Comparative studies of human and porcine pancreatic lipases : N-terminal sequences, sulfhydryl groups and interfacial activity

Screening of Gastrointestinal Lipase Inhibitors Produced by Microorganisms Isolated from Soil and Lake Sediments

Gastrointestinal lipase inhibitors are molecules of pharmaceutical interest due to their use as anti-obesity drugs. In this study, forty strains isolated from soil and sediments were identified with the ability to produce inhibition of gastrointestinal lipase activity. The biomass extract of these strains showed at least 50% inhibition in the hydrolysis of tributyrin by recombinant human pancreatic lipase (rHPL) or rabbit gastric lipase (RGL) by in vitro assays. Based on gene sequencing, the isolates were identified mainly as Streptomycetes. Moreover, none of the identified strains has been reported to be lipase inhibitor producers, so they can be viewed as potential sources for obtaining new drugs. IC₅₀ values of the three best inhibitor extracts showed that AC104-10 was the most promising strain for production of gastrointestinal lipase inhibitors. AC104-10 shows 99% homology (16S rRNA gene fragment) to Streptomyces cinereoruber strain NBRC 12756. An inhibitory study over trypsin activity revealed that AC104-10 extract, as well as THL, had no significant effect on the activity of this protease, showing its specificity for lipases. In addition, analyzes by MALDI-TOF mass spectrometry of the enzyme-inhibitor complex revealed that there is a covalent interaction of the AC104-10 inhibitor with the catalytic serine of the pancreatic lipase, and that the molecular weight of the inhibitor is approximately 686.19 Da.

A novel protocol for the preparation of active recombinant human pancreatic lipase from Escherichia coli

An active recombinant human pancreatic lipase (recHPL) was successfully prepared for the first time from the Escherichia coli expression system using short Strep-tag II (ST II). The recHPL-ST II was solubilized using 8 M urea from E.coli lysate and purified on a Strep-Tactin-Sepharose column. After refolding by stepwise dialyses in the presence of glycerol and Ca2+ for 2 days followed by gel filtration, 1.8-6 mg of active recHPL-ST II was obtained from 1 L of culture. The recHPL was non-glycosylated, but showed almost equal specific activity, pH-dependency and time-dependent stability compared to those of native porcine pancreatic lipase (PPL) at 37°C. However, the recHPL lost its lipolytic activity above 50°C, showing a lower heat-stability than that of native PPL, which retained half its activity at this temperature.

Modulating the activity of avian pancreatic lipases by an alkyl chain reacting with an accessible sulfhydryl group

Both turkey (TPL) and chicken (CPL) pancreatic lipases possess only one exposed sulfhydryl residue (Cystein114). After preincubation with the lipase, the sulfhydryl reagent C12 -TNB was found to be a powerful inhibitor of TPL whereas it had no effect on the CPL activity. Based on the 3D structure modelling and the molecular dynamics, the bulky dodecyl chain might hamper the lid movement of the TPL leading to the lipase inhibition upon reaction with C12 -TNB. Meanwhile, the predicted position of the C12 chain linked to Cystein114 of CPL could not block the lid opening mechanism which explains the absence of inhibition by C12 -TNB. Surprisingly, when added during the substrate hydrolysis, C12 -TNB activated the TPL but not the CPL that was slightly inhibited under these conditions. The 3D structure model generated for the open forms of C12 -TPL and C12 -CPL complexes showed that Cystein114 is still accessible and might react with C12 -TNB. Our models clearly explain the activation of TPL and the partial inhibition of CPL after the binding of the C12 chain to the enzyme.

