Distinct arachidonate-releasing functions of mammalian secreted phospholipase A2s in human embryonic kidney 293 and rat mastocytoma RBL-2H3 cells through heparan sulfate shuttling and external plasma membrane mechanisms.

We analyzed the ability of a diverse set of mammalian secreted phospholipase A(2) (sPLA(2)) to release arachidonate for lipid mediator generation in two transfected cell lines. In human embryonic kidney 293 cells, the heparin-binding enzymes sPLA(2)-IIA, -IID, and -V promote stimulus-dependent arachidonic acid release and prostaglandin E(2) production in a manner dependent on the heparan sulfate proteoglycan glypican. In contrast, sPLA(2)-IB, -IIC, and -IIE, which bind weakly or not at all to heparanoids, fail to elicit arachidonate release, and addition of a heparin binding site to sPLA(2)-IIC allows it to release arachidonate. Heparin nonbinding sPLA(2)-X liberates arachidonic acid most likely from the phosphatidylcholine-rich outer plasma membrane in a glypican-independent manner. In rat mastocytoma RBL-2H3 cells that lack glypican, sPLA(2)-V and -X, which are unique among sPLA(2)s in being able to hydrolyze phosphatidylcholine-rich membranes, act most likely on the extracellular face of the plasma membrane to markedly augment IgE-dependent immediate production of leukotriene C(4) and platelet-activating factor. sPLA(2)-IB, -IIA, -IIC, -IID, and -IIE exert minimal effects in RBL-2H3 cells. These results are also supported by studies with sPLA(2) mutants and immunocytostaining and reveal that sPLA(2)-dependent lipid mediator generation occur by distinct (heparanoid-dependent and -independent) mechanisms in HEK293 and RBL-2H3 cells.

Basic residues of human group IIA phospholipase A2 are important for binding to factor Xa and prothrombinase inhibition comparison with other mammalian secreted phospholipases A2.

Human secreted group IIA phospholipase A2 (hGIIA) was reported to inhibit prothrombinase activity because of binding to factor Xa. This study further shows that hGIIA and its catalytically inactive H48Q mutant prolong the lag time of thrombin generation in human platelet-rich plasma with similar efficiency, indicating that hGIIA exerts an anticoagulant effect independently of phospholipid hydrolysis under ex vivo conditions. Charge reversal of basic residues on the interfacial binding surface (IBS) of hGIIA leads to decreased ability to inhibit prothrombinase activity, which correlates with a reduced affinity for factor Xa, as determined by surface plasmon resonance. Mutation of other surface-exposed basic residues, hydrophobic residues on the IBS, and His48, does not affect the ability of hGIIA to inhibit prothrombinase activity and bind to factor Xa. Other basic, but not neutral or acidic, mammalian secreted phospholipases A2 (sPLA2s) exert a phospholipid-independent inhibitory effect on prothrombinase activity, suggesting that these basic sPLA2s also bind to factor Xa. In conclusion, this study demonstrates that the anticoagulant effect of hGIIA is independent of phospholipid hydrolysis and is based on its interaction with factor Xa, leading to prothrombinase inhibition, even under ex vivo conditions. This study also shows that such an interaction involves basic residues located on the IBS of hGIIA, and suggests that other basic mammalian sPLA2s may also inhibit blood coagulation by a similar mechanism to that described for hGIIA.

Exogenously added human group X secreted phospholipase A(2) but not the group IB, IIA, and V enzymes efficiently release arachidonic acid from adherent mammalian cells.

