Zhen James, Chen Jia, Huang Haigen, Liao Shiqing, Liu Shiheng, Yuan Yan, Sun Ren, Longnecker Richard, Wu Ting-Ting, Zhou Z Hong
bioRxiv. 2024 Jul 9:2024.07.09.602672. doi: 10.1101/2024.07.09.602672.
Epstein-Barr virus (EBV) and Kaposi's sarcoma-associated herpesvirus (KSHV) are classified into the gammaherpesvirus subfamily of , which stands out from its alpha- and betaherpesvirus relatives due to the tumorigenicity of its members. Although structures of human alpha- and betaherpesviruses by cryogenic electron tomography (cryoET) have been reported, reconstructions of intact human gammaherpesvirus virions remain elusive. Here, we structurally characterize extracellular virions of EBV and KSHV by deep learning-enhanced cryoET, resolving both previously known monomorphic capsid structures and previously unknown pleomorphic features beyond the capsid. Through subtomogram averaging and subsequent tomogram-guided sub-particle reconstruction, we determined the orientation of KSHV nucleocapsids from mature virions with respect to the portal to provide spatial context for the tegument within the virion. Both EBV and KSHV have an eccentric capsid position and polarized distribution of tegument. Tegument species span from the capsid to the envelope and may serve as scaffolds for tegumentation and envelopment. The envelopes of EBV and KSHV are less densely populated with glycoproteins than those of herpes simplex virus 1 and human cytomegalovirus, representative members of alpha- and betaherpesviruses, respectively. This population density of glycoproteins correlates with their relative infectivity against HEK293T cells. Also, we observed fusion protein gB trimers exist within triplet arrangements in addition to standalone complexes, which is relevant to understanding dynamic processes such as fusion pore formation. Taken together, this study reveals nuanced yet important differences in the tegument and envelope architectures among human herpesviruses and provides insights into their varied cell tropism and infection.
Discovered in 1964, Epstein-Barr virus (EBV) is the first identified human oncogenic virus and the founding member of the gammaherpesvirus subfamily. In 1994, another cancer-causing virus was discovered in lesions of AIDS patients and later named Kaposi's sarcoma-associated herpesvirus (KSHV), the second human gammaherpesvirus. Despite the historical importance of EBV and KSHV, technical difficulties with isolating large quantities of these viruses and the pleiomorphic nature of their envelope and tegument layers have limited structural characterization of their virions. In this study, we employed the latest technologies in cryogenic electron microscopy (cryoEM) and tomography (cryoET) supplemented with an artificial intelligence-powered data processing software package to reconstruct 3D structures of the EBV and KSHV virions. We uncovered unique properties of the envelope glycoproteins and tegument layers of both EBV and KSHV. Comparison of these features with their non-tumorigenic counterparts provides insights into their relevance during infection.
爱泼斯坦-巴尔病毒(EBV)和卡波西肉瘤相关疱疹病毒(KSHV)被归类为疱疹病毒科的γ疱疹病毒亚科,因其成员具有致瘤性而有别于其α和β疱疹病毒亲属。尽管已报道了通过低温电子断层扫描(cryoET)获得的人类α和β疱疹病毒的结构,但完整的人类γ疱疹病毒病毒体的重建仍然难以实现。在这里,我们通过深度学习增强的低温电子断层扫描对EBV和KSHV的细胞外病毒体进行结构表征,解析了先前已知的单形衣壳结构以及衣壳之外先前未知的多形特征。通过亚断层平均和随后的断层引导亚颗粒重建,我们确定了成熟病毒体中KSHV核衣壳相对于门户的方向,为病毒体内的被膜提供空间背景。EBV和KSHV都有偏心的衣壳位置和被膜的极化分布。被膜种类从衣壳延伸到包膜,可能作为被膜化和包膜化的支架。与α疱疹病毒的代表性成员单纯疱疹病毒1和β疱疹病毒的代表性成员人巨细胞病毒相比,EBV和KSHV包膜上糖蛋白的分布密度较低。这种糖蛋白的分布密度与其对HEK293T细胞的相对感染性相关。此外,我们观察到融合蛋白gB三聚体除了独立复合物外还以三联体排列存在,这与理解诸如融合孔形成等动态过程相关。综上所述,本研究揭示了人类疱疹病毒在被膜和包膜结构上细微但重要的差异,并为它们不同的细胞嗜性和感染提供了见解。
爱泼斯坦-巴尔病毒(EBV)于1964年被发现,是首个被鉴定的人类致癌病毒,也是γ疱疹病毒亚科的创始成员。1994年,在艾滋病患者的病变中发现了另一种致癌病毒,后来被命名为卡波西肉瘤相关疱疹病毒(KSHV),即第二种人类γ疱疹病毒。尽管EBV和KSHV具有重要的历史意义,但分离大量这些病毒的技术困难以及它们包膜和被膜层的多形性限制了对其病毒体的结构表征。在本研究中,我们采用了低温电子显微镜(cryoEM)和断层扫描(cryoET)的最新技术,并辅以人工智能驱动的数据处理软件包来重建EBV和KSHV病毒体的三维结构。我们发现了EBV和KSHV包膜糖蛋白和被膜层的独特性质。将这些特征与其非致瘤性对应物进行比较,有助于深入了解它们在感染过程中的相关性。
