基于Real-time PCR监测番茄黄化曲叶病毒在番茄植株中的动态变化

 本研究根据番茄黄化曲叶病毒(Tomato yellow leaf curl virus, TYLCV)分离物-SH2基因组序列,设计了一对引物,以番茄25S rRNA基因为内参,建立了番茄黄化曲叶病毒SYBR GreenⅠ实时荧光定量PCR检测方法。该方法可检测到浓度为4.64×10^-7 ng/μL的植物DNA中含有TYLCV,其灵敏度是常规PCR的1 000倍。利用该方法,研究了温室条件下以侵染性克隆接种TYLCV后的番茄植株中病毒DNA含量的变化情况。根、茎、叶中病毒DNA定量检测结果表明,TYLCV在3种植物器官中都呈现一个上升、稳定和下降的变化规律;病毒DNA在植株根部最早累积,累积的速度较慢,在叶部和茎部累积较快;叶部和茎部接种18 d后病毒DNA含量达到稳定期;在不同的器官中,病毒的含量不同,在茎部的含量最高,接种33 d后茎部病毒DNA的含量约为根部的100倍。本研究通过对TYLCV含量的动态监测,明确了病毒DNA在番茄植株中的累积和变化规律,为研究TYLCV侵染机制、病毒与寄主互作及病害防治提供了理论依据。     

广东省番茄黄化曲叶病毒的分子鉴定及序列分析

番茄黄化曲叶病毒病是世界番茄生产上一种毁灭性病害,番茄黄化曲叶病毒Tomato yellow leaf curl virus(TYLCV)是引起该病害的主要病原病毒之一。本文采用滚环扩增及基因克隆方法,获得了侵染广东佛山和肇庆番茄的TYLCV 4个分离物全基因组;它们均为2 781 nt,编码6个ORF,其中病毒链上编码AV1和AV2,互补链上编码AC1、AC2、AC3和AC4。同源性比较结果表明,4个广东分离物基因组序列两两间同源性为99%以上;与已报道的TYLCV各分离物同源性在90%以上,而与来自中国不同地区的TYLCV分离物的同源率均在98%以上。系统进化分析显示,广东分离物与来自中国不同地区的TYLCV分离物亲缘关系较近,并聚类在一个分支。因此,侵染引起广东佛山和肇庆番茄黄化曲叶病的病毒应来自国内其他地区。本研究是对TYLCV广东分离物分子特征的首次报道。     

番茄黄化曲叶病毒在湖北首次报道

2014年春季,在湖北省武汉市发现种植的番茄表现植株矮缩,叶片上卷,叶缘黄化等症状。PCR检测结果显示,所有采集的病样中均存在菜豆金色花叶病毒属病毒。进一步通过滚环扩增方法获得了该病毒的湖北分离物HB01的全基因组。基因克隆及序列分析结果表明,该病毒基因组全长为2 781nt,与已报道的番茄黄化曲叶病毒(TYLCV)各分离物同源性在89.0%以上,而与来自中国不同地区的TYLCV分离物的同源率均在97.0%以上。因此,HB01属于TYLCV的一个分离物。     

南疆温室番茄黄化曲叶病病毒种类的分子鉴定

为明确南疆温室番茄黄化曲叶病的病毒种类,利用双生病毒的兼并引物通过PCR扩增,对采集的20个番茄病株进行了分子检测.从20个病株中均扩增到约500 bp的目标片段,对其中4株进行克隆和测序,其相互间序列同源性为97.1％ ～99.3％,与番茄黄化曲叶病毒(Tomato yellow leaf curl virus,TYLCV)的同源性较高,为98.6％ ～ 99.5％.随机选取莎车分离物KS2-5进行全基因组的克隆和测序,KS2-5 DNA全长为2781 nt(序列号:JQ807735),具有典型的双生病毒基因组特征,与TYLCV其它分离物同源性达到98.9％～99.5％,而与其它粉虱传双生病毒的序列同源性较低,为68.3％ ～75.5％,表明危害南疆温室番茄的病毒种类为番茄黄化曲叶病毒TYLCV.     

