A novel method for measuring human lipoprotein lipase and hepatic lipase activities in postheparin plasma

The objective of this study was to establish a new lipoprotein lipase (LPL) and hepatic lipase (HL) activity assay method. Seventy normal volunteers were recruited. Lipase activities were assayed by measuring the increase in absorbance at 546 nm due to the quinoneine dye. Reaction mixture-1 (R-1) contained dioleoylglycerol solubilized with lauryldimethylaminobetaine, monoacylglycerol-specific lipase, glycerolkinase, glycerol-3-phosphate oxidase, peroxidase, ascorbic acid oxidase, and apolipoprotein C-II (apoC-II). R-2 contained Tris-HCl (pH 8.7) and 4-aminoantipyrine. Automated assay of lipase activities was performed with an automatic clinical analyzer. In the assay for HL + LPL activity, 160 microl R-1 was incubated at 37 degrees C with 2 microl of sample for 5 min, and 80 microl R-2 was added. HL activities were measured under the same conditions without apoC-II. HL and LPL activities were also measured by the conventional isotope method and for HL mass by ELISA. Lipase activity detected in a 1.6 M NaCl-eluted fraction from a heparin-Sepharose column was enhanced by adding purified apoC-II in a dose-dependent manner, whereas that eluted by 0.8 M NaCl was not. Postheparin plasma-LPL and HL activities measured in the present automated method had high correlations with those measured by conventional activity and mass methods. This automated assay method for LPL and HL activities is simple and reliable and can be applied to an automatic clinical analyzer.     

Purified postheparin plasma lipoprotein lipase in primary hyperlipoproteinemias.

Purified postheparin plasma lipoprotein lipase (LPL) of normolipidemic and primary hyperlipoproteinemic subjects was characterized by lipoprotein C polypeptide activation and specificity for triglycerides in chylomicrons and VLDL. Chromatography of normal LPL on Sephadex G-100 resulted in two protein peaks, LPLC-1 (activated by C-I but not C-II) and LPLC-II (activated by C-II but not C-I). LPL from type I hyperlipoproteinemic subjects was not activated by C-I and C-II activation was reduced to 40% of control. Hydrolysis of chylomicron and VLDL triglycerides was severely impaired. Although chromatography of type I LPL resulted in two protein peaks, the protein peak corresponding to LPLC-I did not exhibit lipolytic activity and LPLC-II was reduced to 50% of control in protein and enzyme specific activity. Type III LPL was normal in respect to LPLC-I while LPLC-II averaged 40% of control. Hydrolysis of chylomicron and VLDL was reduced to 50% and 10% of control, respectively. An etiological implication for LPLC-I and/or LPLC-II in type I and III hyperlipoproteinemias is suggested.     

A new method for the measurement of lipoprotein lipase in postheparin plasma using sodium dodecyl sulfate for the inactivation of hepatic triglyceride lipase.

Lipoprotein lipase (LPL) and hepatic triglyceride lipase (H-TGL) are lipolytic activities found in postheparin plasma. A simple and precise method for the direct determination of LPL in postheparin plasma is described. Pre-incubations of this plasma (45--60 min at 26 degrees C) with sodium dodecyl sulfate (35--50 mM) in 0.2 M Tris-HCl buffer, pH 8.2, results in the inactivation of H-TGL, while leaving LPL fully active. Direct determination of H-TGL is done in a separate aliquot of the same postheparin plasma sample using previously reported assay conditons that do not measure LPL. The sodium dodecyl sulfate-resistant lipolytic activity has the characteristics of LPL as judged by a) its activation by serum and by apolipoprotein C-II; b) its inactivation (over 90%) by 0.75 M NaCl; and c) its inactivation by a specific antiserum. No sodium dodecyl sulfate-resistant activity was found in postheparin plasma from a patient with LPL deficiency (primary type I hyperlipoproteinemia). An excellent correlation of values was obtained (r = 0.99) for 30 samples assayed after sodium dodecyl sulfate treatment and after immuno-inactivation of H-TGL. The intra-assay coefficient of variation was +/- 11% and 4% before and after normalization of values, respectively.     

