Malygin Vladimir V, Sokolov Vladimir B, Richardson Rudy J, Makhaeva Galina F
Institute of Physiologically Active Compounds, Russian Academy of Sciences, Chernogolovka, Moscow Region, Russia.
J Toxicol Environ Health A. 2003 Apr 11;66(7):611-25. doi: 10.1080/15287390309353770.
Inhibition of acetylcholinesterase (AChE) versus inhibition and aging of neuropathy target esterase (NTE) by organophosphorus (OP) compounds in vivo can give rise to distinct neurological consequences: acute cholinergic toxicity versus OP compound-induced delayed neurotoxicity (OPIDN). Previous work has shown that the relative potency of an OP compound to react with NTE versus AChE in vitro may predict its capability to produce OPIDN. The present study was conducted to evaluate further the validity of such predictions and to enhance them with quantitative structure-activity relationships (QSAR) using a homologous series of alkyl phenylphosphonates (RO)C6H5P(O)ON = CCICH3 (PhP; R = alkyl). Neuropathic potential of PhP was assessed by measuring ki(NTE)ki(AChE) ratios in vitro and comparing these with ED50 ratios in vivo. Selectivity for NTE increased with rising R-group hydrophobicity. The ki(NTE)/ki(AChE) ratios were 0.42 (methyl), 3.6 (ethyl), 15 (isopropyl), 36 (propyl), 69 (isobutyl), 105 (butyl), and 124 (pentyl). Ratios > 1 suggest the potential to produce OPIDN at doses lower than the LD50. Inhibition of NTE and AChE in hen brain in vivo was studied 24 h after i.m. injection of hens with increasing doses of methyl and butyl derivatives. Analysis of dose-response curves yielded ED50(AChE)/ED50(NTE) ratio of 0.86 for methyl PhP and 22.1 for butyl PhP. These results predict that the butyl derivative should be more neuropathic than the methyl analogue. Excellent correspondence between in vivo and in vitro predictions of neuropathic potential indicate that valid predictive QSAR models may be based on the in vitro approach. Adoption of this system would result in reducing experimental animal use, lowering costs, accelerating data production, and enabling standardization of a biochemically based risk assessment of the neuropathic potential of OP compounds.
有机磷(OP)化合物在体内对乙酰胆碱酯酶(AChE)的抑制作用与对神经病靶酯酶(NTE)的抑制及老化作用可导致不同的神经学后果:急性胆碱能毒性与OP化合物诱导的迟发性神经毒性(OPIDN)。先前的研究表明,一种OP化合物在体外与NTE和AChE反应的相对效力可预测其产生OPIDN的能力。本研究旨在进一步评估此类预测的有效性,并使用一系列烷基苯基膦酸酯(RO)C6H5P(O)ON = CCICH3(PhP;R =烷基)通过定量构效关系(QSAR)来加强这些预测。通过测量体外的ki(NTE)/ki(AChE)比值并将其与体内的ED50比值进行比较,评估了PhP的神经病变潜力。对NTE的选择性随R基团疏水性的增加而提高。ki(NTE)/ki(AChE)比值分别为0.42(甲基)、3.6(乙基)、15(异丙基)、36(丙基)、69(异丁基)、105(丁基)和124(戊基)。比值>1表明在低于半数致死剂量(LD50)时具有产生OPIDN的潜力。在给母鸡肌肉注射递增剂量的甲基和丁基衍生物24小时后,研究了其体内对母鸡脑内NTE和AChE的抑制作用。剂量-反应曲线分析得出,甲基PhP的ED50(AChE)/ED50(NTE)比值为0.86,丁基PhP的为22.1。这些结果预测丁基衍生物的神经病变性应比甲基类似物更强。体内和体外对神经病变潜力的预测之间具有极好的一致性,这表明有效的预测QSAR模型可能基于体外方法。采用该系统将减少实验动物的使用、降低成本、加快数据生成,并使基于生化的OP化合物神经病变潜力风险评估标准化。
