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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)
We sought to investigate effects of
lipoprotein lipase
(LpL) on cellular catabolism of lipoproteins rich in apolipoprotein B-100. LpL increased cellular degradation of lipoprotein(a) (
Lp(a)
) and low density lipoprotein (LDL) by 277% +/- 3.8% and 32.5% +/- 4.1%, respectively, and cell association by 509% +/- 8.7% and 83.9% +/- 4.0%. The enhanced degradation was entirely lysosomal. Enhanced degradation of
Lp(a)
had at least two components, one LDL receptor-dependent and unaffected by heparitinase digestion of the cells, and the other LDL receptor-independent and heparitinase-sensitive. The effect of LpL on LDL degradation was entirely LDL receptor-independent, heparitinase-sensitive, and essentially absent from mutant Chinese hamster ovary cells that lack cell surface heparan sulfate proteoglycans. Enhanced cell association of
Lp(a)
and LDL was largely LDL receptor-independent and heparitinase-sensitive. The ability of LpL to reduce net secretion of apolipoprotein B-100 by HepG2 cells by enhancing cellular reuptake of nascent lipoproteins was also LDL receptor-independent and heparitinase-sensitive. None of these effects on
Lp(a)
, LDL, or nascent lipoproteins required LpL enzymatic activity. We conclude that LpL promotes binding of apolipoprotein B-100-rich lipoproteins to cell surface heparan sulfate proteoglycans. LpL also enhanced the otherwise weak binding of
Lp(a)
to LDL receptors. The heparan sulfate proteoglycan pathway represents a novel catabolic mechanism that may allow substantial cellular and interstitial accumulation of cholesteryl ester-rich lipoproteins, independent of feedback inhibition by cellular sterol content.
...
PMID:Mechanisms by which lipoprotein lipase alters cellular metabolism of lipoprotein(a), low density lipoprotein, and nascent lipoproteins. Roles for low density lipoprotein receptors and heparan sulfate proteoglycans. 132 15
Exercise training alters plasma lipoprotein profiles in a manner compatible with decreased coronary artery disease risk. The aim of this study was to ascertain whether interruption of training (detraining) was associated with potentially undesirable changes in the metabolism of post-prandial lipoproteins and plasma levels of
Lp(a)
. Eight normolipidemic, male runners who ran 30-40 miles/week were studied in the trained state and after 14-22 days of detraining. Two of the subjects were studied in the reverse order to control for any confounding effects of exercise sequence. Detraining resulted in (1) a 12% (P = 0.002) reduction in the subjects' aerobic capacity, (2) a 7.7% (P = 0.007) reduction in fasting concentrations of high density lipoprotein cholesterol (HDL-C), (3) a 21% (P = 0.01) reduction in post-heparin
lipoprotein lipase
activity.
Lp(a)
concentrations did not change significantly (mean increase 15%, P = 0.076). Fasting plasma concentrations of total cholesterol (TC), triglycerides (TG) and low density lipoprotein-cholesterol (LDL-C) did not change in the detrained state. There was little fluctuation over 24 h in plasma concentrations of TC, LDL-C and HDL-C in either the trained or detrained states. TG concentrations fluctuated over the 24 h in accord with food intake, but there were no exercise-related changes. Exercise had a dramatic effect on chylomicron and chylomicron remnant metabolism as measured by retinyl palmitate measurements. The mean areas under the concentration vs. time curves (AUC) for chylomicron-retinyl esters increased by 41% (P = 0.013) and for chylomicron remnant-retinyl ester by 37% (P = 0.058) following detraining.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Short-term interruption of training affects both fasting and post-prandial lipoproteins. 141 92
We have recently reported that the apolipoprotein (apo) B-100-apo(a) complex, the protein moiety of lipoprotein(a) [
Lp(a)
], has a high affinity for triglyceride(TG)-rich particles (TRP) and that this complex can affiliate with endogenous TG-rich lipoproteins. To shed more light on the apo B-100-apo(a) complex associated with plasma TRP during postprandial lipidemia, we fed five male subjects presenting with primary hypoalphalipoproteinemia (HP) and four male controls a single fat meal (60 g/m2) containing saturated fatty acids (SFA) and, 6 weeks later, an isocaloric meal containing omega-3 polyunsaturated fatty acids. The subjects were phenotyped for plasma
Lp(a)
and apo C-III levels, apo(a) and apo E isoforms, and
lipoprotein lipase
and hepatic lipase activities. Vitamin A was included in the meal as a marker of intestinally derived TRP. Following the SFA meal, three of the HP subjects showed a decrease in plasma levels of
Lp(a)
