黄瓜资源对黄瓜绿斑驳病毒广东分离物的抗性水平鉴定

【背景】黄瓜绿斑驳花叶病毒(Cucumber green mottle mosaic virus,CGMMV)是严重威胁葫芦科作物生产的毁灭性病原之一,该病毒已入侵我国十多个省份,危害西瓜、黄瓜等作物并造成严重的经济损失。早在2009年广东即发现CGMMV为害西瓜和黄瓜,但黄瓜等葫芦科作物对其抗性情况尚不清楚。【方法】采用人工机械摩擦接种方法,测定了14份黄瓜种质资源对CGMMV广东分离物的抗性水平。【结果】从广东葫芦病样中分离获得CGMMV,该病毒分离物MP基因序列与国内报道的各分离物同源率均在99%以上;14份黄瓜种质资源对该病毒分离物均表现为感病。【结论与意义】广东主要黄瓜资源对CGMMV均表现为感病,这为我省防控该病毒病提供了科学依据,也为黄瓜抗病育种提供了指导。     

黄瓜绿斑驳花叶病毒辽宁分离物全基因组序列测定

以感病组织总RNA为模板,采用RT-PCR方法扩增并测定黄瓜绿斑驳花叶病毒(Cucumber green mottle mosaic virus,CGMMV)辽宁分离物(CGMMV-LN)的基因组全序列。CGMMV-LN基因组全长6 422 nt,5'非编码区(noncoding region,NCR)和3'NCR分别为59 nt和175 nt。CGMMV-LN编码的4个蛋白依次是186 kD和129kD的复制酶,29 kD的移动蛋白和17.4 kD的外壳蛋白。CGMMV-LN与其他4个CGMMV分离物基因组核苷酸序列同源性为97.6%～99.3%,与同属其他3种病毒基因组核苷酸序列同源性仅为61.7%～62.8%。基于186kD复制酶和外壳蛋白氨基酸序列的同源树显示:侵染葫芦科作物的烟草花叶病毒属病毒可分为2个亚组,亚组I包括所有CGMMV分离物,亚组II包括Kyuri绿斑驳花叶病毒(Kyuri green mottle mosaic virus,KGMMV)、黄瓜果实斑驳花叶病毒(Cucumber fruit mottle mosaic virus,CFMMV)和小西葫芦绿斑驳花叶病毒(Zucchini ...     

Transmission Efficiency of Cucumber green mottle mosaic virus via Seeds,Soil, Pruning and Irrigation Water

Cucumber green mottle mosaic virus (CGMMV; genus Tobamovirus) infects frequently the grafted watermelon and is widely distributed in China. Investigating the transmission modes and their efficiency is urgently needed to understand the factors contributing to the epidemiology of this viral disease. In the present study, we found that the occurrence of CGMMV in a bottle gourd seed production base reached 100%, while the contamination rate and transmission rate were 100 and 0.92%, respectively. The bottle gourd plants showed obvious mottle symptom on leaves starting 36 days after seed sowing. The long latent period of CGMMV in seedlings implies a potential risk to use contaminated seeds in the production of grafted watermelon. This virus could overwinter in soil with debris of infected plants, and the infection rate of CGMMV from contaminated soils was 10.30%. CGMMV could be transmitted from infected watermelon plants to healthy ones by pruning at least to the ninth plant during the whole growing season. The transmission distance was 1.87 m by drip irrigation and 2.31 m by flow irrigation. This study suggested that contaminated seeds, contaminated soil, pruning and irrigation could transmit CGMMV at different efficiency, and all contribute to the epidemiology of CGMMV.     