Mammalian secreted phospholipases A(2) (sPLA2s) comprise a group of at least eight enzymes, including the recently identified group X sPLA2. A bacterial expression system was developed to produce human group X sPLA2 (hGX). Inhibition studies show that the sPLA2 inhibitor LY311727 binds modestly more tightly to human group IIA sPLA2 than to hGX and that a pyrazole-based inhibitor of group IIA sPLA2 is much less active against hGX. The phospholipid head group preference of vesicle-bound hGX was determined. hGX binds tightly to phosphatidylcholine vesicles, which is thought to be required to act efficiently on cells. Tryptophan 67 hGX makes a significant contribution to interfacial binding to zwitterionic vesicles. As little as 10 ng/ml hGX releases arachidonic acid for cyclooxygenase-2- dependent prostaglandin E(2) generation when added exogenously to adherent mammalian cells. In contrast, human group IIA, rat group V, and mouse group IB sPLA2s are virtually inactive at releasing arachidonate when added exogenously to adherent cells. Dislodging cells from the growth surface enhances the ability of all the sPLA2s to release fatty acids. Studies with CHO-K1 cell mutants show that binding of sPLA2s to glycosaminoglycans is not the basis for poor plasma membrane hydrolysis by group IB, IIA, and V sPLA2s.

Role of axial ligands in the reactivity of Mn peroxidase from Phanerochaete chrysosporium.

Site-directed mutagenesis was performed on Mn peroxidase (MnP) from the white-rot fungus Phanerochaete chrysosporium to investigate the role of the axial ligand hydrogen-bonding network on heme reactivity. D242 is hydrogen bonded to the proximal His of MnP; in other peroxidases, this conserved Asp, in turn, is hydrogen bonded to a Trp. In MnP and other fungal peroxidases, the Trp is replaced by a Phe (F190). Both residues are thought to have a direct influence on the electronic environment of the catalytic center. To study only the active mutants at D242 and F190, we used degenerate oligonucleotides allowing us to screen all 19 possible amino acid mutants at these positions. Two mutants at D242 passed our screen, D242E and D242S. Both mutations impaired only the functioning of compound II. The reactions of the ferric enzyme with H(2)O(2) were unaffected by the mutations, as were the reactions of compound I with reducing substrates. The D242S and D242E mutations reduced the first-order rate constant for the reaction of MnP compound II with chelated Mn(2+) from 233 s(-1) (wild type) to 154 s(-1) and 107 s(-1), respectively. Three F190 mutants passed our screen, F190V, F190L, and F190W. Similar to mutants at D242, these mutants largely affected the function of compound II. The F190V mutation increased the first-order rate constant for the reduction of compound II by chelated Mn(2+) to 320 s(-1). The F190L mutation decreased this rate to 137 s(-1). The F190W mutant was not very stable, but at pH 6.0, this mutation decreased the rate of compound II reduction by Mn(2+) from 140 s(-1) in the wild type to 36 s(-1). There was no indication that the F190W mutant was capable of forming a protein-centered Trp cation radical. All the mutations altered the midpoint potential of the Fe(3+)/Fe(2+) couple of the enzyme, as calculated from cyclic voltammagrams of the proteins. The values were shifted from -96 mV in the wild-type enzyme to -123 mV in D242S, -162 mV in D242E, -82 mV in F190L, -173 mV in F190V, and -51 mV in F190W. Collectively, these results demonstrate that D242 and F190 in MnP influence the electronic environment around the heme and that the reactions of compound II are far more sensitive to this influence than the reduction of compound I.

Cloning and recombinant expression of a novel mouse-secreted phospholipase A2.

Secreted phospholipases A2 (sPLA2s) form a class of structurally related enzymes that are involved in a variety of physiological and pathological effects including inflammation and associated diseases, cell proliferation, cell adhesion, and cancer, and are now known to bind to specific membrane receptors. Here, we report the cloning and expression of a novel sPLA2 isolated from mouse thymus. Based on its structural features, this sPLA2 is most similar to the previously cloned mouse group IIA sPLA2 (mGIIA sPLA2). As for mGIIA sPLA2, the novel sPLA2 is made up of 125 amino acids with 14 cysteines, is basic (pI = 8.71) and its gene has been mapped to mouse chromosome 4. However, the novel sPLA2 has only 48% identity with mGIIA and displays similar levels of identity with the other mouse group IIC and V sPLA2s, indicating that the novel sPLA2 is not an isoform of mGIIA sPLA2. This novel sPLA2 has thus been called mouse group IID (mGIID) sPLA2. In further contrast with mGIIA, which is found mainly in intestine, transcripts coding for mGIID sPLA2 are found in several tissues including pancreas, spleen, thymus, skin, lung, and ovary, suggesting distinct functions for the two enzymes. Recombinant expression of mGIID sPLA2 in Escherichia coli indicates that the cloned sPLA2 is an active enzyme that has much lower specific activity than mGIIA and displays a distinct specificity for binding to various phospholipid vesicles. Finally, recombinant mGIID sPLA2 did not bind to the mouse M-type sPLA2 receptor, while mGIIA was previously found to bind to this receptor with high affinity.

