Opposite effects of native and oxidized lipoproteins on the activity of secretory phospholipase A(2) group IIA.

Elevated circulating level and activity of secretory phospholipase A(2) group IIA (sPLA(2)(IIA)) are associated with the development of adverse cardiovascular events. The mechanisms of sPLA(2)(IIA) activity regulation in human blood serum so far remain obscure. We have suggested that the enzyme activity is influenced by circulating lipoproteins. The activity of sPLA(2)(IIA) was examined in whole serum of healthy individuals and after removal of lipoproteins from it. The effects of different classes of native and oxidized lipoproteins on sPLA(2)(IIA) in blood serum were compared with their effects on purified sPLA(2)(IIA). Activity of sPLA(2)(IIA) was not detected in whole serum despite the high concentration of the enzyme. However after lipoproteins had been removed from the serum, the lipoprotein-depleted serum displayed sPLA(2)(IIA) activity which was proportional to the amount of sPLA(2)(IIA) in it. Native LDL, HDL and VLDL+IDL inhibited the activity of both purified sPLA(2)(IIA) and the enzyme activity in lipoprotein-depleted serum. By contrast, oxidized LDL, HDL and VLDL+IDL significantly stimulated the activity of purified and serum sPLA(2)(IIA) and enhanced the release of fatty acids from the substrate. The data indicate that native and oxidized lipoproteins regulate catalytic activity of sPLA(2)(IIA). Activation of sPLA(2)(IIA) by oxidized lipoproteins may be regarded as one of the mechanisms of atherosclerosis development.

The catalytically active secretory phospholipase A2 type IIA is involved in restenosis development after PTCA in human coronary arteries and generation of atherogenic LDL.

Secretory phospholipase A2 type IIA (sPLA2) may actively contribute to atherogenesis, acting either within the arterial wall or in plasma. Proinflammatory eicosanoids and lysophospholipids, generated through hydrolysis of cell membrane phospho-lipids by sPLA2, initiate and prolong the inflammatory process. In the present study we examined the possible involvement of sPLA2 in development of restenosis in patients undergoing percutaneous transluminal coronary angioplasty (PTCA). We also investigated whether serum sPLA2 could catalyze accumulation of lysophosphatidylcholine (LPC) in LDL. Concentrations and catalytic activities of sPLA2 were measured in blood serum of 49 consenting patients immediately before, 1-7 and 180 days after PTCA. All patients had repeat angiograms at 180-day follow-up. Restenosis was registered in 19 patients. Accumulation of LPC in LDL was evaluated by thin-layer chromatography after incubation of blood serum with LDL. Serum sPLA2 concentrations increased in all study patients by day 1 post-PTCA, but the increase was significantly greater and more protracted in patients who developed restenosis. Catalytic activities increased significantly 6 days post-PTCA in patients who developed restenosis, whereas for patients without restenosis there was no change in serum sPLA2 activity throughout the study period in spite of the sPLA2 presence in blood. Incubation of blood serum (6 days post-PTCA) with LDL resulted in accumulation of LPC only for those patients who subsequently developed restenosis. Manoalide, a specific inhibitor of sPLA2, completely blocked the LPC accumulation. The data indicate that elevated serum sPLA2 activity after PTCA is associated with restenosis development and may be involved in atherogenic modification of LDL in blood serum.