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ANK基因缺失重组山羊痘病毒的构建与纯化

Construction and purification of ANK gene deleted recombinant goatpox virus.

作者信息

Zhang Xueping, Tong Jianjun, Milikaimu Tuohetiniyazi, He Chuanchuan, Wang Wei, Li Youwen

机构信息

Construction Corps Key Laboratory of Livestock Technology in Tarim, Alar, 843300 Xinjiang China.

College of Life Science, Tarim University, Alar, 843300 Xinjiang China.

出版信息

Virusdisease. 2020 Dec;31(4):526-533. doi: 10.1007/s13337-020-00620-z. Epub 2020 Aug 10.

DOI:10.1007/s13337-020-00620-z
PMID:33381625
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7749001/
Abstract

Sheeppox virus (SPPV) and goatpox virus (GTPV) are two pathogens of host specificity. Previous studies have hypothesized that ankyrin (ANK) family may play an important role in determining host range of SPPV and GTPV. In order to verify the function of ANK proteins, it is critical to generate and purify the ANK gene deleted GTPV. In this study, the GFP gene as a reporter gene was connected with two homologous arms of ANK gene by fusion PCR. The ANK gene deleted transfer vectors were generated by inserting the PCR products into PET42b, and were transfected into testicular primary cells which were infected by GTPV. The rGTPV were identified as green fluorescence positive and properly purified. The results showed that GFP gene and two homologous arms of ANK gene were connected. The sequence was inserted in PET42b to form ANK deleted transfer vector. ANK deleted rGTPV was generated successfully by transferring vector and GTPV in cells. The ANK deleted rGTPV was purified and identified in this study. The study successfully generated the ANK deleted rGTPV. It overcomes the technical barrier for future studies about the function of ANK genes.

摘要

绵羊痘病毒(SPPV)和山羊痘病毒(GTPV)是两种具有宿主特异性的病原体。先前的研究推测锚蛋白(ANK)家族可能在决定SPPV和GTPV的宿主范围中起重要作用。为了验证ANK蛋白的功能,产生并纯化缺失ANK基因的GTPV至关重要。在本研究中,通过融合PCR将绿色荧光蛋白(GFP)基因作为报告基因与ANK基因的两个同源臂连接。通过将PCR产物插入PET42b中产生缺失ANK基因的转移载体,并将其转染到被GTPV感染的睾丸原代细胞中。重组GTPV(rGTPV)被鉴定为绿色荧光阳性并进行了适当的纯化。结果表明,GFP基因与ANK基因的两个同源臂相连。该序列插入PET42b中形成缺失ANK的转移载体。通过在细胞中转移载体和GTPV成功产生了缺失ANK的rGTPV。本研究对缺失ANK的rGTPV进行了纯化和鉴定。该研究成功产生了缺失ANK的rGTPV。它克服了未来关于ANK基因功能研究的技术障碍。

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