Stereospecificity of the interaction of porcine pancreatic phospholipase A2 with micellar and monomeric inhibitors. A time-resolved fluorescence study of the tryptophan residue.

The binding effect of enantiomeric substrate analogs under micellar form on the local conformation and dynamics of the N-terminal region of porcine pancreas phospholipase A2 was examined by time-resolved fluorescence measurements of its single tryptophan residue (Trp3). The complexity of the fluorescence intensity decay of the unliganded protein (four excited-state lifetime populations) suggests a conformational heterogeneity of the N-terminal region of the protein. A considerable simplification of the excited-state lifetime profile was specifically observed in the complex with one of the stereoisomers [(R)-2-tetradecanoylamino)-hexanol-phosphocholine] at low inhibitor/protein molar ratio of approximately 9. This indicates the existence of a definite conformation of the N-terminal region of the protein in the complex. No effect was detected for the S-enantiomer. In parallel, the rotational mobility of the Trp residue in the complex with the R-enantiomer was reduced. At a higher inhibitor/protein molar ratio of approximately 130, the stereospecificity of the interaction was lost and complexes were formed with both stereoisomers. These complexes were, however, not similar to the specific one either in terms of the local Trp3 environment or of the volume of the rotating unit. The local effects of low amounts of monomeric inhibitors added to a preformed protein/micelle complex of a phospholipase A2 double mutant in which a Trp residue was genetically inserted near the active site at position 31 while the natural Trp3 was replaced by Phe [Kuipers, O., Vincent, M., Brochon, J. C., Verheij, H. M., de Haas, G. H. & Gallay, J. (1991) Biochemistry 30, 8771-8785], were also monitored by time-resolved fluorescence of this single Trp residue. A stereospecific dependence of the local perturbations was again observed. These results support the idea that the active conformation of the protein is reached in solution only after formation of a ternary complex: protein-interface-inhibitor.

Competitive inhibition of lipolytic enzymes. VIII: Inhibitor-induced aggregation of porcine pancreatic phospholipase A2.

Several 2-acylaminophospholipid analogues have been demonstrated to behave as potent competitive inhibitors of porcine pancreatic phospholipase A2 (De Haas, G.H., Dijkman, R., Ransac, S. and Verger, R. (1990) Biochim. Biophys. Acta 1046, 249-257). Their inhibitory power appeared to be strictly controlled by the stereoconfiguration around the chiral C-2 atom and effective inhibition of the enzyme was observed only when incorporated into a micellar substrate-water interface. In the present study various direct binding techniques were applied to investigate the interaction of the enzyme with pure micelles of the stereoisomeric forms of 2-tetradecyl-amino-hexanol-1-phosphocholine (R-C14-PN and S-C14-PN). Upon equilibrium gel filtration of the enzyme (monomeric molecular mass = 14 kDa) on calibrated Superdex columns running in micellar solutions of R-C14-PN, the phospholipase eluted as a lipid-protein complex of 74 kDa. Under identical conditions, micellar solutions of S-C14-PN did not give rise to high-molecular mass aggregates and the enzyme eluted at its normal 14 kDa position. Light scattering experiments, ultrasedimentation and time-resolved fluorescence spectroscopy studies confirmed the formation of a high-molecular mass aggregate between enzyme and R-C14-PN micelles. The ultimate complex was shown to consist of four protein and about ten inhibitor molecules. Using time-resolved fluorescence spectroscopy the interaction was studied between the active site of phospholipase A2 and R-C14-PN molecules, both incorporated in an inert lipid matrix.

Competitive inhibition of lipolytic enzymes. VII. The interaction of pancreatic phospholipase A2 with micellar lipid/water interfaces of competitive inhibitors.

