Dentan C, Lesnik P, Chapman M J, Ninio E
Institut National de la Santé et de la Recherche Médicale U-321, Hôpital de la Pitie, Paris, France.
Eur J Biochem. 1996 Feb 15;236(1):48-55. doi: 10.1111/j.1432-1033.1996.00048.x.
Monocyte-derived macrophages and macrophage-derived foam cells in arterial tissue may undergo phagocytic activation and thereby contribute to an inflammatory reaction. We have investigated the effect of phagocytic activation on the formation of platelet-activating factor (1-0-alkyl-2-acetyl-sn-glycero-3-phosphocholine, PAF-acether, PAF), a proinflammatory phospholipid, in human monocyte-derived macrophages (macrophages) and in cholesterol-loaded macrophage foam cells (foam cells). Adherent human monocyte-derived macrophages were transformed into foam cells upon incubation with acetylated low-density lipoproteins (Ac-LDL). Such foam cells characteristically displayed a markedly increased content of cholesteryl esters compared with macrophages (4.3 +/- 1.3 microgram/microgram DNA and 0.2 +/- 0.3 microgram/microgram DNA, n = 5, respectively). After phagocytic stimulation with serum-opsonized zymosan (OPZ), both macrophages and foam cells synthesized PAF transiently with maximal production (0.5-1.1 pmol PAF/microgram DNA, n = 5, corresponding to 4.0-8.8 pmol PAF/10(6) cells, as assessed by bioassay) occurring approximately 15 min after stimulation. A major fraction of the synthesized PAF remained cell-associated; such PAF was composed mainly of the hexadecyl (16:0 PAF, approximately 75%) and the octadecenyl (18:1 PAF) species and of trace amounts of octadecyl (18:0 PAF), as assessed by reverse-phase liquid chromatography. Addition of exogenous 16:0 lyso-PAF alone triggered PAF formation (0.9-1.7 pmol PAF/microgram DNA, after 15 min of cellular stimulation); simultaneous cellular stimulation with OPZ and 16:0 lyso-PAF increased PAF formation in an additive manner. Acetyltransferase, the enzyme which acetylates the precursor lyso-PAF and transforms it into PAF, displayed elevated activity both in macrophages and in foam cells, attaining 83-240 pmol PAF formed per min per mg DNA (n = 4); such elevated activity was not increased by OPZ-stimulation. The activity of acetylhydrolase, the PAF-degrading enzyme, was similar in macrophages and in foam cells, and varied between 120 pmol and 320 pmol PAF degraded per min per mg DNA (n = 5). Cell-associated acetylhydrolase activity was increased significantly by 40+/-15 % (P < 0.003, n = 5) after 15 - 30 min of activation with OPZ compared with non-stimulated cells and may account for the rapid decrease in cellular PAF content observed approximately 30 min after stimulation. These studies have established that metabolism of PAF in foam cells closely resembles that in macrophages, and thus PAF metabolism is largely independent of cellular cholesterol content. Moreover our data are consistent with the hypothesis that both macrophages and macrophage-derived foam cells upon phagocytic-activation constitute a significant transient source of PAF at inflammatory sites in the arterial intima where this phospholipidic mediator may exert potent proatherogenic and prothrombotic effects.
动脉组织中的单核细胞衍生巨噬细胞和巨噬细胞衍生泡沫细胞可能会经历吞噬激活,从而引发炎症反应。我们研究了吞噬激活对人单核细胞衍生巨噬细胞(巨噬细胞)和胆固醇负载的巨噬细胞泡沫细胞(泡沫细胞)中促炎磷脂血小板活化因子(1-0-烷基-2-乙酰基-sn-甘油-3-磷酸胆碱,PAF-乙醚,PAF)形成的影响。贴壁的人单核细胞衍生巨噬细胞在与乙酰化低密度脂蛋白(Ac-LDL)孵育后转变为泡沫细胞。与巨噬细胞相比,此类泡沫细胞的胆固醇酯含量显著增加(分别为4.3±1.3微克/微克DNA和0.2±0.3微克/微克DNA,n = 5)。在用血清调理酵母聚糖(OPZ)进行吞噬刺激后,巨噬细胞和泡沫细胞均短暂合成PAF,刺激后约15分钟产量达到最大值(0.5 - 1.1皮摩尔PAF/微克DNA,n = 5,通过生物测定评估,相当于4.0 - 8.8皮摩尔PAF/10⁶细胞)。合成的PAF大部分与细胞相关;通过反相液相色谱评估,此类PAF主要由十六烷基(16:0 PAF,约75%)和十八烯基(18:1 PAF)种类以及微量的十八烷基(18:0 PAF)组成。单独添加外源性16:0溶血PAF可引发PAF形成(细胞刺激15分钟后为0.9 - 1.7皮摩尔PAF/微克DNA);同时用OPZ和16:0溶血PAF进行细胞刺激以相加方式增加PAF形成。乙酰转移酶是将前体溶血PAF乙酰化并将其转化为PAF的酶,在巨噬细胞和泡沫细胞中活性均升高,达到每分钟每毫克DNA形成83 - 240皮摩尔PAF(n = 4);这种升高的活性不受OPZ刺激的影响。PAF降解酶乙酰水解酶的活性在巨噬细胞和泡沫细胞中相似,每分钟每毫克DNA降解的PAF在120皮摩尔至320皮摩尔之间变化(n = 5)。与未刺激的细胞相比,用OPZ激活15 - 30分钟后,细胞相关的乙酰水解酶活性显著增加40±15%(P < 0.003,n = 5),这可能解释了刺激后约30分钟观察到的细胞PAF含量的快速下降。这些研究表明,泡沫细胞中PAF的代谢与巨噬细胞中的代谢非常相似,因此PAF代谢在很大程度上独立于细胞胆固醇含量。此外我们的数据与以下假设一致,即巨噬细胞和巨噬细胞衍生的泡沫细胞在吞噬激活后在动脉内膜的炎症部位构成PAF的重要短暂来源,这种磷脂介质可能发挥强大的促动脉粥样硬化和促血栓形成作用。
