State Key Laboratory of Marine Environmental Science, State-Province Joint Engineering Laboratory of Marine Bioproducts and Technology, College of Ocean and Earth Sciences, Xiamen University, Xiamen, Fujian, China.
Department of Biotechnology and Bioindustry Sciences, College of Biosciences and Biotechnology, National Cheng Kung University, Tainan, Taiwan.
J Virol. 2020 Nov 23;94(24). doi: 10.1128/JVI.01570-20.
As the most severely lethal viral pathogen for crustaceans in both brackish water and freshwater, white spot syndrome virus (WSSV) has a mechanism of infection that remains largely unknown, which profoundly limits the control of WSSV disease. By using a hematopoietic tissue (Hpt) stem cell culture from the red claw crayfish suitable for WSSV propagation , the intracellular trafficking of live WSSV, in which the acidic-pH-dependent endosomal environment was a prerequisite for WSSV fusion, was determined for the first time via live-cell imaging. When the acidic pH within the endosome was alkalized by chemicals, the intracellular WSSV virions were detained in dysfunctional endosomes, resulting in appreciable blocking of the viral infection. Furthermore, disrupted valosin-containing protein ( VCP [VCP]) activity resulted in considerable aggregation of endocytic WSSV virions in the disordered endosomes, which subsequently recruited autophagosomes, likely by binding to GABARAP via VCP, to eliminate the aggregated virions within the dysfunctional endosomes. Importantly, both autophagic sorting and the degradation of intracellular WSSV virions were clearly enhanced in Hpt cells with increased autophagic activity, demonstrating that autophagy played a defensive role against WSSV infection. Intriguingly, most of the endocytic WSSV virions were directed to the endosomal delivery system facilitated by VCP activity so that they avoided autophagy degradation and successfully delivered the viral genome into Hpt cell nuclei, which was followed by the propagation of progeny virions. These findings will benefit anti-WSSV target design against the most severe viral disease currently affecting farmed crustaceans. White spot disease is currently the most devastating viral disease in farmed crustaceans, such as shrimp and crayfish, and has resulted in a severe ecological problem for both brackish water and freshwater aquaculture areas worldwide. Efficient antiviral control of WSSV disease is still lacking due to our limited knowledge of its pathogenesis. Importantly, research on the WSSV infection mechanism is also quite meaningful for the elucidation of viral pathogenesis and virus-host coevolution, as WSSV is one of the largest animal viruses, in terms of genome size, that infects only crustaceans. Here, we found that most of the endocytic WSSV virions were directed to the endosomal delivery system, strongly facilitated by VCP, so that they avoided autophagic degradation and successfully delivered the viral genome into the Hpt cell nucleus for propagation. Our data point to a virus-sorting model that might also explain the escape of other enveloped DNA viruses.
作为咸水和淡水甲壳类动物中最致命的病毒病原体,白斑综合征病毒(WSSV)的感染机制在很大程度上仍不清楚,这极大地限制了对 WSSV 疾病的控制。通过使用一种适合 WSSV 繁殖的红螯螯虾造血组织(Hpt)干细胞培养物,首次通过活细胞成像确定了活 WSSV 的细胞内运输,其中酸性 pH 依赖性内体环境是 WSSV 融合的先决条件。当化学物质使内体中的酸性 pH 碱化时,细胞内的 WSSV 病毒粒子滞留在功能失调的内体中,从而显著阻止病毒感染。此外,破坏包含 valosin 的蛋白(VCP[VCP])的活性导致内吞 WSSV 病毒粒子在内乱的内体中大量聚集,随后通过 VCP 与 GABARAP 结合招募自噬体,可能是通过 VCP 与 GABARAP 结合来消除功能失调的内体中的聚集病毒粒子。重要的是,在具有增强的自噬活性的 Hpt 细胞中,自噬性分选和细胞内 WSSV 病毒粒子的降解都明显增强,这表明自噬对 WSSV 感染起防御作用。有趣的是,大多数内吞 WSSV 病毒粒子都被定向到由 VCP 活性促进的内体递呈系统,从而避免了自噬降解,并成功将病毒基因组递送到 Hpt 细胞核中,随后产生了后代病毒粒子。这些发现将有益于针对目前影响养殖甲壳类动物的最严重病毒性疾病的抗 WSSV 靶标设计。白斑病是目前养殖虾和蟹等甲壳类动物中最具破坏性的病毒性疾病,已对全球咸水和淡水水产养殖区造成严重的生态问题。由于我们对其发病机制的了解有限,因此仍然缺乏有效的抗病毒控制 WSSV 疾病的方法。重要的是,对 WSSV 感染机制的研究对于阐明病毒发病机制和病毒 - 宿主共同进化也具有重要意义,因为 WSSV 是感染甲壳类动物的最大的动物病毒之一,就基因组大小而言。在这里,我们发现大多数内吞 WSSV 病毒粒子都被定向到由 VCP 强烈促进的内体递呈系统,从而避免了自噬降解,并成功将病毒基因组递送到 Hpt 细胞核中进行繁殖。我们的数据指向一种病毒分选模型,该模型也可能解释其他包膜 DNA 病毒的逃逸。
