Wu Fan, Zhang Jing, Song Fuhang, Wang Sanshan, Guo Hui, Wei Qi, Dai Huanqin, Chen Xiangyin, Xia Xuekui, Liu Xueting, Zhang Lixin, Yu Jin-Quan, Lei Xiaoguang
Beijing National Laboratory for Molecular Sciences, Key Laboratory of Bioorganic Chemistry and Molecular Engineering of Ministry of Education, Department of Chemical Biology, College of Chemistry and Molecular Engineering, Synthetic and Functional Biomolecules Center, and Peking-Tsinghua Center for Life Sciences, Peking University, Beijing 100871, China.
CAS Key Laboratory of Pathogenic Microbiology & Immunology, Chinese Academy of Sciences, Institute of Microbiology, Beijing 100101, China.
ACS Cent Sci. 2020 Jun 24;6(6):928-938. doi: 10.1021/acscentsci.0c00122. Epub 2020 May 4.
Tuberculosis (TB) is a life-threatening disease resulting in an estimated 10 million new infections and 1.8 million deaths annually, primarily in underdeveloped countries. The economic burden of TB has been estimated as approximately 12 billion USD annually in direct and indirect costs. Additionally, multi-drug-resistant (MDR) and extreme-drug-resistant (XTR) TB strains resulting in about 250 000 deaths annually are now widespread, increasing pressure on the identification of new anti-TB agents that operate by a novel mechanism of action. Chrysomycin A is a rare C-aryl glycoside first discovered over 60 years ago. In a recent high-throughput screen, we found that chrysomycin A has potent anti-TB activity, with minimum inhibitory concentration (MIC) = 0.4 μg/mL against MDR-TB strains. However, chrysomycin A is obtained in low yields from fermentation of , and the mechanism of action of this compound is unknown. To facilitate the mechanism of action and preclinical studies of chrysomycin A, we developed a 10-step, scalable synthesis of the isolate and its two natural congeners polycarcin V and gilvocarcin V. The synthetic sequence was enabled by the implementation of two sequential C-H functionalization steps as well as a late-stage C-glycosylation. In addition, >10 g of the advanced synthetic intermediate has been prepared, which greatly facilitated the synthesis of 33 new analogues to date. The structure-activity relationship was subsequently delineated, leading to the identification of derivatives with superior potency against MDR-TB (MIC = 0.08 μg/mL). The more potent derivatives contained a modified carbohydrate residue which suggests that further optimization is additionally possible. The chemistry we report here establishes a platform for the development of a novel class of anti-TB agents active against drug-resistant pathogens.
结核病(TB)是一种危及生命的疾病,主要在不发达国家,每年估计有1000万新感染病例和180万人死亡。结核病的经济负担估计每年约为120亿美元的直接和间接成本。此外,每年导致约25万例死亡的耐多药(MDR)和极端耐药(XTR)结核菌株现在广泛存在,这增加了对通过新作用机制发挥作用的新型抗结核药物进行鉴定的压力。金霉素A是60多年前首次发现的一种罕见的C-芳基糖苷。在最近的一次高通量筛选中,我们发现金霉素A具有强大的抗结核活性,对耐多药结核菌株的最低抑菌浓度(MIC)=0.4μg/mL。然而,金霉素A通过发酵获得的产量很低,并且该化合物的作用机制尚不清楚。为了促进金霉素A的作用机制和临床前研究,我们开发了一种10步、可扩展的合成方法,用于分离物及其两种天然同系物多癌菌素V和吉尔维菌素V的合成。该合成序列通过实施两个连续的C-H官能化步骤以及后期的C-糖基化得以实现。此外,已经制备了超过10g的高级合成中间体,这极大地促进了迄今为止33种新类似物的合成。随后描绘了构效关系,从而鉴定出对耐多药结核具有更高效力的衍生物(MIC = 0.08μg/mL)。效力更强的衍生物含有修饰的碳水化合物残基,这表明进一步优化是可能的。我们在此报道的化学方法为开发一类对耐药病原体具有活性的新型抗结核药物建立了一个平台。
