利用酵母同源重组系统快速构建柑橘叶斑驳病毒的侵染性克隆

doi:10.3864/j.issn.0578-1752.2018.09.007

摘要/Abstract

摘要： 【目的】构建柑橘叶斑驳病毒（Citrus leaf blotch virus，CLBV）中国分离株的侵染性克隆，为从分子水平解析其致病机理打下基础。【方法】以GeneArt® pYES1L Vector为模板，PYES2117F、PYES2117R为引物扩增含有酵母相关复制起始位点的片段pYES1L-2117，利用限制性内切酶Sac II单酶切双元载体DK1317-2并回收其大片段，利用In-Fusion HD Cloning Kit重组连接双元载体DK1317-2骨架和片段pYES1L-2117，得到可以在酵母-农杆菌-大肠杆菌中复制的三元穿梭载体pCY。以马铃薯X病毒(Potato virus X,PVX)全长cDNA侵染性克隆为模板，pCY-PVX-F、pCY-PVX-R为引物扩增PVX全长，采用限制性内切酶Stu I、Sma I酶切质粒pCY，采用醋酸锂转化法将获得的PVX基因组全长cDNA与线性化的pCY载体共转化酵母菌YPH501，通过同源重组获得PVX基因组全长cDNA克隆。通过农杆菌介导接种本生烟验证所构建克隆的侵染性，从而建立基于酵母同源重组的病毒侵染性克隆快速构建体系。在此基础上，以CLBV中国分离物（CLBV-HBYD）全长cDNA为模板，分段扩增其基因组，得到片段CLBV-1、CLBV-2；利用所建体系对CLBV-1、CLBV-2及pCY载体片段进行同源重组。得到重组质粒pCY-CLBV后,经农杆菌介导接种本生烟和锦橙幼苗，并利用RT-PCR和Northern blot检测其侵染性。【结果】建立了酵母-大肠杆菌-农杆菌的三元穿梭载体PCY，该载体全长10 347 bp,含有酵母、农杆菌、大肠杆菌的复制位点，能在酵母-农杆菌-大肠杆菌稳定复制，可用于在酵母中通过同源重组快速构建病毒基因组全长cDNA克隆，也可用于通过农杆菌介导直接接种植物寄主。利用该体系获得了CLBV中国分离株的基因组全长cDNA克隆16个。随机选取1个克隆进行了序列测定（GenBank登录号：MG572236），其基因组全长8 747 nt，包含3个开放阅读框(open reading frame，ORF)，ORF1为5 889 nt、ORF2为1 089 nt、ORF3为1 092 nt。全基因组序列比对显示，CLBV-HBYD与已登录的9个CLBV分离物的核酸序列一致性为79％—98％，其中与柑橘来源的EU857540一致性最高，为98%，与猕猴桃来源的JN983454、JN983455、JN983456和JN900477的一致性均为79%。在利用MEGA6 软件构建的系统发育树上，CLBV-HBYD与柑橘来源的CLBV分离株聚为一簇，而猕猴桃来源的CLBV分离株聚为另一簇。将所获16个CLBV全长cDNA克隆转化农杆菌，以pCY空载体为阴性对照注射接种本生烟。接种20 d后，抽提RNA进行RT-PCR检测，结果表明11个克隆的接种植株检测出CLBV特异性条带；随机选取5个阳性克隆进一步进行了Northern blot杂交，结果显示pCY-CLBV 1、2、3、14、15接种的本生烟可以检测到CLBV特异性条带，而对照样本未检测到任何条带，表明这些克隆均为侵染性克隆。【结论】构建了基于三元穿梭载体pCY的酵母重组克隆体系，利用该体系获得了中国CLBV分离株的适于农杆菌介导接种的基因组全长cDNA侵染性克隆。