Transgenic watermelon rootstock resistant to CGMMV (cucumber green mottle mosaic virus) infection

In watermelon, grafting of seedlings to rootstocks is necessary because watermelon roots are less viable than the rootstock. Moreover, commercially important watermelon varieties require disease-resistant rootstocks to reduce total watermelon yield losses due to infection with viruses such as cucumber green mottle mosaic virus (CGMMV). Therefore, we undertook to develop a CGMMV-resistant watermelon rootstock using a cDNA encoding the CGMMV coat protein gene (CGMMV-CP), and successfully transformed a watermelon rootstock named gongdae. The transformation rate was as low as 0.1–0.3%, depending on the transformation method used (ordinary co-culture vs injection, respectively). However, watermelon transformation was reproducibly and reliably achieved using these two methods. Southern blot analysis confirmed that the CGMMV-CP gene was inserted into different locations in the genome either singly or multiple copies. Resistance testing against CGMMV showed that 10 plants among 140 T₁ plants were resistant to CGMMV infection. This is the first report of the development by genetic engineering of watermelons resistant to CGMMV infection.     

Nucleotide sequences of two Korean isolates of Cucumber green mottle mosaic virus

The nucleotide sequences of the genomic RNAs of Cucumber green mottle mosaic virus Korean watermelon isolate (CGMMV-KW) and Korean oriental melon isolate (CGMMV-KOM) were determined and compared to the sequences of other tobamoviruses including CGMMV strains W and SH. Each CGMMV isolate had a genome of 6,424 nucleotides. Each also had 60 and 176 nucleotides of 5' and 3' untranslated regions (UTRs), respectively, and four open reading frames (ORF1-4). ORFs 1 to 4 encode proteins of 129, 186, 29, and 17.4 kDa, respectively. The nucleotide and deduced amino acid sequences of CGMMV-KOM and CGMMV-KW were more than 98.3% identical. When compared to other CGMMV strains in a phylogenetic analysis they were found to form a distinct virus clade, and were more distantly related to other tobamoviruses (23.5-56.7% identity).     

Transgenic <Emphasis Type="Italic">Nicotiana benthamiana</Emphasis> plants resistant to cucumber green mottle mosaic virus based on RNA silencing

RNA silencing technology was used to confer resistance to cucumber green mottle mosaic virus (CGMMV). Nicotiana benthamiana was transformed with a transgene designed to produce an inverted repeat RNA containing CGMMV-coat protein gene (CP) sequences, which were separated by an intron sequence, under the control of the cauliflower mosaic virus 35S promoter. We attempted to confirm the resistance of seven independent transgenic lines; five lines showed resistance to CGMMV infection. The systemic spread of virus was prevented after the inoculation of CGMMV, and the CP-specific short interfering RNA (siRNA) was detected in resistant lines. Thus, the resistance against CGMMV through RNA silencing is strong and efficient.     

Argonaute 1 and 5 proteins play crucial roles in the defence against cucumber green mottle mosaic virus in watermelon

RNA silencing, a core part of plants' antiviral defence, requires the ARGONAUTE, DICER-like, and RNA-dependent RNA polymerase proteins. However, how these proteins contribute to watermelon's RNA interference (RNAi) pathway response to cucumber green mottle mosaic virus (CGMMV) has not been characterized. Here, we identify seven ClAGO, four ClDCL, and 11 ClRDR genes in watermelon and analyse their expression profiles when infected with CGMMV. ClAGO1 and ClAGO5 expression levels were highly induced by CGMMV infection. The results of ClAGO1 and ClAGO5 overexpression and silencing experiments suggest that these genes play central roles in watermelon's antiviral defence. Furthermore, co-immunoprecipitation and bimolecular fluorescence complementation experiments showed that ClAGO1 interacts with ClAGO5 in vivo, suggesting that ClAGO1 and ClAGO5 co-regulate watermelon defence against CGMMV infection. We also identified the ethylene response factor (ERF) binding site in the promoters of the ClAGO1 and ClAGO5 genes, and ethylene (ETH) treatment significantly increased ClAGO5 expression. Two ERF genes (Cla97C08G147180 and Cla97C06G122830) closely related to ClAGO5 expression were identified using co-expression analysis. Subcellular localization revealed that two ERFs and ClAGO5 predominantly localize at the nucleus, suggesting that enhancement of resistance to CGMMV by ETH is probably achieved through ClAGO5 but not ClAGO1. Our findings reveal aspects of the mechanisms underlying RNA silencing in watermelon against CGMMV.     