吉林番茄黄化曲叶病毒分离物的检测及其DNA-A全基因组序列分析

从吉林省松原市田间表现黄化曲叶症状的番茄上分离到病毒分离物JLSY,基因组全序列测定结果表明,基因组全长2781 bp,共编码6个ORF。序列比对表明,JLSY基因组与番茄黄化曲叶病毒（TYLCV）安徽分离物（FN650807）相似性最高,为99.5%,而与其他双生病毒的序列相似性低于89%。经系统进化分析,该病毒分离物属于TYLCV以色列株系（TYLCV-IL）。这是首次在我国吉林省检测到番茄黄化曲叶病毒。     

陕西省番茄黄化曲叶病毒基因间隔区缺失突变体的鉴定与不同分离物间群体进化研究

为明确番茄黄化曲叶病毒(tomato yellow leaf curl virus, TYLCV)基因组的变异情况, 分别从陕西省杨凌区?泾阳县?大荔县和阎良区采集了表现为番茄黄化曲叶病症状的抗病品种番茄样品20份以及感病品种番茄样品4份?经TYLCV特异性引物检测, 24个样品均为阳性?通过全长扩增测序获得了15个TYLCV分离物的基因组序列?序列分析显示, 其中7个分离物基因组大小为正常的2 781 bp, 而有8个TYLCV分离物基因组大小为2 768 bp?与正常基因组相比, 这8个分离物在基因间隔区(intergenic region, IR)的TATA-box与保守9核苷酸序列之间发生了13个核苷酸的缺失?对我国不同地区TYLCV分离物全基因组序列进行变异分析, 发现IR区域是发生核苷酸变异最大的区域?系统进化分析表明, 本研究分离到的15个TYLCV分离物均属于TYLCV-Israel进化分支下的中国亚群, 其中8个TYLCV IR缺失突变体与国内已报道的IR缺失突变体BJ04和BJ06亲缘关系较远, 而与本研究中分离得到的正常TYLCV分离物亲缘关系最近, 疑似为陕西地区出现的一类新TYLCV IR缺失突变体?本研究首次对我国不同地区多个TYLCV分离物出现IR区缺失现象进行了报道?     

南瓜蚜传黄化病毒甜瓜分离物的侵染性克隆构建

 南瓜蚜传黄化病毒(cucurbit aphid-borne yellows virus,CABYV)近年来发生普遍,严重威胁甜瓜的生产。前期构建了一个CABYV丝瓜分离物(CABYV-QY)的侵染性克隆,但其在甜瓜中的侵染率偏低,不宜用于甜瓜接种。本研究以CABYV甜瓜分离物CABYV-WS为研究对象,通过RT-PCR扩增、拼接获得全基因组序列,通过构建全长基因组cDNA克隆,分析其侵染性。结果显示,该分离物基因组全长为5682 nt,与CABYV-QY(MT943520)的核苷酸序列一致性为88.61%~100.00%,氨基酸为84.94%~100.00%。将cDNA克隆接种分析,发现所用的8个甜瓜品种均能被系统侵染并引起典型的黄化症状,侵染率为70%~100%。其中,甜瓜品种‘新密杂11号’和‘新密25号’感病性较强,接种CABYV后发病周期短且侵染率可达100%。CABYV侵染性克隆的成功构建有助于该病毒的分子致病性和寄主的抗病性等研究。     

