Youssef Gargouri

Kinetic assay of human gastric lipase on short- and long-chain triacylglycerol emulsions.

Under optimal conditions, assay for pure human gastric lipase was carried out with short- and long-chain triacylglycerol emulsions. Maximal specific activities of 1160 and 620 U/mg were obtained with tributyrin and soybean emulsion, respectively. We observed that with a tributyrin substrate, bovine serum albumin or bile salts must be added before the addition of the enzyme in order to prevent its irreversible interfacial denaturation. With long-chain triacylglycerols as substrate, a decrease with time in the rate of hydrolysis was associated with release of protonated long-chain fatty acids. The inhibitory effect of protonated fatty acids was also observed using tributyrin at pH 3.0. These observations support the conclusion that human gastric lipase shows no intrinsic specificity for short-chain triacylglycerols and that its apparent specificity is modulated by pH and presence of amphiphile in the incubation medium. Our conclusions support the view that, in the human, gastric lipolysis may play an important role in long-chain fat digestion.

Interactions of lipases with lipid monolayers: Facts and questions

Among the proteins, lipolytic enzymes provide a valuable model for studying protein-lipid interactions. Lipases having a catalytic action which is strictly dependent upon the presence of a lipid interface were used in the present study in order to gain better insight into protein-lipid interactions. Most of the data presented here were obtained using the monolayer technique, by recording (either independently or simultaneously) the lipolytic activity, the amount of protein adsorbed to the lipid monolayer, and the surface pressure variations following protein adsorption. Several non-enzymatic proteins were used as controls in order to determine how lipase behaviour differs from that of other proteins. At all initial surface pressures tested, with zwitterionic monolayers, a good correlation was observed between the amount of lipase bound to the monolayer and the surface pressure increase, in agreement with previous studies. Conversely, with neutral lipid monolayers the amount of lipase bound to the monolayer was not found to be surface pressure dependent. This latter behaviour observed with lipases on neutral films is not specific to lipases, since it was also observed with bovine serum albumin and beta-lactoglobulin A. Lipase activity in the presence of various proteins was investigated with monomolecular films of glycerol didecanoate, either at constant surface area or at constant surface pressure. Depending upon the nature of the lipase and the protein, inhibition of lipase activity was either observed or not. Inhibition was correlated with a decrease in lipase surface concentration. The ability of the various proteins to inhibit lipolysis is: (i) a function of their excess versus lipase in the bulk phase, and: (ii) correlated with their penetration capacity (i.e., the initial rate of surface pressure increase of a glycerol didecanoate monolayer having an initial surface pressure of 20 dyn/cm, after the injection-of the protein). Since lipase inhibition was observed with low surface densities of inhibitory proteins, a long-range effect is probably involved in the mechanism of interfacial lipase inhibition. The nature of the ionic charge added to the monolayer by the protein is not critical for determining lipase adsorption or desorption. It is hypothesized that the lack of lipase adsorption to, or desorption from, the lipid monolayer results from a change in the organization of the hydrocarbon moiety of the lipid.

Biochemical and molecular characterization of Staphylococcus simulans lipase

Staphylococcus simulans strain secretes a non-induced lipase in the culture medium. Staphylococcus simulans lipase (SSL), purified to homogeneity, is a tetrameric protein (160 kDa) corresponding to the association of four lipase molecules. The 30 N-terminal amino acid residues were sequenced. This sequence is identical to the one of Staphylococcus aureus PS54 lipase (SAL PS54) and exhibits a high degree of homology with Staphylococcus aureus NCTC8530 lipase (SAL NCTC8530), Staphylococcus hyicus lipase (SHL) and Staphylococcus epidermis RP62A lipase (SEL RP62A) sequences. But the cloning and sequencing of the part of the gene encoding the mature lipase show some differences from SAL PS54 sequence, which suggest that it is a new sequence. The lipase activity was maximal at pH 8.5 and 37 degrees C. SSL is able to hydrolyze triacylglycerols without chain length specificity. A specific activity of about 1000 U/mg was measured on tributyrin or triolein as substrate at 37 degrees C and at pH 8.5 in the presence of 3 mM CaCl(2). In contrast to other staphylococcal lipases previously characterized, Ca(2+) is not required to express the activity of SSL. SSL was found to be stable between pH 4 and pH 9. The enzyme is inactivated after a few minutes when incubated at 60 degrees C. Using tripropionin as substrate, SSL does not present the interfacial activation phenomenon. In contrast to many lipases, SSL is able to hydrolyze its substrate in the presence of bile salts or amphiphilic proteins.

