干扰素基因刺激因子基因敲除对猪伪狂犬病病毒复制的影响

doi:10.11843/j.issn.0366-6964.2019.11.011

畜牧兽医学报 ›› 2019, Vol. 50 ›› Issue (11): 2273-2282.doi: 10.11843/j.issn.0366-6964.2019.11.011

干扰素基因刺激因子基因敲除对猪伪狂犬病病毒复制的影响

侯璐, 王一, 张爽, 李国利, 曾磊, 郭玉堃, 翟云云, 于朋伟, 王棋, 王春凤, 杜永坤*, 万博*

河南农业大学农业部动物生化与营养重点开放实验室, 郑州 450002

收稿日期:2019-05-30 出版日期:2019-11-23 发布日期:2019-11-23
通讯作者: 杜永坤,主要从事基础兽医学研究,E-mail:mututushen@163.com;万博,主要从事基础兽医学研究,E-mail:wanboyi2000@163.com
作者简介:侯璐(1992-),女,河南洛阳人,硕士生,主要从事基础兽医学研究,E-mail:627557768@qq.com;王一(1993-),男,河南焦作人,硕士生,主要从事基础兽医学研究,E-mail:1530760117@qq.com。
基金资助:
转基因生物新品种培育重大专项（2016ZX08006001-006）；优势特色学科建设经费（203/18xk0102）；2019河南省重点研发与推广专项（192102110191）；“十二五”农村领域国家科技计划课题（2015BAD12B02-3）

Effect of Interferon Gene Stimulating Factor Gene Knockout on Replication of Porcine Pseudorabies Virus

HOU Lu, WANG Yi, ZHANG Shuang, LI Guoli, ZENG Lei, GUO Yukun, ZHAI Yunyun, YU Pengwei, WANG Qi, WANG Chunfeng, DU Yongkun*, WAN Bo*

Key Laboratory of Animal Biochemistry and Nutrition of Ministry of Agriculture and Rural Affairs, Henan Agricultural University, Zhengzhou 450002, China

Received:2019-05-30 Online:2019-11-23 Published:2019-11-23

摘要/Abstract

摘要： 研究干扰素基因刺激因子（STING）基因敲除对猪伪狂犬病病毒（PRV）复制的影响。用CRISPR/Cas9技术敲除猪肺巨噬细胞系（3D4/21）的STING基因，用T7核酸酶检测靶基因敲除效率，用细胞计数试剂盒检测基因敲除细胞的活力，用表达绿色荧光蛋白（GFP）的重组病毒PRV-GFP感染基因敲除细胞，用流式细胞术检测感染细胞的荧光强度，用定量RT-PCR检测PRV的gB、TK基因表达及其感染细胞的IL-1β、IFN-β、ISG15基因转录，用Western blot检测PRV gE蛋白表达水平，用病毒滴定法测定子代病毒滴度。结果显示：设计的3个STING基因外显子2特异sgRNA均能切割3D4/21细胞的靶序列，其中sgRNA3的基因编辑效率最高；对sgRNA1介导STING基因敲除系进行克隆化，获得基因敲除细胞系3株，基因敲除对细胞活力无影响；亲本细胞培养的PRV-GFP感染阳性细胞占80.77%，STING基因敲除细胞培养的PRV-GFP感染阳性细胞占95.55%；STING基因敲除对PRV基因表达具有促进作用，亲本3D4/21细胞的病毒滴度为10^6.2 TCID₅₀·0.1 mL^-1，STING基因敲除细胞的病毒滴度为10^8.3TCID₅₀·0.1 mL^-1，病毒感染细胞的IL-1β、IFN-β和ISG15转录下调明显。STING基因敲除能促进PRV在3D4/21细胞中复制，可能与感染细胞的IL-β、IFN-β和ISG15表达抑制有关。

Abstract: This study was conducted to explore the effect of interferon gene stimulating factor (STING) gene knockout on replication of pseudorabies virus (PRV). The STING gene of porcine pulmonary macrophage cell line 3D4/21 was knocked out by using CRISPR/Cas9 technique, the target gene knockout efficiency was detected by using T7 nuclease, and the activity of gene knockout cells was detected by using cell counting kit. The recombinant virus PRV-GFP expressing green fluorescent protein (GFP) was used to infect the knockout cells, and the fluorescence intensity of the infected cells was detected by flow cytometry. The expression of gB and TK genes in PRV and the transcription of IL-1β, IFN-β and ISG15 genes in infected cells were detected by quantitative RT-PCR, the expression level of PRV gE protein was detected by Western blot, and the viral titer of offspring was determined by viral titration. The results showed that all of three designed exon2 specific sgRNA of STING gene could cleave the target sequences of 3D4/21 cells, and the gene editing efficiency of sgRNA3 was the highest. SgRNA1-mediated STING gene knockout lines were cloned and three gene knockout cell lines were obtained. Gene knockout had no effect on cell activity. PRV-GFP positive cells cultured in parental cells accounted for 80.77%, and PRV-GFP positive cells cultured in STING knockout cells accounted for 95.55%. STING gene knockout could promote the expression of PRV gene. The virus titer of parent 3D4/21 cells was 10^6.2 TCID₅₀·0.1 mL^-1, and the virus titer of STING knockout cells was 10^8.3 TCID₅₀·0.1 mL^-1. The transcription of IL-1β, IFN-β and ISG15 in virus infected cells were significantly down-regulated. STING gene knockout can promote the replication of PRV in 3D4/21 cells, which may be related to the inhibition of IL-1β, IFN-β and ISG15 expression in infected cells.