1,3-Dioxane-4,6-dione-5-carboxamide-based inhibitors of human group IIA phospholipase A: X-ray structure of the complex and interfacial selection of inhibitors from a structural library.

A library of 109 1,3-dioxane-4,6-dione-5-carboxamides was prepared by solution-phase methods as potential inhibitors of human group IIa phospholipase A2. Tight binding inhibitors were found by an interfacial affinity selection method. The crystal structure of the secreted phospholipase A2 containing one of the inhibitors was determined, and it reveals the inhibitor-calcium bidendate coordination.

Action of human group IIa secreted phospholipase A2 on cell membranes. Vesicle but not heparinoid binding determines rate of fatty acid release by exogenously added enzyme.

Human group IIa phospholipase A2 (hIIa-PLA2) is a highly basic protein that is secreted from a number of cells during inflammation and may play a role in arachidonate liberation and in destruction of invading bacteria. It has been proposed that rodent group IIa PLA2 is anchored to cell surfaces via attachment to heparan sulfate proteoglycan and that this interaction facilitates lipolysis. hIIa-PLA2 contains 13 lysines, 2 histidines, and 10 arginines that fall into 10 clusters. A panel of 26 hIIa-PLA2 mutants were prepared in which 1-4 basic residues in each cluster were changed to glutamate or aspartate (charge reversal). A detailed analysis of the affinities of these mutants for anionic vesicles and for heparin and heparan sulfate in vitro and of the specific activities of these proteins for hydrolysis of vesicles in vitro and of living cell membranes reveal the following trends: 1) the affinity of hIIa-PLA2 for heparin and heparan sulfate is modulated not by a highly localized site of basic residues but by diffuse sites that partially overlap with the interfacial binding site. In contrast, only those residues on the interfacial binding site of hIIa-PLA2 are involved in binding to membranes; 2) the relative ability of these mutants to hydrolyze cellular phospholipids when enzymes were added exogenously to CHO-K1, NIH-3T3, and RAW 264.7 cells correlates with their relative in vitro affinity for vesicles and not with their affinity for heparin and heparan sulfate. 3) The rates of exogenous hIIa-PLA2-catalyzed fatty acid release from wild type CHO-K1 cells and two mutant lines, one lacking glycosaminoglycan and one lacking heparan sulfate, were similar. Thus basic residues that modulate interfacial binding are important for plasma membrane fatty acid release by exogenously added hIIa-PLA2. Binding of hIIa-PLA2 to cell surface heparan sulfate does not modulate plasma membrane phospholipid hydrolysis by exogenously added hIIa-PLA2.

Mapping the interfacial binding surface of human secretory group IIa phospholipase A2.

