Federal Research Centre "Fundamentals of Biotechnology" of the Russian Academy of Sciences (Research Centre of Biotechnology RAS), Leninsky prospect, 33, build. 2, 119071, Moscow, Russia.
Institute of Medical Microbiology, Section of Experimental Virology, Jena University Hospital, Hans-Knöll-Straße 2, 07745, Jena, Germany.
Eur J Med Chem. 2024 Nov 5;277:116768. doi: 10.1016/j.ejmech.2024.116768. Epub 2024 Aug 15.
Influenza viruses that cause seasonal and pandemic flu are a permanent health threat. The surface glycoprotein, neuraminidase, is crucial for the infectivity of the virus and therefore an attractive target for flu drug discovery campaigns. We have designed and synthesized more than 40 3-indolinone derivatives. We mainly investigated the role of substituents at the 2 position of the core as well as the introduction of substituents or a nitrogen atom in the fused phenyl ring of the core for inhibition of influenza virus neuraminidase activity and replication in vitro and in vivo. After evaluating the compounds for their ability to inhibit the viral neuraminidase, six potent inhibitors 3c, 3e, 7c, 12o, 12v, 18d were progressed to evaluate for cytotoxicity and inhibition of influenza virus A/PR/8/34 replication in in MDCK cells. Two hit compounds 3e and 12o were tested in an animal model of influenza virus infection. Molecular mechanism of the 3-indolinone derivatives interactions with the neuraminidase was revealed in molecular dynamic simulations. Proposed inhibitors bind to the 430-cavity that is different from the conventional binding site of commercial compounds. The most promising 3-indolinone inhibitors demonstrate stronger interactions with the neuraminidase in molecular models that supports proposed binding site.
引起季节性和大流行性流感的流感病毒是一种永久性的健康威胁。表面糖蛋白神经氨酸酶对于病毒的感染力至关重要,因此是流感药物发现活动的一个有吸引力的靶标。我们已经设计和合成了超过 40 种 3-吲哚啉酮衍生物。我们主要研究了核心 2 位取代基的作用以及在核心稠合的苯基环中引入取代基或氮原子对抑制流感病毒神经氨酸酶活性和体外及体内复制的作用。在评估化合物抑制病毒神经氨酸酶的能力后,将 6 种强效抑制剂 3c、3e、7c、12o、12v、18d 推进到 MDCK 细胞中评估对细胞毒性和流感病毒 A/PR/8/34 复制的抑制作用。两种命中化合物 3e 和 12o 在流感病毒感染的动物模型中进行了测试。分子动力学模拟揭示了 3-吲哚啉酮衍生物与神经氨酸酶相互作用的分子机制。提出的抑制剂结合到 430 腔,与商业化合物的常规结合位点不同。最有前途的 3-吲哚啉酮抑制剂在分子模型中与神经氨酸酶的相互作用更强,支持了提出的结合位点。