中图分类号:

S852.659.1

侯璐, 王一, 张爽, 李国利, 曾磊, 郭玉堃, 翟云云, 于朋伟, 王棋, 王春凤, 杜永坤, 万博. 干扰素基因刺激因子基因敲除对猪伪狂犬病病毒复制的影响[J]. 畜牧兽医学报, 2019, 50(11): 2273-2282.

HOU Lu, WANG Yi, ZHANG Shuang, LI Guoli, ZENG Lei, GUO Yukun, ZHAI Yunyun, YU Pengwei, WANG Qi, WANG Chunfeng, DU Yongkun, WAN Bo. Effect of Interferon Gene Stimulating Factor Gene Knockout on Replication of Porcine Pseudorabies Virus[J]. ACTA VETERINARIA ET ZOOTECHNICA SINICA, 2019, 50(11): 2273-2282.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: https://www.xmsyxb.com/CN/10.11843/j.issn.0366-6964.2019.11.011

https://www.xmsyxb.com/CN/Y2019/V50/I11/2273

参考文献 30

[1]	SERāO N V L, MATIKA O, KEMP R A, et al. Genetic analysis of reproductive traits and antibody response in a PRRS outbreak herd[J]. J Anim Sci, 2014, 92(7):2905-2921.
[2]	YAMAMOTO-FURUSHO J K, PODOLSKY D K. Innate immunity in inflammatory bowel disease[J]. World J Gastroenterol, 2007, 13(42):5577-5580.
[3]	HAZLETT L, WU M H. Defensins in innate immunity[J]. Cell Tissue Res, 2011, 343(1):175-188.
[4]	SUN J C, BEILKE J N, LANIER L L. Adaptive immune features of natural killer cells[J]. Nature, 2009, 457(7229):557-561.
[5]	OLANRATMANEE E O, THANAWONGNUWECH R, KUNAVONGKRIT A, et al. Reproductive performance of sows with and without PRRS modified live virus vaccination in PRRS-virus-seropositive herds[J]. Trop Anim Health Prod, 2014, 46(6):1001-1007.
[6]	KELLY B, O'NEILL L A. Metabolic reprogramming in macrophages and dendritic cells in innate immunity[J]. Cell Res, 2015, 25(7):771-784.
[7]	ZHOU L L, CAO X X, FANG J, et al. Macrophages polarization is mediated by the combination of PRR ligands and distinct inflammatory cytokines[J]. Int J Clin Exp Pathol, 2015, 8(9):10964-10974.
[8]	BURDETTE D L, MONROE K M, SOTELO-TROHA K, et al. STING is a direct innate immune sensor of cyclic di-GMP[J]. Nature, 2011, 478(7370):515-518.
[9]	MA Z, JACOBS S R, WEST J A, et al. Modulation of the cGAS-STING DNA sensing pathway by gammaherpesviruses[J]. Proc Natl Acad Sci U S A, 2015, 112(31):E4306-E4315.
[10]	MA Z, DAMANIA B. The cGAS-STING defense pathway and its counteraction by viruses[J]. Cell Host Microbe, 2016, 19(2):150-158.
[11]	OUYANG S Y, SONG X Q, WANG Y Y, et al. Structural analysis of the STING adaptor protein reveals a hydrophobic dimer interface and mode of cyclic di-GMP binding[J]. Immunity, 2012, 36(6):1073-1086.
[12]	HÄRTLOVA A, ERTTMANN S F, RAFFI F A, et al. DNA damage primes the type I interferon system via the cytosolic DNA sensor STING to promote anti-microbial innate immunity[J]. Immunity, 2015, 42(2):332-343.
[13]	LAM E, STEIN S, FALCK-PEDERSEN E. Adenovirus detection by the cGAS/STING/TBK1 DNA sensing cascade[J]. J Virol, 2014, 88(2):974-981.
[14]	王娟萍, 姚敬明,高英杰,等. 多重PCR/RT-PCR技术检测PRRSV、PPV、PRV和PCV-2[J]. 中国兽医学报, 2009, 29(3):258-262.
	WANG J P, YAO J M, GAO Y J, et al. Development of a multiplex PCR/RT-PCR assay for detection of porcine reproductive and respiratory syndrome virus, porcine parvovirus, pseudorabies virus and porcine circovirus type 2[J]. Chinese Journal of Veterinary Science, 2009, 29(3):258-262. (in Chinese)