侵染扶桑和棉花的木尔坦棉花曲叶病毒侵染性克隆构建及致病性测定

从广东广州扶桑和广西南宁棉花中分离得到木尔坦棉花曲叶病毒(Cotton leaf curl Multan virus,CLCuMV)的2个分离物GD37和GX01,序列分析表明两分离物的基因组全序列同源性为99.4%,卫星分子序列同源性为99.2%。构建了GD37和GX01的侵染性克隆,农杆菌接种表明CLCuMV GD37能侵染本氏烟、心叶烟、三生烟、普通烟,GD37和GD37β共同接种产生叶片下卷、植株矮化等症状,但不能侵染棉花、番茄、矮牵牛;而分离自棉花的CLCuMV GX01能够侵染本氏烟,GX01和GX01β共同接种在本氏烟上产生叶片下卷皱缩等症状,但不能侵染棉花。Southern-blot结果表明在GD37单独侵染或与GD37β共同侵染的植株中均能检测到相应DNA分子的积累。     

北京地区番茄黄化曲叶病病毒分离物测定及株系的初步鉴定

 番茄黄化曲叶病毒病是番茄生产中的一种毁灭性病毒病害,2009年传入北京。利用烟粉虱传双生病毒简并引物PA/PB对2010年~2011年采集自北京市5个区县的53个番茄样品进行检测,30个表现典型黄化曲叶病症状的样品均扩增得到约500 bp的特异条带,测定了其中7个样品的部分序列,经序列比对分析表明其为番茄黄化曲叶病毒（Tomato yellow leaf curl virus, TYLCV）。利用TYLCV特异引物TJ-F/TJ-R、TY-F/TY-R对样品BJDXXY、BJFS02、BJFS03、BJMY2231进行TYLCV基因组克隆和序列测定,经分析4个样品携带的TYLCV基因组长度均为2 781碱基,编码6个蛋白。基因组序列比较发现,这4个分离物与TYLCV-Israel株系同源性达到98%以上;通过建立系统发育树,发现BJDXXY、BJFS02、BJFS03与河北分离物（HBLF4）、山东分离物（SDSG）亲缘关系较近,BJMY2231与上海分离物（TYLCV-Israel）、江苏分离物（JSNJ1）亲缘关系较近。     

Tomato leaf curl Guangxi virus is a distinct monopartite begomovirus species

Three begomovirus isolates were obtained from tomato plants showing leaf curl symptoms in Guangxi province of China. Typical begomovirus DNA components representing the three isolates (GX-1, GX-2 and GX-3) were cloned and their full-length sequences were determined to be 2752 nucleotides. Nucleotide identities among the three viral sequences were 98.9–99.7%, but all shared <86.7% nucleotide sequence identity with other reported begomoviruses. The sequence data indicated that GX-1, GX-2 and GX-3 are isolates of a distinct begomovirus species for which the name Tomato leaf curl Guangxi virus (ToLCGXV) is proposed. Further analysis indicated that ToLCGXV probably originated through recombination among viruses related to Ageratum yellow vein virus, Tomato leaf curl China virus and Euphorbia leaf curl virus. PCR and Southern blot analyses demonstrated that isolates GX-1 and GX-2 were associated with DNAβ components, but not isolate GX-3. Sequence comparisons revealed that GX-1 and GX-2 DNAβ components shared the highest sequence identity (86.2%) with that of Tomato yellow leaf curl China virus (TYLCCNV). An infectious construct of ToLCGXV isolate GX-1 (ToLCGXV-GX) was produced and determined to be highly infectious in Nicotiana benthamiana, N. glutinosa, tobacco cvs. Samsun and Xanthi, tomato and Petunia hybrida plants inducing leaf curl and stunting symptoms. Co-inoculation of tomato plants with ToLCGXV-GX and TYLCCNV DNAβ resulted in disease symptoms similar to that caused by ToLCGXV-GX alone or that observed in infected field tomato plants.     

