Post-heparin plasma hepatic triacylglycerol lipase-catalyzed tributyrin hydrolysis. Effect of trypsin treatment

Hepatic triacylglycerol lipase (EC 3.1.1.3) hydrolyzes water-insoluble fatty acid esters, e.g., trioleoylglycerol (lipase activity) and water-soluble fatty acid esters, e.g., tributyrin (esterase activity). Esterase activity of hepatic triacylglycerol lipase is enhanced by triolein emulsion and phospholipid vesicles [1]. The catalytic mechanism and structure of human hepatic triacylglycerol lipase isolated from human post-heparin plasma and the effect of trypsin treatment on the lipase and esterase activities of the enzyme were examined. Treatment of hepatic triacylglycerol lipase with trypsin resulted in loss of its lipase activity, but had no effect on its esterase activity. Chromatography of hepatic triacylglycerol lipase on Bio-Gel A5m showed that hepatic triacylglycerol lipase binds to dipalmitoylphosphatidylcholine vesicles. However, on chromatography of the trypsin-treated enzyme after incubation with dipalmitoylphosphatidylcholine vesicles, a part of hepatic triacylglycerol lipase that retained esterase activity was eluted separately from the dipalmitoylphosphatidylcholine vesicles. Addition of vesicles of dipalmitoylphosphatidylcholine to the trypsin-treated enzyme did not enhance its esterase activity. These results are consistent with the hypothesis that hepatic triacylglycerol lipase has a catalytic site that hydrolyzes tributyrin and a lipid interface recognition site, and that these sites are different: trypsin modified the lipid interface recognition site of the hepatic triacylglycerol lipase but not the catalytic site.     

Human lipoprotein lipase: the loop covering the catalytic site is essential for interaction with lipid substrates.

Lipoprotein lipase (LPL), a key enzyme which initiates the hydrolysis of triglycerides present in chylomicrons and very low density lipoproteins, consists of multiple functional domains which are necessary for normal activity. The catalytic domain of LPL mediates the esterase function of the enzyme but separate lipid binding sites have been proposed to be involved in the interaction of LPL with emulsified lipid substrates at the water-lipid interface. Like pancreatic lipase (PL), LPL contains a surface loop covering the catalytic pocket that may modulate access of the substrate to the active site of the enzyme. Secondary structural analysis of this loop reveals a helix-turn-helix motif with two short amphipathic helices that have hydrophobic moments of 0.64 and 0.68. In order to investigate the role of the loop in the initial interaction of LPL with its substrate, we utilized site-directed mutagenesis to generate eight constructs in which the amphipathic properties of the loop were altered and expressed them in human embryonal kidney-293 cells. Reducing the amphiphilicity without changing the predicted secondary structure of the loop abolished the ability of the lipase to hydrolyze emulsified, long chain fatty acid triglycerides (triolein) but not the water soluble substrate tributyrin. Replacing the loop of LPL with the loop of hepatic lipase, which differs in 15 of 22 amino acids but is also amphiphilic, led to the expression of an enzyme that retained both triolein and tributyrin hydrolyzing activity. Substitution of the LPL loop by a short four amino acid peptide, which may allow more direct access to the active site than the 22 amino acid loop, enhanced hydrolysis of short chain fatty acid triglycerides by more than 2-fold, while the ability to hydrolyze emulsified substrates was abolished. Thus, disruption of the amphipathic structure of the LPL loop selectively decreases the hydrolysis of emulsified lipid substrate without affecting the esterase or catalytic function of the enzyme. These studies establish that the loop with its two amphipathic helices is essential for hydrolysis of long chain fatty acid substrate by LPL providing new insight into the role of the LPL loop in lipid-substrate interactions. We propose that the interaction between the lipoprotein substrates and the amphipathic helices within this loop may in part determine lipase substrate specificity.     

