Cloning and characterization of human pancreatic lipase cDNA

Pancreatic lipase (triacylglycerol acylhydrolase, EC 3.1.1.3) hydrolyzes dietary long chain triacylglycerol to free fatty acids and monoacylglycerols in the intestinal lumen. In the presence of bile acids, the activity of lipase is stimulated by colipase. As a prelude to studying the relationship of the protein structures to the functional properties of lipase and colipase, a cDNA encoding human pancreatic lipase was isolated from a lambda gt11 cDNA library screened with a rabbit polyclonal anti-human pancreatic lipase antibody. The full length cDNA clone of 1477 base pairs contained an open reading frame encoding a 465-amino acid protein, including a 16-amino acid signal peptide. The nucleotide sequence was 69% identical to the dog pancreatic lipase cDNA. The predicted NH2-terminal protein sequence agreed with the published NH2-terminal sequence of human pancreatic lipase and the predicted protein sequence was 85 and 70% identical to the protein sequences of pig and dog pancreatic lipase, respectively. A region of homology around Ser-153 is conserved in a number of lipid-binding proteins. Human hepatic lipase and lipoprotein lipase share extensive homology with pancreatic lipase, suggesting that the three proteins are members of a small gene family. In vitro translation of mRNA transcribed from the cDNA resulted in a protein of the expected molecular size that could be processed by microsomal membranes to yield a glycolated protein with proper signal peptide cleavage. RNA blot analysis demonstrated tissue specificity for pancreatic lipase. Thus, for the first time, a full length human pancreatic lipase cDNA has been isolated and characterized. The demonstrated regions of homology with other lipases will aid definition of interactions with substrate and colipase through site-specific mutagenesis.     

The catalytic site residues and interfacial binding of human pancreatic lipase.

In this study, the essential serine residue and 2 other amino acids in human pancreatic triglyceride lipase (triacylglycerol acylhydrolase, EC 3.1.1.3) were tested for their contribution to the enzyme's catalytic site or interfacial binding site. By site-specific mutagenesis of the cDNA for human pancreatic lipase, amino acid substitutions were made at Ser153, His264, and Asp177. The mutant cDNAs were expressed in transfected COS-1 cells. Both the medium and the cells were examined for the presence of pancreatic lipase by Western blot analysis. The activity of the expressed proteins against triolein and the interfacial binding was measured. Proteins with mutations in Ser153 were secreted by the cells and bound to interfaces but had no detectable activity. Changing His264 to a leucine or Asp177 to an asparagine also produced inactive lipase. Substituting glutamic acid for Asp177 produced an active protein. These results demonstrate that Ser153 is involved in the catalytic site of pancreatic lipase and is not crucial for interfacial binding. Moreover, the essential roles of His264 and Asp177 in catalysis were demonstrated. A Ser-His-Asp catalytic triad similar to that present in serine proteases is present in human pancreatic lipase.     

Inactivation of human pancreatic lipase by 5-dodecyldithio-2-nitrobenzoic acid.

Both thiol groups of native human pancreatic lipase can react with the new hydrophobic sulfhydryl reagent 5-dodecyldithio-2-nitrobenzoic acid (Dod-S-NbS) in the absence of a denaturing agent. Here we describe for the first time the covalent and stoichiometric modification of the inaccessible SHII group of native pancreatic lipase, using a 16-fold molar excess of this hydrophobic sulfhydryl reagent. A direct correlation was found to exist between the covalent modification of this SHII group and the loss of lipase activity. The question has not yet been answered, however, as to how Dod-S-NbS reaches the SHII-containing residue, whereas classical hydrophilic sulfhydryl reagents are unable to do so. This difference in reactivity may be attributable to the hydrophobic character of Dod-S-NbS and its potential capacity to form aggregates inducing a conformational change in the lipase molecule.     

