Structure of bovine milk lipoprotein lipase

The primary structure of bovine milk lipoprotein lipase (bLPL) was determined by alignment of peptides produced by tryptic digestion, Staphylococcus aureus V8 protease digestion, and cyanogen bromide cleavage. bLPL consists of 450 amino acid residues. Most tryptic peptides were isolated and analyzed, except for the dipeptide, Glu-Lys (position 423-424), and the 2 Lys at positions 416 and 488. Peptides resulting from digestion by S. aureus V8 protease and cyanogen bromide cleavage filled the missing part and completed the primary sequence of bLPL. The NH2 terminus of bLPL was determined to be Asp by sequencing the intact protein with a gas phase sequencer for up to 30 residues, whereas the COOH terminus was identified as Gly through, carboxyl peptidase Y cleavage. The enzyme contains 10 cysteine residues, all of which exist in disulfide linkages. They are formed between Cys29 and Cys42, Cys218 and Cys241, Cys266 and Cys285, Cys277, and Cys280, and Cys420 and Cys440. The sites of N-glycosylation were identified at Asn44 and Asn361. In accordance with a common structural homology of serine-type esterases, -G-X-S-X-G- (Yang, C. Y., Manoogian, D., Pao, Q., Lee, F., Knapp, R. D., Gotto, A. M., Jr., and Pownall, H. J. (1987) J. Biol. Chem., 262, 3086-3191), the active site serine of bLPL was assigned to the serine at position 134. The chymotrypsin nick of bLPL was determined to be between residues 390 and 391. A model of the enzyme is proposed on the basis of our data and available chemical data.     

The effects of bovine serum albumin and oleic acid on rat pancreatic lipase and bovine milk lipoprotein lipase

The effects of bovine serum albumin on rat pancreatic lipase and bovine milk lipoprotein lipase were studied in a system of triacylglycerol emulsions stabilized by 1 1 mg/ml albumin. At concentrations greater than 1 mg/ml, albumin inhibited the activity of pancreatic lipase and interfered with enzyme binding to emulsified triacylglycerol particles. These effects could be countered by occupying five fatty acid binding sites on albumin with oleic acid. Following an initial lag period which increased with albumin concentrations, enzyme activity escaped from inhibition presumably due to saturation of fatty acid sites on albumin with oleic acid. Pancreatic lipase was active at 1 mg/ml albumin and 1 mM emulsion-bound oleic acid in the system. The effects of albumin on lipoprotein lipase were diametrically opposed to the above; enzyme activity was completely inhibited by 0.1 mM oleic acid, it increased with increasing fatty acid-free albumin concentrations and decreased as the fatty acid sites on albumin were filled. At 1 mM oleic acid and no added albumin the enzyme failed to bind at the oil water interface, whereas fatty acid-free or saturated albumin had no effect on binding. It is concluded that if the inhibition of pancreatic lipase by albumin is due to the inaccessibility of the enzyme to an oil-water interface blocked by denatured albumin, then albumin saturated with oleic acid would seem to be protected from unfolding at the interface and more readily displaced by the lipase. Pancreatic lipase and lipoprotein lipase, although sharing a number of common features, are distinct enzymes both functionally and mechanistically.     

Kinetics of bovine milk lipoprotein lipase and the mechanism of enzyme activation by apolipoprotein C-II

The kinetics of bovine milk lipoprotein lipase (LPL) were studied in order to determine the reaction mechanism of this enzyme. Reaction velocities were determined at varying concentrations of emulsified trioleoylglycerol (TG) and different fixed concentrations of apolipoprotein C-II (C-II) or at varying C-II concentrations and different fixed concentrations of TG. Neither the apparent Km(TG) nor the apparent Km(C-II) was affected by varying the concentrations of C-II or TG, respectively. However, C-II increased the apparent Vmax for the enzyme about 20-fold. The following kinetic parameters were calculated from Lineweaver-Burk plots: Km(C-II) = 2.5 X 10(-8) M and Km (TG) = 2.5 X 10(-3) M. The dissociation constant (KS) of the enzyme-TG binary complex was determined from Scatchard plots to be 7.6 X 10(-8) M. Heparin was found to be a competitive dead-end inhibitor against both TG and C-II. Tricapryloylglycerol represented a competitive inhibitor against TG but a noncompetitive inhibitor against C-II. C-II was shown to interact with dansylated bovine milk LPL, increasing its fluorescent emission by inducing a conformational change in the enzyme. Based on these studies, it was concluded that the LPL-catalyzed reaction follows a random, bireactant, rapid-equilibrium mechanism and the role of C-II in the activation process involves an increase in the catalytic rate constant (Kp) resulting from conformational changes of LPL induced by C-II.     