A novel method for measuring human hepatic lipase activity in postheparin plasma

The objective of this study was to establish a hepatic lipase (HL) assay method that can be applied to automatic clinical analyzers. Seventy-four hyperlipidemic subjects (men/women 45/29) were recruited. Lipase activity was assayed measuring the increase in absorbance at 546 nm due to quinonediimine dye production. Reaction mixture R-1 contained 50 mM Tris-HCl (pH 9.5), 0.5 mM glycerol-1,2-dioleate, 0.4% (unless otherwise noted) polyoxyethylene-nonylphenylether, 3 mM ATP, 3 mM MgCl(2), 1.5 mM CaCl(2), monoacylglycerol-specific lipase, glycerol kinase, glycerol-3-phosphate oxidase, 0.075% N,N-bis-(4-sulfobutyl)-3-methylaniline-2 Na, peroxidase, ascorbic acid oxidase. Reaction mixture R-2 contained 50 mM Tris-HCl (pH9.5), 0.15% 4-aminoantypirine. Automated assay for activity was performed with a Model 7080 Hitachi analyzer. In the lipase assay, 160 microl of R-1 was incubated at 37 degrees C with 3 microl of samples for 5 min, and 80 microl of R-2 was added. Within-run coefficient of variations was 0.9-1.0%. Calibration curve of lipase activity was linear (r = 0.999) between 0 and 320 U/l. Analytical recoveries of purified HL added to plasma were 96.6-99.8%. HL activity in postheparin plasma measured in this method had a closer correlation with HL mass by a sandwich ELISA (r = 0.888, P < 0.0001) than those in the conventional method using [(14)C-]triolein (r = 0.730, P < 0.0001). This assay method for HL activity can be applied to an automatic clinical analyzer.     

Differential characteristics of purified hepatic triglyceride lipase and lipoprotein lipase from human postheparin plasma.

Evidence is presented that hepatic triglyceride lipase (H-TGL) and lipoprotein lipase (LPL), purified from human postheparin plasma, can each hydrolyze both glyceryl trioleate and palmitoyl-CoA. The average ratio of glyceryl trioleate/palmitoyl-CoA hydrolase activities, obtained with enzyme preparations from 15 human postheparin plasma samples was 1.30 (1.18-1.52) for H-TGL and 8.75 (7.45-10.25) for LPL. Albumin was identified as the serum cofactor required for the hydrolysis of palmitoyl-CoA by H-TGL. It protected this enzyme from inactivation by this substrate. In contrast, palmitoyl-CoA activated and protected LPL from denaturation by dilution and incubation at 25 degrees C. The effects of other detergents were investigated on glyceryl trioleate hydrolase activities of both enzymes. Sodium dodecyl sulfate (0.4 mM) and Trisoleate (0.4 mM), which also effectively activated and protected LPL against inactivation, had only moderate protective effect on H-TGL. Sodium dodecyl sulfate at a higher concentration (1 mM) produced little or no inhibition of LPL, while completely inactivating H-TGL. Conversely, sodium taurodeoxycholate (0.4 mM) protected and activated H-TGL, but had only moderate protective effect on LPL. Triton X-100 (0.1-0.8 mM) and egg lysolecithin (0.05-2 mM) also protected H-TGL, but not LPL. The very dissimilar effects of detergents on preparations on H-TGL and LPL may form the basis for the direct assay of each enzyme in the presence of the other.     

A sandwich-enzyme immunoassay for the quantification of lipoprotein lipase and hepatic triglyceride lipase in human postheparin plasma using monoclonal antibodies to the corresponding enzymes

We have developed a sandwich-enzyme immunoassay (EIA) for the quantification of lipoprotein lipase (LPL) and hepatic triglyceride lipase (HTGL) in human postheparin plasma (PHP) using monoclonal antibodies (MAbs) directed against the corresponding enzymes purified from human PHP. The sandwich-EIA for LPL was performed by using the combination of two distinct types of anti-LPL MAbs that recognize different epitopes on the LPL molecule. The immunoreactive mass of LPL was specifically measured using a beta-galactosidase-labeled anti-LPL MAb as an enzyme-linked MAb, an anti-LPL MAb linked with the bacterial cell wall as an insolubilized MAb, and purified human PHP-LPL as a standard. The sandwich-EIA for HTGL was carried out by using two distinct anti-HTGL MAbs that recognize different epitopes on HTGL. The limit of detection was 20 ng/ml for LPL and 60 ng/ml for HTGL. Each method yielded a coefficient of variation of less than 6% in intra- and inter-assays, and a high concentration of triglyceride did not interfere with the assays. The average recovery of purified human PHP-LPL and -HTGL added to human PHP samples was 98.8% and 97.5%, respectively. The immunoreactive masses of LPL and HTGL in PHP samples, obtained at a heparin dose of 30 IU/kg, from 34 normolipidemic and 20 hypertriglyceridemic subjects were quantified by the sandwich-EIA. To assess the reliability of the measured mass values, they were compared with the corresponding enzyme activities measured by selective immunoinactivation assay using rabbit anti-human PHP-LPL and -HTGL polyclonal antisera. Both assay methods yielded a highly significant correlation in either normolipidemic (r = 0.945 for LPL; r = 0.932 for HTGL) or hypertriglyceridemic subjects (r = 0.989 for LPL; r = 0.954 for HTGL). The normal mean (+/- SD) level of lipoprotein lipase mass and activity in postheparin plasma was 223 +/- 66 ng/ml and 10.1 +/- 2.9 mumol/h per ml, and that of hepatic triglyceride lipase mass and activity was 1456 +/- 469 ng/ml and 26.4 +/- 8.7 mumol/h per ml, respectively. The present sandwich-enzyme immunoassay methods make it possible to study the molecular nature of LPL and HTGL in PHP from patients with either primary or secondary hyperlipoproteinemia.     