Conformational changes in human urokinase induced by a specific reduction of disulfide bond in Cys-194-Cys-222 associated with exhibition of enzymatic activity

The mechanism of action of hepatic triacylglycerol lipase (EC 3.1.1.3) was examined by comparing the hydrolysis of a water-soluble substrate, tributyrin, with that of triolein by hepatic triacylglycerol lipase purified from human post-heparin plasma. The hydrolyzing activities toward tributyrin and triolein were coeluted from heparin-Sepharose at an NaCl concentration of 0.7 M. The maximal velocity of hepatic triacylglycerol lipase (Vmax) for tributyrin was 17.9 mumol/mg protein per h and the Michaelis constant (Km) value was 0.12 mM, whereas the Vmax for triolein was 76 mumol/mg per h and the Km value was 2.5 mM. The hydrolyses of tributyrin and triolein by hepatic triacylglycerol lipase were inhibited to similar extends by procainamide, NaF, Zn2+, Cu2+, Mn2+, SDS and sodium deoxycholate. Triolein hydrolysis was inhibited by the addition of tributyrin. Triolein hydrolysis was also inhibited by the addition of dipalmitoylphosphaidylcholine vesicles. In contrast, the additions of triolein emulsified with Triton X-100 and dipalmitoylphosphatidylcholine vesicles enhanced the rate of tributyrin hydrolysis by hepatic triacylglycerol lipase. In the presence of dipalmitoylphosphatidylcholine, the Vmax and Km values of hepatic triacylglycerol lipase for tributyrin were 41 mumol/mg protein per h and 0.12 mM, respectively, indicating that the enhancement of hepatic triacylglycerol lipase activity for tributyrin by dipalmitoylphosphatidycholine vesicles was mainly due to increase in the Vmax. The enhancement of hepatic triacylglycerol lipase activity for tributyrin by phospholipid was not correlated with the amount of tributyrin associated with the phospholipid vesicles. On Bio-Gel A5m column chromatography, glycerol tri[1-14C]butyrate was not coeluted with triolein emulsion, and hepatic triacylglycerol lipase activity was associated with triolein emulsion even in the presence of 2 mM tributyrin. These results suggest that hepatic triacylglycerol lipase has a catalytic site for esterase activity and a separate site for lipid interface recognition, and that on binding to a lipid interface the conformation of the enzyme changes, resulting in enhancement of the esterase activity.     

Studies on the degradation of human very low density lipoproteins by human milk lipoprotein lipase

Human milk lipoprotein lipase (LPL) was purified by heparin-Sepharose 4B affinity chromatography. The time required for the purification was approximately 2 h. The acetone-diethyl ether powder of milk cream was extracted by a 0.1% Triton X-100 buffer solution and the extract was applied to the heparin-Sepharose 4B column. The partially purified LPL eluted by heparin had a specific activity of 5120 units/mg which represented a 2500-fold purification of the enzyme. The LPL was found to be stable in the heparin solution for at least 2 days at 4 °C. This enzyme preparation was found to be free of the bile salt-activated lipase activity, esterase activity, and cholesterol esterase activity. The LPL had no demonstrable basal activity with emulsified triolein in the absence of a serum cofactor. The enzyme was activated by serum and by apolipoprotein C-II. The application of milk LPL to studies on the in vitro degradation of human very low density lipoproteins can result in a 90–97% triglyceride hydrolysis. The LPL degraded very low density lipoprotein triglyceride and phospholipid without any effect on cholesterol esters. Of the partial glycerides potentially generated by lipolysis with milk LPL, only monoglycerides were present in measurable amounts after 60 min of lipolysis. These results show that the partially purified human milk LPL with its high specific activity and ease of purification represents a very suitable enzyme preparation for studying the kinetics and reaction mechanisms involved in the lipolytic degradation of human triglyceride-rich lipoproteins.     