[15]	李春华, 王英,蒋凤英,等. 猪伪狂犬病研究进展[J]. 动物医学进展, 2008, 29(3):68-72.
	LI C H, WANG Y, JIANG F Y, et al. Progress on porcine pseudorabies[J]. Progress in Veterinary Medicine, 2008, 29(3):68-72. (in Chinese)
[16]	KLIPPEL S, STRUNCK E, TEMERINAC S, et al. Quantification of PRV-1 mRNA distinguishes polycythemia vera from secondary erythrocytosis[J]. Blood, 2003, 102(10):3569-3574.
[17]	TANG Y D, GUO J C, WANG T Y, et al. CRISPR/Cas9-mediated 2-sgRNA cleavage facilitates pseudorabies virus editing[J]. FASEB J, 2018, 32(8):4293-4301.
[18]	CARTY M, BOWIE A G. Evaluating the role of Toll-like receptors in diseases of the central nervous system[J]. Biochem Pharmacol, 2011, 81(7):825-837.
[19]	ZHANG Y G, YERUVA L, MARINOV A, et al. The DNA sensor, cyclic GMP-AMP synthase, is essential for induction of IFN-β during Chlamydia trachomatis infection[J]. J Immunol, 2014, 193(5):2394-2404.
[20]	LIU X, WANG C. The emerging roles of the STING adaptor protein in immunity and diseases[J]. Immunology, 2016, 147(3):285-291.
[21]	FERGUSON B J, MANSUR D S, PETERS N E, et al. DNA-PK is a DNA sensor for IRF-3-dependent innate immunity[J]. eLife, 2012, 1:e00047.
[22]	BALDWIN S L, POWELL T D, SELLINS K S, et al. The biological effects of five feline IFN-α subtypes[J]. Vet Immunol Immunopathol, 2004, 99(3-4):153-167.
[23]	FU J, KANNE D B, LEONG M, et al. STING agonist formulated cancer vaccines can cure established tumors resistant to PD-1 blockade[J]. Sci Transl Med, 2015, 7(283):283ra52.
[24]	GUO F, HAN Y X, ZHAO X S, et al. STING agonists induce an innate antiviral immune response against hepatitis B virus[J]. Antimicrob Agents Chemother, 2015, 59(2):1273-1281.
[25]	GAJ T, GERSBACH C A, BARBAS III C F. ZFN, TALEN, and CRISPR/Cas-based methods for genome engineering[J]. Trends Biotechnol, 2013, 31(7):397-405.
[26]	SAMSON J E, MAGADAN A H, MOINEAU S. The CRISPR-Cas immune system and genetic transfers:reaching an equilibrium[J/OL]. Microbiol Spectr, 2015, 3(1):PLAS-0034-2014.[2019-09-03]. https://www.asmscience.org/content/journal/microbiolspec/10.1128/microbiolspec.PLAS-0034-2014.
[27]	黄健. Ⅰ型单纯疱疹病毒皮层蛋白VP22和UL46逃逸宿主抗病毒天然免疫的分子机制研究[D]. 苏州:苏州大学, 2018.
	HUANG J. Molecular mechanism of escape of herpes simplex virus type I cortical proteins VP22 and UL46 from host antiviral innate immunity[D]. Suzhou:Suzhou University, 2018. (in Chinese)
[28]	DALRYMPLE N A, CIMICA V, MACKOW E R. Dengue virus NS proteins inhibit RIG-I/MAVS signaling by blocking TBK1/IRF3 phosphorylation:dengue virus serotype 1 NS4A is a unique interferon-regulating virulence determinant[J]. mBio, 2015, 6(3):e00553-15.
[29]	LI M, XIN T, GAO X T, et al. Foot-and-mouth disease virus non-structural protein 2B negatively regulates the RLR-mediated IFN-β induction[J]. Biochem Biophys Res Commun, 2018, 504(1):238-244.
[30]	DING Z, FANG L R, JING H Y, et al. Porcine epidemic diarrhea virus nucleocapsid protein antagonizes beta interferon production by sequestering the interaction between IRF3 and TBK1[J]. J Virol, 2014, 88(16):8936-8945.