Effect of acute ethanol load on postheparin plasma lipoprotein lipase and hepatic lipase activities and intravenous fat tolerance

This study aimed to examine the possibility that ethanol-induced rise of serum triglyceride concentration in man is partly due to an impaired removal of triglycerides from the circulation. Acute ethanol loads given to normal human subjects after an overnight fast reduced the postheparin plasma lipoprotein lipase activity by an average of 25% but did not influence the postheparin plasma hepatic lipase activity or fractional removal of Intralipid triglyceride. When alcolhol was administered to fed subjects in the evening the postheparin plasma hepatic lipase was significantly decreased in the next morning as compared to corresponding control value but the lipoprotein lipase and Intralipid clearance were not changed. It is concluded that the slight decrease of lipoprotein lipase during alcohol intoxication may contribute to the hyperlipemic effect of ethanol.     

Purification and characterization of lipoprotein lipase and hepatic triglyceride lipase from human postheparin plasma: production of monospecific antibody to the individual lipase

Lipoprotein lipase (LPL) and hepatic triglyceride lipase (HTGL) were purified to homogeneity from human postheparin plasma. Molecular, catalytic and immunological properties of the purified enzymes were investigated. The native molecular weights of LPL and HTGL were 67,200 and 65,500, respectively, by gel chromatography. The subunit molecular weights of LPL and HTGL were 60,600 and 64,600, respectively, suggesting that these enzymes are catalytically active in a monomeric form. In addition, the purified LPL and HTGL each gave a single protein band when they were detected as glycoproteins with a probe of concanavalin A. The purified enzyme preparations were free of detectable antithrombin III by Western blot analysis. Catalytic properties of the purified enzymes were examined using triolein-gum arabic emulsion and triolein particles stabilized with phospholipid monolayer as substrates. LPL catalyzed the complete hydrolysis of triolein to free oleate and monooleate in the presence of apolipoprotein C-II. Apparent Km values for triolein and apolipoprotein C-II were 1.0 mM and 0.6 microM, and Vmax was 40.7 mmol/h per mg. HTGL hydrolyzed triolein substrate at a rate much slower than LPL, and produced mainly free oleate with little monooleate. Apparent Km and Vmax values were 2.5 mM and 16.1 mmol/h per mg, respectively. Polyclonal antibodies were developed against the purified LPL and HTGL. The purity and specificity of these antisera were ascertained by immunotitration, Ouchterlony double diffusion and Western blot analyses. The anti-human LPL and anti-human HTGL antiserum specifically reacted with the corresponding either native or denaturated enzyme, indicating that two enzymes were immunologically distinct. We developed an assay system for LPL and HTGL in human PHP by selective immunoprecipitation of each enzyme with the corresponding antiserum.     

Distribution of lipoprotein lipase and hepatic lipase between plasma and tissues: effect of hypertriglyceridemia

Lipoprotein lipase and hepatic lipase were measured in rat plasma using specific antisera. Mean values for lipoprotein lipase in adult rats were 1.8-3.6 mU/ml, depending on sex and nutritional state. Values for hepatic lipase were about three times higher. Lipoprotein lipase activity in plasma of newborn rats was 2-4-times higher than in adults. In contrast, hepatic lipase activity was lower in newborn than in adult rats. Following functional hepatectomy there was a progressive increase in lipoprotein lipase activity in plasma, indicating that transport of the enzyme from peripheral tissues to the liver normally takes place. Lipoprotein lipase, but not hepatic lipase, increased in plasma after a fat meal. An even more marked increase, up to 30 mU/ml, was seen after intravenous injection of Intralipid. Plasma lipase activity decreased in parallel with clearing of the injected triacylglycerol. 125I-labeled lipoprotein lipase injected intravenously during the hyperlipemia disappeared somewhat slower from the circulation than in fasted rats, but the uptake was still primarily in the liver. Hyperlipemia, or injection of heparin, led to increased lipoprotein lipase activity in the liver. This was seen even when the animals had been pretreated with cycloheximide to inhibit synthesis of new enzyme protein. These results suggest that during hypertriglyceridemia lipoprotein lipase binds to circulating lipoproteins/lipid droplets which results in increased plasma levels of the enzyme and increased transport to the liver.     

