Department of Microbiology and Immunology, Albert Einstein College of Medicine, Bronx, New York, USA.
Department of Microbiology and Immunology, Albert Einstein College of Medicine, Bronx, New York, USA
mBio. 2021 Feb 16;12(1):e03616-20. doi: 10.1128/mBio.03616-20.
Genomic surveillance of viral isolates during the 2013-2016 Ebola virus epidemic in Western Africa, the largest and most devastating filovirus outbreak on record, revealed several novel mutations. The responsible strain, named Makona, carries an A-to-V substitution at position 82 (A82V) in the glycoprotein (GP), which is associated with enhanced infectivity Here, we investigated the mechanistic basis for this enhancement as well as the interplay between A82V and a T-to-I substitution at residue 544 of GP, which also modulates infectivity in cell culture. We found that both 82V and 544I destabilize GP, with the residue at position 544 impacting overall stability, while 82V specifically destabilizes proteolytically cleaved GP. Both residues also promote faster kinetics of lipid mixing of the viral and host membranes in live cells, individually and in tandem, which correlates with faster times to fusion following colocalization with the viral receptor Niemann-Pick C1 (NPC1). Furthermore, GPs bearing 82V are more sensitive to proteolysis by cathepsin L (CatL), a key host factor for viral entry. Intriguingly, CatL processed 82V variant GPs to a novel product with a molecular weight of approximately 12,000 (12K), which we hypothesize corresponds to a form of GP that is pre-triggered for fusion. We thus propose a model in which 82V promotes more efficient GP processing by CatL, leading to faster viral fusion kinetics and higher levels of infectivity. The 2013-2016 outbreak of Ebola virus disease in West Africa demonstrated the potential for previously localized outbreaks to turn into regional, or even global, health emergencies. With over 28,000 cases and 11,000 confirmed deaths, this outbreak was over 50 times as large as any previously recorded. This outbreak also afforded the largest-ever collection of Ebola virus genomic sequence data, allowing new insights into viral transmission and evolution. Viral mutants arising during the outbreak have attracted attention for their potentially altered patterns of infectivity in cell culture, with potential, if unclear, implications for increased viral spread and/or virulence. Here, we report the properties of one such mutation in the viral glycoprotein, A82V, and its interplay with a previously described polymorphism at position 544. We show that mutations at both residues promote infection and fusion activation in cells but that A82V additionally leads to increased infectivity under cathepsin-limited conditions and the generation of a novel glycoprotein cleavage product.
2013-2016 年期间在西非暴发的埃博拉病毒疫情是有记录以来最大和最具破坏性的丝状病毒疫情,对病毒分离株进行的基因组监测显示了一些新的突变。负责该疫情的病毒株名为 Makona,其糖蛋白(GP)第 82 位发生了 A 到 V 的取代(A82V),这与增强的感染性有关。在此,我们研究了这种增强的机制基础,以及 A82V 与 GP 第 544 位 T 到 I 取代之间的相互作用,后者也会影响细胞培养中的感染性。我们发现,82V 和 544I 都会使 GP 不稳定,第 544 位残基影响整体稳定性,而 82V 则特异性地使蛋白水解切割的 GP 不稳定。这两个残基还分别促进活细胞中病毒和宿主膜的脂质混合更快动力学,在串联时更快,这与 NPC1 病毒受体共定位后融合的时间更快有关。此外,携带 82V 的 GPs 对组织蛋白酶 L(CatL)的蛋白水解更敏感,CatL 是病毒进入的关键宿主因子。有趣的是,CatL 将 82V 变异的 GP 加工成分子量约为 12,000(12K)的新型产物,我们假设这对应于一种预先触发融合的 GP 形式。因此,我们提出了一种模型,即 82V 促进 CatL 更有效地加工 GP,从而导致更快的病毒融合动力学和更高的感染性水平。2013-2016 年西非的埃博拉病毒病疫情表明,以前局部暴发有可能转变为区域甚至全球卫生紧急情况。这次疫情的病例超过 28000 例,确诊死亡 11000 例,是有记录以来规模最大的一次。这次疫情还提供了有史以来最大的埃博拉病毒基因组序列数据集,使人们对病毒传播和进化有了新的认识。在疫情中出现的病毒突变因其在细胞培养中的潜在感染性改变模式而受到关注,但对病毒传播和/或毒力的潜在影响尚不清楚。在此,我们报告病毒糖蛋白中一个这样的突变 A82V 及其与之前描述的 544 位位置多态性的相互作用。我们表明,两个残基的突变都促进了细胞中的感染和融合激活,但 A82V 还导致在组织蛋白酶限制条件下增加了感染性,并产生了一种新型糖蛋白切割产物。
