Hadley E Neal, Chelsea T Barrett, Kearstin Edmonds, Carole L Moncman, Rebecca Ellis Dutch
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Mutation of either site to alter the furin recognition motif blocked cell-cell fusion activity. To assess the role of Pep27 in F processing and expression, we deleted the Pep27 fragment, but preserved the cleavage sites. Deletion of Pep27 reduced F surface expression and cell-cell fusion. Two conserved N-linked glycosylation sites within Pep 27 are present in both the RSV A2 and RSV B9320 F. Randomization of the Pep27 sequence, while conserving the two N-liked glycosylation sites, did not significantly change surface expression, and only modestly reduced cell-cell fusion. However, the disruption of either Pep27 glycosylation site reduced cell-cell fusion. 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引用次数: 0
摘要
呼吸道合胞病毒(RSV)融合蛋白(F)可促进病毒-细胞膜融合(这对病毒进入和细胞-细胞融合至关重要)。与许多 I 型融合蛋白不同的是,RSV F 必须在两个不同的位点上进行蛋白水解才能产生融合。这两个位点的裂解都会释放出一个 27 个氨基酸的片段,称为 Pep27。我们研究了 RSV A2 和 RSV B9320 实验室适应株的 RSV F 的蛋白水解过程和 Pep27 的作用,从而对 A 支系和 B 支系的 F 蛋白进行了重要比较。两个支系的 F 蛋白都在两个位点被裂解,脉冲追逐分析表明,两个位点的裂解都发生在合成后的早期,很可能是在分泌途径中。突变任何一个位点以改变呋喃识别基序,都会阻止细胞-细胞融合活性。为了评估 Pep27 在 F 加工和表达中的作用,我们删除了 Pep27 片段,但保留了裂解位点。Pep27的缺失降低了F的表面表达和细胞融合。Pep27 中的两个保守的 N-连接糖基化位点存在于 RSV A2 和 RSV B9320 F 中。随机化 Pep27 序列虽然保留了两个 N-连接糖基化位点,但并没有显著改变 F 的表面表达,仅适度降低了细胞融合。然而,破坏任何一个 Pep27 糖基化位点都会降低细胞融合。这项工作明确了 RSV F 蛋白质解裂的时间,并深入揭示了 Pep27 中的 N-连接糖基化位点在 F 的生物功能中发挥的关键作用。
Examination of respiratory syncytial virus fusion protein proteolytic processing and roles of the P27 domain.
The respiratory syncytial virus (RSV) fusion protein (F) facilitates virus-cell membrane fusion, which is critical for viral entry, and cell-cell fusion. In contrast to many type I fusion proteins, RSV F must be proteolytically cleaved at two distinct sites to be fusogenic. Cleavage at both sites results in the release of a 27 amino-acid fragment, termed Pep27. We examined proteolytic processing and the role of Pep27 for RSV F from both RSV A2 and RSV B9320 laboratory-adapted strains, allowing important comparisons between A and B clade F proteins. F from both clades was cleaved at both sites, and pulse-chase analysis indicated that cleavage at both sites occurs early after synthesis, most likely within the secretory pathway. Mutation of either site to alter the furin recognition motif blocked cell-cell fusion activity. To assess the role of Pep27 in F processing and expression, we deleted the Pep27 fragment, but preserved the cleavage sites. Deletion of Pep27 reduced F surface expression and cell-cell fusion. Two conserved N-linked glycosylation sites within Pep 27 are present in both the RSV A2 and RSV B9320 F. Randomization of the Pep27 sequence, while conserving the two N-liked glycosylation sites, did not significantly change surface expression, and only modestly reduced cell-cell fusion. However, the disruption of either Pep27 glycosylation site reduced cell-cell fusion. This work clarifies the timing of RSV F proteolytic cleavage and offers insight into the crucial role the N-linked glycosylation sites within Pep27 play in the biological function of F.
期刊介绍:
Journal of Virology (JVI) explores the nature of the viruses of animals, archaea, bacteria, fungi, plants, and protozoa. We welcome papers on virion structure and assembly, viral genome replication and regulation of gene expression, genetic diversity and evolution, virus-cell interactions, cellular responses to infection, transformation and oncogenesis, gene delivery, viral pathogenesis and immunity, and vaccines and antiviral agents.