that lasted 10 to 12 hours in the presence of an increased hypertriglyceridemic response. Two HP subjects who had low preprandial
lipoprotein lipase
activity and elevated plasma apo C-III levels showed an increase in plasma
Lp(a)
levels along with the hypertriglyceridemic excursion. However, in all cases, inclusive of the controls, there was an elevation in plasma levels of TRP of Sf greater than 1,000 that contained apo B-100-apo(a) 6 to 8 hours after the meal. This TRP excursion appeared not to be related to the basal levels of plasma
Lp(a)
, high-density lipoprotein (HDL) cholesterol, TGs, or apo(a) and apo E isoforms, and it did not coincide with the retinyl ester peak.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Postprandial lipoprotein(a) response to a single meal containing either saturated or omega-3 polyunsaturated fatty acids in subjects with hypoalphalipoproteinemia. 146 Nov 42
There is little doubt today that apolipoproteins play a key role in lipid metabolism and thus in atherogenesis. There are five major classes of apo Lp known: Apo AI, the main component of HDL not only mediates the action of LCAT, a key enzyme in cholesterol metabolism, but also through specific cell receptors is responsible for the reverse cholesterol transport, which is discussed as the main atherogenic process. Apo B is necessary for the secretion of neutral lipids out of the liver and the intestine. In addition, apo B containing lipoproteins are recognized by specific cell surface receptors leading to the fast removal of cholesterol rich fractions from circulation. Apo C proteins regulate the activity of
lipoprotein lipase
, the key enzyme of triglyceride metabolism. Apo E containing lipoproteins are recognized by the B/E-receptor with a 10 to 100 fold affinity. There exists, however, another specific receptor for Apo E, which is responsible for the fast removal of the atherogenic remnants from circulation. Apo E in addition serves to secrete deposited cholesterol out of macrophages and foam cells.
Apolipoprotein(a)
is a peculiar fraction of apo B containing lipoproteins whose biological function is completely unknown. Cloning of the cDNA revealed striking similarities of apo(a) with the structure of plasminogen. The cross connection of
Lp(a)
with hemostasis and thrombogenesis is currently focus of intensive research. The knowledge of the specific function of apolipoproteins in lipid metabolism arose to a great extent from the characterization of apo-Lp isoforms and their impact of atherogenesis. In addition, intensive research by molecular biology techniques helped to unravel the pathophysiology in a wide array.
...
PMID:[The role of apolipoproteins in lipid metabolism]. 216 81
CAD results from atherosclerosis, a chronic disease process that has its origin in childhood. Children and adolescents can be at higher risk for CAD by virtue of being from families with premature CAD or familial dyslipoproteinemias. The plasma lipid and lipoprotein levels result from a number of complex metabolic processes that are under the control of genetic and environmental (e.g., diet) influences. The normal ranges of plasma lipids and lipoproteins in children are known, and children and adolescents with dyslipoproteinemia are ordinarily defined as those having levels of plasma total, LDL, or triglyceride above the 95th percentile or with a low HDL cholesterol below the 5th percentile. Children of a parent with documented dyslipoproteinemia or with family history of premature CAD may be screened in the fasting state any time after 2 years of age. Following the exclusion of secondary causes of dyslipoproteinemia, the diagnosis of primary dyslipoproteinemia can be made. Lipoprotein patterns are not diagnostic for a given genotype. Efforts to determine further the biochemical defects responsible for a given phenotype have led to the investigation of gene coding for the apolipoproteins, the key enzymes in the lipoproteins pathways (LPL, HDL, and LCAT) and the receptors that process lipoproteins, such as the LDL receptor and the chylomicron remnant receptor. From a practical standpoint, the diagnosis of the kind of dyslipoproteinemia in a child will depend upon the nature and severity of the dyslipoproteinemia, both in the child (or adolescent) and in parents and siblings. Marked increases in plasma total and LDL cholesterol in the child and in at least one of the parents often reflect the presence of familial hypercholesterolemia, an inherited dominant condition due to a defect in the LDL receptor gene. The triglyceride levels are often normal. If the child has a different dyslipoproteinemia pattern from siblings and parents, then the diagnosis of familial combined hyperlipidemia or hyperapobetalipoproteinemia should be considered. Most children with mild or borderline elevations in total and LDL cholesterol will have polygenic hypercholesterolemia. Triglyceride problems in children and adolescents are relatively uncommon, particularly the more severe hypertriglyceridemia such as that found in
