Structure-activity analysis of the effects of lysophosphatidic acid on platelet aggregation.

Lysophosphatidic acid (1-acyl-sn-glycero-3-phosphate or LPA) is a phospholipid mediator displaying numerous and widespread biological activities and thought to act via G-protein-coupled receptors. Here we have studied the effects on human platelets of a number of LPA analogues, including two enantiomers of both N-palmitoyl-(L)-serine-3-phosphate ((L) and (D)NAPS for N-acyl-phosphoserine) and 2-(R)-N-palmitoyl-norleucinol-1-phosphate ((R) and (S)PNPA), cyclic analogues of 1-acyl-sn-glycero-3-phosphate (cPA) and of 1-O-hexadecyl-sn-glycero-3-phosphate (cAGP), sphingosine-1-phosphate (SPP), as well as two palmitoyl derivatives of dioxazaphosphocanes bearing either a P-H or a P-OH bond (DOXP-H and DOXP-OH, respectively). Nine of these compounds induced platelet aggregation with the following order of potency: SPP < cAGP < DOXP-OH < (L)NAPS = (D)NAPS < (R)PNPA = (S)PNPA < LPA < AGP, EC50 varying between 9.8 nM and 8.3 microM. Two of these compounds (SPP and cAGP) appeared as weak agonists inducing platelet aggregation to only 33% and 41%, respectively, of the maximal response attained with LPA and other analogues. In cross-desensitization experiments, all of these compounds specifically inhibited LPA-induced aggregation, suggesting that they were all acting on the same receptor(s). In contrast, cPA and DOXP-H did not trigger platelet aggregation but instead specifically inhibited the effects of LPA in a concentration-dependent manner. The inhibitory action of cPA did not vary with the acyl chain length or the presence of a double bond and did not involve an increase in cAMP. These data thus confirm the lack of stereospecificity of platelet LPA receptor(s). In addition, since the order of potency of some analogues is different from that described in other cells, our results suggest that platelets contain (a) pharmacologically distinct receptor(s) whose molecular identity still remains to be established. Finally, this unique series of compounds might be used for further characterization of other endogenous or recombinant LPA receptors.

Lysophosphatidic acid as a phospholipid mediator: pathways of synthesis.

From very recent studies, including molecular cloning of cDNA coding for membrane receptors, lysophosphatidic acid (LPA) reached the status of a novel phospholipid mediator with various biological activities. Another strong argument supporting this view was the discovery that LPA is secreted from activated platelets, resulting in its appearance in serum upon blood coagulation. The metabolic pathways as well as the enzymes responsible for LPA production are poorly characterized. However, a survey of literature data indicates some interesting issues which might be used as the basis for further molecular characterization of phospholipases A able to degrade phosphatidic acid.

Inhibition of platelet type II phospholipase A2 by an acylamino phospholipid does not alter arachidonate liberation.

An acylamino phospholipid analogue (2-(R)-N-palmitoylnorleucinol-1-phosphoglycol or (R)-PNPG) was examined for its inhibitory effects against type II phospholipase A2 (PLA2) acting on membranes from Escherichia coli. Using two enzyme sources (rat platelet membranes or recombinant human type II PLA2), (R)-PNPG inhibited phospholipid hydrolysis to a maximal value of 80-85%, half-maximal effect being attained at a substrate/inhibitor molar ratio of 80-250. In contrast, (S)-PNPG was 12-fold less potent and thus provided a control for possible non-specific effects of these polar lipids. However, both analogues exerted only marginal effects on the liberation of [3H]arachidonic acid from rat platelets challenged with calcium ionophore A23187. Since, among various animal species, rat platelets contain by far the highest amounts of this enzyme, our data rule out any possible involvement of secretory PLA2 in arachidonic acid liberation from platelet phospholipids, cytosolic PLA2 appearing in this case as the best candidate able to regulate eicosanoid biosynthesis.