Inactivation of pancreatic and gastric lipases by THL and C12:0-TNB: a kinetic study with emulsified tributyrin

THL is a potent inhibitor of pancreatic (PPL) and gastric (HGL, RGL) lipases. Inactivation occurs preferentially at the oil/water interface (method B, C). In the aqueous phase (method A), the inhibition of HGL was accelerated by the presence of bile salts. C12:0-TNB, a disulfide reagent, specifically inactivates gastric lipases and had no effect on the pancreatic lipase (in the presence of bile salts) whatever the method used. The capacity of THL and C12:0-TNB to inactivate lipases using Methods B and C was found to depend directly upon the interfacial area of the system used. Consequently, inactivation can be reduced or prevented by further addition of a water-insoluble substrate which reduces the surface density of inactivator molecules. With a heterogeneous system of this kind, typical of lipolysis, the use of a classical Michaelis-Menten model is irrelevant and hence the traditional kinetic parameters (Km, KI, Vmax) are only apparent values.

[10] Covalent inactivation of lipases

Publisher Summary This chapter presents and discusses results chiefly concerning the covalent inhibition of gastric and pancreatic lipases. Lipolysis is catalyzed by preduodenal and pancreatic lipases. In humans, the hydrolysis of alimentary triacylglycerols begins in the stomach and is catalyzed by human gastric lipase (HGL) that is able to hydrolyze short- and long-chain triacylglycerols at comparable rates. Under acidic pH conditions, HGL has been shown to be remarkably stable and active, whereas pancreatic lipase irreversibly loses its lipolytic capacity. Achieving specific and covalent inhibition of lipolytic enzymes is a difficult task, because of nonmutually exclusive processes such as interfacial denaturation, changes in “interfacial quality,” and surface dilution phenomena. Furthermore, the interfacial enzyme binding and/or the catalytic turnover can be diversely affected by the presence of potential amphipathic inhibitors. The chapter provides selected experimental data illustrating the specific problems encountered during the covalent inhibition of digestive lipases.

N-terminal peptide of Rhizopus oryzae lipase is important for its catalytic properties

In a culture medium, the Rhizopus oryzae strain produces only one form of lipase, ROL32. When the concentrated culture medium was stored at 0 °C during several months or kept at 6 °C during a few days, we noticed the appearance of a second shorter form of ROL32 lacking its N‐terminal 28 amino acid (ROL29). ROL29 was purified to homogeneity and its 21 N‐terminal amino acid residues were found to be identical to the 29–49 sequence of ROL32. The cleavage of the N‐terminal peptide reduced the specific activity of ROL29 by 50% using either triolein or tributyrin as substrates. In order to explain this decrease of the specific activity of ROL29, we measured its critical surface pressure of penetration into phosphatidyl choline from egg yolk films which was found to be 10 mN/m, in contrast to a value of 23 mN/m found in ROL32. A kinetic study on the surface pressure dependency, stereoselectivity and regioselectivity of ROL29 was performed using the three dicaprin isomers spread as monomolecular films at the air–water interface. Our results showed that in contrast to ROL32, ROL29 presented a preference for the distal ester groups of one diglyceride isomer (1,3‐sn‐dicaprin). Furthermore, ROL32 was markedly more stereoselective than ROL29 for the sn‐3 position of the 2,3‐sn‐enantiomer of dicaprin. A structural explanation of the enhanced penetration capacity as well as the catalytic activity of ROL32 was proposed by molecular modeling. We concluded that the N‐terminal peptide of ROL32 can play an important role in the specific activity, the regioselectivity, the stereoselectivity and the binding of the enzyme to its substrate.