侵染甜椒的番茄黄化曲叶病毒的分子鉴定和全序列分析

<正>番茄黄化曲叶病毒(Tomato yellow leaf curl virus,TYLCV)在世界范围内可危害多种作物,造成植株矮化、叶片皱缩变形、局部黄化等症状。该病毒自1964年首次报道以来已蔓延至世界多地。在我国2006年上海首次报道该病毒[1],随后江苏、山东、安徽、北京、河北、天津等地相继报道,危害严重。TYLCV为双生病毒科(Geminiviridae)菜豆金色花叶病毒属(Begomovirus)成员,基因组为单组     

四川省红叶石楠炭疽病病原菌鉴定及其潜在侵染源测定

为明确引起四川省红叶石楠炭疽病的病原菌及其潜在侵染源,采集疑似感染炭疽病的典型病叶进行分离获得纯化病原菌菌株,从中随机选取菌株HYSN3制成分生孢子悬浮液和菌饼,以无伤、刺伤、剪伤3种方式进行接种,筛选出效果最好的接种方式进行致病性测定,结合形态学特征与多基因序列分析将病原菌鉴定到种,并采用筛选出的接种方式将分离自其它19种寄主的23株炭疽菌接种到红叶石楠上,明确其潜在侵染源。结果表明,从红叶石楠病叶中共纯化得到14株菌株,基于形态特征和显微初步鉴定结果,从中选择8株代表菌株进行进一步鉴定。3种接种方式中,以刺伤后接种菌株HYSN3菌饼的效果最好,可用于致病性测定。基于形态学特征、致病性测定和多基因序列分析结果,将病原菌鉴定为胶孢炭疽菌Colletotrichum gloeosporioides(5株)、喀斯特炭疽菌C.karstii(1株)和暹罗炭疽菌C. siamense(2株),表明四川省红叶石楠炭疽病是由多种病原菌复合侵染引起的。来自其它寄主的23株炭疽菌菌株都能侵染红叶石楠,但致病力强弱不同,附近受炭疽菌侵染的植物都有可能成为红叶石楠炭疽病的潜在侵染源,园林植物养护过程中需予以一定的重视。     

Cloning of DNA fragments specific to the pathotype and race of <Emphasis Type="Italic">Verticillium dahliae</Emphasis>

Japanese isolates of Verticillium dahliae, a causal agent of wilt disease in many plants, are classifiable into pathotypes based on their pathogenicity. Because these pathotypes are morphologically indistinguishable, establishing a rapid identification method is very important for the control of this pathogen in Japan. For cloning DNA fragments that are useful for identification and specific detection of V. dahliae pathotypes, we performed random amplified polymorphic DNA (RAPD) analyses using various isolates. One polymerase chain reaction (PCR) product, E10-U48, was specific to isolates pathogenic to sweet pepper. The other product, B68-TV, was specific to race 1 of isolates pathogenic to tomato. The specificity of these sequences was confirmed by genomic Southern hybridization. Further analyses revealed that the region peripheral to B68-TV obtained from the genomic DNA library includes the sequence specific to all isolates pathogenic to tomato (races 1 and 2). Moreover, sequence tagged site (STS) primers designed from B68-TV and its peripheral region showed race-specific and pathotype-specific amplification in a PCR assay. The probes and primers obtained in this study are likely to be useful tools for the identification and specific detection of pathotypes and races of V. dahliae. The nucleotide sequence data reported are available in the DDBJ/EMBL/GenBank databases under accession number AB095266.     

The first report of tomato foot rot caused by <Emphasis Type="Italic">Rhizoctonia solani</Emphasis> AG-3 PT and AG-2-Nt and its host range and molecular characterization

