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携带接近弗林裂解位点的刺突突变和 N 端结构域缺失的伽马(P.1)亚谱系的传播推动了巴西亚马逊州 SARS-CoV-2 的持续传播。

Spread of Gamma (P.1) Sub-Lineages Carrying Spike Mutations Close to the Furin Cleavage Site and Deletions in the N-Terminal Domain Drives Ongoing Transmission of SARS-CoV-2 in Amazonas, Brazil.

机构信息

Laboratório de Ecologia de Doenças Transmissíveis na Amazônia, Instituto Leônidas e Maria Deane, Fiocruz, Manaus, Amazonas, Brazil.

Laboratório de Flavivírus, Instituto Oswaldo Cruz, Fiocruz, Rio de Janeiro, Rio de Janeiro, Brazil.

出版信息

Microbiol Spectr. 2022 Feb 23;10(1):e0236621. doi: 10.1128/spectrum.02366-21.

DOI:10.1128/spectrum.02366-21
PMID:35196783
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8865440/
Abstract

The Amazonas was one of the most heavily affected Brazilian states by the COVID-19 epidemic. Despite a large number of infected people, particularly during the second wave associated with the spread of the Variant of Concern (VOC) Gamma (lineage P.1), SARS-CoV-2 continues to circulate in the Amazonas. To understand how SARS-CoV-2 persisted in a human population with a high immunity barrier, we generated 1,188 SARS-CoV-2 whole-genome sequences from individuals diagnosed in the Amazonas state from 1st January to 6th July 2021, of which 38 were vaccine breakthrough infections. Our study reveals a sharp increase in the relative prevalence of Gamma plus (P.1+) variants, designated Pango Lineages P.1.3 to P.1.6, harboring two types of additional Spike changes: deletions in the N-terminal (NTD) domain (particularly Δ144 or Δ141-144) associated with resistance to anti-NTD neutralizing antibodies or mutations at the S1/S2 junction (N679K or P681H) that probably enhance the binding affinity to the furin cleavage site, as suggested by our molecular dynamics simulations. As lineages P.1.4 (S:N679K) and P.1.6 (S:P681H) expanded (Re > 1) from March to July 2021, the lineage P.1 declined (Re < 1) and the median Ct value of SARS-CoV-2 positive cases in Amazonas significantly decreases. Still, we did not find an increased incidence of P.1+ variants among breakthrough cases of fully vaccinated patients (71%) in comparison to unvaccinated individuals (93%). This evidence supports that the ongoing endemic transmission of SARS-CoV-2 in the Amazonas is driven by the spread of new local Gamma/P.1 sublineages that are more transmissible, although not more efficient to evade vaccine-elicited immunity than the parental VOC. Finally, as SARS-CoV-2 continues to spread in human populations with a declining density of susceptible hosts, the risk of selecting more infectious variants or antibody evasion mutations is expected to increase. The continuous evolution of SARS-CoV-2 is an expected phenomenon that will continue to happen due to the high number of cases worldwide. The present study analyzed how a Variant of Concern (VOC) could still circulate in a population hardly affected by two COVID-19 waves and with vaccination in progress. Our results showed that the answer behind that was a new generation of Gamma-like viruses, which emerged locally carrying mutations that made it more transmissible and more capable of spreading, partially evading prior immunity triggered by natural infections or vaccines. With thousands of new cases daily, the current pandemics scenario suggests that SARS-CoV-2 will continue to evolve and efforts to reduce the number of infected subjects, including global equitable access to COVID-19 vaccines, are mandatory. Thus, until the end of pandemics, the SARS-CoV-2 genomic surveillance will be an essential tool to better understand the drivers of the viral evolutionary process.

