Carine Mounier

Platelet secretory phospholipase A2 fails to induce rabbit platelet activation and to release arachidonic acid in contrast with venom phospholipases A2

The ability of platelet secretory phospholipase A2 (sPLA2) to induce platelet activation was investigated. sPLA2 (group II) contained in an activated platelet supernatant, as well as high concentrations of purified recombinant platelet sPLA2, failed to induce platelet activation. Furthermore, sPLA2 did not modify platelet activation induced by various agonists. The possible relationship between the failure of this enzyme to induce platelet activation and its origin (mammalian) or its structural group (group II) was then investigated, using pancreatic PLA2s (group I) and venom PLA2s from groups I, II and III. All venom PLA2s induced platelet activation that was accompanied by the liberation of arachidonic acid and was abolished by aspirin. In contrast, as observed for platelet sPLA2, enzymes from hog or bovine pancreas were unable to induce platelet activation even when used at high concentrations. Interestingly, PLA2 able to induce platelet activation efficiently hydrolyse phosphatidylcholine, while those inactive on platelets did not. Taken together, these results suggest that the catalytic activity of added PLA2 is necessary but not sufficient to induce platelet activation. Moreover, the ability of PLA2 to induce platelet activation is not related to its structural group (I, II, III) but rather to its origin (venom vs. mammalian) and capacity to hydrolyse phosphatidylcholine, the major phospholipid of the outer leaflet of the plasma membrane.

Group X Phospholipase A2 Stimulates the Proliferation of Colon Cancer Cells by Producing Various Lipid Mediators

Among mammalian secreted phospholipases A2 (sPLA2s), the group X enzyme has the most potent hydrolyzing capacity toward phosphatidylcholine, the major phospholipid of cell membrane and lipoproteins. This enzyme has recently been implicated in chronic inflammatory diseases such as atherosclerosis and asthma and may also play a role in colon tumorigenesis. We show here that group X sPLA2 [mouse (m)GX] is one of the most highly expressed PLA2 in the mouse colon and that recombinant mouse and human enzymes stimulate proliferation and mitogen-activated protein kinase activation of various colon cell lines, including Colon-26 cancer cells. Among various recombinant sPLA2s, mGX is the most potent enzyme to stimulate cell proliferation. Based on the use of sPLA2 inhibitors, catalytic site mutants, and small interfering RNA silencing of cytosolic PLA2α and M-type sPLA2 receptor, we demonstrate that mGX promotes cell proliferation independently of the receptor and via its intrinsic catalytic activity and production of free arachidonic acid and lysophospholipids, which are mitogenic by themselves. mGX can also elicit the production of large amounts of prostaglandin E2 and other eicosanoids from Colon-26 cells, but these lipid mediators do not play a role in mGX-induced cell proliferation because inhibitors of cyclooxygenases and lipoxygenases do not prevent sPLA2 mitogenic effects. Together, our results indicate that group X sPLA2 may play an important role in colon tumorigenesis by promoting cancer cell proliferation and releasing various lipid mediators involved in other key events in cancer progression.

Structure–activity relationships in platelet-activating factor (PAF). 11-From PAF-antagonism to phospholipase A2 inhibition: syntheses and structure–activity relationships in 1-arylsulfamido-2-alkylpiperazines

1-Benzoyl-2-alkyl piperazines are strong inhibitors of Group I and II secreted PLA(2)s. An improvement of their activity was obtained by replacing the amide function by a sulfamide and by introduction of electrodonor substituents on the para position of the benzenesulfonyl moiety. Neither the position on one of the carbon of the piperazine ring nor the absolute configuration of this carbon have an effect on the affinity for one or the other group of PLA(2), but the lipophilicity remains for these series an essential parameter. In addition structure-activity relationships allow new hypothesis on interaction of these piperazine derivatives with the catalytic site of PLA(2)s.

