Grijalba M T, Andrade P B, Meinicke A R, Castilho R F, Vercesi A E, Schreier S
Department of Biochemistry, Institute of Chemistry, Universidade de São Paulo, SP, Brazil.
Free Radic Res. 1998 Mar;28(3):301-18. doi: 10.3109/10715769809069282.
In the present study we show that K+/H+ hydroxyl-containing ionophores lasalocid-A (LAS) and nigericin (NIG) in the nanomolar concentration range, inhibit Fe2+-citrate and 2,2'-azobis(2-amidinopropane) dihydrochloride (ABAP)-induced lipid peroxidation in intact rat liver mitochondria and in egg phosphatidylcholine (PC) liposomes containing negatively charged lipids--dicetyl phosphate (DCP) or cardiolipin (CL)--and KCl as the osmotic support. In addition, monensin (MON), a hydroxyl-containing ionophore with higher affinity for Na+ than for K+, promotes a similar effect when NaCl is the osmotic support. The protective effect of the ionophores is not observed when the osmolyte is sucrose. Lipid peroxidation was evidenced by mitochondrial swelling, antimycin A-insensitive O2 consumption, formation of thiobarbituric acid-reactive substances (TBARS), conjugated dienes, and electron paramagnetic resonance (EPR) spectra of an incorporated lipid spin probe. A time-dependent decay of spin label EPR signal is observed as a consequence of lipid peroxidation induced by both inductor systems in liposomes. Nitroxide destruction is inhibited by butylated hydroxytoluene, a known antioxidant, and by the hydroxyl-containing ionophores. In contrast, valinomycin (VAL), which does not possess alcoholic groups, does not display this protective effect. Effective order parameters (Seff), determined from the spectra of an incorporated spin label are larger in the presence of salt and display a small increase upon addition of the ionophores, as a result of the increase of counter ion concentration at the negatively charged bilayer surface. This condition leads to increased formation of the ion-ionophore complex, the membrane binding (uncharged) species. The membrane-incorporated complex is the active species in the lipid peroxidation inhibiting process. Studies in aqueous solution (in the absence of membranes) showed that NIG and LAS, but not VAL, decrease the Fe2+-citrate-induced production of radicals derived from piperazine-based buffers, demonstrating their property as radical scavengers. Both Fe2+-citrate and ABAP promote a much more pronounced decrease of LAS fluorescence in PC/CL liposomes than in dimyristoyl phosphatidylcholine (DMPC, saturated phospholipid)-DCP liposomes, indicating that the ionophore also scavenges lipid peroxyl radicals. A slow decrease of fluorescence is observed in the latter system, for all lipid compositions in sucrose medium, and in the absence of membranes, indicating that the primary radicals stemming from both inductors also attack the ionophore. Altogether, the data lead to the conclusion that the membrane-incorporated cation complexes of NIG, LAS and MON inhibit lipid peroxidation by blocking initiation and propagation reactions in the lipid phase via a free radical scavenging mechanism, very likely due to the presence of alcoholic hydroxyl groups in all three molecules and to the attack of the aromatic moiety of LAS.
在本研究中,我们发现纳摩尔浓度范围的含K⁺/H⁺羟基离子载体拉沙洛西-A(LAS)和尼日利亚菌素(NIG)可抑制完整大鼠肝线粒体以及含有带负电荷脂质(二鲸蜡基磷酸酯(DCP)或心磷脂(CL))和KCl作为渗透支持物的卵磷脂(PC)脂质体中柠檬酸铁和2,2'-偶氮二(2-脒基丙烷)二盐酸盐(ABAP)诱导的脂质过氧化。此外,莫能菌素(MON)是一种对Na⁺的亲和力高于对K⁺的亲和力的含羟基离子载体,当NaCl作为渗透支持物时,它也能促进类似的效果。当渗透剂是蔗糖时,未观察到离子载体的保护作用。脂质过氧化通过线粒体肿胀、抗霉素A不敏感的O₂消耗、硫代巴比妥酸反应性物质(TBARS)的形成、共轭二烯以及掺入的脂质自旋探针的电子顺磁共振(EPR)光谱来证明。由于脂质体中两种诱导系统诱导的脂质过氧化,观察到自旋标记EPR信号随时间衰减。氮氧化物的破坏受到已知抗氧化剂丁基化羟基甲苯和含羟基离子载体的抑制。相比之下,不具有醇基的缬氨霉素(VAL)没有这种保护作用。从掺入的自旋标记光谱确定的有效序参数(Seff)在有盐存在时更大,并且在加入离子载体后略有增加,这是由于带负电荷的双层表面反离子浓度增加的结果。这种情况导致离子 - 离子载体复合物(膜结合(不带电荷)物种)形成增加。膜结合复合物是脂质过氧化抑制过程中的活性物种。在水溶液(无膜)中的研究表明,NIG和LAS,但不是VAL,可降低柠檬酸铁诱导的哌嗪基缓冲液衍生自由基的产生,证明它们作为自由基清除剂的特性。柠檬酸铁和ABAP在PC/CL脂质体中比在二肉豆蔻酰磷脂酰胆碱(DMPC,饱和磷脂)-DCP脂质体中更显著地降低LAS荧光,表明离子载体也能清除脂质过氧自由基。在蔗糖介质中所有脂质组成的后者系统以及无膜情况下,观察到荧光缓慢下降,表明两种诱导剂产生的初级自由基也会攻击离子载体。总之,数据得出结论,NIG、LAS和MON的膜结合阳离子复合物通过自由基清除机制阻断脂质相中的引发和传播反应来抑制脂质过氧化,这很可能是由于所有三个分子中都存在醇羟基以及LAS的芳香部分受到攻击。
