载体的易感性受到蓝舌病病毒中一小段缺失或点突变的强烈影响。

Vector competence is strongly affected by a small deletion or point mutations in bluetongue virus.

机构信息

Department of Virology, Wageningen Bioveterinary Research, Lelystad, The Netherlands.

Arthropod-Borne Animal Diseases Research Unit, Centre for Grain and Animal Health Research, USDA-ARS, Manhattan, KS, USA.

出版信息

Parasit Vectors. 2019 Oct 11;12(1):470. doi: 10.1186/s13071-019-3722-2.

DOI:10.1186/s13071-019-3722-2

PMID:31604476

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6790033/

Abstract

BACKGROUND

Transmission of vector-borne virus by insects is a complex mechanism consisting of many different processes; viremia in the host, uptake, infection and dissemination in the vector, and delivery of virus during blood-feeding leading to infection of the susceptible host. Bluetongue virus (BTV) is the prototype vector-borne orbivirus (family Reoviridae). BTV serotypes 1-24 (typical BTVs) are transmitted by competent biting Culicoides midges and replicate in mammalian (BSR) and midge (KC) cells. Previously, we showed that genome segment 10 (S10) encoding NS3/NS3a protein is required for virus propagation in midges. BTV serotypes 25-27 (atypical BTVs) do not replicate in KC cells. Several distinct BTV26 genome segments cause this so-called 'differential virus replication' in vitro.

METHODS

Virus strains were generated using reverse genetics and their growth was examined in vitro. The midge feeding model has been developed to study infection, replication and disseminations of virus in vivo. A laboratory colony of C. sonorensis, a known competent BTV vector, was fed or injected with BTV variants and propagation in the midge was examined using PCR testing. Crossing of the midgut infection barrier was examined by separate testing of midge heads and bodies.

RESULTS

A 100 nl blood meal containing ±10 TCID/ml of BTV11 which corresponds to ±20 TCID infected 50% of fully engorged midges, and is named one Midge Alimentary Infective Dose (MAID). BTV11 with a small in-frame deletion in S10 infected blood-fed midge midguts but virus release from the midgut into the haemolymph was blocked. BTV11 with S1[VP1] of BTV26 could be adapted to virus growth in KC cells, and contained mutations subdivided into 'corrections' of the chimeric genome constellation and mutations associated with adaptation to KC cells. In particular one amino acid mutation in outer shell protein VP2 overcomes differential virus replication in vitro and in vivo.

CONCLUSION

Small changes in NS3/NS3a or in the outer shell protein VP2 strongly affect virus propagation in midges and thus vector competence. Therefore, spread of disease by competent Culicoides midges can strongly differ for very closely related viruses.

摘要

背景

昆虫传播的虫媒病毒是一个由许多不同过程组成的复杂机制；宿主中的病毒血症、在媒介中的摄取、感染和传播，以及在吸血过程中病毒的传递导致易感宿主的感染。蓝舌病病毒（BTV）是虫媒病毒的原型（科 Reoviridae）。血清型 1-24 的 BTV（典型 BTV）由有能力的吸血库蠓传播，并在哺乳动物（BSR）和库蠓（KC）细胞中复制。以前，我们表明，编码 NS3/NS3a 蛋白的基因组片段 10（S10）是病毒在库蠓中繁殖所必需的。血清型 25-27 的 BTV（非典型 BTV）不能在 KC 细胞中复制。几个不同的 BTV26 基因组片段导致了这种所谓的“体外病毒复制差异”。

方法

使用反向遗传学生成病毒株，并在体外研究其生长情况。已经开发了库蠓喂养模型来研究病毒在体内的感染、复制和传播。使用已知的 BTV 有效媒介 C. sonorensis 的实验室品系，用 BTV 变体喂养或注射，并使用 PCR 检测来检测库蠓中的繁殖情况。通过单独检测库蠓的头部和身体来检测中肠感染屏障的交叉。

结果

含有±10 TCID/ml BTV11 的 100 nl 血餐对应于±20 TCID 感染了 50%完全饱食的库蠓，被命名为一个库蠓肠道感染剂量（MAID）。S10 中有小的框架内缺失的 BTV11 感染了饱食的库蠓中肠，但病毒从中肠释放到血淋巴中被阻断。具有 BTV26 的 S1[VP1]的 BTV11 可以适应 KC 细胞中的病毒生长，并且包含分为“纠正”嵌合基因组排列和与适应 KC 细胞相关的突变的突变。特别是，外壳蛋白 VP2 中的一个氨基酸突变克服了体外和体内的差异病毒复制。

结论

NS3/NS3a 或外壳蛋白 VP2 的微小变化强烈影响库蠓中的病毒繁殖，从而影响媒介能力。因此，具有媒介能力的库蠓传播疾病的范围可能因非常密切相关的病毒而有很大差异。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e0bf/6790033/8fe5f2facb64/13071_2019_3722_Fig1_HTML.jpg

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载体的易感性受到蓝舌病病毒中一小段缺失或点突变的强烈影响。

Vector competence is strongly affected by a small deletion or point mutations in bluetongue virus.

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