Effect of limited tryptic modification of a bacterial poly(3-hydroxybutyrate) depolymerase on its catalytic activity

The extracellular poly(3-hydroxybutyrate) depolymerase of Alcaligenes faecalis T1, which hydrolyzes both hydrophobic poly(3-hydroxybutyrate) and water-soluble oligomers of D(-)-3-hydroxybutyrate, lost its hydrolyzing activity toward the hydrophobic substrate on mile trypsin treatment, but retained its activity toward water-soluble oligomers. The molecular mass of the trypsin-treated enzyme was 44 kDa, as estimated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, which was 6 kDa smaller than that of the native enzyme (50 kDa). The trypsin-treated enzyme seemed to be less hydrophobic than the native one, because it was rather weakly adsorbed to a hydrophobic butyl-Toyopearl column compared with the native enzyme, and showed no ability to bind to poly(3-hydroxybutyrate), to which the native enzyme tightly bound. These results suggest that, in addition to a catalytic site, the enzyme has a hydrophobic site, which is not essential for the hydrolysis of water-soluble oligomers, but is necessary for the hydrolysis of hydrophobic substrates, and this hydrophobic site is removed from the enzyme by the action of trypsin.     

Hepatic triacylglycerol lipase in circulating blood of normal and tumor-bearing mice and its hydrolysis of very-low-density lipoprotein and synthetic acylglycerols

A large amount of triacylglycerol lipase activity was present in the circulating blood of normal mice, and this activity decreased with development of Sarcoma 180 inoculated intraperitoneally. Triacylglycerol lipase in plasma of both normal and tumor-bearing mice was retained on the heparin-Sepharose columns and over 90% of the activity was eluted with 0.75 M NaCl. This enzyme had similar properties to hepatic triacylglycerol lipase and hydrolyzed very-low-density lipoprotein (VLDL)-triacylglycerol. Hepatic triacylglycerol lipase in plasma of normal mice hydrolyzed tricaprin and trilaurin most readily and better than 1-monoacylglycerols with the same acyl chain length. The hydrolyzing activities decreased with increase in the acyl chain length. The activity toward triolein was also higher than that toward 1-monoolein. 1-Monomyristin was hydrolyzed better than trimyristin. In contrast, hepatic triacylglycerol lipase in plasma of mice on day 4 after tumor inoculation hydrolyzed 1-monoacylglycerols better than triacylglycerols with the same acyl chain length. Hydrolysis of triolein by hepatic triacylglycerol lipase in plasma of both normal and tumor-bearing mice was reduced in the presence of 1-monoacylglycerols in the reaction mixture. The orders of their inhibitory effects coincided with the orders of the hydrolyzing activities toward 1-monoacylglycerols.     

Human lipoprotein lipase. Analysis of the catalytic triad by site-directed mutagenesis of Ser-132, Asp-156, and His-241.

Lipoprotein lipase (LPL) plays a central role in normal lipid metabolism as the key enzyme involved in the hydrolysis of triglycerides present in chylomicrons and very low density lipoproteins. LPL is a member of a family of hydrolytic enzymes that include hepatic lipase and pancreatic lipase. Based on primary sequence homology of LPL to pancreatic lipase, Ser-132, Asp-156, and His-241 have been proposed to be part of a domain required for normal enzymic activity. We have analyzed the role of these potential catalytic residues by site-directed mutagenesis and expression of the mutant LPL in human embryonic kidney-293 cells. Substitution of Ser-132, Asp-156, and His-241 by several different residues resulted in the expression of an enzyme that lacked both triolein and tributyrin esterase activities. Mutation of other conserved residues, including Ser-97, Ser-307, Asp-78, Asp-371, Asp-440, His-93, and His-439 resulted in the expression of active enzymes. Despite their effect on LPL activity, substitutions of Ser-132, Asp-156, and His-241 did not change either the heparin affinity or lipid binding properties of the mutant LPL. In summary, mutation of Ser-132, Asp-156, and His-241 specifically abolishes total hydrolytic activity without disrupting other important functional domains of LPL. These combined results strongly support the conclusion that Ser-132, Asp-156, and His-241 form the catalytic triad of LPL and are essential for LPL hydrolytic activity.     