Exploring the active site cavity of human pancreatic lipase

Within the scope of improving the efficiency of pancreatic enzyme replacement therapy in cystic fibrosis, the feasibility of shifting the pH-activity profile of pancreatic lipase toward acidic values was investigated by site specific mutagenesis in different regions of the catalytic cavity. We have shown that introducing a negative charge close to the catalytic histidine induced a shift of the pH optimum toward acidic values but strongly reduced the lipase activity. On the other hand, a negative charge in the entrance of the catalytic cleft gives rise to a lipase with improved properties and twice more active than the native enzyme at acidic pH.     

Further characterization of bovine pancreatic lipase.

1. The amino acid composition of bovine pancreatic lipase is very similar to that of porcine lipase. 2. Bovine lipase possesses a residue of lysine at the N-terminal position and a half cystine or a cysteine at the C-terminal position. 3. Bovine lipase contains two free sulfhydryl groups of different reactivities to 5, 5'-dithiobis-(2-nitrobenzoic) acid. One of these groups is buried in the native conformation of the enzyme and is fully titrated in 1.5 M urea when reaction is performed in the presense of 1 mM EDTA.     

Transcytosis of pancreatic bile salt-dependent lipase through human Int407 intestinal cells.

In previous studies, we have shown that the bile-salt-dependent-lipase (BSDL), secreted by pancreatic acinar cells and secreted into the duodenal lumen, can be transcytosed through intestinal cells up to the lamina propria. In this study, we used an in vitro system to provide insights into the apical to basolateral transport of BSDL, across the intestinal barrier. The Int407 human epithelial cell line, grown under conditions that optimize polarity, was used as a tight epithelium model. We attempted to delineate uptake mechanisms and the transcytotic pathway followed by this pancreatic enzyme within the intestinal Int407 cells, which do not produce BSDL. When added to the apical reservoir of Transwell-grown Int407 cells, BSDL was shown to first interact with the apical membrane. Further, BSDL forms clusters that are internalized via clathrin-coated pits. Following endocytosis, BSDL is directed to a nocodazole- and colchicin-sensitive multivesicular compartment. Interestingly, this protein transits through the Golgi apparatus, where it was found to colocalize with the KDEL retrieval-receptor. Finally, enzymatically active intact BSDL was released at the basolateral membrane level. This is the first demonstration for an apical-to-basolateral transcytotic pathway of a secreted pancreatic digestive enzyme through polarized intestinal cells.     

Human pancreatic lipase: a glycoprotein.

Human lipase has been purified from pancreatic juice. The protein has a molecular weight of 48 000 and an N-terminal residue of lysine. It has been characterized as a glycoprotein containing 4.7 mol of glucosamine, 2.8 mol of mannose, 2.9 mol of fucose, 3.0 mol. of galactose and 1.1 mol of glucose per mol of protein. Two isolipases have been separated by polyacrylamide gel electrophoresis. Their isoelectric points are 5.80 and 5.85, respectively and both are glycoproteins. Immunological cross reactions have been obtained between human lipase and other mammalian lipases (porcine, bovine, ovine, canine and rat).     

Fatty acids generated by gastric lipase promote human milk triacylglycerol digestion by pancreatic colipase-dependent lipase

The concerted action of purified bovine gastric lipase and human pancreatic colipase-dependent lipase and colipase, or crude human pancreatic juice, in the digestion of human milk triacylglycerols was explored in vitro. Gastric lipase hydrolyzed milk triacylglycerol with an initially high rate but became severely inhibited already at low concentration of released fatty acid. In contrast, colipase-dependent lipase could not, by itself, hydrolyze milk triacylglycerol. However, a short preincubation of milk with gastric lipase, resulting in a limited lipolysis, made the milk fat triacylglycerol available for an immediate and rapid hydrolysis by pancreatic juice, and also for purified colipase-dependent lipase, provided colipase and bile salts were present. The same effect was obtained when incubation with gastric lipase was replaced by addition of long-chain fatty acid. Long-chain fatty acid increased the binding of colipase-dependent lipase to the milk fat globule. Binding was efficient only in the presence of both fatty acid and colipase. We conclude that a limited gastric lipolysis of human milk triacylglycerol, resulting in a release of a low concentration of long-chain fatty acids, is of major importance for the subsequent hydrolysis by colipase-dependent lipase in the duodenum.     

