerotic disease multiple genes are involved (genetics). The role of only a minority of genes involved in the atherosclerotic process is known. Far less is known about particular gene-gene and gene-environment interactions. In some families disease can be explained mostly by a single, major gene (monogenic), of which the lipid disorder Familial Hypercholesterolemia is an example. In other cases, one or several variations in minor genes (multigenic) contribute to an atherosclerotic predisposition, for instance the
lipoprotein lipase
gene. Although mutations in this gene influence lipoprotein levels, disease development is predominantly depending on environmental influences. Recently several additional genetic risk factors were identified including elevated levels of lipoprotein (a) [
Lp(a)
], the DD genotype of angiotensin converting enzyme (ACE), and elevated levels of homocysteine. This illustrates the complexity of genetics in relation to atherosclerosis and the difficulty to assign predictive values to separate genetic risk factors. Furthermore, little attention has been given to protective genes thus far, explaining why some high risk patients are protected from vascular disease. Genetics based treatment or elimination of the genetic risk factor requires complete understanding of the pathogenic molecular basis. Once this requirement is fulfilled, disease management can be strived for, provided that adequate medical management is available. Recent studies suggest that such treatment should be genotype specific, as the genetic makeup can determine the outcome of a pharmacological intervention (pharmacogenetics). Once the trigger for atherosclerosis has initiated disease development, various genes are activated or silenced and contribute to lesion progression. Every stage of lesion development depends on a different gene expression programme (genomics). In this review paper an introduction is provided into genetics, pharmacogenetics and gene expression with respect to atherosclerotic disease.
...
PMID:Molecular genetics and gene expression in atherosclerosis. 1157 98
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