关键词: 酵母同源重组, 柑橘叶斑驳病毒, 三元穿梭载体, 侵染性克隆

Abstract: 【Objective】 The objective of this study is to construct infectious cDNA clone of Citrus leaf blotch virus (CLBV) isolated from China and lay a foundation for studies on the pathogenesis of CLBV at the molecular level.【Method】Using GeneArt® pYES1L Vector as a template, a 2.1-kb fragment containing the yeast replication origin and Trp-1 gene were amplified by primer pair PYES2117F/PYES2117R. Plasmid of a binary vector DK1317-2 was digested with Sac II. The amplified and digested productions containing expected fragments were then purified with the Gel Extraction Kit and subjected to In-Fusion cloning. In this way a ternary shuttle vector pCY was obtained. Using Potato virus X (PVX) infectious clones as a template, pCY-PVX-F and pCY-PVX-R as primers, the full length cDNA of PVX genome was amplified. Plasmid pCY was digested with restriction endonuclease Stu I and Sma I. The fragment and the linearized vector obtained above were co-transformed into yeast YPH501 by lithium acetate conversion method, and the full-length cDNA clone of PVX genome was obtained by homologous recombination. The infectivity of the resulting constructs was verified by Agrobacterium tumefaciens mediated inoculation on N. benthamiana, and a rapid cloning system based on homologous recombination in yeast cell was established for construction of viral infectious clone. On this basis, two fragments covering the full-length genome of CLBV-HBYD were amplified, and CLBV-1 and CLBV-2 were obtained. The homologous recombination was then performed to assemble CLBV-1, CLBV-2 and pCY vector fragments using the cloning system established. Then, N. benthamiana and Jincheng (C. sinensis) was inoculated with A. tumefaciens carrying the recombinant plasmid pCY-CLBV. RT-PCR and Northern blot were used to detect the inoculated seedlings.【Result】A ternary yeast-E. coli-A. tumefaciens shuttle vector, pCY, was constructed based on DK1317-2 and pYES1L. The vector is 10 347 bp in length and contains the replication elements of three bacteria, and can be stably replicated in yeast, A. tumefaciens, and E. coli. Using this vector, 16 full-length cDNA clones of CLBV-HBYD genome were obtained through homologous recombination in yeast cell. One clone was randomly selected and sequenced (GenBank: MG572236). Sequence analysis showed that CLBV-HBYD is 8 747 nt in length and encodes 3 open reading frames (ORF). ORF1, ORF2 and ORF3 is 5 889, 1 089 and 1 092 nt, respectively. The nucleotide sequence identity between CLBV-HBYD and 9 isolates of CLBV ranged 79%-98%, in which the highest identity was 98% with EU857540 isolate from citrus, while only 79% was seen when compared with kiwifruit isolates JN983454, JN983455, JN983456 and JN900477. In the phylogenetic tree generated by MEGA 6 software, CLBV-HBYD clustered with other citrus isolates into the same cluster. Sixteen CLBV full-length cDNA clones were inoculated on N. benthamiana and Jincheng by A. tumefaciens mediated inoculation, and pCY empty vector was used as a negative control. After 20 days of inoculation, RNA was extracted for RT-PCR detection. The results showed that CLBV specific genes were detected in plants inoculated with 11 full-length cDNA clones of CLBV-HBYD, respectively. Five set of RT-PCR positive plants were randomly selected for further Northern blot. The results showed that specific bands of CLBV were detected by Northern blot in plants inoculated with pCY-CLBV 1, 2, 3, 14, 15, whereas no gene was detected in the control samples, indicating that these clones were infectious clones.【Conclusion】A rapid cloning system based on a ternary yeast-E. coli-A. tumefaciens shuttle vector pCY and homologous recombination in yeast was constructed, and an infectious cDNA clone of Chinese isolate of CLBV was developed for the first time.

Key words: yeast homologous recombination, Citrus leaf blotch virus (CLBV), ternary shuttle vector, infectious clone

崔甜甜，晏建红，宾羽，李中安，周常勇，宋震. 利用酵母同源重组系统快速构建柑橘叶斑驳病毒的侵染性克隆[J]. 中国农业科学, 2018, 51(9): 1695-1705.

CUI TianTian, YAN JianHong, BIN Yu, LI ZhongAn, ZHOU ChangYong, SONG Zhen. Construction of Citrus leaf blotch virus Infectious cDNA Clone by Yeast Homologous Recombination System[J]. Scientia Agricultura Sinica, 2018, 51(9): 1695-1705.

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