Immunological studies on bovine milk lipoprotein lipase. Effects of Fab fragments on enzyme activity

Rabbit antiserum was prepared against purified bovine mild lipoprotein lipase. Immunoelectrophoresis of lipoprotein lipase gave a single precipitin line against the antibody which was coincident with enzyme activity. The gamma-globulin fraction inhibited heparin-releasable lipoprotein lipase activity of bovine arterial intima, heart muscle and adipose tissue. The antibody also inhibited the lipoprotein lipase activity from adipose tissue of human and pig, but not that of rat and dog. Fab fragments were prepared by papain digestion of the gamma-globulin fraction. Fab fragments inhibited the lipoprotein lipase-catalyzed hydrolysis of dimyristoylphosphatidylcholine vesicles and trioleoylglycerol emulsions to the same extent. The Fab fragments also inhibited the lipolysis of human plasma very low density lipoproteins. The change of the kinetic parameters for the lipoprotein lipase-catalyzed hydrolysis of trioleoylglycerol by the Fab fragments was accompanied with a 3-fold increase in Km and a 10-fold decrease in Vmax. Preincubation of lipoprotein lipase with apolipoprotein C-II, the activator protein for lipoprotein lipase, did not prevent inhibition of enzyme activity by the Fab fragments. However, preincubation with dipalmitoylphosphatidylcholine-emulsified trioleoylglycerol or Triton X-100-emulsified trioleoylglycerol had a protective effect (remaining activity 7.0 or 25.8%, respectively, compared to 1.0 or 0.4% with no preincubation). The addition of both apolipoprotein C-II and substrate prior to the incubation with the Fab fragments was associated with an increased protective effect against inhibition of enzyme activity; remaining activity with dipalmitoylphosphatidylcholine-emulsified trioleoylglycerol was 40.6% and with Triton X-100-emulsified trioleoylglycerol, 45.4%. Human plasma very low density lipoproteins also protected against the inhibition of enzyme activity by the Fab fragments. These immunological studies suggest that the interaction of lipoprotein lipase with apolipoprotein C-II in the presence of lipids is associated with a conformational change in the structure of the enzyme such that the Fab fragments are less inhibitory. The consequence of a conformational change in lipoprotein lipase may be to facilitate the formation of an enzyme-triacylglycerol complex so as to enhance the rate of the lipoprotein lipase-catalyzed turnover of substrate to products.     

Kinetics of human and bovine milk lipoprotein lipase and the mechanism of enzyme activation by apolipoprotein C-II

The kinetics of human and bovine milk lipoprotein lipase (HM-LPL and BM-LPL, respectively) were compared by varying apolipoprotein C-II (C-II) or triacylglycerol (TG) concentrations. The apparent Km (TG) and Km (C-II) for HM-LPL were 2.2 and 6.7-fold higher than for BM-LPL. Plots of 1/v vs 1/[TG] or 1/[C-II] intercepted the respective abscissas at the same points: C-II had no effect on Km (TG) and TG had no effect on Km (C-II). Replots of slope 1/s vs 1/[C-II] gave straight lines which yielded KA values identical to Km (C-II). It is concluded that the HM-LPL system follows a random, bireactant, rapid equilibrium mechanism as shown previously for BM-LPL.     

Comparison of the phospholipase activity of bovine milk lipoprotein lipase against rat plasma very low density and high density lipoprotein.

The hydrolytic activity of a lipoprotein lipase from bovine milk against triacylglycerol and phosphatidylcholine of rat plasma very low density lipoprotein was determined and compared to that against phosphatidylcholine of high density lipoprotein. 85--90% of the triacylglycerol in very low density lipoprotein were hydrolyzed to fatty acids and 25--35% of the phosphatidylcholine to lysophosphatidylcholine. High density lipoprotein phosphatidylcholine was only minimally susceptible to the enzyme. Even with high amounts of enzyme and prolonged incubation periods, lysophosphatidylcholine generation did not exceed 2--4% of the original amounts of labeled phosphatidylcholine in the high density lipoprotein. We conclude that phospholipids in high density lipoprotein are not substrates for the phospholipase activity of this lipoprotein lipase. These observations suggest that factors other than the presence of apolipoprotein C-II and of glycerophosphatides are of importance for the activity of lipoprotein lipases.     