干扰素基因刺激因子基因敲除对猪伪狂犬病病毒复制的影响

Effect of Interferon Gene Stimulating Factor Gene Knockout on Replication of Porcine Pseudorabies Virus

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献 30

相关文章 15

编辑推荐

Metrics

本文评价

[1]	迟丽丽, 王君娜, 张宇名, 刘健, 陈志远, 李树凡, 尹燕博, 徐守振. 禽腺病毒4型fiber-2与8b型fiber截短融合蛋白的原核表达及其免疫原性分析[J]. 畜牧兽医学报, 2023, 54(12): 5162-5170.
[2]	李林燕, 滕蔓, 刘金玲, 郑鹿平, 柴书军, 丁轲, 余祖华, 罗俊. 马立克病病毒单克隆抗体库构建及gB蛋白特异性单抗的筛选与鉴定[J]. 畜牧兽医学报, 2023, 54(11): 4712-4723.
[3]	张芳源, 杨大为, 仇德洋, 姜国骞, 李桂梅, 单虎. 非洲猪瘟病毒P30蛋白的表达及抗体液相芯片检测方法的建立[J]. 畜牧兽医学报, 2023, 54(10): 4300-4310.
[4]	冯永智, 龚婷, 吴东东, 高琦, 郑晓宇, 张桂红, 孙彦阔. 影响非洲猪瘟病毒对培养细胞感染性的因素分析[J]. 畜牧兽医学报, 2023, 54(8): 3406-3414.
[5]	张翼, 王晨燕, 杨骁, 邵国青, 侯博. 鸡传染性喉气管炎病毒WF03株关键抗原基因和毒力基因的遗传演化与致病性分析[J]. 畜牧兽医学报, 2023, 54(8): 3435-3444.
[6]	丁晓艳, 何久香, 周晓杨, 周伃欣, 李晋涛. 非洲猪瘟病毒感染相关调控基因以及毒力基因初步筛选[J]. 畜牧兽医学报, 2023, 54(7): 2964-2971.
[7]	陈宏建, 曹艳, 樊杰, 甘荣萱, 宋文博, 喻盛炜, 杨婷, 赵艳霞, 魏春燕, 谢锐, 华琳, 彭忠, 吴斌. 2020—2022年湖北省生猪屠宰场伪狂犬病病毒的分离鉴定及遗传进化分析[J]. 畜牧兽医学报, 2023, 54(7): 2972-2981.
[8]	王佳丽, 周宁, 陈曦, 岳华, 汤承. 犬腺病毒2型E3基因自然缺失毒株的分离鉴定及其致病性[J]. 畜牧兽医学报, 2023, 54(7): 2982-2990.
[9]	冯伟民, 刘潇, 黄腾. 畜禽疱疹病毒逃避CTL识别的策略:干扰MHC-Ⅰ分子抗原递呈途径[J]. 畜牧兽医学报, 2023, 54(6): 2241-2251.
[10]	高真贞, 蒙泽菁, 何小兵, 房永祥, 田慧慧, 陈国华, 景志忠. 鼠痘病毒EVM135和EVM085蛋白免疫原性及抗体中和活性的鉴定[J]. 畜牧兽医学报, 2023, 54(6): 2468-2477.
[11]	王映, 朱家宏, 赵加凯, 纪品品, 陈旭, 张路, 刘宝元, 孙亚妮, 赵钦. 抗非洲猪瘟病毒NP419L蛋白纳米抗体的筛选鉴定及其在抗体检测中的初步应用[J]. 畜牧兽医学报, 2023, 54(6): 2509-2520.
[12]	邱英武, 常昊, 彭杰, 易和友, 王秋梅, 郭彦辰, 吴倩雯, 曹雪珍, 林丽苗, 李薇, 周庆丰, 张桂红, 李群辉, 龚浪. 一种快速检测非洲猪瘟病毒I177L基因缺失毒株的荧光定量PCR方法[J]. 畜牧兽医学报, 2023, 54(6): 2521-2527.
[13]	龙琴琴, 魏敏, 王雨婷, 文明, 庞峰. 羊口疮病毒与宿主的博弈:免疫应答与病毒免疫逃逸机制[J]. 畜牧兽医学报, 2023, 54(5): 1845-1853.
[14]	王国超, 赵亚茹, 张忠辉, 张玉龙, 白鸽, 耿抒贤, 樊洁, 杨吉飞, 关贵全, 殷宏, 罗建勋, 牛庆丽. 非洲猪瘟病毒RNA聚合酶亚基D205R基因生物信息学分析及多克隆抗体制备[J]. 畜牧兽医学报, 2023, 54(5): 2042-2049.
[15]	袁生, 李安琪, 吕文珂, 羊露露, 周峰, 黄良宗, 白挨泉, 温峰, 黄淑坚, 郭锦玥. 一株猪伪狂犬病病毒的主要毒力相关基因的变异分析及其对家兔的致病性[J]. 畜牧兽医学报, 2023, 54(5): 2195-2199.