Battelle Memorial Institute, Atlanta, Georgia, USA.
Oak Ridge Institute of Science and Education (ORISE), Oak Ridge, Tennessee, USA.
mSphere. 2020 Feb 5;5(1):e00822-19. doi: 10.1128/mSphere.00822-19.
While working overnight at a swine exhibition, we identified an influenza A virus (IAV) outbreak in swine, Nanopore sequenced 13 IAV genomes from samples we collected, and predicted in real time that these viruses posed a novel risk to humans due to genetic mismatches between the viruses and current prepandemic candidate vaccine viruses (CVVs). We developed and used a portable IAV sequencing and analysis platform called (Mobile Influenza Analysis) to complete and characterize full-length consensus genomes approximately 18 h after unpacking the mobile lab. Exhibition swine are a known source for zoonotic transmission of IAV to humans and pose a potential pandemic risk. Genomic analyses of IAV in swine are critical to understanding this risk, the types of viruses circulating in swine, and whether current vaccines developed for use in humans would be predicted to provide immune protection. Nanopore sequencing technology has enabled genome sequencing in the field at the source of viral outbreaks or at the bedside or pen-side of infected humans and animals. The acquired data, however, have not yet demonstrated real-time, actionable public health responses. The system rapidly identified three genetically distinct swine IAV lineages from three subtypes, A(H1N1), A(H3N2), and A(H1N2). Analysis of the hemagglutinin (HA) sequences of the A(H1N2) viruses identified >30 amino acid differences between the HA1 of these viruses and the most closely related CVV. As an exercise in pandemic preparedness, all sequences were emailed to CDC collaborators who initiated the development of a synthetically derived CVV. Swine are influenza virus reservoirs that have caused outbreaks and pandemics. Genomic characterization of these viruses enables pandemic risk assessment and vaccine comparisons, though this typically occurs after a novel swine virus jumps into humans. The greatest risk occurs where large groups of swine and humans comingle. At a large swine exhibition, we used Nanopore sequencing and on-site analytics to interpret 13 swine influenza virus genomes and identified an influenza virus cluster that was genetically highly varied to currently available vaccines. As part of the National Strategy for Pandemic Preparedness exercises, the sequences were emailed to colleagues at the CDC who initiated the development of a synthetically derived vaccine designed to match the viruses at the exhibition. Subsequently, this virus caused 14 infections in humans and was the dominant U.S. variant virus in 2018.
在一次猪展览的夜间工作中,我们发现了猪群中的流感病毒 (IAV) 爆发,我们使用 Nanopore 对收集的样本进行了 13 个 IAV 基因组测序,并实时预测这些病毒由于与当前大流行候选疫苗病毒 (CVV) 之间的基因不匹配,对人类构成了新的风险。我们开发并使用了一个名为 的便携式 IAV 测序和分析平台(Mobile Influenza Analysis),在拆开移动实验室大约 18 小时后,完成并描述了全长一致基因组。展览用猪是 IAV 向人类传播的已知的人畜共患病源,并且构成潜在的大流行风险。对猪中的 IAV 进行基因组分析对于了解这种风险、猪中流行的病毒类型以及当前开发用于人类的疫苗是否能预测提供免疫保护至关重要。Nanopore 测序技术使在病毒爆发源头或感染人类和动物的病床或围栏边进行现场基因组测序成为可能。然而,获得的数据尚未证明能够实时采取行动的公共卫生应对措施。 系统从三个亚型 A(H1N1)、A(H3N2)和 A(H1N2)中快速鉴定了三种遗传上不同的猪 IAV 谱系。对 A(H1N2)病毒血凝素 (HA)序列的分析表明,这些病毒的 HA1 与最接近的 CVV 有超过 30 个氨基酸差异。作为大流行准备的一项练习,所有序列都通过电子邮件发送给 CDC 合作者,他们启动了一种合成衍生 CVV 的开发。猪是流感病毒的宿主,已经引起了爆发和大流行。对这些病毒的基因组特征进行分析可用于评估大流行风险和疫苗比较,尽管这通常是在新型猪病毒跳跃到人类之后进行的。最大的风险发生在大量猪和人类混杂的地方。在一次大型猪展览会上,我们使用 Nanopore 测序和现场分析来解释 13 个猪流感病毒基因组,并鉴定了一个遗传上高度多样化的流感病毒群,与现有的疫苗相比。作为国家大流行防范战略演习的一部分,序列通过电子邮件发送给 CDC 的同事,他们启动了一种合成衍生疫苗的开发,该疫苗旨在与展览会上的病毒相匹配。随后,该病毒导致 14 人感染,并成为 2018 年美国主要的变异病毒。