On the issue of interfacial activation of lipase in nonaqueous media

The question of whether lipases can be activated by adsorption onto an interface in organic solvents was addressed using Rhizomucor miehei lipase as a model. In aqueous solution, this enzyme was shown to undergo a marked interfacial activation. However, lipase (either lyophilized or precipitated from water with acetone) suspended in ethanol or 2-(2-ethoxyethoxy)ethanol containing triolein exhibited no jump in catalytic activity when the concentration of triolein exceeded its solubility in these solvents, thereby resulting in formation of an interface. To test whether the lack of interfacial activation was due to the insolubility of the enzyme in organic media, lipase was covalently modified with poly(ethylene glycol). The modified lipase, although soluble in nonaqueous media, was still unable to undergo interfacial activation, regardless of the hydrophobicity of the interface. This inability was found to be caused by the absence of adsorption of lipase onto interfaces in organic solvents, presumably because of the absence of the hydrophobic effect (the driving force of lipase adsorption onto hydrophobic interfaces in water) in such media. The uncovered lack of interfacial adsorption and activation suggests that the short alpha-helical "lid" covering the active center of the lipase remains predominantly closed in nonaqueous media, thus contributing to diminished enzymatic activity. (c) 1996 John Wiley & Sons, Inc.     

Hepatic lipase. Purification and characterization

Hepatic lipase has been purified to homogeneity from rat liver homogenates. The purified enzyme exhibits a single band on SDS-polyacrylamide gel electrophoresis. The molecular size of the native hepatic lipase is 200 000, while on SDS-polyacrylamide gel electrophoresis the apparent minimum molecular weight of the enzyme is 53 000, suggesting that the active enzyme is composed of four subunits. The relationship between triacylglycerol, monoacylglycerol and phospholipid hydrolyzing activities of the purified rat liver enzyme was studied. All three activities had a pH optimum of 8.5. The maximal reaction rates obtained with triolein, monoolein and dipalmitoylphosphatidylcholine were 55 000, 66 000 and 2600 mumol fatty acid/mg per h with apparent Michaelis constant (Km) values of 0.4, 0.25 and 1.0 mM, respectively. Hydrolysis of triolein and monoolein probably takes place at the same site on the enzyme molecule, since competitive inhibition between these two substrates was observed, and a similar loss of hydrolytic activity occurred in the presence of diisopropylfluorophosphate. Addition of apolipoproteins C-II and C-I had no effect on the hydrolytic activity of the enzyme with the three substrates tested. However, the triacylglycerol hydrolyzing activity was inhibited by the addition of apolipoprotein C-III. Monospecific antiserum to the pure hepatic lipase has been raised in a rabbit.     

Maturation of lipoprotein lipase. Expression of full catalytic activity requires glucose trimming but not translocation to the cis-Golgi compartment.

The relationship between maturation of lipoprotein lipase (LPL) and its translocation from the endoplasmic reticulum (ER) to the Golgi complex was determined by measuring lipolytic activity under conditions preventing transport of the enzyme from the ER to the Golgi compartment. In the presence of brefeldin A, a reagent that inhibits movement of proteins from the ER and causes the disassembly of the Golgi complex, pro-5 Chinese hamster ovary cells accumulated catalytically active LPL, while secretion of the enzyme was effectively blocked. LPL retained intracellularly by brefeldin A treatment possessed oligosaccharide chains that were processed to the complex form by the Golgi enzymes redistributed into the ER. At 16 degrees C, a condition disrupting protein transport to the cis-Golgi, the retained enzyme again remained catalytically active although the oligosaccharides remained in the high mannose form. Lastly, attachment of the specific ER retention signal KDEL (Lys-Asp-Glu-Leu) to the carboxyl terminus of LPL also resulted in intracellularly retained enzyme that was fully active. The importance of oligosaccharide processing for attainment of LPL catalytic activity in vitro was also determined. LPL was active and secreted when trimming of the mannose residues was inhibited by deoxymannojirimycin and when addition of complex sugars was blocked using Chinese hamster ovary mutants (lec1 and lec2), indicating that these processing events are not necessary for the expression of a functional enzyme. However, blocking glucose removal by glucosidase inhibitors (castanospermine and N-methyl-deoxynojirimycin) resulted in a significant reduction in LPL specific activity and secretion. Thus, glucose trimming of LPL oligosaccharides is essential for enzyme activation; however, further oligosaccharide processing or translocation of the enzyme to the cis-Golgi is not required for full expression of lipolytic activity in vitro.     

