Perry Jeffrey W, Chen Yanhua, Speliotes Elizabeth, Tai Andrew W
Division of Gastroenterology, Department of Internal Medicine, University of Michigan Medical School, Ann Arbor, Michigan, USA.
Division of Gastroenterology, Department of Internal Medicine, University of Michigan Medical School, Ann Arbor, Michigan, USA
J Virol. 2018 Mar 14;92(7). doi: 10.1128/JVI.02085-17. Print 2018 Apr 1.
In the last few decades, dengue virus, an arbovirus, has spread to over 120 countries. Although a vaccine has been approved in some countries, limitations on its effectiveness and a lack of effective antiviral treatments reinforce the need for additional research. The functions of several viral nonstructural proteins are essentially unknown. To better understand the functions of these proteins and thus dengue virus pathogenesis, we embarked on a genomewide transposon mutagenesis screen with next-generation sequencing to determine sites in the viral genome that tolerate 15-nucleotide insertions. Using this approach, we generated support for several published predicted transmembrane and enzymatic domains. Next, we created 7 mutants containing the 15-nucleotide insertion from the original selection and found 6 of them were capable of replication in both mammalian and mosquito tissue culture cells. Interestingly, one mutation had a significant impairment of viral assembly, and this mutation may lead to a better understanding of viral assembly and release. In addition, we created a fully infectious virus expressing a functionally tagged NS4B protein, which will provide a much-needed tool to elucidate the role of NS4B in viral pathogenesis. Dengue virus is a mosquito-borne virus distributed in tropical and subtropical regions globally that can result in hospitalization and even death in some cases. Although a vaccine exists, its limitations and a lack of approved antiviral treatments highlight our limited understanding of dengue virus pathogenesis and host immunity. The functions of many viral proteins are poorly understood. We used a previously published approach using transposon mutagenesis to develop tools to study these proteins' functions by adding insertions randomly throughout the viral genomes. These genomes were transferred into cells, and infectious progeny were recovered to determine sites that tolerated insertions, as only the genomes that tolerated insertions would be able to propagate. Using these results, we created viruses with epitope tags, one in the viral structural protein Capsid and one in the viral nonstructural protein NS4B. Further investigation of these mutants may elucidate the roles of Capsid and NS4B during dengue virus infections.
在过去几十年里,登革病毒作为一种虫媒病毒,已传播至120多个国家。尽管在一些国家已批准使用一种疫苗,但其有效性存在局限,且缺乏有效的抗病毒治疗方法,这凸显了开展更多研究的必要性。几种病毒非结构蛋白的功能基本未知。为了更好地理解这些蛋白的功能以及登革病毒的发病机制,我们采用全基因组转座子诱变筛选结合下一代测序技术,以确定病毒基因组中能够耐受15个核苷酸插入的位点。通过这种方法,我们为几个已发表的预测跨膜结构域和酶结构域提供了支持。接下来,我们创建了7个含有原始筛选出的15核苷酸插入片段的突变体,发现其中6个能够在哺乳动物和蚊子组织培养细胞中复制。有趣的是,一个突变对病毒组装有显著损害,该突变可能有助于更好地理解病毒的组装和释放过程。此外,我们构建了一种表达功能标记的NS4B蛋白的完全感染性病毒颗粒,这将为阐明NS4B在病毒发病机制中的作用提供急需的工具。登革病毒是一种通过蚊子传播的病毒,分布于全球热带和亚热带地区,在某些情况下可导致住院甚至死亡。尽管有疫苗,但疫苗的局限性以及缺乏经批准的抗病毒治疗方法,凸显了我们对登革病毒发病机制和宿主免疫的了解有限。许多病毒蛋白的功能尚不清楚。我们采用先前发表的利用转座子诱变的方法,通过在整个病毒基因组中随机添加插入片段来开发研究这些蛋白功能的工具。将这些基因组转入细胞中,回收感染性子代以确定能够耐受插入的位点,因为只有能够耐受插入的基因组才能进行增殖。利用这些结果,我们创建了带有表位标签的病毒,一个标签位于病毒结构蛋白衣壳中,另一个位于病毒非结构蛋白NS4B中。对这些突变体的进一步研究可能会阐明衣壳蛋白和NS4B在登革病毒感染过程中的作用。