A comparison of the lipoprotein lipase activity in the tissues and post-heparin plasma of atherosclerosis-susceptible and atherosclerosis-resistant pigeons

1. The lipoprotein lipase activity measured in acetone-ether powders of tissues from White Carneau and Show Racer pigeons was invariably somewhat lower in the former compared with the latter species. 2. At 100 and 200 Units of heparin per kg body weight the peak post-heparin lipolytic activity present in the plasma of White Carneau pigeons was significantly lower than that for Show Racers. At 50 Units per kg, this position was reversed. 3. It was concluded that the White Carneau pigeon may have an impaired functional lipoprotein lipase capacity compared to the Show Racer control.     

Identification of lipoprotein lipase immunoreactive protein in pre- and postheparin plasma from normal subjects and patients with type I hyperlipoproteinemia

Postheparin plasma is a convenient source for the measurement of lipoprotein lipase (LPL) in humans. Previous studies have focused on the measurement of LPL catalytic activity, and have been unable to conveniently measure the LPL protein or identify possibly different plasma forms of the enzyme. Pre- and postheparin plasma was treated with a highly specific antibody raised against bovine milk LPL and the immunoprecipitate was analyzed by Western blotting. In normal subjects there were several species of LPL in plasma. A 56 kD protein increased after heparin injection, and likely represented active LPL. The anti-LPL antibody reacted specifically with this 56 kD protein, and also reacted specifically with proteins at 52 kD, 69 kD, as well as a 20 kD breakdown product. In addition, using peptide mapping, the 56 kD protein was structurally similar to the 52 and 69 kD LPL proteins. The antibodies were affinity purified, biotinylated, and used to quantitate LPL immunoreactive mass using an enzyme-linked immunosorbent assay (ELISA). LPL immunoreactive mass was present in all subjects in preheparin plasma. In postheparin plasma, five patients with type I hyperlipoproteinemia displayed decreased LPL immunoreactive mass when compared to normal subjects, although there was a wide range of specific activity of the small amount of enzyme present. When the LPL from the plasma of the patients was immunoprecipitated and Western blotted, there was considerable heterogeneity in the appearance of the LPL forms, and an overall decrease in LPL protein. Thus, several different immunoreactive LPL proteins were present in pre- and postheparin plasma. In preheparin plasma, as well as in patients with type I hyperlipoproteinemia, there was decreased immunoreactive LPL protein, and the LPL protein that was present was of low specific activity.     

Isolation and cDNA sequence of human postheparin plasma hepatic triglyceride lipase

Hepatic triglyceride lipase (H-TGL) was isolated from human postheparin plasma by column chromatography on heparin-Sepharose and phenyl-Sepharose and immunoaffinity chromatography with monoclonal antibodies. The purified enzyme had an apparent molecular weight of 65,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and an amino-terminal sequence of Leu-Gly-Gln-Ser-Leu-Lys-Pro-Glu. Partial amino acid sequences of seven cyanogen bromide peptides were obtained. A human hepatoma cDNA library was screened with synthetic oligonucleotides derived from the partial protein sequence. The cloned H-TGL cDNA of 1569 nucleotides predicts a mature protein of 477 amino acids plus a leader sequence of 22 amino acids. Blot hybridization analysis of poly(A)+ mRNA with a putative H-TGL cDNA clone gave a single hybridizing band of 1.7 kilobases. The protein contains four consensus N-glycosylation sequences based on the cDNA sequence. Comparison of the enzyme sequence with that of other lipases reveals highly conserved sequences in regions of putative lipid and heparin binding. The carboxyl terminus of H-TGL contains a highly basic sequence which is not reported to be present in rat H-TGL or other members of the lipase gene family.     