lipoprotein lipase
and apoC-II deficiency, dysbetalipoproteinemia, and type V hyperlipoproteinemia. High levels of
Lp(a)
lipoprotein, in isolation or in combination with other dyslipoproteinemia, accelerate risk for CAD. Low levels of HDL cholesterol in the absence of other abnormalities suggest the diagnosis of hypoalphalipoproteinemia.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Diagnosis and management of familial dyslipoproteinemia in children and adolescents. 225 50
Apoprotein, lipoprotein and lipid parameters of 36 normolipidemic subjects (23 males, mean age 22.7 +/- 7.6 years; 13 females, mean age 26.2 +/- 9.8 years) receiving oral isotretinoin (mean daily dose 0.73 +/- 0.26 mg/kg body weight) for nodulocystic acne (n = 18), severe acne papulopustulosa (n = 15), gram-negative folliculitis (n = 2) and papulopustular rosacea (n = 1) were monitored before and during isotretinoin therapy at biweekly intervals over a period of 14.6 +/- 5.6 weeks. Pretreatment values of mean plasma triglycerides increased significantly (p less than 0.001) from 81.8 +/- 31.9 mg/dl to 112.4 +/- 38.7 mg/dl (47.4%) during isotretinoin treatment. With respect to the mean percent increase of plasma triglycerides from pretreatment levels, patients were classified as nonresponders (less than 10% triglyceride increase), responders (greater than 10% less than 50% triglyceride increase) and hyperresponders (greater than 50% triglyceride increase), revealing a distribution of 25.0, 36.1 and 38.9%, respectively. Isotretinoin treatment had no influence on the isoelectric focusing pattern of apoprotein E isoforms and C apoproteins. In particular, apoprotein C-II, the cofactor of
lipoprotein lipase
, was not affected. No correlation between apoprotein E phenotypes (2/3, 3/3, 3/4) and the mean plasma triglyceride increase could be demonstrated. Apoprotein B-48, a marker of chylomicrons and atherogenic chylomicron remnants, could not be detected by SDS-PAGE. On the other hand in 21.0% of patients with preexisting mean
lipoprotein Lp(a)
levels of 18.1 +/- 12.9 mg/dl a moderate increase of atherogenic
Lp(a)
to mean levels of 37.0 +/- 22.0 mg/dl was observed. Pretreatment values of very-low-density lipoprotein (VLDL) apoprotein (apo) B (7.5 +/- 2.0 mg/dl), low-density lipoprotein apo B (67.3 +/- 17.5 mg/dl) and total plasma apo B (76.6 +/- 19.0 mg/dl) increased significantly to levels of 10.3 +/- 2.4 mg/dl (p less than 0.001), 75.7 +/- 15.8 mg/dl (p less than 0.10) and 85.9 +/- 17.7 mg/dl (p less than 0.05), respectively. As
lipoprotein lipase
and hepatic lipase activities have been shown to be unaffected by isotretinoin treatment, our data support the hypothesis that isotretinoin induces hepatic oversecretion of VLDL, a condition resembling type IV hyperlipidemia in diabetics, familial hypertriglyceridemia of familial combined hyperlipidemia.
...
PMID:Characterization of apoprotein metabolism and atherogenic lipoproteins during oral isotretinoin treatment. 296 29
Effects of a combination therapy of fluvastatin, a new inhibitor of HMG-CoA reductase, and niceritrol on lipid metabolism were investigated measuring a wide range of parameters in 42 patients with primary hypercholesterolemia. After a wash-out period patients were randomly allocated to 1 of the 2 groups, the fluvastatin-preceding group (G-1) and the niceritrol-preceding group (G-2). In G-1 fluvastatin monotherapy (30 mg/day) significantly decreased total cholesterol (TC) and LDL-cholesterol (LDL-C). There was no significant change in HDL-cholesterol (HDL-C), triglyceride (TG) and lipoprotein (a) (
Lp(a)
). Further effect in HDL-C and TG was observed after the addition of niceritrol (750 mg/day). On the other hand, in G-2, while niceritrol alone (750 mg/day) produced no significant change in TC, LDL-C, HDL-C, TG and
Lp(a)
, the addition of fluvastatin (30 mg/day) reduced TC and LDL-C levels significantly. Cholesterol ester transfer (CET) activity was significantly reduced by niceritrol monotherapy. After the concomitant use of the 2 drugs CET activity was significantly reduced only in G-2. No significant change in
lipoprotein lipase
and hepatic triglyceride lipase activities were observed in the 2 groups at either point in time. No serious adverse effect was observed in this study. It is concluded that fluvastatin is an effective drug for lowering LDL-cholesterol and causes no adverse alteration in lipid metabolism. Combination with niceritrol at a dose of 750 mg/day dose not appear to augment or attenuate beneficial effects of fluvastatin.
...
