Carty T J, Sweeney F J, Griffiths R J, Eskra J D, Ernest M J, Pillar J S, Cheng J D, Loose L D, Joseph P A, Pazoles P P, Moore P F, Nagahisa A, Murase S, Kadin S B
Central Research Division, Pfizer Inc., Groton, CT 06340, USA.
Inflamm Res. 1997 May;46(5):168-79. doi: 10.1007/s000110050163.
The effect of tenidap on the metabolism of arachidonic acid via the 5-lipoxygenase (5-LO) pathway was investigated in vitro and in vivo.
In vitro (cells). Arachidonic acid (AA) stimulated rat basophilic leukemia, (RBL) cells; A23817 activated neutrophils (human rat, and rabbit), macrophages (rat), and blood (human). In vitro (enzyme activity). RBL-cell homogenate; purified human recombinant 5-LO. In vivo: Rat (Sprague-Dawley) models in which peritoneal leukotriene products were measured after challenge with zymosan (3 animals per group), A23187 (11 animals per group), and immune complexes (3-5 animals per group), respectively.
5-Hydroxyeicosatetraenoic acid (5-HETE) and dihydroxyeicosatetraenoic acids (diHETEs, including LTB4) were measured as radiolabeled products (derived from [14C]-AA) or by absorbance at 235 or 280 nm, respectively, after separation by HPLC. Radiolabeled 5-HPETE was measured by a radio-TLC analyser after separation by thin layer chromatography (TLC). Deacylation of membrane bound [14C]-AA was determined by measuring radiolabel released into the extracellular medium. 5-LO translocation from cytosol to membrane was assessed by western analysis. Rat peritoneal fluid was assayed for PGE, 6-keto-PGF1 alpha, LTE4 or LTB4 content by EIA and for TXB2 by RIA.
Tenidap suppressed 5-LO mediated product production in cultured rat basophilic leukemia (RBL-1) cells from exogenously supplied AA, and in human and rat neutrophils, and rat peritoneal macrophages stimulated with A23187 (IC50, 5-15 microM). In addition, tenidap was less potent in inhibiting the release of radiolabeled AA from RBL-1 cells (IC50, 180 microM), suggesting that the decrease in 5-LO derived products could not be explained by an effect on cellular mobilization of AA (i.e., phospholipase). Tenidap blocked 5-hydroxyeicosatetraenoic acid (5-HETE) production by dissociated RBL-1 cell preparations (IC50, 7 microM), as well as by a 100000 x g supernatant of 5-LO/hydroperoxidase activity, suggesting a direct effect on the 5-LO enzyme itself. In addition, tenidap impaired 5-LO translocation from cytosol to its membrane-bound docking protein (FLAP) which occurs when human neutrophils are stimulated with calcium ionophore, indicating a second mechanism for inhibiting the 5-LO pathway. Surprisingly, tenidap did not block the binding of radiolabeled MK-0591, an indole ligand of FLAP, to neutrophil membranes. Although its ability to inhibit the cyclooxygenase pathway was readily observed in whole blood and in vivo, tenidap's 5-LO blockade could not be demonstrated by ionophore stimulated human blood, nor after oral dosing in rat models in which peritoneal leukotriene products were measured after challenge with three different stimuli. The presence of extracellular proteins greatly reduced the potency of tenidap as a 5-LO inhibitor in vitro, suggesting that protein binding is responsible for loss of activity in animal models.
Tenidap inhibits 5-lipoxygenase activity in vitro both directly and indirectly by interfering with its translocation from cytosol to the membrane compartment in neutrophils. A potential mechanism for the latter effect is discussed with reference to tenidap's ability to lower intracellular pH. Tenidap did not inhibit 5-LO pathway activity in three animal models.
在体外和体内研究替硝唑对花生四烯酸通过5-脂氧合酶(5-LO)途径代谢的影响。
体外(细胞)。花生四烯酸(AA)刺激大鼠嗜碱性白血病(RBL)细胞;A23817激活中性粒细胞(人、大鼠和兔)、巨噬细胞(大鼠)和血液(人)。体外(酶活性)。RBL细胞匀浆;纯化的人重组5-LO。体内:用酵母聚糖(每组3只动物)、A23187(每组11只动物)和免疫复合物(每组3 - 5只动物)攻击后测量腹膜白三烯产物的大鼠(Sprague-Dawley)模型。
5-羟基二十碳四烯酸(5-HETE)和二羟基二十碳四烯酸(二HETEs,包括LTB4)分别作为放射性标记产物(源自[14C]-AA)或通过高效液相色谱(HPLC)分离后在235或280nm处的吸光度进行测量。放射性标记的5-HPETE在通过薄层色谱(TLC)分离后用放射性TLC分析仪测量。通过测量释放到细胞外培养基中的放射性标记来确定膜结合的[14C]-AA去酰化。通过蛋白质印迹分析评估5-LO从细胞质到膜的转位。通过酶免疫分析(EIA)测定大鼠腹膜液中PGE、6-酮-PGF1α、LTE4或LTB4含量,通过放射免疫分析(RIA)测定TXB2含量。
替硝唑抑制外源性提供的AA刺激的培养大鼠嗜碱性白血病(RBL-1)细胞、人及大鼠中性粒细胞以及用A23187刺激的大鼠腹膜巨噬细胞中5-LO介导的产物生成(IC50,5 - 15μM)。此外,替硝唑抑制RBL-1细胞中放射性标记AA释放的效力较低(IC50,180μM),这表明5-LO衍生产物的减少不能用对AA细胞动员(即磷脂酶)的影响来解释。替硝唑通过解离的RBL-1细胞制剂(IC50,7μM)以及5-LO/氢过氧化物酶活性的100000×g上清液阻断5-羟基二十碳四烯酸(5-HETE)的生成,表明对5-LO酶本身有直接作用。此外,替硝唑损害了5-LO从细胞质到其膜结合对接蛋白(FLAP)的转位,这种转位在人中性粒细胞用钙离子载体刺激时发生,这表明了抑制5-LO途径的第二种机制。令人惊讶的是,替硝唑没有阻断放射性标记的MK-0591(FLAP的吲哚配体)与中性粒细胞膜的结合。尽管在全血和体内很容易观察到其抑制环氧化酶途径的能力,但在离子载体刺激的人血液中以及在大鼠模型中口服给药后(在三种不同刺激攻击后测量腹膜白三烯产物),均未证明替硝唑对5-LO的阻断作用。细胞外蛋白质的存在大大降低了替硝唑作为5-LO抑制剂在体外的效力,这表明蛋白质结合是动物模型中活性丧失的原因。
替硝唑在体外通过干扰其从细胞质到中性粒细胞膜区室的转位直接和间接抑制5-脂氧合酶活性。参考替硝唑降低细胞内pH的能力讨论了后一种作用的潜在机制。替硝唑在三种动物模型中未抑制5-LO途径活性。