Serum pancreatic lipase activity in cystic fibrosis.

Patients with cystic fibrosis have been found to have abnormal serum concentrations of immunoreactive trypsin and abnormal activities of pancreatic isoamylase. A study was undertaken to discover whether activity of pancreatic lipase is also altered in cystic fibrosis. Serum from 23 patients with cystic fibrosis was assayed for immunoreactive trypsin and pancreatic lipase. Median serum pancreatic lipase activity was significantly lower in patients with cystic fibrosis than in controls, as was immunoreactive trypsin concentration (p less than 0.0001). Some patients had supranormal lipase concentrations but these were not always associated with absence of malabsorption. Serum pancreatic lipase activity is considerably changed in cystic fibrosis.     

The lipase C-terminal domain. A novel unusual inhibitor of pancreatic lipase activity

In vertebrates, dietary fat digestion mainly results from the combined effect of pancreatic lipase, colipase, and bile. It has been proposed that in vivo lipase adsorption on oil-water emulsion is mediated by a preformed lipase-colipase-mixed micelle complex. The main lipase-colipase binding site is located on the C-terminal domain of the enzyme. We report here that in vitro the isolated C-terminal domain behaves as a potent noncovalent inhibitor of lipase and that the inhibitory effect is triggered by the presence of micelles. Lipase inhibition results from the formation of a nonproductive C-terminal domain-colipase-micelle ternary complex, which competes for colipase with the active lipase-colipase-micelle ternary complex, thus diverting colipase from its lipase-anchoring function. The formation of such a complex has been evidenced by molecular sieving experiments. This nonproductive complex lowers the amount of active lipase thus reducing lipolysis. Preliminary experiments performed in rats show that the C-terminal domain also behaves as an inhibitor in vivo and thus could be considered a potential new tool for specifically reducing intestinal lipolysis.     

Two novel human pancreatic lipase related proteins, hPLRP1 and hPLRP2. Differences in colipase dependence and in lipase activity.

We have isolated cDNAs coding for two novel human pancreatic lipase (hPL)-related human proteins, referred to as hPL-related proteins 1 and 2 (hPLRP1 and hPLRP2) and for hPL. The two novel proteins show an amino acid sequence identity to hPL of 68 and 65% for hPLRP1 and 2, respectively. All three proteins are secreted into the medium after transfection of COS cells with the corresponding cDNAs. The size of the three expressed proteins is similar and ranges between 45 and 50 kDa. The expressed hPLRP2 shows a lipolytic activity that is, however, in contrast to that of hPL only marginally dependent on the presence of colipase, whereas hPLRP1 shows no activity in this assay. A Northern analysis of normal human pancreas mRNA shows that the expression levels of hPLRP1 and hPLRP2 are about 4-fold and 24-fold lower, respectively, than that of hPL. hPLRP2 is, additionally, most closely related to a lipase reported to be expressed in mouse T-cells. A comparison of the sequences of the three proteins with sequences described as pancreatic lipases of other animal species shows three subfamilies of closer kinship. This suggests that the two novel proteins also exist in other species and that some of the sequences reported to be pancreatic lipase might more likely be the orthologues of hPLRP1 or hPLRP2 in those species.     

Identification of the active-site serine in human pancreatic lipase by chemical modification with tetrahydrolipstatin.