In a recent series of kinetic studies (De Haas et al. (1990) Biochim. Biophys. Acta 1046, 249-257 and references therein) we have demonstrated that synthetic (R)-phospholipid analogues containing a 2-acylaminogroup instead of the 2-acyloxy function found in natural phospholipids, behave as strong competitive inhibitors of porcine pancreatic phospholipase A2 (PLA2). We also showed that these analogues strongly bind to the active site of the enzyme but only after their incorporation into a micellar substrate/water interface. In the present study we investigated the interaction of native PLA2 and of an inactive PLA2 in which the active site residue His-48 has been modified by alkylation with 1-bromo-2-octanone, with pure micelles of several of these inhibitors in both enantiomeric forms by means of ultraviolet difference absorption spectroscopy. Our results show that the first interaction step between native or modified enzyme and micellar lipid/water interfaces probably consists of a low-affinity Langmuir-type adsorption characterized by signals arising from the perturbation of the single Trp-3 residue. Once present at the interface the native enzyme is able to bind, in a second step, a single inhibitor molecule of the (R)-configuration in its active site, whereas the (S)-enantiomer is not bound in the active site. The overall dissociation constant of the interfacial phospholipase-inhibitor complex is three orders of magnitude lower for micelles composed of the (R)-isomer than those of the (S)-isomer. The modified PLA2 still adsorbs to micellar lipid/water interfaces but cannot bind either of the two enantiomers into its active site and similar dissociation constants were found for lipid-protein complexes with micelles of either the (R) or the (S) inhibitors. After blanking the ultraviolet signals due to the perturbation of Trp-3 in the initial adsorption step of the enzyme to a micellar surface of a non-inhibitory phospholipid analogue, the progressive binding of a single (R)-inhibitor molecule into the active site could be followed quantitatively by a tyrosine perturbation. These titrations yielded numerical values for the dissociation constants in the interface and provide a possible explanation for the large difference in overall dissociation constants of the complexes between enzyme and micelles of (R)-and (S)-inhibitors. With the use of PLA2 mutants in which each time a single tyrosine was replaced by phenylalanine, the tyrosine residues involved in binding of the monomeric inhibitor molecule were identified as Tyr-69 and Tyr-52.

Competitive inhibition of lipolytic enzymes. V. A monolayer study using enantiomeric acylamino analogues of phospholipids as potent competitive inhibitors of porcine pancreatic phospholipase A2.

For the first time, we have shown that a stereospecific interaction occurs between porcine pancreatic phospholipase A2 and a monomolecular film of amidophospholipid used as inhibitor. Direct binding experiments, using radiolabelled phospholipase A2, showed that 13 times more enzyme was bound to phospholipid films of the L series by comparison with films of the D series. These results were confirmed by indirect binding studies using re-spreading experiments. Kinetic studies of the porcine pancreatic PLA2, using enantiomeric acyl-amino phospholipid analogues, have shown that: (1) inhibitors of the L series are more potent than inhibitors of the D series, (2) inhibitors having a negative charge are more potent than zwitterionic inhibitors, (3) inhibitory power values are greater when evaluated in micellar system than in a the monolayer system, (4) the inhibitory power increases continuously with surface pressure.

A monolayer and bulk study on the kinetic behavior of Pseudomonas glumae lipase using synthetic pseudoglycerides.

A heat-stable lipase from Pseudomonas glumae was purified to homogeneity. Its positional and stereospecific properties were investigated and compared with those of the well-known porcine pancreatic lipase. The kinetic properties of both enzymes were determined by use of six isomeric synthetic pseudoglycerides all composed of a single hydrolyzable fatty acyl ester bond and two lipase-resistant groups: one acylamino and one ether function. Two enzyme assay techniques were applied: a detergent-free system, the monomolecular surface film technique, and the pH-stat technique using clear micellar solutions of substrate in the presence of Triton X-100. Regarding the cleavage of primary ester bonds, P. glumae lipase possesses no stereopreference. In contrast, a large stereopreference in favor of the R-isomer is found for the hydrolysis of secondary ester bonds. Secondary ester bonds are efficiently cleaved by the lipase, which makes it of potential interest for enzymatic synthetic purposes. For the hydrolysis of this R-isomer a correlation between the experimental catalytic turnover rate and the binding constant for micelles was observed. The kinetic data of P. glumae lipase have been analyzed in terms of the scooting and hopping models for the action of lipolytic enzymes [Upreti, G.C., & Jain, M.K. (1980) J. Membr. Biol. 55, 113-121]. The results presented in this study are best explained by assuming that glumae lipase leaves the interface after a limited number of catalytic cycles.