Glucose tolerance, plasma lipoproteins and tissue lipoprotein lipase activities in body builders

Oral glucose tolerance, insulin binding to erythrocyte receptors, serum lipids, and lipoproteins, and lipoprotein lipase activities of adipose tissue and skeletal muscle were measured in nine body builders (relative body weight (RBW) 118 +/- 4%), eight weight-matched (RBW 120 +/- 5%) and seven normal-weight controls (RBW 111 +/- 3%). The body builders had 50% higher relative muscle mass of body weight (% muscle) and 50% smaller relative body fat content (% fat) than the two other groups (P less than 0.005). Maximal aerobic power was comparable in the three groups. In the oral glucose tolerance test (OGTT), blood glucose levels, and plasma insulin levels were lower (P less than 0.05) in the body builders than in weight-matched controls. Insulin binding to erythrocytes was similar in each group. On the basis of multiple linear regression analysis, 87% of the variation in plasma insulin response could be explained by body composition (% muscle and % fat) and VO2max. Plasma total cholesterol, low-density lipoprotein (LDL) cholesterol, and very low-density lipoprotein (VLDL) triglyceride concentrations were significantly lower in the body builders than in weight-matched controls. In comparison with the normal-weight group, the body builders had a lower total cholesterol level. High density lipoprotein (HDL) cholesterol, its subfractions (HDL2 and HDL3 cholesterol) and lipoprotein lipase (LPL) activities of adipose tissue and skeletal muscle were comparable in all three groups. Partial correlation analysis showed a positive relationship between plasma total triglyceride, total cholesterol and LDL cholesterol on the other hand and the % fat on the other.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of low and moderate exercise intensity on postprandial lipemia and postheparin plasma lipoprotein lipase activity in physically active men.

This study was designed to assess differences in the intensity of exercise to attenuate postprandial lipemia (PPL). Thirteen healthy men (age 23.8 +/- 0.9 yr) participated in three random-ordered trials: in low-(25% peak oxygen consumption; Low) and moderate-intensity (65% peak oxygen consumption; Mod) exercise trials, which were completed 1 h before a high-fat meal (1.3 g fat/kg body mass), and a control (Con), fat meal only, trial. Venous blood samples were obtained before the fat meal, and at 2, 4, 6, 8, and 20 h after the fat meal. PPL in the Mod trial (267 +/- 50 mg.dl-1.8 h) was lower compared with that in either Con (439 +/- 81 mg.dl-1.8 h) or Low (403 +/- 91 mg.dl-1.8 h) trials (P < 0.05), whereas there was no difference in PPL between Con and Low trials (P > 0.05). High-density lipoprotein cholesterol (HDL-C) and HDL subtype 2 cholesterol were not different between or within trials (P > 0.05). Postprandial insulinemia was lower in the Mod trial (20.5 +/- 5.7 microIU.ml-1.8 h; P < 0.05), but not in the Low trial (31.4 +/- 4.7 microIU.ml-1.8 h), compared with that in the Con trial (34.9 +/- 5.0 microIU.ml-1.8 h). Postheparin lipoprotein lipase activity at 8 h was higher in the Low trial compared with that in either Con or Mod trials, whereas there were no differences between trials at 20 h. These results suggest that, when exercise is performed 1 h before a fat meal, only exercise of moderate but not of low intensity attenuates PPL and that this effect is not associated with changes in postheparin lipoprotein lipase activity.     

A glycosaminoglycan activator of lipoprotein lipase in human plasma

By use of ion exchange chromatography we have isolated two discrete classes of “free” glycosaminoglycans (GAG) from human plasma. The GAG fractions were tested for their effects on two lipoprotein lipase (LPL) enzyme systems containing an apolipo-protein C-II activated emulsion as the triglyceride substrate and bovine serum albumin as the free fatty acid acceptor. The low-charge GAG (Fraction I) had essentially no effect on the LPL reaction. The high-charge GAG (Fraction II) stimulated the LPL reaction 100 to 300%. The GAG composition of each fraction was investigated with chemical and enzymatic techniques. Fraction I consisted of low-charge chondroitin sulfate noncovalently bound to protein. Fraction II consisted of a mixture of high-charge GAG non-covalently bound to protein. Degradation with nitrous acid eliminated the ability of high-charge GAG to stimulate LPL. This and other evidence suggests that the high-charge GAG in human plasma responsible for LPL activation is heparan sulfate (HS). We suggest that plasma HS may modulate triglyceride clearance mechanisms $\text{in vivo}$ by its interaction with LPL.     

A stable, radioactive substrate emulsion for assay of lipoprotein lipase.

A method is described for the assay of lipoprotein lipase, using a stable, radioactive substrate emulsion. Fatty acid-labeled trioleoylglycerol was emulsified by homogenization in glycerol with lecithin as detergent. This anhydrous emulsion was stable for at least six weeks. Substrate solutions for enzyme assay were prepared by diluting the emulsion with buffer containing serum and albumin. The fatty acid produced on hydrolysis was isolated in a one-step liquid-liquid partition system. Incubations with extracts of acetone powders from adipose tissue displayed characteristics of lipoprotein lipase activity, i.e., serum dependence and inhibition by NaCl and protamine. The method is rapid (less than 1 hour), sensitive and reproducible, and suitable for routine use.