A chemical modification approach was used in this study to identify the active site serine residue of human pancreatic lipase. Purified human pancreatic lipase was covalently modified by incubation with [3H], [14C] tetrahydrolipstatin (THL), a potent inhibitor of pancreatic lipase. The radiolabeled lipase was digested with thermolysin, and the peptides were separated by HPLC. A single THL-peptide-adduct was obtained which was identical to that obtained earlier from porcine pancreatic lipase. This pentapeptide with the sequence VIGHS is covalently bound to a THL molecule via the side chain hydroxyl group of the serine unit corresponding to Ser-152 of the lipase. The selective cleavage of the THL-serine bond by mild acid treatment resulted in the formation of the delta-lactone Ro 40-4441 in high yield and clearly proves that THL is attached via an ester bond and with retention of stereochemistry at all chiral centers to the side chain hydroxyl group of Ser-152 of the lipase. The results obtained for human pancreatic lipase corroborate the inhibition mechanism of THL found on the porcine enzyme, and are in full agreement with the identification of the Ser-152 ... His-263 ... Asp-176 catalytic triad in the X-ray structure of human pancreatic lipase.     

Hydrolysis of triacylglycerol arachidonic and linoleic acid ester bonds by human pancreatic lipase and carboxyl ester lipase

The hydrolysis of polyenoic fatty acid ester bonds with pure human colipase-dependent lipase, with carboxyl ester lipase (CEL) and with these enzymes in combination was studied, using [3H]arachidonic- and [14C]linoleic acid-labelled rat chylomicrons as a model substrate. During the hydrolysis with colipase-dependent lipase, the amount of 3H appearing in 1,2-X-diacylglycerol (DG) markedly exceeded that of 14C. When CEL was added in addition this [3H]DG was efficiently hydrolyzed. CEL alone hydrolyzed the triacylglycerol (TG) at a low rate. The hydrolysis pattern with human duodenal content was similar to that seen with colipase-dependent lipase and CEL in combination. Increasing the concentration of taurodeoxycholate (TDC) and taurocholate (TC) or of TDC alone stimulated the hydrolysis of [3H]- and [14C]TG, but increased the accumulation of labelled DG that could act as substrate for CEL. It is suggested that very-long-chain polyenoic fatty acids of DG formed during the action of the colipase-dependent lipase on TG containing these fatty acids may be a physiological substrate for CEL.     

Ovine pancreatic lipase : purification and some properties.

Lipase has been isolated from sheep pancreas. The lipoprotein complex formed in pancreas homogenates by the enzyme and endogenous lipids is split by treatment with acetone. Lipase is further purified by ion-exchange chromatography and gel filtration. The molecular weight and the amino-acid composition of ovine lipase are very similar to that of the porcine and bovine enzymes. As previously found in bovine lipase, no carbohydrate is covalently bound to the polypeptide chain which has a N-terminal residue of lysine. The study of the catalytic properties of ovine pancreatic lipase indicates that the enzyme is fully activated by colipase from various species in the presence of conjugated bile salt micellar solutions.     

Purification of rat pancreatic lipase

A procedure for the isolation of lipase (glycerolester hydrolase, EC 3.1.1.3) from rat pancreas is described. The purification scheme includes homogenization of the pancreas, centrifugation at 3,000 rpm, centrifugation at 40,000 rpm, DEAE-cellulose chromatography, precipitation of amylase as the amylase-glycogen complex, gel filtration of the amylase-free proteins on Sephadex G-100, and chromatography on carboxymethyl-Sephadex C-50. The enzyme showed only one band on polyacrylamide gel electrophoresis and had a specific activity of 5330 +/- 80 units/mg of protein.     

Conformational states of pancreatic lipase

Spin-label method was applied to the studies of conformation properties of pancreatic lipase. Spin-labelled derivatives of the enzyme in SH- and NH2-groups were obtained. ESR-spectra of both samples belong to the immobilized type, in the first case the ESR-spectrum corresponding to strong immobilization of the spin-label, and in the second--to the average one. In both cases the rotation correlation time of the enzyme molecule was measured. The time proved the same independent of the site of the label attachment; it corresponded to the rotation of macromolecule with molecular weight 50000. This fact points to the absence of both intramolecular flexibility of the enzyme molecule and of the association of lipase molecules in solution. It has been shown that introduction of substrates and inhibitors of the enzyme and the interface as well, induces no changes in the ESR spectra, which points to the absence of local conformation changes of protein near the spin-labels introduced.