Identification of a lipoprotein lipase cofactor-binding site by chemical cross-linking and transfer of apolipoprotein C-II-responsive lipolysis from lipoprotein lipase to hepatic lipase

To localize the regions of lipoprotein lipase (LPL) that are responsive to activation by apoC-II, an apoC-II peptide fragment was cross-linked to bovine LPL. Following chemical hydrolysis and peptide separation, a specific fragment of LPL (residues 65-86) was identified to interact with apoC-II. The fragment contains regions of amino acid sequence dissimilarity compared with hepatic lipase (HL), a member of the same gene family that is not responsive to apoC-II. Using site-directed mutagenesis, two sets of chimeras were created in which the two regions of human LPL (residues 65-68 and 73-79) were exchanged with the corresponding human HL sequences. The chimeras consisted of an HL backbone with the suspected LPL regions replacing the corresponding HL sequences either individually (HLLPL-(65-68) and HLLPL-(73-79)) or together (HLLPLD). Similarly, LPL chimeras were created in which the candidate regions were replaced with the corresponding HL sequences (LPLHL-(77-80), LPLHL-(85-91), and LPLHLD). Using a synthetic triolein substrate, the lipase activity of the purified enzymes was measured in the presence and absence of apoC-II. Addition of apoC-II to HLLPL-(65-68) and HLLPL-(73-79) did not significantly alter their enzyme activity. However, the activity of HLLPLD increased approximately 5-fold in the presence of apoC-II compared with an increase in native LPL activity of approximately 11-fold. Addition of apoC-II to LPLHL-(77-80) resulted in approximately 10-fold activation, whereas only approximately 6- and approximately 4-fold activation of enzyme activity was observed in LPLHL-(85-91) and LPLHLD, respectively. In summary, our results have identified 11 amino acid residues in the N-terminal domain of LPL (residues 65-68 and 73-79) that appear to act cooperatively to enable substantial activation of human LPL by apoC-II.     

The kinetics of heparin inhibition of the esterase and basal lipase activities of lipoprotein lipase

The kinetics of inhibition of the esterase and lipase activities of bovine milk lipoprotein lipase (LPL) were compared. The esterase LPL activity against emulsified tributyrylglycerol was not affected by the enzyme activator apolipoprotein C-II (C-II) and amounted to about 15% of the "plus activator" lipase enzyme activity. Heparin at concentrations of 20 micrograms/ml inhibited 25% of the esterase activity. The reaction followed Henri-Michaelis-Menten kinetics and the inhibition by heparin followed a linear, intersecting, noncompetitive kinetic model. On the other hand, the basal lipase activity of LPL against emulsified trioleoylglycerol (TG) was very sensitive to inhibition by heparin: 1 microgram/ml inhibited about 80% of the reaction and 3 micrograms/ml drove the reaction to zero. The velocity curve for the uninhibited basal LPL activity was sigmoidal with an apparent nH(TG) of 2.94. Heparin inhibited the lipase activity competitively: heparin decreased nH(TG) and increased[TG]0.5 6.4-fold, while TG decreased the nH(Heparin) from 2.14 to 0.95 and caused a 3-fold increase in [Heparin]0.5. C-II, at concentrations lower than 2.5 X 10(-8) M (i.e., lower than KA), countered the inhibitory effects of heparin: at constant inhibitor concentrations, C-II increased nH(TG) from 1.78 to 2.52 and decreased [TG]0.5 about 10-fold; it also increased the apparent Vmax. At the lower C-II concentrations, nH(C-II) was approximately equal to 1.0 and increasing the TG concentrations decreased [C-II]0.5 from 3.8 X 10(-8) to 8.5 X 10(-9) M, with no effect on the nH(C-II). At the higher C-II concentrations, nH(C-II) was 2.5 and TG decreased [C-II]0.5 about 2-fold with no effect on the nH(C-II). In the absence of heparin, C-II had no effect on nH(TG) nor on [TG]0.5, but it increased the apparent Vmax. On the other hand, TG had no effect on nH(C-II) nor on [C-II]0.5, but at any given C-II concentration, the reaction velocity increased with increasing TG concentrations. It is concluded that TG and heparin as well as C-II and heparin are mutually exclusive and that lipoprotein lipase is a multisite enzyme, possibly a tetramer, with three high-affinity catalytic sites, and an equal number of sites for C-II and heparin per oligomer. However, LPL differs from classical allosteric enzymes in that its activator has no effect on substrate cooperativity nor on [S]0.5; its only effect is to increase Vmax by increasing the catalytic rate constant kp by inducing conformational changes in the enzyme.     

