乙型肝炎病毒衣壳分解的分子机制

Zhaleh Ghaemi, M. Gruebele, E. Tajkhorshid
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引用次数: 10

摘要

乙型肝炎病毒(HBV)是一种DNA病毒,其传染性是艾滋病毒的100倍。尽管有疫苗,但全球这种病毒的慢性感染率仍超过2.5亿人。目前尚无治愈方法的HBV慢性感染可导致肝癌。因此,对该病毒的感染周期进行调查的需求尚未得到满足。病毒复制周期中最关键的步骤之一是将其遗传物质释放到细胞核。在这一步骤中,包裹遗传物质的病毒衣壳解体。然而,其机制尚不清楚。在这里,我们利用分子模拟来揭示导致衣壳分解的原子细节事件。病毒衣壳的分解导致其遗传物质释放到宿主细胞中是病毒感染的一个基本步骤。在乙型肝炎病毒(HBV)中,衣壳由相同的蛋白质单体组成,它们二聚,然后在衣壳表面排列成五聚体或六聚体。通过对整个溶剂化HBV衣壳进行原子分子动力学模拟,我们监测了衣壳的分解过程,并在20个独立的模拟副本中分析了这一过程,直至单个氨基酸的水平。各向同性外力的应变,加上结构波动,导致HBV衣壳出现结构不均匀的裂缝。对单体-单体界面的分析表明,与纯力学考虑的预期相反,裂纹主要发生在六聚体位点,而五聚体位点基本保持完整。只有一小部分衣壳蛋白单体,在每个模拟中都是不同的,参与了每个分解实例。我们确定了在拆卸过程中最容易丢失相互作用的特定残基;R127, I139, Y132, N136, A137和V149是位于六聚体内的二聚体之间界面的热点,导致拆卸。这些热点残基中的大多数在进化过程中被保存下来,这暗示了它们通过避免衣壳的过度稳定而对分解的重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Molecular mechanism of capsid disassembly in hepatitis B virus
Significance Hepatitis B virus (HBV) is a DNA virus that is 100 times more infectious than HIV. Despite the availability of a vaccine, the chronic infection rate of this virus is still over 250 million people globally. HBV chronic infection, for which no cure is currently available, can lead to liver cancer. Therefore, there is an unmet need to investigate the infection cycle of the virus. One of the most crucial steps in the virus-replication cycle is the release of its genetic material to the nucleus. During this step, the viral capsid enclosing the genetic material disassembles. However, its mechanism is unknown. Here, we utilize molecular simulations to shed light on the events leading to the capsid disassembly with atomistic detail. The disassembly of a viral capsid leading to the release of its genetic material into the host cell is a fundamental step in viral infection. In hepatitis B virus (HBV), the capsid consists of identical protein monomers that dimerize and then arrange themselves into pentamers or hexamers on the capsid surface. By applying atomistic molecular dynamics simulation to an entire solvated HBV capsid subjected to a uniform mechanical stress protocol, we monitor the capsid-disassembly process and analyze the process down to the level of individual amino acids in 20 independent simulation replicas. The strain of an isotropic external force, combined with structural fluctuations, causes structurally heterogeneous cracks to appear in the HBV capsid. Analysis of the monomer–monomer interfaces reveals that, in contrast to the expectation from purely mechanical considerations, the cracks mainly occur within hexameric sites, whereas pentameric sites remain largely intact. Only a small subset of the capsid protein monomers, different in each simulation, are engaged in each instance of disassembly. We identify specific residues whose interactions are most readily lost during disassembly; R127, I139, Y132, N136, A137, and V149 are among the hot spots at the interfaces between dimers that lie within hexamers, leading to disassembly. The majority of these hot-spot residues are conserved by evolution, hinting to their importance for disassembly by avoiding overstabilization of capsids.
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