Structural analysis of the coat protein of cucumber green mottle mosaic virus

Using reversed-phase high-performance liquid chromatography, two components of the coat protein of isolate No. 3 of the cucumber green mottle mosaic virus (CGMMV, cucumber strain), Cp1 (minor) and Cp2 (major), were isolated and characterized by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOFMS). In the Cp2 mass spectrum, two polypeptides with Mr of 16,727.0 and 16,813.5 were detected. By Edman degradation in combination with mass spectrometry, the primary structure of the tryptic peptides of Cp2 comprising in total 150 amino acid residues was determined. Two amino acid substitutions, Val-56-->Ala-56 and Asp-64-->Ser-64, were revealed in Cp2, as compared to the watermelon strain of the virus. Cp1 was shown to consist of three polypeptides with Mr of 10,014.2, 10,224.9, and 10,355.9 corresponding to the N-terminal regions of Cp2 (positions 1-92, 1-94, and 1-95). The observed heterogeneity of the coat protein of CGMMV, cucumber strain, may be due to proteolysis during protein isolation.     

Epidemiological study of Cucumber green mottle mosaic virus in greenhouses enables reduction of disease damage in cucurbit production

Since 2007, the tobamovirus Cucumber green mottle mosaic virus (CGMMV) has become widespread in Israel, causing severe damage to trellised cucumber and melon in greenhouses and watermelon grown in open fields. To reduce disease damage below the economic threshold, this study focused on four objectives: (a) monitoring the patterns of virus distribution within commercial cucumber greenhouses; (b) studying the potential transmission of CGMMV by agrotechnical activities; (c) virus localization in plant tissues; and (d) searching for techniques that might be adapted for mitigating the disease in trellised cucurbit growth. The results of our surveys demonstrated the role of contaminated seeds and soil as primary inoculum sources, and secondary spread caused by agrotechnical activities. The patterns of secondary disease spread were demonstrated in a series of inoculation experiments involving contaminated knives, shears or hands on wet and dry plants, conducted under research‐greenhouse conditions. In parallel experiments using CGMMV‐specific antibody and secondary antibody conjugated to Alexa fluor 488, the viral coat protein was visualized in several plant tissues: phloem, xylem, trichomes and grasping tendrils. In addition, commercial‐greenhouse experiments were aimed at reducing the number of inoculum sources by identifying and removing infected plants from the plots (early monitoring) prior to agrotechnical activities and/or by adding intermediate medium (IM), such as virus‐free compost, to the planting pits at the planting stage. It is suggested that the use of IM combined with early monitoring, awareness of worker mobility (from contaminated structures to young planting areas) and proper sanitation (e.g. disinfection of agrotechnical tools) may reduce the yield losses caused by CGMMV below the economic threshold.     

广西黄瓜绿斑驳花叶病毒（CGMMV）黄瓜分离物的RT—PCR检测及CP基因序列分析

利用黄瓜绿斑驳花叶病毒（Cucumber Green Mottle Mosaic Virus,CGMMV）的特异性引物对来自广西一温室栽培的黄瓜病样进行RT—PCR检测,结果扩增得到了与预期大小相符的目的片段（650bp）。序列分析表明,该目的片段包含有CGMMV完整的CP基因序列、部分运动蛋白基因（MP）及3’端非编码区（3＇-UTR）序列,其中CP基因全长486bp,与已报道的CP基因序列同源性为91．2％～99．4％。经系统发育分析,明确该GX-CS分离物与日本、法国、印度等分离物属于CGMMV同一类群,并推测该分离物与广西的葫芦（GX—BG）分离物具有相同的起源关系。     