Characterization of turkey pancreatic lipase

Turkey pancreatic lipase (TPL) was purified from delipidated pancreases. Pure TPL (glycerol ester hydrolase, EC 3.1.1.3) was obtained after ammonium sulfate fractionation, Sephacryl S-200 gel filtration, anion exchange chromatography (DEAE-Sepharose) and size exclusion column using high performance liquid chromatography system (HPLC). The pure lipase, which is not a glycoprotein, was presented as a monomer having a molecular mass of about 45 kDa. The lipase activity was maximal at pH 8.5 and 37 degrees C. TPL hydrolyses the long chains triacylglycerols more efficiently than the short ones. A specific activity of 4300 U/mg was measured on triolein as substrate at 37 degrees C and at pH 8.5 in the presence of colipase and 4 mM NaTDC. This enzyme presents the interfacial activation when using tripropionin as substrate. TPL was inactivated when the enzyme was incubated at 65 degrees C or at pH less than 5. Natural detergent (NaTDC), synthetic detergent (Tween-20) or amphipatic protein (beta-lactoglobulin A) act as potent inhibitors of TPL activity. To restore the lipase activity inhibited by NaTDC, colipase should be added to the hydrolysis system. When lipase is inhibited by synthetic detergent or protein, simultaneous addition of colipase and NaTDC was required to restore the TPL activity. The first 22 N-terminal amino acid residues were sequenced. This sequence was similar to those of mammals pancreatic lipases. The biochemical properties of pancreatic lipase isolated from bird are similar to those of mammals.

Phospholipases: An Overview

Phospholipids are present in all living organisms. They are a major component of all biological membranes, along with glycolipids and cholesterol. Enzymes aimed at cleaving the various bonds in phospholipids, namely phospholipases, are consequently widespread in nature, playing very diverse roles from aggression in snake venom to signal transduction, lipid mediators production, and digestion in humans. Although all phospholipases target phospholipids as substrates, they vary in the site of action on the phospholipids molecules, physiological function, mode of action, and their regulation. Significant studies on phospholipases characterization, physiological role, and industrial potential have been conducted worldwide. Some of them have been directed for biotechnological advances, such as gene discovery and functional enhancement by protein engineering. Others reported phospholipases as virulence factors and major causes of pathophysiological effects. In this introductory chapter, we provide brief details of different phospholipases.

Enzymatic synthesis of eugenol benzoate by immobilized Staphylococcus aureus lipase: Optimization using response surface methodology and determination of antioxidant activity

The ability of a non-commercial immobilized Staphylococcus aureus lipase to catalyze the esterification of eugenol with benzoic acid was checked and the antioxidant power of the ester formed was evaluated. Response surface methodology based on four variables (the reaction temperature, the amount of lipase, the benzoic acid/eugenol molar ratio and the volume of solvent) was used to optimize the experimental conditions of eugenol benzoate synthesis. The maximum conversion yield (75%) was obtained using 240 IU of immobilized lipase, a benzoic acid/eugenol molar ratio of 1.22 dissolved in 4.6 ml chloroform at 41 degrees Celsius. The antioxidant activities of eugenol and its ester were evaluated. Compared to BHT, used as a model synthetic antioxidant, the eugenol benzoate showed a higher antioxidative activity. The IC(50) value for 1,1-diphenyl-2-picrylhydrazyl was found to be 18.2 microg/ml versus 20.2 microg/ml for eugenol and eugenol benzoate.

Kinetic studies of Rhizopus oryzae lipase using monomolecular film technique

Rhizopus oryzae lipase (ROL) was found to be a true lipase. This enzyme presents the interfacial activation phenomenon. The N-terminal amino acid sequence of ROL was compared to those of rhizopus lipases. Purified ROL possesses the same N-terminal sequence as the mature Rhizopus niveus lipase (RNL). This sequence was found in the last 28 amino acids of the propeptide sequence derived from the cDNA of Rhizopus delemar lipase (RDL). Using the baro-stat method, we have measured the hydrolysis rate of dicaprin films by ROL as a function of surface pressure. Our results show that Rhizopus oryzae lipase is markedly stereoselective of the sn-3 position of the 2,3 enantiomer of dicaprin. Polyclonal antibodies (PAB) directed against ROL have been produced and purified by immunoaffinity. The effects of these PAB on the interfacial behavior of ROL were determined. The immunoblot analysis with polyclonal antibodies anti-ROL (PAB anti-ROL) and various lipases shows a cross-immunoreactivity between the lipase from the rhizopus family (Rhizopus delemar lipase and Rhizopus arrhizus lipase).