Activation of rabbit blood platelets by anandamide through its cleavage into arachidonic acid

Anandamide (ANA), a cannabinoid receptor ligand, stimulated platelet aggregation at concentrations similar to those of arachidonic acid (AA). The aggregating effect of ANA was inhibited by aspirin but not by SR‐141716, a cannabinoid receptor antagonist. In addition, HU‐210, a cannabinoid receptor agonist, failed to induce platelet activation. Radiolabelling experiments showed that exogenous ANA was cleaved by platelets into AA through a phenylmethylsulfonyl fluoride (PMSF)‐sensitive pathway. In agreement, PMSF was shown to abolish the aggregating effect of ANA. In conclusion, ANA is able to induce platelet activation via its cleavage by a PMSF‐sensitive amidase activity, leading to the release of AA which in turn activates platelets.

4-Alkoxybenzamidines as new potent phospholipase A2 inhibitors.

A series of 4-alkoxybenzamidines was synthesized, varying the number of carbons of the alkyl chain, and their potency as phospholipase A2 (PLA2) inhibitors was evaluated. The relationship between their capacity to inhibit PLA2 activity and their lipophilicity was examined. The optimum of the inhibitory effect against two extracellular PLA2S from rabbit platelets and bovine pancreas was observed with compounds bearing an alkyl chain of 12 and 14 carbons. These 4-dodecyl and tetradecyloxbenzamidines inhibited bovine pancreatic and rabbit platelet lysate PLA2S with IC50 values of 3 microM and 5-5.8 microM, respectively. The mechanism of inhibition was of the competitive type. In addition, 4-tetradecyloxbenzamidine was shown to exert an antiinflammatory effect in vivo on the carrageenan-induced rat paw oedema. These results show that 4-tetradecyloxybenzamidine will serve as an interesting tool to investigate the physiological role of mammalian-secreted PLA2, both in vitro and in vivo.

Total direct chemical synthesis and biological activities of human group IIA secretory phospholipase A2.

Human group IIA secretory phospholipase A(2) (hGIIA sPLA(2)) is reported to be involved in inflammation, since its expression level is enhanced under various inflammatory conditions. In this work, we report the total chemical synthesis of this enzyme (124 amino acids) by solid-phase method. The identity of the protein, in denatured or folded (7 disulphide bonds) forms, was confirmed by electrospray MS. Synthetic sPLA(2) possesses the same circular dichroism spectrum, enzymic activity in hydrolysing different phospholipid substrates, and inhibitory effect in thrombin formation from prothrombinase complex as the recombinant sPLA(2). Furthermore, LY311727, a reported specific hGIIA sPLA(2) inhibitor, is able to inhibit the synthetic and the recombinant enzymes with the same efficiency. This study demonstrates that chemically continuous solid phase synthesis is an alternative and less time-consuming approach to producing small, structurally folded and fully active proteins of up to 124 amino acids, such as hGIIA sPLA(2). Moreover, this technique provides more flexibility in analogue synthesis to elucidate their physiological functions and pathological effects.

Structure-activity relationships in platelet activating factor. 9. From PAF-antagonism to PLA2 inhibition

Many important mediators of inflammation result from the liberation of free arachidonic acid from phospholipid pools, which arise from the action of phospholipase A2 (PLA2). Therefore the inhibition of this enzyme would be an important treatment in many inflammatory disease states. Starting from a series of compounds which are known as PAF-antagonists, we have synthesized new molecules. These new compounds inhibited various secretory PLA2s, with IC50s in the mumol range. This allowed us to analyze the structure-activity relationships for PLA2 inhibition. The results showed that inhibition of secretory PLA2 depends on the length of the alkyl chain, with an optimum for 13 to 17 carbons, which is in agreement with X-ray crystallographic and nuclear magnetic resonance (NMR) studies on the active site of PLA2s, and that a free nitrogen on the piperazine ring is required to ensure a good inhibitory potency.