西瓜花叶病毒中国分离株全基因组核苷酸序列测定

西瓜花叶病毒(Watermelon mosaic virus,WMV)是马铃薯Y病毒属(Potyvirus)成员,主要危害西瓜和甜瓜,引起花叶病。在田间,该病害主要由蚜虫以非持久性方式传播。西瓜和甜瓜花叶病在国内陕西、山东、云南、辽宁、山西、新疆、河南和黑龙江等地广泛发生[1-6]。从20世纪80年代中期开始发生,逐渐上升为普遍发生的主要病害。我国大部分地区因西瓜和甜瓜病毒病造成的损失为30%~50%,甚至会绝产,西瓜花叶病毒已经成为制约西瓜和甜瓜高产稳产最主要的因素之一[7]。到目前为止,多数工作集中在对西瓜和甜瓜病毒病的鉴定,在分子生物学上仅限于对CP基因…     

Detection of gene flow from GM to non-GM watermelon in a field trial

Gene flow from genetically modified (GM) crops to conventional non-GM crops is a serious concern for protection of conventional and organic farming. Gene flow from GM watermelon developed for rootstock use, containing cucumber green mottle mosaic virus (CGMMV)-coat protein (CP) gene, to a non-GM isogenic control variety “Clhalteok” and grafted watermelon “Keumcheon” was investigated in a small scale field trial as a pilot study. Hybrids between GM and non-GM watermelons were screened from 1304 “Chalteok” seeds and 856 “Keumcheon” seeds using the duplex PCR method targeting theCGMMV- CP gene as a marker. Hybrids were found in all pollen recipient plots. The gene flow frequencies were greater for “Chaiteok” than for “KeumcheonD; with 75% outcrossing in the “Chaiteok” plot at the closest distance (0.8 m) to the GM plot. A much larger scale field trial is necessary to identify the isolation distance between GM and non-GM watermelon, as the behaviors of insect pollinators needs to be clarified in Korea.     

Genetic diversity of cucumber green mottle mosaic virus (CGMMV) infecting cucurbits

Cucumber green mottle mosaic virus (CGMMV), a well-known Tobamovirus, infects cucurbits across the globe. To determine its current status, molecular characterization, genetic recombination, gene flow and selection pressure, 10 districts from Punjab province of Pakistan were surveyed and a total of 2561 cucurbits samples were collected during 2019–2020. These samples were subjected to virus-specific double antibody sandwich-enzyme linked immunosorbent assay (DAS-ELISA) for the detection of CGMMV. The results revealed that viral disease was prevalent in all surveyed districts of Punjab with an overall 25.69% disease incidence. ELISA positive samples were further confirmed through RT-PCR and sequencing of coat protein (CP) cistron. Sequence analysis showed that the present studied CGMMV isolates have 96–99.5% nucleotide and 94.40–99.50% amino acid identities with those already available in GenBank. Phylogenetic analysis also revealed that understudied isolates were closely related with South Korean (AB369274) and Japanese (V01551) isolates and clustered in a separate clad. Sequence polymorphisms were observed in 663 bp of sequence within 31 CGMMV isolates covering complete CP gene. Total number of sites were 662, of which 610 and 52 sites were monomorphic and polymorphic (segregating), respectively. Of these polymorphic, 24 were singleton variable and 28 were parsimony informative. Overall nucleotide diversity (π) in all the understudied 31 isolates was 0.00010 while a total of 1 InDel event was observed and InDel Diversity (k) was 0.065. Haplotype diversity analysis revealed that there was a total 29 haplotypes with haplotype diversity (Hd) of 0.993458 in all the 31 isolates which provide evidence of less diversity among Pakistani isolates. The statistical analysis revealed the values 2.568, 5.31304 and 4.86698 of Tajima's D, Fu, & Li’s F* and D*, respectively, which witnessed the population of CGMMV was under balanced selection pressure.