Human secretory group IIa phospholipase A2 (hIIa-PLA2) contains a large number of prominent cationic patches on its molecular surface and has exceptionally high affinity for anionic surfaces, including anionic membranes. To identify the cationic amino acid residues that support binding of hIIa-PLA2 to anionic membranes, we have performed extensive site-directed mutagenesis of this protein and measured vesicle binding and interfacial kinetic properties of the mutants using polymerized liposomes and nonpolymerized anionic vesicles. Unlike other secretory PLA2s, which have a few cationic residues that support binding of enzyme to anionic membranes, interfacial binding of hIIa-PLA2 is driven in part by electrostatic interactions involving a number of cationic residues forming patches on the putative interfacial binding surface. Among these residues, the amino-terminal patch composed of Arg-7, Lys-10, and Lys-16 makes the most significant contribution to interfacial adsorption, and this is supplemented by contributions from other patches, most notably Lys-74/Lys-87/Arg-92 and Lys-124/Arg-127. For these mutants, complete vesicle binding occurs in the presence of high vesicle concentrations, and under these conditions the mutants display specific activities comparable to that of wild-type enzyme. These studies indicate that electrostatic interactions between surface lysine and arginine residues and the interface contribute to interfacial binding of hIIa-PLA2 to anionic vesicles and that cationic residues closest to the opening of the active-site slot make the most important interactions with the membrane. However, because the wild type binds extremely tightly to anionic vesicles, it was not possible to exactly determine what fraction of the total interfacial binding energy is due to electrostatics.

Oxidation of 1,2,4,5-tetramethoxybenzene by lignin peroxidase of Phanerochaete chrysosporium.

We have reinvestigated the lignin peroxidase-catalyzed oxidation of 1,2,4,5-tetramethoxybenzene (TMB) by using presteady-state and steady-state kinetic methods. Our presteady-state kinetic results show that the reaction of compound I with TMB obeyed second order kinetics with a rate constant of 1.1 x 10(7) M-1s-1. The reaction of compound II with TMB exhibits a hyperbolic concentration dependence with a Kd of 16 microM and K = 24 s-1. The stoichiometry of TMB oxidation during steady state is two TMB cation radicals formed per H2O2 consumed. These results clearly show that TMB is a good substrate for both compounds I and II of lignin peroxidase.

Oxidation of guaiacol by lignin peroxidase. Role of veratryl alcohol.

We have investigated the lignin peroxidase-catalyzed oxidation of guaiacol and the role of veratryl alcohol in this reaction by steady-state and pre-steady-state methods. Pre-steady-state kinetic analyses demonstrated that guaiacol is a good substrate for both compounds I and II, the two- and one-electron oxidized enzyme intermediates, respectively, of lignin peroxidase. The rate constant for the reaction with compound I is 1.2 x 10(6) M-1s-1. The reaction of guaiacol with compound II exhibits a Kd of 64 microM and a first-order rate constant of 17 s-1. Oxidation of guaiacol leads to tetraguaiacol formation. This reaction exhibits classical Michaelis-Menten kinetics with a Km of 160 microM and a kcat of 7.7 s-1. Veratryl alcohol, a secondary metabolite of ligninolytic fungi, is capable of mediating the oxidation of guaiacol. This was shown by steady-state inhibition studies. Guaiacol completely inhibited the oxidation of veratryl alcohol, whereas veratryl alcohol had no corresponding inhibitory effect on guaiacol oxidation. In fact, at low guaiacol concentrations, veratryl alcohol stimulated the rate of guaiacol oxidation. These results collectively demonstrate that veratryl alcohol can serve as a mediator for phenolic substrates in the lignin peroxidase reaction.

Kinetic analysis of lignin peroxidase: explanation for the mediation phenomenon by veratryl alcohol.

We investigated the role of veratryl alcohol in lignin peroxidase-catalyzed oxidation of anisyl alcohol with pre-steady-state and steady-state kinetic methods. Veratryl alcohol has been proposed to act as a redox mediator for substrates that are not directly oxidized by the enzyme. Alternatively, its mediation activity has also been attributed to its ability to protect the enzyme from H2O2-dependent inactivation. As previously reported, veratryl alcohol was able to stimulate the oxidation of anisyl alcohol. However, this stimulation is not due to mediation or protection of the enzyme. The stimulation can be attributed to the relative reactivity of anisyl alcohol with compounds I and II of lignin peroxidase. We found that anisyl alcohol reacts with compound I, but not with compound II. Therefore, inclusion of veratryl alcohol or another substrate, which reacts with compound II, is essential for completion of the catalytic cycle.