PMID:Effects of fluvastatin, a new inhibitor of HMG-CoA reductase, and niceritrol on serum lipids, lipoproteins and cholesterol ester transfer activity in primary hypercholesterolemic patients. 758 1
Epidemiological studies have elucidated that diabetes mellitus (DM) is one of the risk factors of coronary heart disease and that DM often accompanies dyslipidemia. Dyslipidemia in DM can be classified as either quantitative or qualitative. Although dyslipdemia in DM is affected by the type of DM and glycemic conditions, the characteristics of dyslipidemia in DM, especially in NIDDM are the increase in triglycerides accompanied by the decrease in HDL-cholesterol level. Recently, new commercial kits for measurement of atherogenic lipoproteins which increase in DM are clinically available. The usefulness of these kits in DM was reviewed. Polyacrylamide electrophoresis can detect IDL and
Lp(a)
qualitatively. It has also become possible to estimate
Lp(a)
quantitatively by ELISA, TIA and LIA methods. Remnant lipoprotein can be measured in the fraction unbound to anti-apo A1 and anti-apo B100 antibodies by immunoaffinity gel analysis. Apoproteins, apoprotein E phenotype, post-heparin
lipoprotein lipase
, and Lp AI (HDL with apo AI and without apo AII) can be measured by the commercially available kits. Modified LDLs (glycated, oxidative) increase in DM, but their measurements remain complicated at the moment. Analysis of plasma fatty acids by gaschromatography is useful for dietary assessment. The measurement of these new markers seems to be useful to assess the extent of atherogenic risk in DM.
...
PMID:[Plasma fatty acids, lipids, lipoprotein and macroangiopathy]. 778 61
There is a general interest to know whether lipoprotein(a) [
Lp(a)
] is under hormonal control. Hypothyroidism is a well known cause of secondary hyperlipidemia, which mainly affects low density lipoprotein (LDL) cholesterol levels, but the result on the effects of L-T4 replacement therapy on the
Lp(a)
concentration is controversial. We studied 12 severely hypothyroid, hypercholesterolemic patients under basal conditions and during L-T4 treatment. We found a rapid decrease in both LDL cholesterol (5.71 +/- 0.62 vs. 4.37 +/- 0.44 mmol/L basally and after 1 month of thyroid replacement, respectively) and apolipoprotein-B (Apo-B) levels (1.89 +/- 0.02 vs. 1.52 +/- 0.17 g/L, respectively); these changes persisted for up 1 yr of analytical euthyroidism and paralleled the improvement in the thyroid status of the patients. In contrast, the plasma
Lp(a)
concentration did not change at any time (496 +/- 123, 464 +/- 128, and 441 +/- 110 mg/L under basal conditions and after 1 and 14-15 months of thyroid replacement, respectively), and the small fluctuations observed in some patients did not correlate with those in LDL cholesterol or Apo-B, and were not associated with any particular Apo(a) phenotype. In relation to HDL fractions, high density lipoprotein3 (HDL3) remained stable, but HDL2 cholesterol and phospholipid levels decreased during treatment, changes that were the inverse of those in postheparin plasma hepatic lipase activity. Patients in the present study were normotriglyceridemic, except one who was hypertriglyceridemic at diagnosis, but even in this patient, triglyceride levels were unaffected by T4 substitution therapy, as was postheparin plasma
lipoprotein lipase
activity. The changes observed in LDL, HDL2, and hepatic lipase activity delineate the lipoprotein-related response to T4 replacement therapy, whereas potential individual fluctuations in
Lp(a)
levels are probably more dependent on other factors, such as the production rate, which are not affected by thyroid hormones.
...
PMID:Long-term thyroid replacement therapy and levels of lipoprotein(a) and other lipoproteins. 785 21
In a double-blind, randomized crossover study, 29 patients with non-insulin-dependent diabetes mellitus (NIDDM) and hyperlipoproteinemia were treated with gemfibrozil (1,200 mg/d) or simvastatin (10 mg/d) for 4 months. After gemfibrozil treatment, the insulin concentration was increased during the major part of the intravenous glucose tolerance test (IVGTT) and during the hyperinsulinemic euglycemic clamp. Similar but less pronounced elevations were caused by simvastatin. Insulin sensitivity decreased by 27% and 28% during gemfibrozil and simvastatin treatment, respectively. Low-density lipoprotein (LDL) cholesterol was decreased with simvastatin treatment by 24%. The LDL cholesterol level was not changed by gemfibrozil, but very-low-density lipoprotein (VLDL) cholesterol was reduced by 40%. The VLDL triglyceride concentration was reduced to a significantly greater extent by gemfibrozil. After gemfibrozil treatment, lipoprotein(a) [
Lp(a)
] was decreased by 24%, and the plasma free fatty acid (FFA) concentration was increased by 20% and skeletal muscle
lipoprotein lipase
activity (LPLA) by 37%. Although simvastatin more effectively decreased LDL cholesterol levels and the LDL to high-density lipoprotein (HDL) ratio, it cannot be claimed unreservedly that this drug is necessarily preferable in NIDDM patients. Gemfibrozil improved triglyceride removal and decreased VLDL concentrations, with qualitative changes in LDL. The apparent effects on insulin sensitivity are difficult to evaluate and need further study.
...
PMID:A comparison between the effects of gemfibrozil and simvastatin on insulin sensitivity in patients with non-insulin-dependent diabetes mellitus and hyperlipoproteinemia. 786 18
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