Partial purification and characterization of a triglyceride lipase from pig adipose tissue.

A triglyceride lipase was extracted from defatted pig adipose tissue powder with dilute ammonia and purified about 230-fold by a combination of ammonium sulfate fractionation, heparin-Sepharose 4B, DEAE-cellulose, and Sephadex G-150 column chromatographies and isoelectrofocusing electrophoresis. The enzyme was distinguishable in physical and kinetic properties from the two previously defined lipases in adipose tissue, lipoprotein lipase, and hormone-sensitive lipase. The purified enzyme was fully active in the absence of serum lipoprotein and was not stimulated by adenosine 3':5'-monophosphate-dependent protein kinase. In marked contrast to the already defined lipases, the enzyme was strongly inhibited by serum albumin. The enzyme had a molecular weigt of about 43,000, a pI of 5.2, and pH optimum of 7.0. The enzyme hydrolyzed triolein to oleic acid and glycerol, and did not exhibit esterase activity. The apparent Km for triolein was 0.05 mM. Physiological roles of this new species of lipase remained to be explored.     

Long term incubation of cardiac myocytes with oleic acid and very-low density lipoprotein reduces heparin-releasable lipoprotein lipase activity

An exogenous [³H]triolein emulsion was hydrolyzed by intact cardiac myocytes with functional LPL located on the cell surface. This surface-bound LPL could be released into the medium when cardiac myocytes were incubated with heparin. Incubation of cardiac myocytes with VLDL, or the products of TG breakdown, oleic acid or 2-monoolein, did not increase LPL activity in the medium. However, incubation of cardiac myocytes with either VLDL or oleic acid for > 60 min did reduce heparin-releasable LPL activity. In the heart, this inhibitory effect of FFA could regulate the translocation of LPL from its site of synthesis in the cardiac myocyte to its functional site at the capillary endothelium.Abbreviations LPL lipoprotein lipase - TG triacylglycerol - FFA free fatty acids - VLDL very-low density lipoprotein     

Carboxyl ester lipase: structure-function relationship and physiological role in lipoprotein metabolism and atherosclerosis

Carboxyl ester lipase (CEL), previously named cholesterol esterase or bile salt-stimulated (or dependent) lipase, is a lipolytic enzyme capable of hydrolyzing cholesteryl esters, tri-, di-, and mono-acylglycerols, phospholipids, lysophospholipids, and ceramide. The active site catalytic triad of serine-histidine-aspartate is centrally located within the enzyme structure and is partially covered by a surface loop. The carboxyl terminus of the protein regulates enzymatic activity by forming hydrogen bonds with the surface loop to partially shield the active site. Bile salt binding to the loop domain frees the active site for accessibility by water-insoluble substrates. CEL is synthesized primarily in the pancreas and lactating mammary gland, but the enzyme is also expressed in liver, macrophages, and in the vessel wall. In the gastrointestinal tract, CEL serves as a compensatory protein to other lipolytic enzymes for complete digestion and absorption of lipid nutrients. Importantly, CEL also participates in chylomicron assembly and secretion, in a mechanism mediated through its ceramide hydrolytic activity. Cell culture studies suggest a role for CEL in lipoprotein metabolism and oxidized LDL-induced atherosclerosis. Thus, this enzyme, which has a wide substrate reactivity and diffuse anatomic distribution, may have multiple functions in lipid and lipoprotein metabolism, and atherosclerosis.     

Identification of two separate allelic mutations in the lipoprotein lipase gene of a patient with the familial hyperchylomicronemia syndrome.

