QSAR Modeling of Antimycobacterial Activity and Activity Against Other Bacteria of 3‐Formyl Rifamycin SV Derivatives

I. DimovDimcho, Z. Nedyalkova, Svetla Haladjova, G. Schüürmann, O. Mekenyan
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引用次数: 8

Abstract

Rifamycins form a class of antibiotics with a specific potency as drug against tuberculosis via inhibition of the DNA-dependent RNA polymerase. In the present study, literature data on the antibacterial potency against Mycobacterium tuberculosis and other bacteria of 53 derivatives of 3-formyl rifamycin SV are subjected to a QSAR analysis using AM1-based quantum chemical descriptors and the recently introduced dynamic approach that allows explicit consideration of the conformational space of properly generated 3D structures. Data pre-treatment includes normalization of the minimum inhibition concentration (MIC) values of ordinary bacteria using the well-known antituberculosis drug rifampicine as reference compound (RIA), and averaging over the different strains as motivated by a mathematical analysis of the two-step inhibition process. For both this generalized potency against ordinary bacteria and the antimycobacterial activity, QSAR modelling yields 3-variable regression equations with acceptable statistics for screening purposes (r2 around 0.60), which however differ partly in the stepwise-selected molecular descriptors and the respective conformers. While both types of activity are increased by increasing HOMO energy reflecting an increased electron donor capability and tendency to undergo hydroquinone-semiquinone-quinone oxidation, the models differ in the best 2nd and 3rd local quantum chemical descriptors, pointing to partially conflicting electronic structure requirements for optimal antimycobacterial activity and generalized activity against other bacteria. The discussion includes a detailed mechanistic analysis of the underlying bioreactivity aspects.
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3‐甲酰基利福霉素SV衍生物抗细菌活性和抗其他细菌活性的QSAR模型
利福霉素是一类通过抑制dna依赖性RNA聚合酶而具有抗结核特异性效力的抗生素。在本研究中,使用基于am1的量子化学描述符和最近引入的动态方法对53种3-甲酰基利福霉素SV衍生物对结核分枝杆菌和其他细菌的抑菌力的文献数据进行了QSAR分析,该方法允许明确考虑适当生成的三维结构的构象空间。数据预处理包括使用著名的抗结核药物利福平(rifampicine)作为对照化合物(RIA)对普通细菌的最小抑制浓度(MIC)值进行归一化,并根据两步抑制过程的数学分析对不同菌株进行平均。对于这种针对普通细菌和抗细菌活性的一般效力,QSAR建模产生具有可接受的筛选统计数据的3变量回归方程(r2约为0.60),然而,在逐步选择的分子描述符和各自的构象中存在部分差异。虽然这两种类型的活性都通过增加HOMO能量而增加,这反映了电子供体能力的增加和对苯二酚-半醌-醌氧化的倾向,但模型在最佳的第二和第三局部量子化学描述符上存在差异,这表明最佳抗真菌活性和对其他细菌的普遍活性的电子结构要求部分冲突。讨论包括对潜在生物反应性方面的详细机理分析。
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