Faculty of Biology and Astbury Centre for Structural Molecular Biology, University of Leeds, Leeds, United Kingdom
Department of Microbiology, School of Dental Medicine, University of Pennsylvania, Philadelphia, Pennsylvania, USA.
mBio. 2017 Aug 22;8(4):e01268-17. doi: 10.1128/mBio.01268-17.
All enveloped viruses, including herpesviruses, must fuse their envelope with the host membrane to deliver their genomes into target cells, making this essential step subject to interference by antibodies and drugs. Viral fusion is mediated by a viral surface protein that transits from an initial prefusion conformation to a final postfusion conformation. Strikingly, the prefusion conformation of the herpesvirus fusion protein, gB, is poorly understood. Herpes simplex virus (HSV), a model system for herpesviruses, causes diseases ranging from mild skin lesions to serious encephalitis and neonatal infections. Using cryo-electron tomography and subtomogram averaging, we have characterized the structure of the prefusion conformation and fusion intermediates of HSV-1 gB. To this end, we have set up a system that generates microvesicles displaying full-length gB on their envelope. We confirmed proper folding of gB by nondenaturing electrophoresis-Western blotting with a panel of monoclonal antibodies (MAbs) covering all gB domains. To elucidate the arrangement of gB domains, we labeled them by using (i) mutagenesis to insert fluorescent proteins at specific positions, (ii) coexpression of gB with Fabs for a neutralizing MAb with known binding sites, and (iii) incubation of gB with an antibody directed against the fusion loops. Our results show that gB starts in a compact prefusion conformation with the fusion loops pointing toward the viral membrane and suggest, for the first time, a model for gB's conformational rearrangements during fusion. These experiments further illustrate how neutralizing antibodies can interfere with the essential gB structural transitions that mediate viral entry and therefore infectivity. The herpesvirus family includes herpes simplex virus (HSV) and other human viruses that cause lifelong infections and a variety of diseases, like skin lesions, encephalitis, and cancers. As enveloped viruses, herpesviruses must fuse their envelope with the host membrane to start an infection. This process is mediated by a viral surface protein that transitions from an initial conformation (prefusion) to a final, more stable, conformation (postfusion). However, the prefusion conformation of the herpesvirus fusion protein (gB) is poorly understood. To elucidate the structure of the prefusion conformation of HSV type 1 gB, we have employed cryo-electron microscopy to study gB molecules expressed on the surface of vesicles. Using different approaches to label gB's domains allowed us to model the structures of the prefusion and intermediate conformations of gB. Overall, our findings enhance our understanding of HSV fusion and lay the groundwork for the development of new ways to prevent and block HSV infection.
所有包膜病毒,包括疱疹病毒,必须将其包膜与宿主膜融合,将其基因组递送到靶细胞中,这使得这个关键步骤容易受到抗体和药物的干扰。病毒融合由病毒表面蛋白介导,该蛋白从初始的预融合构象转变为最终的融合后构象。引人注目的是,疱疹病毒融合蛋白 gB 的预融合构象仍未被充分了解。单纯疱疹病毒 (HSV) 是疱疹病毒的模型系统,可引起从轻度皮肤损伤到严重脑炎和新生儿感染等各种疾病。我们使用冷冻电子断层扫描和子断层平均化技术,对 HSV-1 gB 的预融合构象和融合中间体进行了特征描述。为此,我们建立了一个系统,该系统在其包膜上显示全长 gB 的微泡。我们通过使用(i)插入荧光蛋白的诱变在特定位置,(ii)与针对具有已知结合位点的中和单克隆抗体的 Fab 共表达 gB,以及(iii)与针对融合环的抗体孵育,用一系列单克隆抗体(MAb)进行非变性电泳-Western 印迹来确认 gB 的正确折叠,该 MAb 覆盖 gB 的所有结构域。为了阐明 gB 结构域的排列,我们使用(i)在特定位置插入荧光蛋白的诱变,(ii)与针对具有已知结合位点的中和单克隆抗体的 Fab 共表达 gB,以及(iii)与针对融合环的抗体孵育来标记 gB。我们的结果表明,gB 首先以紧凑的预融合构象开始,融合环指向病毒膜,并首次提出了 gB 在融合过程中构象重排的模型。这些实验进一步说明了中和抗体如何干扰介导病毒进入和因此感染性的基本 gB 结构转变。疱疹病毒家族包括单纯疱疹病毒 (HSV) 和其他引起终生感染和多种疾病的人类病毒,如皮肤损伤、脑炎和癌症。作为包膜病毒,疱疹病毒必须将其包膜与宿主膜融合才能开始感染。该过程由病毒表面蛋白介导,该蛋白从初始构象(预融合)转变为最终更稳定的构象(融合后)。然而,疱疹病毒融合蛋白(gB)的预融合构象仍未被充分了解。为了阐明 HSV 1 型 gB 的预融合构象的结构,我们使用冷冻电子显微镜研究了在囊泡表面表达的 gB 分子。使用不同的方法标记 gB 的结构域使我们能够对 gB 的预融合和中间构象的结构进行建模。总的来说,我们的研究结果增进了我们对 HSV 融合的理解,并为开发预防和阻断 HSV 感染的新方法奠定了基础。