Purification and partial characterization of feline classical pancreatic lipase

Classical pancreatic lipase has been purified and partially characterized in many species. The objective of this project was to purify feline classical pancreatic lipase (fPL) from pancreatic tissue and partially characterize this protein. Pancreata were collected from cats (Felis catus) euthanized for unrelated research projects. Fat was removed by trimming away grossly visible fat and by extraction in organic solvents. The delipidated pancreatic extract was further purified by extracting the enzymes in a Tris-buffer containing two different protease inhibitors, benzamidine and phenylmethylsulfonyl fluoride, followed by anion-exchange, size-exclusion, and cation-exchange chromatography. Feline pancreatic lipase was successfully purified from feline pancreatic tissue. The purified product showed a single band on sodium dodecyl sulfate polyacrylamide gel electrophoresis with a molecular mass of approximately 52.5 kDa. Exact molecular mass was determined by mass spectrometry as 52.4 kDa. Approximate specific absorbance at 280 nm of fPL was 1.18 for a 1 mg/ml solution. N-terminal amino acid sequence of the first 25 amino acid residues showed the sequence Lys-Glu-Ile-?-Phe-Pro-Arg-Leu-Gly-?-Phe-Ser-Asp-Asp-Ala-Pro-Trp-Ala-Gly-Ile-Ala-Gln-Arg-Pro-Leu. This sequence showed close homology with the amino acid sequence of classical pancreatic lipase in other species.

Inactivation of pancreatic lipases by amphiphilic reagents 5-(dodecyldithio)-2-nitrobenzoic acid and tetrahydrolipstatin. Dependence upon partitioning between micellar and oil phases

We have reported previously that Cys103 (SHII) of human pancreatic lipase (HPL), unlike the nonessential Cys181 (SHI), was buried and inaccessible to classical water-soluble sulfhydryl reagents. The lipolytic activity of HPL was lost after the labeling of the above two SH groups with the amphiphilic sulfhydryl reagent, 5-(dodecyldithio)-2-nitrobenzoic acid (C12-TNB), suggesting that the SHII residue may play an important role in the hydrolytic process [Gargouri, Y., Cudrey, C., Medjoub, H., & Verger, R. (1992) Eur. J. Biochem. 204, 1063-1067]. For the present experiments, we selected dog pancreatic lipase (DPL), purifying it for the first time, and recombinant guinea pig pancreatic lipase (r-GPL), which both contain a buried SHII group but no accessible SHI group. The single SHII of DPL and r-GPL reacted only with the amphiphilic SH reagent (C12-TNB), and its labeling was correlated with a rapid lipase inactivation. Although it is spatially remote from the catalytic triad, the SHII group of pancreatic lipases, when chemically labeled, was found to be responsible for the loss of their lipolytic activity. The presence of a bulky dodecyl chain, linked by a disulfide bond to the SHII, may have prevented the critical beta-5 loop (residues 76-85) movement by steric hindrance and consequently disturbed the formation of the oxyanion hole. Thus, pancreatic lipase inactivation by the amphiphilic sulfhydryl reagent can be said to be due to the prevention of a productive induced fit. Tetrahydrolipstatin (THL) is an amphiphilic inactivator reacting with the essential serine of the lipase active site.(ABSTRACT TRUNCATED AT 250 WORDS)

Kinetics and mechanisms of reactions catalysed by immobilized lipases

This review focuses on the kinetics and mechanisms of reactions catalysed by immobilized lipases. The effects of pH, temperature, and various substances on the catalytic properties of immobilized lipases and on the processes by which they are deactivated are reviewed and discussed.

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.

Inactivation of pancreatic and gastric lipases by tetrahydrolipstatin and alkyl-dithio-5-(2-nitrobenzoic acid). A kinetic study with 1,2-didecanoyl-sn-glycerol monolayers

We studied the covalent inhibition of lipases by the monolayer technique. We report the inactivation of porcine pancreatic and human and rabbit gastric lipases, acting on mixed monomolecular films of dicaprin containing tetrahydrolipstatin or new hydrophobic disulfide compounds, which can be described as a 'poisoned-interface' system. A kinetic model is presented for depicting the covalent inactivation of lipolytic enzymes at a lipid/water interface. The stoichiometry of the interfacial situation can be described as follows: one lipase molecule embedded among 10(5) substrate molecules will be inactivated to half its initial velocity by the presence of 10 tetrahydrolipstatin molecules. This inactivation was independent of the surface pressure. When tested in the form of mixed films, all the disulfide compounds investigated specifically reduced the hydrolysis of 1,2-didecanoyl-sn-glycerol films by gastric lipases, but did not affect hydrolysis by pancreatic lipase. With this poisoned-interface system, tetrahydrolipstatin was found to be the most potent inactivator, whereas disulfide compounds showed a higher degree of selectivity than tetrahydrolipstatin.

