SARS-CoV-2 Mpro抑制剂:实现多样性,发展耐药性和未来策略

Conrad Fischer, Jenson R. Feys
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引用次数: 7

摘要

虽然COVID-19大流行似乎正在消退,但长期COVID-19病例的不明确影响、免疫功能低下个体的突破性感染、疫苗犹豫以及不均匀的卫生保健可及性构成了不可低估的威胁。这些病例,连同大流行的准备工作,要求警惕地识别新药,并优化现有药物,作为治疗这种疾病和未来潜在疾病的治疗选择。Mpro抑制剂很早就被确定为抗冠状病毒的有效候选药物,因为它们靶向病毒内可行的加工机制,即将病毒RNA编码的多蛋白切割成功能蛋白的主要蛋白酶。在设计有效的SARS-CoV-2 Mpro抗病毒药物时,已经探索了不同的策略,包括可逆性和不可逆性抑制以及变抗性抑制剂,这些策略主要来自药物再利用。雄心勃勃的筛选工作显示出了突出的化学和结构多样性,这导致六种先导化合物目前正在进行临床试验,美国食品和药物管理局紧急批准利托那韦(ritonvir)增强的nirmatrelvir作为COVID-19治疗药物。本文对已获得的抑制剂多样性进行了全面分析,将其分为不可逆、可逆和变抗性Mpro结合物,并讨论了新出现的耐药报告和可能的规避策略,旨在刺激持续的Mpro药物设计工作。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
SARS-CoV-2 Mpro Inhibitors: Achieved Diversity, Developing Resistance and Future Strategies
While the COVID-19 pandemic seems to be on its decline, the unclear impacts of long-COVID cases, breakthrough infections in immunocompromised individuals, vaccine hesitancy, and inhomogeneous health-care accessibility constitute a not to be underestimated threat. These cases, along with pandemic preparedness, ask for an alert identification of new drugs and the optimization of existing drugs as therapeutic treatment options for this and potential future diseases. Mpro inhibitors were identified early on as potent drug candidates against coronaviruses, since they target viable processing machinery within the virus, i.e., the main protease that cleaves the polyproteins encoded by the viral RNA into functional proteins. Different strategies, including reversible and irreversible inhibition as well as allosteric inhibitors, mostly from drug repurposing endeavors, have been explored in the design of potent SARS-CoV-2 Mpro antivirals. Ambitious screening efforts have uttered an outstanding chemical and structural diversity, which has led to half a dozen lead compounds being currently in clinical trials and the emergency FDA approval of ritonavir-boosted nirmatrelvir as a COVID-19 therapeutic. This comprehensive analysis of the achieved inhibitor diversity sorted into irreversible, reversible, and allosteric Mpro binders, along with a discussion of emerging resistance reports and possible evasion strategies, is aimed at stimulating continuing Mpro drug design efforts.
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