摘要

亚马孙州是巴西受 COVID-19 疫情影响最严重的州之一。尽管有大量感染者,尤其是在与关注变体 (VOC) Gamma (谱系 P.1) 传播相关的第二波疫情期间,但 SARS-CoV-2 仍在亚马孙州继续传播。为了了解 SARS-CoV-2 如何在具有高免疫屏障的人群中持续存在,我们从 2021 年 1 月 1 日至 7 月 6 日期间在亚马孙州诊断出的个体中生成了 1188 个 SARS-CoV-2 全基因组序列,其中 38 个是疫苗突破性感染。我们的研究揭示了 Gamma 加(P.1+)变体的相对流行率急剧增加,指定的 Pango 谱系 P.1.3 至 P.1.6 ,携带有两种类型的额外 Spike 变化:N 端(NTD)域中的缺失(特别是 Δ144 或 Δ141-144)与抗 NTD 中和抗体的抗性有关,或 S1/S2 连接处的突变(N679K 或 P681H),这可能增强了与弗林裂解位点的结合亲和力,正如我们的分子动力学模拟所表明的那样。随着谱系 P.1.4(S:N679K)和 P.1.6(S:P681H)从 2021 年 3 月到 7 月扩张(Re > 1),谱系 P.1 下降(Re < 1),亚马孙州 SARS-CoV-2 阳性病例的中位 Ct 值显著降低。尽管如此,我们没有发现完全接种疫苗的患者(71%)突破性病例中 P.1+变体的发病率增加,而未接种疫苗的个体(93%)。这一证据表明,SARS-CoV-2 在亚马孙地区的持续流行传播是由新的本地 Gamma/P.1 亚谱系的传播驱动的,这些亚谱系更具传染性,尽管不如原始 VOC 更有效地逃避疫苗诱导的免疫。最后,随着 SARS-CoV-2 在宿主易感密度不断下降的人群中继续传播,选择更具传染性的变体或抗体逃避突变的风险预计会增加。SARS-CoV-2 的持续进化是一种预期现象,由于全球病例数量众多,这种现象将继续发生。本研究分析了一种关注变体(VOC)如何仍然能够在受两波 COVID-19 疫情影响较小且正在进行疫苗接种的人群中传播。我们的结果表明,其背后的答案是新一代的 Gamma 样病毒,这些病毒在当地出现,携带使其更具传染性和传播能力的突变,部分逃避了由自然感染或疫苗引发的先前免疫。由于每天都有数千例新病例,目前的大流行情况表明,SARS-CoV-2 将继续进化,减少感染人数的努力,包括全球公平获得 COVID-19 疫苗,是强制性的。因此,直到大流行结束,SARS-CoV-2 的基因组监测将是更好地了解病毒进化过程驱动因素的重要工具。

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2
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Cell Host Microbe. 2022 Mar 9;30(3):373-387.e7. doi: 10.1016/j.chom.2022.01.006. Epub 2022 Jan 21.
3
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4
New variants of COVID-19 (XBB.1.5 and XBB.1.16, the "Arcturus"): A review of highly questioned concerns, a brief comparison between different peaks in the COVID-19 pandemic, with a focused systematic review on expert recommendations for prevention, vaccination, and treatment measures in the general population and at-risk groups.新型冠状病毒变异株(XBB.1.5 和 XBB.1.16,即“Arcturus”):备受质疑的问题综述,对 COVID-19 大流行不同高峰期的简要比较,以及对普通人群和高危人群预防、接种和治疗措施的专家建议进行的重点系统评价。
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10
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PLoS One. 2023 Aug 17;18(8):e0285742. doi: 10.1371/journal.pone.0285742. eCollection 2023.
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Nature. 2022 Mar;603(7902):679-686. doi: 10.1038/s41586-022-04411-y. Epub 2022 Jan 7.
4
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Sci Transl Med. 2022 Feb 23;14(633):eabk3445. doi: 10.1126/scitranslmed.abk3445.
5
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iScience. 2022 Jan 21;25(1):103589. doi: 10.1016/j.isci.2021.103589. Epub 2021 Dec 10.
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Reduced sensitivity of SARS-CoV-2 variant Delta to antibody neutralization.德尔塔变异株对抗体中和的敏感性降低。
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Immunity. 2021 Jul 13;54(7):1611-1621.e5. doi: 10.1016/j.immuni.2021.06.003. Epub 2021 Jun 8.