Dmitry I. Osolodkin, Liubov I. Kozlovskaya, Ildar R. Iusupov, Alexander V. Kurkin, Elena Y. Shustova, Alexey A. Orlov, Evgeny V. Khvatov, Elena S. Mutnykh, Svetlana S. Kurashova, Anna N. Vetrova, Darya O. Yatsenko, Alexander S. Goryashchenko, Vladimir N. Ivanov, Evgeny R. Lukyanenko, Evgenia V. Karpova, Daria A. Stepanova, Viktor P. Volok, Svetlana E. Sotskova, Tamara K. Dzagurova, Galina G. Karganova, Alexander N. Lukashev, Aydar A. Ishmukhametov
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引用次数: 0
摘要
病毒的进化潜力会导致知名病毒的爆发和新型病毒的出现。目前还没有干预各种不常见但同样重要的病毒繁殖的药理学方法,也没有大多数已知化合物的抗病毒活性谱。在化学生物学范式的框架下,对新化合物的抗病毒活性谱进行表征可以扩展抗病毒化学空间,并为数据驱动的药物发现提供新的重要结构-活性关系。在此,我们针对不同基因组、病毒体结构和基因组实现方案的病毒(正黄病毒(蜱传脑炎病毒,TBEV)、肠道病毒(脊髓灰质炎病毒、肠道病毒 A71、埃可病毒 30)、腺病毒(人腺病毒 C5)和汉坦病毒(普马拉病毒)),在表型试验中对七元杂环的螺烷化衍生物(氧杂环庚烷和氮杂环庚烷)的抗病毒活性进行了初步评估。在减产试验中,命中化合物抑制了腺病毒 C5(所研究的病毒集中唯一的 DNA 病毒)的繁殖,但没有抑制 RNA 病毒的繁殖。
Phenotypic assessment of antiviral activity for spiro-annulated oxepanes and azepenes
Evolutionary potential of viruses can result in outbreaks of well-known viruses and emergence of novel ones. Pharmacological methods of intervening the reproduction of various less popular, but not less important viruses are not available, as well as the spectrum of antiviral activity for most known compounds. In the framework of chemical biology paradigm, characterization of antiviral activity spectrum of new compounds allows to extend the antiviral chemical space and provides new important structure–activity relationships for data-driven drug discovery. Here we present a primary assessment of antiviral activity of spiro-annulated derivatives of seven-membered heterocycles, oxepane and azepane, in phenotypic assays against viruses with different genomes, virion structures, and genome realization schemes: orthoflavivirus (tick-borne encephalitis virus, TBEV), enteroviruses (poliovirus, enterovirus A71, echovirus 30), adenovirus (human adenovirus C5), hantavirus (Puumala virus). Hit compounds inhibited reproduction of adenovirus C5, the only DNA virus in the studied set, in the yield reduction assay, and did not inhibit reproduction of RNA viruses.
期刊介绍:
Chemical Biology & Drug Design is a peer-reviewed scientific journal that is dedicated to the advancement of innovative science, technology and medicine with a focus on the multidisciplinary fields of chemical biology and drug design. It is the aim of Chemical Biology & Drug Design to capture significant research and drug discovery that highlights new concepts, insight and new findings within the scope of chemical biology and drug design.
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