The localization of the previously postulated interface recognition site (IRS) in porcine pancreatic phospholipase A2, required for a specific interaction between the enzyme and organized lipid-water interfaces, was investigated by ultraviolet difference spectroscopy, by measurements of the intrinsic fluorescence of the unique Trp residue, and by protection experiments against specific tryptic hydrolysis. Using the enzymically nondegradable substrate analogues: CnH(2n+1)(0-)OOCH2CH2N+(CH3)3-(H,OH), it is shown that the rather hydrophobic N-terminal sequence of the enzyme, viz., Ala-Leu-Trp-Gln-Phe-Arg, is directly involved in the interaction with the lipid-water interface. Besides hydrophobic probably also polar interactions contribute to the binding process. At neutral or acidic pH the presence of a salt bridge between the N-terminal alpha-NH3+ group and a negatively charged side chain stablizes the interface recognition site and allows the enzyme to penetrate micellar surfaces, even in the absence of metal ion. At alkaline pH, interaction of the enzyme with micellar interfaces requires the presence of Ca2+ (Ba2+) ions.
The genes coding for the mature part of the lipases from Sfaphy1ococc~u.s uureuks NCTC8530 and Stup1iylococcu.s hyicus have been cloned and overexpressed in Escherichiu coli as fusion proteins with an N-terminal hexa-histidine tag. The enzymes accumulated in the cytoplasm and were purified using sequential precipitation with protamine sulphate and ammonium sulphate, followed by metal-affinity and hydroxyapatite chromatography. The yield of pure lipase was 4.5 mg/g wet cells for S. uureus lipase and 13 mglg for S. hyicus lipase. The purified enzymes need calcium for activity, albeit with different affinities, and a low residual activity was found in the absence of calcium. In contrast to S. hyicus lipase, not only strontium but also barium can replace calcium with full retention of activity of S. uureus lipase. Whereas S. hyicu.s lipase is optimally active at pH 8.5, the optimum pH for enzymatic activity for S. uureus lipase was found to be pH 6.5. The S. uureMs lipase has a narrow substrate specificity: short-chain triacylglycerols and acyl esters of both p-nitrophenol and umbelliferone are readily degraded, whereas medium-and long-chain lipids, as well as phospholipids, are poor substrates. In contrast, S. hyicus lipase prefers phospholipids as substrate and hydrolyses neutral lipids irrespective of their chain length. The results are discussed in view of the large sequence similarity between both lipases.Keywords: Stuphylococcus u u e u s lipase ; Sfaplzylococcw hyicus lipase ; overexpression ; purification ; substrate specificity.Lipases (glycerol ester hydrolase) are active at a lipid-water interface where they degrade water-insoluble triacylglycerols. These enzymes usually have a broad substrate specificity and also degrade acyl p-nitrophenyl esters, Tweens and phospholipids often with positional, stereo-and chain-length selectivity (Jaeger et al., 1994, and references therein).All lipases of known three-dimensional structure belong to the class of serine esterases (Brady et al., 1990; Grochulski et al., 1993: Schrag et al., 1991Winkler et al., 1990). The active site of these enzymes contains a catalytic triad consisting of Ser, His and an acidic residue which in the case of lipases is either Asp or Glu. This catalytic machinery is covered by at1 amphipathic surface loop, the so-called lid. The structures of a lipaseinhibitor complex and a lipase-micelle complex (Brzozowski et al., 1991 ; van Tilbeurgh et al., 1993) showed that the lid moves away, presumably due to the interaction with the substrate interCorr-[,sl)ondenc,r ro H. M. Verheij,
Interfacial regulation of phospholipase A2 activity on lecithin monolayers was investigated by using radioactively labeled enzyme. Labeling of the protein with 125I did not produce a change of the enzyme and protein properties as compared to the 3H fully amidinated phospholipase A2. The induction time observed during pre-steady-state kinetics reflects the rate-limiting step of the penetration of the enzyme in the interface. This penetration is reversible. However, in the surface pressure range where the enzyme is able to hydrolyze the lecithin films, the desorption of the protein from the film is slow as compared to the adsorption. Below a surface pressure of 10 dyn/cm nonspecific adsorption occurs. Using lecithins with fatty acids of different chain lengths, we have shown that the kinetics of the penetration process is governed by the packing density of the substrate molecules independent of the surface pressure. However, the steady-state surface concentration of the enzyme increases with the fatty acyl chain length of the lecithin, indicating that hydrophobic interaction occurs between phospholipase A2 and the lipid molecules at the interface. From the lecithins used pancreatic phospholipase A2 preferentially splits substrate molecules with nine carbon atoms in the acyl chain.
The role of aspartic acid-49 (Asp-49) in the active site of porcine pancreatic phospholipase A2 was studied by recombinant DNA techniques: two mutant proteins were constructed containing either glutamic acid (Glu) or lysine (Lys) at position 49. Enzymatic characterization indicated that the presence of Asp-49 is essential for effective hydrolysis of phospholipids. Conversion of Asp-49 to either Glu or Lys strongly reduces the binding of Ca2+ ions, in particular for the lysine mutant, but the affinity for substrate analogues is hardly affected. Extensive purification of naturally occurring Lys-49 phospholipase A2 from the venom of Agkistrodon piscivorus piscivorus yielded a protein that was nearly inactive. Inhibition studies showed that this residual activity was due to a small amount of contaminating enzyme and that the Lys-49 homologue itself has no enzymatic activity. Our results indicate that Asp-49 is essential for the catalytic action of phospholipase A2. The importance of Asp-49 was further evaluated by comparison of the primary sequences of 53 phospholipases A2 and phospholipase homologues showing that substitutions at position 49 are accompanied by structural variations of otherwise conserved residues. The occurrence of several nonconserved substitutions appeared to be a general characteristic of nonactive phospholipase A2 homologues.
An NMR study has been made of porcine pancreatic phospholipase A2 (PLA) in three environments: free in solution, in a binary complex with dodecylphosphocholine micelles, and in a ternary complex with a micelle and the substrate-like inhibitor (R)-1-octyl-2-(N-dodecanoylamino)-2-deoxyglycero-3-phosph oglycol. 1H and 15N chemical shifts, amide exchange rates, and NOE intensities are compared for the enzyme in different environments. From these data, structural differences are found for the N-terminal part, the end of the surface loop at residues Tyr69 and Thr70, and the active site residue His48, and also for the Ca-binding loop (residues 28-32). Specifically, when binding to a micelle, the side chains of residues Ala1, Trp3, and Tyr69, as well as all protons of Thr70, are found to be closer together. After subsequent introduction of the competitive inhibitor, further changes are found for these residues. The N-terminus is flexible in PLA free in solution, in contrast with the crystal structures where it adopts an alpha-helical conformation. According to the NMR data, this helix is rigidly formed only in the ternary complex. Furthermore, in the ternary complex, the N-terminal amino group and the exchangeable hydrogen at N3 of the ring of His48 are observed. We propose that PLA is activated in two steps. An initial conformational change occurs upon binding to a micellar interface. The catalytically active conformation of the enzyme, which has an extensive network of hydrogen bonds, is formed only when binding a substrate or competitive inhibitor at a lipid-water interface.
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