The molecular defects resulting in a deficiency of lipoprotein lipase activity in a patient with the familial hyperchylomicronemia syndrome have been identified. Increased lipoprotein lipase mass but undetectable lipoprotein lipase activity in the patient's post-heparin plasma indicate the presence of an inactive enzyme. No major gene rearrangements were identified by Southern blot analysis of the patient's lipoprotein lipase gene and Northern blot hybridization revealed an lipoprotein lipase mRNA of normal size. Sequence analysis of polymerase chain reaction-amplified lipoprotein lipase cDNA identified two separate allelic mutations. A T to C transition at nucleotide 836 results in the substitution of Ile194, located near the putative interfacial recognition site of lipoprotein lipase, to a Thr. A G to A mutation at base 983 leads to the substitution of a His for Arg243 and the loss of a HhaI restriction enzyme site. Arg243 is near His241, which has been postulated to be part of the catalytic triad of lipoprotein lipase. Direct sequencing of amplified cDNA and digestion with HhaI established that the proband is a compound heterozygote for each base substitution. Transient expression of each of the mutant lipoprotein lipase cDNAs in human embryonal kidney-293 cells resulted in the synthesis of enzymically inactive proteins, establishing the functional significance of the mutations. We conclude that the Ile194 to Thr194 and Arg243 to His243 substitutions occur in lipoprotein lipase regions essential for normal enzyme activity and each mutation results in the expression of a nonfunctional enzyme leading to the hyperchylomicronemia syndrome manifested in the proband.     

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.     

Direct solid phase radioimmunoassay for chicken lipoprotein lipase.

A direct, noncompetitive immunoassay for chicken lipoprotein lipase (LPL) was developed. Antibodies to LPL were purified by immunoadsorption chromatography of goat antisera on an LPL-Sepharose column. Purified anti-LPL immunoglobulins were coupled covalently to hydrophilic polyacrylamide beads by a carbodiimide reagent. An excess amount of these beads was incubated with the sample or the standard to be assayed. The amount of LPL immobilized by the beads was then detected by an excess amount of ¹²⁵I-labeled anti-LPL immunoglobulin. A linear relationship was obtained between the radioactivity bound and the amount of highly purified LPL used as a standard. The range of the assay was from 0.1-1.1 ng LPL. The assay was specific for chicken LPL and showed no cross-reactivity with liver lipase. It does not distinguish heat-inactivated from catalytically active enzyme species. This assay should be useful in studies of lipoprotein lipase where both catalytic activity and enzyme mass need to be quantitated.     

Activation of myocardial neutral triglyceride lipase and neutral cholesterol esterase by cAMP-dependent protein kinase

Lipolysis of intracellular triglycerides in the heart has been shown to be regulated by hormones. However, activation of myocardial triglyceride lipase in a cell-free system has not been directly demonstrated. In the present studies, initial attempts to demonstrate cAMP-dependent activation of triglyceride lipase using the 1,000 X g supernatant fraction (S1) of mouse heart homogenate were unsuccessful, presumably due to the masking effects of high levels of lipoprotein lipase activity even when assayed at pH 7.4 and in the absence of apolipoprotein C-II. Myocardial lipoprotein lipase in the 40,000 X g supernatant fraction was then removed by heparin-Sepharose affinity chromatography. The lipoprotein lipase-free fractions were shown to contain neutral triglyceride lipase and neutral cholesterol esterase of about equal activities. The triglyceride lipase and cholesterol esterase activities fell progressively during preincubation in the presence of 5 mM Mg2+. Additions of cAMP and ATP resulted in 40-70% activation of both triglyceride lipase and cholesterol esterase. The activation was blocked by protein kinase inhibitor and was restored by the addition of exogenous cAMP-dependent protein kinase. Since lipoprotein lipase has no activity toward cholesteryl oleate, activation of cholesterol esterase in untreated S1 was readily demonstrable. Both triglyceride lipase and cholesterol esterase activities were present in homogenates prepared from isolated rat heart myocytes. We conclude that the myocardium contains a hormone-sensitive lipase that is regulated in a fashion similar to that of the adipose tissue enzyme.