Crystallization and preliminary X-ray study of horse pancreatic lipase

Horse (Equus caballus) pancreatic lipase (EC 3.1.1.3) has been crystallized using the hanging drop method of vapour diffusion at 20 degrees C. The best crystals were grown from an 8 mg/ml solution in 10 to 20% (w/v) polyethylene glycol 8000, 10 mM-MgCl2, 0.1 M-NaCl, 0.1 M-Mes buffer (pH 5.6). They reach dimensions of 0.8 mm x 0.4 mm x 0.6 mm. X-ray examination of the lipase crystals shows that they are orthorombic with a space group P2(1)2(1)2(1). Their cell dimensions are a = 79.8 A, b = 97.2 A c = 145.3 A. Two molecules per asymmetric unit give a Vm value of 2.82 A3/dalton (56% water content). Lipase crystals strongly diffract to at least 1.8 A resolution. Some molecular properties of horse lipase compared to those of the better-known porcine enzyme are also presented.

Recent advances in the purification, characterization and structure determination of lipases

Recently, lipases have been purified from mammalian, bacterial, fungal and plant sources by different methodologies. Purified lipases subsequently have been characterized for molecular size, metal binding capabilities, glycoside and phosphorus contents, and substrate specificities. Primary structures of several lipases have been determined either from amino acid or nucleic acid sequences. Lipases sequenced to date share sequence homologies including a significant region, Gly-X-Ser-X-Gly, that is conserved in all. The Ser residue is suspected to be essential for binding to lipid substrates.

Minireview on pancreatic lipase and colipase

By hydrolyzing the dietary triacylglycerols, pancreatic lipase causes catalysis in heterogeneous medium. In vivo, lipase action cannot take place without colipase due to the presence of bile salts. The cofactor enables lipase anchoring to the water-lipid interface. The lipase-colipase system furnishes an excellent example of specific interactions (protein-protein and protein-lipid). The studies of lipase catalytic properties brought to light the importance of certain parameters related to the 'quality of the interface'. The structure-function relationship analyses revealed a certain number of functional amino acid residues in lipase and colipase involved either in the catalytic site of the enzyme or in the recognition sites (lipase-colipase and protein-interface). Comparisons of the sequences of lipases derived from different sources display interesting similarities in certain cases.

Partial amino acid sequence of human pancreatic stone protein, a novel pancreatic secretory protein

Pancreatic stone protein (PSP) is the major organic component of human pancreatic stones. With the use of monoclonal antibody immunoadsorbents, five immunoreactive forms (PSP-S) with close Mr values (14,000-19,000) were isolated from normal pancreatic juice. By CM-Trisacryl M chromatography the lowest-Mr form (PSP-S1) was separated from the others and some of its molecular characteristics were investigated. The Mr of the PSP-S1 polypeptide chain calculated from the amino acid composition was about 16,100. The N-terminal sequences (40 residues) of PSP and PSP-S1 are identical, which suggests that the peptide backbone is the same for both of these polypeptides. The PSP-S1 sequence was determined up to residue 65 and was found to be different from all other known protein sequences.

Immunoreactive pancreatic colipase, lipase and phospholipase A2 in human plasma and urine from healthy individuals

A radioimmunoassay for each of the human pancreatic proteins (colipase, lipase and phospholipase A2) is described. Determinations of the mean concentration of each protein in plasma and urine from healthy individuals were carried out with the radioimmunoassays. The values obtained in plasma were 0.5 nM (5.3 micrograms/l), 0.6 nM (32 micrograms/l) and 0.3 nM (4.3 micrograms/l) for colipase, lipase and phospholipase A2, respectively. In urine, the corresponding values were found to be 0.2 nM (2.4 micrograms/l), 0.09 nM (4.4 micrograms/l) and less than 0.017 nM (0.2 micrograms/l). No physical interaction between any of the three proteins and the lipid particles of plasma was demonstrated by centrifugation experiments or gel filtration. Gel filtration of plasma depleted of fat by centrifugation showed the proteins only in their monomeric form. The corresponding porcine proteins displayed a binding to antibodies against the human proteins, but with a lower affinity than the homologous interactions. The binding was weak but could differentiate between the porcine proforms and activated ones, i.e., procolipase and colipase87.