Klimstra William B, Tilston-Lunel Natasha L, Nambulli Sham, Boslett James, McMillen Cynthia M, Gilliland Theron, Dunn Matthew D, Sun Chengqun, Wheeler Sarah E, Wells Alan, Hartman Amy L, McElroy Anita K, Reed Douglas S, Rennick Linda J, Duprex W Paul
Center for Vaccine Research, School of Medicine, University of Pittsburgh, Pittsburgh, Pennsylvania, USA.
Department of Microbiology and Molecular Genetics, School of Medicine, University of Pittsburgh, Pittsburgh, Pennsylvania, USA.
bioRxiv. 2020 Jun 22:2020.06.19.154930. doi: 10.1101/2020.06.19.154930.
SARS-CoV-2, the causative agent of COVID-19, emerged at the end of 2019 and by mid-June 2020, the virus has spread to at least 215 countries, caused more than 8,000,000 confirmed infections and over 450,000 deaths, and overwhelmed healthcare systems worldwide. Like SARS-CoV, which emerged in 2002 and caused a similar disease, SARS-CoV-2 is a betacoronavirus. Both viruses use human angiotensin-converting enzyme 2 (hACE2) as a receptor to enter cells. However, the SARS-CoV-2 spike (S) glycoprotein has a novel insertion that generates a putative furin cleavage signal and this has been postulated to expand the host range. Two low passage (P) strains of SARS-CoV-2 (Wash1: P4 and Munich: P1) were cultured twice in Vero-E6 cells and characterized virologically. Sanger and MinION sequencing demonstrated significant deletions in the furin cleavage signal of Wash1: P6 and minor variants in the Munich: P3 strain. Cleavage of the S glycoprotein in SARS-CoV-2-infected Vero-E6 cell lysates was inefficient even when an intact furin cleavage signal was present. Indirect immunofluorescence demonstrated the S glycoprotein reached the cell surface. Since the S protein is a major antigenic target for the development of neutralizing antibodies we investigated the development of neutralizing antibody titers in serial serum samples obtained from COVID-19 human patients. These were comparable regardless of the presence of an intact or deleted furin cleavage signal. These studies illustrate the need to characterize virus stocks meticulously prior to performing either or pathogenesis studies.
严重急性呼吸综合征冠状病毒2(SARS-CoV-2)是冠状病毒病(COVID-19)的病原体,于2019年底出现。到2020年6月中旬,该病毒已传播至至少215个国家,导致超过800万例确诊感染和超过45万例死亡,使全球医疗系统不堪重负。与2002年出现并引发类似疾病的严重急性呼吸综合征冠状病毒(SARS-CoV)一样,SARS-CoV-2是一种β冠状病毒。两种病毒都利用人类血管紧张素转换酶2(hACE2)作为受体进入细胞。然而,SARS-CoV-2刺突(S)糖蛋白有一个新的插入片段,产生了一个假定的弗林蛋白酶切割信号,并据推测这扩大了宿主范围。两种低传代(P)的SARS-CoV-2毒株(华盛顿1号:P4和慕尼黑:P1)在Vero-E6细胞中培养了两代,并进行了病毒学特征分析。桑格测序和MinION测序显示,华盛顿1号:P6的弗林蛋白酶切割信号有明显缺失,慕尼黑:P3毒株有微小变异。即使存在完整的弗林蛋白酶切割信号,在感染SARS-CoV-2的Vero-E6细胞裂解物中,S糖蛋白的切割效率也很低。间接免疫荧光显示S糖蛋白到达了细胞表面。由于S蛋白是开发中和抗体的主要抗原靶点,我们研究了从COVID-19患者获得的系列血清样本中中和抗体滴度的变化。无论弗林蛋白酶切割信号是否完整,这些中和抗体滴度都是可比的。这些研究表明,在进行疫苗或发病机制研究之前,需要仔细鉴定病毒毒株。