Characterization of serum-stimulated lipoprotein lipase from bovine heart

1. A triglyceride (TG) lipase is present in whole homogenate and tissue extracts of beef myocardium with characteristics of lipoprotein lipase (LPL); i.e., activity is stimulated by serum, inhibited by NaCl and protamine sulfate, the protein binds to heparin-Sepharose, and the enzyme has an alkaline pH optimum. 2. This TG lipase, eluted from heparin-Sepharose at 0.9-1.0 M NaCl, has an apparent mol. wt of 64 K daltons. Its primary mRNA is 3.7 kb. 3. Expression of LPL mRNA and enzyme activities are in the ratio of approximately 20:8:1 for hearts of mouse, rat and beef, respectively and correlate with r = +0.99.     

The low density lipoprotein receptor-related protein/alpha 2-macroglobulin receptor binds and mediates catabolism of bovine milk lipoprotein lipase.

Lipoprotein lipase (LPL), the major lipolytic enzyme involved in the conversion of triglyceride-rich lipoproteins to remnants, was found to compete with binding of activated alpha 2-macroglobulin (alpha 2M*) to the low density lipoprotein receptor-related protein (LRP)/alpha 2-macroglobulin receptor. Bovine milk LPL displaced both 125I-labeled alpha 2M* and 39-kDa alpha 2M receptor-associated protein (RAP) from the surface of cultured mutant fibroblasts lacking LDL receptors with apparent KI values at 4 degrees C of 6.8 and 30 nM, respectively. Furthermore, LPL inhibited the cellular degradation of 125I-alpha 2M* at 37 degrees C. Because both alpha 2M* and RAP interact with LRP, these data suggest that LPL binds specifically to this receptor. This was further supported by observing that an immunoaffinity-isolated polyclonal antibody against LRP blocked cellular degradation of 125I-LPL in a dose-dependent manner. In addition, 125I-LPL bound to highly purified LRP in a solid-phase assay with a KD of 18 nM, and this binding could be partially displaced with alpha 2M* (KI = 7 nM) and RAP (KI = 3 nM). Taken together, these data establish that LPL binds with high affinity to LRP and undergoes LRP-mediated cellular uptake. The implication of these findings for lipoprotein catabolism in vivo may be important if LRP binding is preserved when LPL is attached to lipoproteins. If so, LPL might facilitate LRP-mediated clearance of lipoproteins.     

Monoclonal antibodies to bovine milk lipoprotein lipase. Evidence for proteolytic degradation of the native enzyme

Lipoprotein lipase was purified from bovine skim milk by chromatography on heparin-Sepharose. Polyacrylamide gel electrophoresis showed a single protein with an apparent molecular weight of 55,000 in the trailing edge of the elution profile; fractions in the leading edge contained additional proteins with molecular weights of 36,000 and 18,000-22,000. Nine monoclonal antibodies were prepared against the 55,000-dalton protein. By immunoblotting, we show that the Mr = 18,000-22,000 components share common antigen determinants with the 55,000-dalton protein, suggesting that they represent proteolytic degradation products. Incubation of partially purified lipoprotein lipase for 24 h at 37 degrees C results in breakdown of the 55,000-dalton protein with concomitant enrichment in lower Mr components; the proteolytic activity is prevented by incubating the milk with phenylmethane, sulfonyl fluoride prior to chromatography on heparin-Sepharose. This study shows the presence of milk proteases which co-purify and degrade lipoprotein lipase. We suggest that this degradation could account for part of the known instability of the enzyme.     

Isolation of an active-site peptide of lipoprotein lipase from bovine milk and determination of its amino acid sequence

Lipoprotein lipase from bovine milk reacted stoichiometrically with diisopropylphosphorofluoridate (DFP), an inactivator of serine esterases, resulting in the loss of enzymatic activity against triacylglycerols. The reaction obeyed first-order kinetics with a rate constant of 0.69 h-1. In order to isolate the peptide containing the diisopropylphosphoryl moiety (DIP), partially purified lipoprotein lipase was covalently labeled with [3H]DFP, and the labeled protein was reduced, carboxymethylated, and further purified to about 90% homogeneity. Cyanogen bromide cleavage followed by gel filtration yielded a radioactive peptide of 6-8 kDa. This peptide was succinylated and then digested with Staphylococcus aureus V8 proteinase. From this digest, a peptide containing 0.95 mol of [3H] DIP/mol of peptide was isolated by gel-permeation chromatography followed by reverse-phase high performance liquid chromatography. Automated Edman degradation provided the following sequence: Ala-Ile-Gly-Ile-His-Trp-Gly-Gly- (DIP)Ser-Pro-Asn-Gln-Lys-Asn-Gly-Ala-Val-Phe-Ile-Asn-(Ser, Leu)-Glu. Analysis of the sequence for secondary structure suggests that the reactive serine of lipoprotein lipase is in a beta-turn, a structure similar to those of the active sites of most other serine proteinases. Lipoprotein lipase appears to share this secondary structure with other serine hydrolases despite significant differences in the primary structure of this domain.     

