Department of Pharmaceutical Science, Faculty of Pharmacy, University of Toronto, Toronto, Ontario, Canada.
Chem Biol Interact. 2011 May 30;191(1-3):308-14. doi: 10.1016/j.cbi.2011.01.017. Epub 2011 Jan 26.
Methanol (CH(3)OH), a common industrial solvent, is metabolized to toxic compounds by several enzymatic as well as free radical pathways. Identifying which process best enhances or prevents CH(3)OH-induced cytotoxicity could provide insight into the molecular basis for acute CH(3)OH-induced hepatoxicity. Metabolic pathways studied include those found in 1) an isolated hepatocyte system and 2) cell-free systems. Accelerated Cytotoxicity Mechanism Screening (ACMS) techniques demonstrated that CH(3)OH had little toxicity towards rat hepatocytes in 95% O(2), even at 2M concentration, whereas 50 mM was the estimated LC(50) (2h) in 1% O(2), estimated to be the physiological concentration in the centrilobular region of the liver and also the target region for ethanol toxicity. Cytotoxicity was attributed to increased NADH levels caused by CH(3)OH metabolism, catalyzed by ADH1, resulting in reductive stress, which reduced and released ferrous iron from Ferritin causing oxygen activation. A similar cytotoxic mechanism at 1% O(2) was previous found for ethanol. With 95% O(2), the addition of Fe(II)/H(2)O(2), at non-toxic concentrations were the most effective agents for increasing hepatocyte toxicity induced by 1M CH(3)OH, with a 3-fold increase in cytotoxicity and ROS formation. Iron chelators, desferoxamine, and NADH oxidizers and ATP generators, e.g. fructose, also protected hepatocytes and decreased ROS formation and cytotoxicity. Hepatocyte protein carbonylation induced by formaldehyde (HCHO) formation was also increased about 4-fold, when CH(3)OH was oxidized by the Fenton-like system, Fe(II)/H(2)O(2), and correlated with increased cytotoxicity. In a cell-free bovine serum albumin system, Fe(II)/H(2)O(2) also increased CH(3)OH oxidation as well as HCHO protein carbonylation. Nontoxic ferrous iron and a H(2)O(2) generating system increased HCHO-induced cytotoxicity and hepatocyte protein carbonylation. In addition, HCHO cytotoxicity was markedly increased by ADH1 and ALDH2 inhibitors or GSH-depleted hepatocytes. Increased HCHO concentration levels correlated with increased HCHO-induced protein carbonylation in hepatocytes. These results suggest that CH(3)OH at 1% O(2) involves activation of the Fenton system to form HCHO. However, at higher O(2) levels, radicals generated through Fe(II)/H(2)O(2) can oxidize CH(3)OH/HCHO to form pro-oxidant radicals and lead to increased oxidative stress through protein carbonylation and ROS formation which ultimately causes cell death.
甲醇(CH(3)OH),一种常见的工业溶剂,通过多种酶促和自由基途径代谢为有毒化合物。确定哪种过程最能增强或防止 CH(3)OH 诱导的细胞毒性,可以深入了解急性 CH(3)OH 诱导肝毒性的分子基础。研究的代谢途径包括 1)在分离的肝细胞系统中和 2)无细胞系统中发现的途径。加速细胞毒性机制筛选(ACMS)技术表明,即使在 2M 浓度下,CH(3)OH 在 95%O(2)中对大鼠肝细胞的毒性很小,而在 1%O(2)中的估计 LC(50)(2h)为 50mM,估计为肝中央小叶区的生理浓度,也是乙醇毒性的靶区。细胞毒性归因于 ADH1 催化的 CH(3)OH 代谢引起的 NADH 水平升高,导致还原应激,从而从铁蛋白中还原并释放二价铁,导致氧激活。以前在 1%O(2)下发现了类似的乙醇细胞毒性机制。在 95%O(2)下,添加非毒性浓度的 Fe(II)/H(2)O(2)是增加 1M CH(3)OH 诱导的肝细胞毒性最有效的试剂,细胞毒性和 ROS 形成增加了 3 倍。铁螯合剂、去铁胺和 NADH 氧化剂和 ATP 生成剂,如果糖,也能保护肝细胞并减少 ROS 形成和细胞毒性。当 Fenton 样系统 Fe(II)/H(2)O(2)氧化 CH(3)OH 时,甲醛(HCHO)形成诱导的肝细胞蛋白羰基化也增加了约 4 倍,并且与细胞毒性增加相关。在无细胞牛血清白蛋白系统中,Fe(II)/H(2)O(2)也增加了 CH(3)OH 氧化和 HCHO 蛋白羰基化。非毒性二价铁和 H(2)O(2)生成系统增加了 HCHO 诱导的细胞毒性和肝细胞蛋白羰基化。此外,ADH1 和 ALDH2 抑制剂或 GSH 耗尽的肝细胞显着增加了 HCHO 的细胞毒性。增加的 HCHO 浓度水平与肝细胞中 HCHO 诱导的蛋白羰基化增加相关。这些结果表明,1%O(2)下的 CH(3)OH 涉及 Fenton 系统的激活以形成 HCHO。然而,在较高的 O(2)水平下,通过 Fe(II)/H(2)O(2)产生的自由基可以氧化 CH(3)OH/HCHO 形成促氧化剂自由基,并通过蛋白羰基化和 ROS 形成导致氧化应激增加,最终导致细胞死亡。
