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印度德里连续三次感染高峰期间的 SARS-CoV-2 谱系追踪和演变趋势:一项临床基因组学研究。

SARS-CoV-2 Lineage Tracking, and Evolving Trends Seen during Three Consecutive Peaks of Infection in Delhi, India: a Clinico-Genomic Study.

机构信息

Genome Sequencing Laboratory, Institute of Liver and Biliary Sciencesgrid.418784.6, New Delhi, India.

Department of Clinical Virology, Institute of Liver and Biliary Sciencesgrid.418784.6, New Delhi, India.

出版信息

Microbiol Spectr. 2022 Apr 27;10(2):e0272921. doi: 10.1128/spectrum.02729-21. Epub 2022 Mar 21.

DOI:10.1128/spectrum.02729-21
PMID:35311567
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9045110/
Abstract

Since its advent, the pandemic has caused havoc in multiple waves due partly to amplified transmissibility and immune escape to vaccines. Delhi, India also witnessed brutal multiple peaks causing exponential rise in cases. Here we had retrospectively investigated clade variation, emergence of new lineages and varied clinical characteristics during those three peaks in order to understand the trajectory of the ongoing pandemic. In this study, a total of 123,378 samples were collected for a time span of 14 months (1 June 2020 to 3 August 2021) encompassing three different peaks in Delhi. A subset of 747 samples was processed for sequencing. Complete clinical and demographic details of all the enrolled cases were also collected. We detected 26 lineages across three peaks nonuniformly from 612 quality passed samples. The first peak was driven by diverse early variants, while the second one by B.1.36 and B.1.617.2, unlike third peak caused entirely by B.1.617.2. A total of 18,316 mutations with median of 34 were reported. Majority of mutations were present in less than 1% of samples. Differences in clinical characteristics across three peaks was also reported. To be ahead of the frequently changing course of the ongoing pandemic, it is of utmost importance that novel lineages be tracked continuously. Prioritized sequencing of sudden local outburst and community hot spots must be done to swiftly detect a novel mutation/lineage of potential clinical importance. Genome surveillance of the Delhi data provides a more detailed picture of diverse circulating lineages. The added value that the current study provides by clinical details of the patients is of importance. We looked at the shifting patterns of lineages, clinical characteristics and mutation types and mutation load during each successive infection surge in Delhi. The importance of widespread genomic surveillance cannot be stressed enough to timely detect new variants so that appropriate policies can be immediately implemented upon to help control the infection spread. The entire idea of genomic surveillance is to arm us with the clues as to how the novel mutations and/or variants can prove to be more transmissible and/or fatal. In India, the densely populated cities have an added concern of the huge burden that even the milder variants of the virus combined with co-morbidity can have on the community/primary health care centers.

摘要

自疫情出现以来,由于病毒传播性增强和对疫苗的免疫逃逸,疫情已经多次出现大规模爆发。印度德里也经历了多次残酷的高峰期,导致病例呈指数级增长。在这里,我们回顾性地研究了三个高峰期的谱系变异、新谱系的出现和不同的临床特征,以了解当前疫情的发展轨迹。在这项研究中,共收集了 123378 个样本,时间跨度为 14 个月(2020 年 6 月 1 日至 2021 年 8 月 3 日),涵盖了德里的三个不同高峰期。从 747 个样本中选取了一部分进行测序。还收集了所有入组病例的完整临床和人口统计学细节。我们从 612 个合格的样本中检测到了 26 个谱系,在三个高峰期呈非均匀分布。第一个高峰期由多种早期变异驱动,而第二个高峰期则由 B.1.36 和 B.1.617.2 驱动,与完全由 B.1.617.2 引起的第三个高峰期不同。共报告了 18316 个突变,中位数为 34 个。大多数突变出现在不到 1%的样本中。三个高峰期的临床特征也存在差异。为了在不断变化的疫情中抢占先机,连续跟踪新的谱系至关重要。必须优先对突然的局部爆发和社区热点进行测序,以迅速发现具有潜在临床重要性的新突变/谱系。德里数据的基因组监测提供了更详细的多样化循环谱系图。本研究通过患者的临床详细信息提供了更多的附加价值。我们观察了德里每个连续感染高峰期间谱系、临床特征和突变类型和突变负荷的变化模式。广泛的基因组监测的重要性怎么强调都不为过,及时发现新的变异体,以便能够立即实施相应的政策来帮助控制感染的传播。基因组监测的全部意义在于,为我们提供线索,了解新的突变和/或变异如何变得更具传染性和/或致命性。在印度,人口稠密的城市除了要担心病毒的轻度变异与合并症结合可能对社区/初级保健中心造成的巨大负担之外,还有更多的担忧。

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