Phospholipase activity of bovine milk lipoprotein lipase on phospholipid vesicles: influence of apolipoproteins C-II and C-III.

The effect of human plasma apolipoproteins C-II and C-III on the hydrolytic activity of lipoprotein lipase from bovine milk was determined using dimyristoyl phosphatidylcholine (DMPC) vesicles as substrate. In the absence of apoC-II or C-III, lipoprotein lipase has limited phospholipase activity. When the vesicles were preincubated with apoC-II and then phospholipase activity determined, there was a time dependent release of lysolecithin; activity was dependent upon both apoC-II and lipoprotein lipase concentrations. The addition of apoC-III to DMPC did not stimulate phospholipase activity. We conclude that apoC-II has an activator effect on the phospholipase activity of lipoprotein lipase and that the mechanism is beyond that of simply altering the lateral compressibility of the lipid.     

Kinetics of acylglycerol hydrolysis by human milk lipoprotein lipase

The incubation of human plasma very-low-density lipoprotein with human milk lipoprotein lipase results in an almost complete hydrolysis of triacylglycerols. The degradation of these substrates can be described by a consecutive reaction as follows: (Formula: see text), where k1, k2 and k3 are the apparent first-order rate constants of degradation. Using least-squares non-linear curve fitting, k1 and k2 are determined to be directly proportional to enzyme concentration. k1/k2 ratio of 1:12 is similar for both VLDL and trioleoylglycerol substrates of lipoprotein lipase. However, when trioleoylglycerol and rac-1,2-dioleoylglycerol are used as substrates, a direct measurement indicates a k1/k2 ratio of 1:1.5. This result suggests that the intermediary diacylglycerol produced by the lipoprotein reaction is incompletely re-equilibrated with the bulk of the substrate in the assay mixture. The k3 value is not proportional to lipoprotein lipase concentration, and in the enzyme concentration range studied, the value decreases when the enzyme concentration increases.     

Immunologic and enzymatic comparisons between human and bovine lipoprotein lipase

Studies were conducted to compare human and bovine lipoprotein lipase (LPL) preparations with regard to immunological cross-reactivity and substrate specificity. LPL was partially purified from human milk. An antiserum against the human LPL preparation was produced in a goat. This antiserum inhibited LPL enzymatic activity in human milk and in human post-heparin plasma. Neither bovine milk nor bovine post-heparin plasma LPL enzymatic activity was inhibited by this antiserum. These findings suggest that there are significant structural differences between the human and bovine enzymes in domains that are involved in enzymatic activity. Human and bovine post-heparin plasma and partially purified preparations of LPL from human and bovine milk were compared with regard to substrate specificity, by comparing their lipolytic activities against triglyceride, cholesteryl esters, and retinyl esters. Only the partially purified bovine milk LPL preparation possessed retinyl palmitate hydrolase activity. The results suggest that this latter activity may be the result of a previously unrecognized contaminant in the commonly used LPL preparations from bovine milk.     

Monoclonal antibodies against bovine milk lipoprotein lipase. Characterization of an antibody specific for the apolipoprotein C-II binding site

Ten murine monoclonal antibodies have been produced that are specific for bovine milk lipoprotein lipase. One monoclonal antibody, bLPL-mAb-7, inhibited completely the apolipoprotein C-II (apo-C-II)-dependent enzymic hydrolysis of trioleoylglycerol in a phospholipid-stabilized emulsion, but had no effect on the hydrolysis of the water-soluble substrate p-nitro-phenylacetate. Four times more bLPL-mAb-7 was required to achieve 50% inactivation of lipoprotein lipase activity when the enzyme was preincubated with excess apo-C-II. Disruption of the binding of a dansyl-labeled apo-C-II peptide to lipoprotein lipase by bLPL-mAb-7 was demonstrated by resonance energy transfer, both in the presence and absence of lipid. This antibody thus appears to recognize the apo-C-II binding site of lipoprotein lipase. In addition, bLPL-mAb-7 also inhibited the lipoprotein lipase activity of human post-heparin plasma.