Stereoselectivity of lipases. I. Hydrolysis of enantiomeric glyceride analogues by gastric and pancreatic lipases, a kinetic study using the monomolecular film technique.

In the present study, porcine pancreatic lipase, rabbit gastric lipase, and human gastric lipase stereospecificity toward enantiomeric glyceride derivatives was kinetically investigated using the monomolecular film technique. Pseudoglycerides such as enantiomeric 1(3)-alkyl-2,3(1,2)-diacyl-sn-glycerol, enantiomeric 1(3)-alkyl-2-acyl-sn-glycerol, or enantiomeric 1(3)-acyl-2-acylamino-2-deoxy-sn-glycerol were synthesized in order to assess the lipase stereoselectivity during the hydrolysis of either the primary or the secondary ester position of these glycerides analogues. The cleaved acyl moiety was the same in both enantiomers, thereby excluding the possibility of effects occurring due to fatty acid specificity. We observed a porcine pancreatic lipase sn-3 stereoselectivity when using the enantiomeric 1(3)-alkyl-2-acylamino-2-deoxy-sn-glycerol (diglyceride analogue) which contrasted with the lack of stereoselectivity observed when using the enantiomeric 1(3)-alkyl-2,3(1,2)-diacyl-sn-glycerol (triglyceride analogue). The gastric lipases, in contrast to the pancreatic lipase, preferentially catalyze the hydrolysis of the primary sn-3 ester bond of the enantiomeric monoakyl-diacyl pair tested. From these kinetic data, high hydrolysis rates and no chiral discrimination were observed in the case of rabbit gastric lipase, whereas low rates and a clear chiral discrimination was noticed in the case of human gastric lipase during hydrolysis of the acyl chain from the secondary ester bond of 1(3)-alkyl-2-acyl enantiomers. It is particularly obvious that in the case of human gastric lipase decreasing the lipid packing increases the lipase sn-3 stereopreference during hydrolysis of the primary ester bond of the enantiomeric 2-acylamino derivatives (diglyceride analogue).

Purification and substrate specificity of Staphylococcus hyicus lipase.

The Staphylococcus hyicus lipase gene has been cloned and expressed in Staphylococcus carnosus. From the latter organism the enzyme was secreted into the medium as a protein with an apparent molecular mass of 86 kDa. This protein was purified, and the amino-terminal sequence showed that the primary gene product was indeed cleaved at the proposed signal peptide cleavage site. The protein was purified from large-scale preparations after tryptic digestion. This limited proteolysis reduced the molecular mass to 46 kDa and increased the specific activity about 3-fold. Although the enzyme had a low specific activity in the absence of divalent cations, the activity increased about 40-fold in the presence of Sr2+ or Ca2+ ions. The purified lipase has a broad substrate specificity. The acyl chains were removed from the primary and secondary positions of natural neutral glycerides and from a variety of synthetic glyceride analogues. Thus triglycerides were fully hydrolyzed to free fatty acid and glycerol. The enzyme hydrolyzed naturally occurring phosphatidylcholines, their synthetic short-chain analogues, and lysophospholipids to free fatty acids and water-soluble products. The enzyme had a 2-fold higher activity on micelles of short-chain D-lecithins than on micelles composed of the L-isomers. Thus the enzyme from S. hyicus has lipase activity and also high phospholipase A and lysophospholipase activity.