Insights into Omicron's Low Fusogenicity through In Silico Molecular Studies on Spike-Furin Interactions.

IF 2.3 Q3 BIOCHEMICAL RESEARCH METHODS Bioinformatics and Biology Insights Pub Date : 2023-01-01 DOI:10.1177/11779322231189371
Spencer Mark Mondol, Md Hasib, Md Belayet Hasan Limon, A S M Rubayet Ul Alam
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Abstract

The Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) Omicron variant and its subvariants have a unique set of mutations. Two of those mutations (N679 K and P681 H) reside close to the S1 /S2 furin cleavage site (FCS; 685-686). When these mutations reside together, they exert less-efficient membrane fusion than wild type and most other variants of concern such as the Delta variant. Here, we in silico targeted these mutations to find out which of the amino acids and interactions change plays the key role in fusion. To comprehend the epistatic effect of N679 K and P681 H mutations on the spike protein, we in silico constructed three types of spike protein sequences by changing the respective amino acids on 679 and 681 positions (P681 H, N679 K, K679 N-H681 P variants). We then analyzed the binding affinity of furin and spike (Furin-Wild, Furin-Omicron, Furin-P681 H, Furin-N679 K, and Furin-K679 N/H681 P) complexes. Omicron and P681 H variants showed a similar higher binding energy trend compared to the wild type and N679 K. The variation in hydrogen, hydrophobic, and salt bridge bonds between spike protein and furin provided an explanation for the observed low fusogenicity of Omicron. The fate of the epistasis in furin binding and possible cleavage depends on the efficient interaction between FCS in spike and furin catalytic triad, and in addition, the loss of the hydrogen bond between Arg 681 (spike) and Asn 295 (furin) along with inhibitor-like ineffective higher affinity plays an important role in the enzymatic activity.

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通过对Spike-Furin相互作用的硅分子研究了解Omicron的低融合原性。
严重急性呼吸综合征冠状病毒2 (SARS-CoV-2)组粒变体及其亚变体具有一组独特的突变。其中两个突变(N679 K和P681 H)位于S1 /S2 furin切割位点附近(FCS;685 - 686)。当这些突变聚集在一起时,它们的膜融合效率低于野生型和大多数其他变体,如Delta变体。在这里,我们以这些突变为目标,找出哪些氨基酸和相互作用的变化在融合中起关键作用。为了了解N679 K和P681 H突变对穗蛋白的上位性影响,我们通过改变679和681位点的氨基酸,构建了三种类型的穗蛋白序列(P681 H、N679 K、K679 N-H681 P变体)。然后,我们分析了furin与spike (furin - wild、furin - omicron、furin - p681 H、furin - n679 K和furin - k679 N/H681 P)配合物的结合亲和力。与野生型和N679 K相比,Omicron和P681 H变异表现出类似的高结合能趋势。刺突蛋白和furin之间的氢、疏水和盐桥键的变化解释了Omicron的低熔断性。在furin结合和可能的裂解中,FCS的命运取决于spike和furin催化三联体之间的有效相互作用,此外,Arg 681 (spike)和Asn 295 (furin)之间氢键的丧失以及抑制剂样的无效高亲和力在酶活性中起重要作用。
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来源期刊
Bioinformatics and Biology Insights
Bioinformatics and Biology Insights BIOCHEMICAL RESEARCH METHODS-
CiteScore
6.80
自引率
1.70%
发文量
36
审稿时长
8 weeks
期刊介绍: Bioinformatics and Biology Insights is an open access, peer-reviewed journal that considers articles on bioinformatics methods and their applications which must pertain to biological insights. All papers should be easily amenable to biologists and as such help bridge the gap between theories and applications.
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