J Org Chem. 2018 Jun 15;83(12):6664-6672. doi: 10.1021/acs.joc.8b00988. Epub 2018 May 24.
Residual complexity (RC) involves the impact of subtle but critical structural and biological features on drug lead validation, including unexplained effects related to unidentified impurities. RC commonly plagues drug discovery efforts due to the inherent imperfections of chromatographic separation methods. The new diketopiperazine, rufomyazine (6), and the previously known antibiotic, rufomycin (7), represent a prototypical case of RC that (almost) resulted in the misassignment of biological activity. The case exemplifies that impurities well below the natural abundance of C (1.1%) can be highly relevant and calls for advanced analytical characterization of drug leads with extended molar dynamic ranges of >1:1,000 using qNMR and LC-MS. Isolated from an actinomycete strain, 6 was originally found to be active against Mycobacterium tuberculosis with a minimum inhibitory concentration (MIC) of 2 μg/mL and high selectivity. As a part of lead validation, the dipeptide was synthesized and surprisingly found to be inactive. The initially observed activity was eventually attributed to a very minor contamination (0.24% [m/m]) with a highly active cyclic peptide (MIC ∼ 0.02 μM), subsequently identified as an analogue of 7. This study illustrates the serious implications RC can exert on organic chemistry and drug discovery, and what efforts are vital to improve lead validation and efficiency, especially in NP-related drug discovery programs.
残留复杂性(RC)涉及到微妙但关键的结构和生物学特征对药物先导化合物验证的影响,包括与未识别杂质相关的未解释的作用。由于色谱分离方法的固有不完美性,RC 经常困扰着药物发现工作。新的二酮哌嗪 rufomyazine(6)和以前已知的抗生素 rufomycin(7)代表了 RC 的典型案例,(几乎)导致了生物活性的错误分配。该案例表明,低于自然丰度 C(1.1%)的杂质可能具有高度相关性,并呼吁使用 qNMR 和 LC-MS 对摩尔动态范围大于 1:1000 的药物先导化合物进行高级分析表征。从放线菌菌株中分离得到的 6 最初被发现对结核分枝杆菌具有活性,最小抑菌浓度(MIC)为 2 μg/mL,具有很高的选择性。作为先导化合物验证的一部分,合成了二肽,但令人惊讶的是,它没有活性。最初观察到的活性最终归因于微量的高度活性环状肽(MIC∼0.02 μM)的污染(0.24%[m/m]),随后被鉴定为 7 的类似物。该研究说明了 RC 对有机化学和药物发现的严重影响,以及为了提高先导化合物验证和效率而采取的重要措施,特别是在 NP 相关药物发现计划中。