Foot rot of mature tomato plants was found in four cities of Hokkaido, Japan, from 2004 to 2007. Six of eight isolates obtained from damaged tissues were identified as Rhizoctonia solani anastomosis group (AG)-3, and the remaining two isolates belonged to AG-2-1. We compared these isolates with nine reference isolates including the different subgroups in AG-3 (PT, TB and TM) and AG-2-Nt (pathogen of tobacco leaf spot) within AG-2-1 in terms of pathogenicity to tomato, tobacco and potato. All eight isolates caused foot rot on tomato. The six AG-3 isolates caused stem rot on young potato plants. While, all reference isolates of AG-3 PT causing stem rot of young potato plants incited foot rot on tomato. The two AG-2-1 isolates and an AG-2-Nt reference isolate caused severe leaf spot on tobacco leaves. The sequences of rDNA- ITS region and rDNA-IGS1 region of the AG-3 isolates showed high similarity to that of AG-3 PT isolates. Phylogenetic tree based on ITS and IGS1 regions of rDNA indicated that the AG-2-1 isolates from tomato formed a single clade with AG-2-Nt isolates and that they were separate from Japanese AG-2-1 isolates (culture type II). Pathogenicity tests and DNA sequence evaluation of the causal fungi revealed that the present isolates of AG-3 and AG-2-1 belonged to AG-3 PT and AG-2-Nt, respectively. This is the first report of tomato foot rot caused by R. solani in Japan.     

Characterization of Passionfruit severe leaf distortion virus,a novel begomovirus infecting passionfruit in Brazil,reveals a close relationship with tomato‐infecting begomoviruses

Molecular and biological characterization of the begomovirus isolate BR:LNS2:Pas:01, obtained from yellow passionfruit plants in Livramento de Nossa Senhora, Bahia state, Brazil, was carried out. Sequence analysis demonstrated that the BR:LNS2:Pas:01 DNA‐A had highest nucleotide sequence identity with Tomato chlorotic mottle virus (77%) and had five ORFs corresponding to the genes cp, rep, trap, ren and ac4. The DNA‐B had highest nucleotide sequence identity with Tomato yellow spot virus (74%) and two ORFs corresponding to the genes mp and nsp. These identity values indicate that this isolate represents a new begomovirus species, for which the name Passionfruit severe leaf distortion virus (PSLDV), is proposed. Phylogenetic analysis clustered the PSLDV DNA‐A and ‐B in a monophyletic branch with Brazilian tomato‐infecting begomoviruses. The isolate’s host range was restricted to species from the Passifloraceae and Solanaceae. PSLDV‐[BR:LNS2:Pas:01] was capable of forming pseudorecombinants with tomato‐infecting begomoviruses, reinforcing its close relationship with these viruses and suggesting a possible common origin. However, the virus was not capable of infecting tomato.     

Arabidopsis thaliana,an experimental host for tomato yellow leaf curl disease‐associated begomoviruses by agroinoculation and whitefly transmission

Tomato yellow leaf curl disease is one of the most devastating viral diseases affecting tomato crops worldwide. This disease is caused by several begomoviruses (genus Begomovirus, family Geminiviridae), such as Tomato yellow leaf curl virus (TYLCV), that are transmitted in nature by the whitefly vector Bemisia tabaci. An efficient control of this vector‐transmitted disease requires a thorough knowledge of the plant–virus–vector triple interaction. The possibility of using Arabidopsis thaliana as an experimental host would provide the opportunity to use a wide variety of genetic resources and tools to understand interactions that are not feasible in agronomically important hosts. In this study, it is demonstrated that isolates of two strains (Israel, IL and Mild, Mld) of TYLCV can replicate and systemically infect A. thaliana ecotype Columbia plants either by Agrobacterium tumefaciens‐mediated inoculation or through the natural vector Bemisia tabaci. The virus can also be acquired from A. thaliana‐infected plants by B. tabaci and transmitted to either A. thaliana or tomato plants. Therefore, A. thaliana is a suitable host for TYLCV–insect vector–plant host interaction studies. Interestingly, an isolate of the Spain (ES) strain of a related begomovirus, Tomato yellow leaf curl Sardinia virus (TYLCSV‐ES), is unable to infect this ecotype of A. thaliana efficiently. Using infectious chimeric viral clones between TYLCV‐Mld and TYLCSV‐ES, candidate viral factors involved in an efficient infection of A. thaliana were identified.