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Morphogenesis of herpesvirus particles is highly conserved; however, the capsid assembly and genome packaging of human cytomegalovirus (HCMV) exhibit unique features. Examples of these include the essential role of the small capsid protein (SCP) and the existence of the β-herpesvirus-specific capsid-associated protein pp150. SCP and pp150, as well as the UL77 and UL93 proteins, are important capsid constituents, yet their precise mechanism of action is elusive. Here, we analyzed how deletion of the open reading frames (ORFs) encoding pUL77, pUL93, pp150, or SCP affects the protein composition of nuclear capsids. This was achieved by generating HCMV genomes lacking the respective genes, combined with a highly efficient transfection technique that allowed us to directly analyze these mutants in transfected cells. While no obvious effects were observed when pUL77, pUL93, or pp150 was missing, the absence of SCP impeded capsid assembly due to strongly reduced amounts of major capsid protein (MCP). Vice versa, when MCP was lacking, SCP became undetectable, indicating a mutual dependence of SCP and MCP for establishing appropriate protein levels. The SCP domain mediating stable MCP levels could be narrowed down to a C-terminal helix known to convey MCP binding. Interestingly, an SCP-EGFP (enhanced green fluorescent protein) fusion protein which also impaired the production of infectious progeny acted in a different manner, as capsid assembly was not abolished; however, SCP-EGFP-harboring capsids were devoid of DNA and trapped in paracrystalline nuclear structures. These results indicate that SCP is essential in HCMV because of its impact on MCP levels and reveal SCP as a potential target for antiviral inhibitors. Human cytomegalovirus (HCMV) is a ubiquitous pathogen causing life-threatening disease in immunocompromised individuals. Virus-specific processes such as capsid assembly and genome packaging can be exploited to design new antiviral strategies. Here, we report on a novel function of the HCMV small capsid protein (SCP), namely, ensuring stable levels of major capsid protein (MCP), thereby governing capsid assembly. Furthermore, we discovered a mutual dependence of the small and major capsid proteins to guarantee appropriate levels of the other respective protein and were able to pin down the SCP domain responsible for this effect to a region previously shown to mediate binding to the major capsid protein. In summary, our data contribute to the understanding of how SCP plays an essential part in the HCMV infection cycle. Moreover, disrupting the SCP-MCP interface may provide a starting point for the development of novel antiviral drugs.

疱疹病毒粒子的形态发生高度保守；然而，人类巨细胞病毒（HCMV）的衣壳组装和基因组包装表现出独特的特征。这些特征的例子包括小衣壳蛋白（SCP）的重要作用和β疱疹病毒特异性衣壳相关蛋白 pp150 的存在。SCP 和 pp150 以及 UL77 和 UL93 蛋白是重要的衣壳成分，但它们的确切作用机制尚不清楚。在这里，我们分析了缺失编码 pUL77、pUL93、pp150 或 SCP 的开放阅读框（ORF）如何影响核衣壳的蛋白组成。这是通过生成缺乏相应基因的 HCMV 基因组，并结合高效的转染技术来实现的，该技术使我们能够直接在转染的细胞中分析这些突变体。当 pUL77、pUL93 或 pp150 缺失时，没有明显的影响，但 SCP 的缺失会由于主要衣壳蛋白（MCP）的含量大大减少而阻碍衣壳组装。相反，当 MCP 缺失时，SCP 变得无法检测到，表明 SCP 和 MCP 相互依赖以建立适当的蛋白水平。介导稳定 MCP 水平的 SCP 结构域可以缩小到已知传递 MCP 结合的 C 端螺旋。有趣的是，一种 SCP-EGFP（增强型绿色荧光蛋白）融合蛋白也会损害感染性后代的产生，但它的作用方式不同，因为衣壳组装并没有被废除；然而，SCP-EGFP 携带的衣壳没有 DNA，被困在准晶核结构中。这些结果表明，SCP 在 HCMV 中是必不可少的，因为它对 MCP 水平有影响，并揭示了 SCP 作为抗病毒抑制剂的潜在靶点。

人巨细胞病毒（HCMV）是一种普遍存在的病原体，会导致免疫功能低下的个体发生危及生命的疾病。衣壳组装和基因组包装等病毒特异性过程可被用于设计新的抗病毒策略。在这里，我们报告了 HCMV 小衣壳蛋白（SCP）的一个新功能，即确保主要衣壳蛋白（MCP）的稳定水平，从而控制衣壳组装。此外，我们发现小和大衣壳蛋白之间存在相互依赖关系，以保证各自蛋白的适当水平，并且能够确定负责这种效应的 SCP 结构域到以前显示介导与主要衣壳蛋白结合的区域。总之，我们的数据有助于理解 SCP 在 HCMV 感染周期中如何发挥重要作用。此外，破坏 SCP-MCP 界面可能为开发新型抗病毒药物提供起点。