Division of Neurological Sciences, Vetsuisse Faculty, University of Berngrid.5734.5, Bern, Switzerland.
Institute of Chemistry and Biotechnology, Center for Organic and Medicinal Chemistry, Zurich University of Applied Sciences (ZHAW), Wädenswil, Switzerland.
mBio. 2021 Dec 21;12(6):e0262121. doi: 10.1128/mBio.02621-21. Epub 2021 Nov 2.
Multiple enveloped RNA viruses of the family and like measles virus (MeV), Nipah virus (NiV), canine distemper virus (CDV), or respiratory syncytial virus (RSV), are of high clinical relevance. Each year a huge number of lives are lost as a result of these viral infections. Worldwide, MeV infection alone is responsible for over a hundred thousand deaths each year despite available vaccine. Therefore, there is an urgent need for treatment options to counteract these viral infections. The development of antiviral drugs in general stands as a huge challenge due to the rapid emergence of viral escape mutants. Here, we disclose the discovery of a small-molecule antiviral, compound 1 (ZHAWOC9045), active against several pneumo-/paramyxoviruses, including MeV, NiV, CDV, RSV, and parainfluenza virus type 5 (PIV-5). A series of mechanistic characterizations revealed that compound 1 targets a host factor which is indispensable for viral genome replication. Drug resistance profiling against a paramyxovirus model (CDV) demonstrated no detectable adaptation despite prolonged time of investigation, thereby mitigating the rapid emergence of escape variants. Furthermore, a thorough structure-activity relationship analysis of compound 1 led to the invention of 100-times-more potent-derivatives, e.g., compound 2 (ZHAWOC21026). Collectively, we present in this study an attractive host-directed pneumoviral/paramyxoviral replication inhibitor with potential therapeutic application. Measles virus, respiratory syncytial virus, canine distemper virus, and Nipah virus are some of the clinically significant RNA viruses that threaten substantial number of lives each year. Limited to no availability of treatment options for these viral infections makes it arduous to handle the outbreaks. This highlights the major importance of developing antivirals to fight not only ongoing infections but also potential future epidemics. Most of the discovered antivirals, in clinical trials currently, are virus targeted, which consequently poses the challenge of rapid emergence of escape variants. Here, we present compound 1 (ZHAWOC9045), discovered to target viral replication in a host-dependent manner, thereby exhibiting broad-spectrum activity against several members of the family The inability of viruses to mutate against the inhibitor mitigated the critical issue of generation of escape variants. Importantly, compound 1 was successfully optimized to a highly potent variant, compound 2 (ZHAWOC21026), with a promising profile for pharmacological intervention.
家族 和 的多种包膜 RNA 病毒,如麻疹病毒 (MeV)、尼帕病毒 (NiV)、犬瘟热病毒 (CDV) 或呼吸道合胞病毒 (RSV),具有很高的临床相关性。每年,由于这些病毒感染,大量生命丧失。全球范围内,仅 MeV 感染每年就导致超过 10 万人死亡,尽管有可用的疫苗。因此,迫切需要治疗方案来对抗这些病毒感染。由于病毒逃逸突变的迅速出现,一般来说,抗病毒药物的开发仍然是一个巨大的挑战。在这里,我们发现了一种小分子抗病毒化合物 1(ZHAWOC9045),它对多种肺病毒/副粘病毒具有活性,包括 MeV、NiV、CDV、RSV 和副流感病毒 5 型 (PIV-5)。一系列机制表征表明,化合物 1 靶向一种宿主因子,该因子对于病毒基因组复制是不可或缺的。针对副粘病毒模型 (CDV) 的耐药性分析表明,尽管经过长时间的研究,仍未检测到适应性,从而减轻了逃逸变异的快速出现。此外,对化合物 1 的全面构效关系分析导致了 100 倍更有效的衍生物的发明,例如化合物 2(ZHAWOC21026)。总的来说,我们在这项研究中提出了一种有吸引力的宿主定向肺病毒/副粘病毒复制抑制剂,具有潜在的治疗应用。麻疹病毒、呼吸道合胞病毒、犬瘟热病毒和尼帕病毒是一些具有临床意义的 RNA 病毒,每年都会威胁到大量生命。由于这些病毒感染的治疗选择有限甚至没有,因此处理疫情变得困难。这凸显了开发抗病毒药物的重要性,不仅可以对抗正在进行的感染,还可以对抗潜在的未来流行。目前,临床试验中发现的大多数抗病毒药物都是针对病毒的,这就带来了快速产生逃逸变异的挑战。在这里,我们提出了化合物 1(ZHAWOC9045),它被发现以宿主依赖的方式靶向病毒复制,从而表现出对家族成员的广谱活性。病毒无法针对抑制剂突变减轻了产生逃逸变异的关键问题。重要的是,化合物 1 成功优化为具有高潜力的变体化合物 2(ZHAWOC21026),具有有前景的药理学干预特性。
