我国不同CMV分离物2b基因片段的RT-PCR扩增及其序列比较

 本研究根据黄瓜花叶病毒2b基因的保守序列设计引物,利用一步RT-PCR技术对多个不同寄主和不同地理来源的黄瓜花叶病毒分离物的2b基因片段进行扩增,获得了含该基因全长约90%的cDNA片段(300bp)。序列测定与比较分析结果表明,国内不同CMV分离物2b基因片段核酸序列同源性达93%以上,推测的氨基酸序列同源性超过90%,且均属于亚组Ⅰ。     

白术矮化病毒病病原的分子鉴定和部分序列分析

 本试验在生物学接种的基础上,利用非序列依赖性PCR扩增(sequence-independent amplification,SIA)对白术矮化病毒病病原进行了分子鉴定,序列测定及分析。结果发现,具有矮化症状的白术为黄瓜花叶病毒(Cucumber mosaic virus,CMV)所侵染。为明确CMV白术分离物(CMV-Am)的分类地位,本研究进一步克隆了CMV-Am的外壳蛋白基因(CP)和移动蛋白基因(MP)全序列。序列比对分析表明,CMV-Am与CMV亚组ⅠB中株系XJ2序列同源性最高,核苷酸、氨基酸序列同源性分别为98.9%、99.1%。氨基酸序列同源性聚类分析表明,CMV-Am与中国大多数CMV分离物一样,属于CMV亚组ⅠB。     

新疆石河子、伊宁地区黄瓜花叶病毒株系分化

为了研究新疆黄瓜花叶病毒(Cucumber mosaic virus,CMV)分子变异及株系分化,对从石河子和伊宁地区采集的205个加工番茄、23个辣椒、4个番茄、2个南瓜样品进行酶联免疫检测和RT-PCR检测.在4种寄主上均检出了亚组Ⅰ型CMV,其中加工番茄的感染率高达74.15％.进一步对来自辣椒的YN-6、LJ-4、L-10,加工番茄的S1-1、S1-14,番茄的YN-2,以及南瓜的YN-9等7个样品CP、RNA3、MP核苷酸序列进行相似性和进化树分析.7个样品与CMV亚组ⅠB株系分离物的相似性较高、亲缘关系最近,均可归为CMV亚组ⅠB.而来自辣椒的LJ-4、L-10与其余5个样品的序列相似性较低,亲缘关系较远,在进化树上形成独立分支.说明在新疆加工番茄及其它蔬菜上广泛流行的CMV存在分子变异.     

侵染百合的黄瓜花叶病毒亚组Ⅱ分离物cp基因克隆和序列分析

 从云南大理的东方型百合上得到黄瓜花叶病毒分离物(CMV-DL), ELISA检测初步确定为CMV亚组Ⅱ分离物, 设计并合成CMV亚组Ⅱ的特异引物, RT-PCR扩增得到1条约800 nt的特异片段, 经克隆及序列测定, 该片段长828 nt, 包含的外壳蛋白(CP)基因由657 nt组成。将该分离物的cp基因与其它14个CMV分离物进行同源性比较, 在核苷酸水平上与CMV亚组I和亚组Ⅱ的同源性分别为76.8%~78.1%和98.6%~99.2%;在氨基酸水平上与CMV亚组I和亚组Ⅱ的同源性分别为82.0%~84.3%和95.9%~100.0%。结果表明CMV-DL为CMV亚组Ⅱ成员。     

黄瓜花叶病毒对烟草花叶病毒的干扰作用的研究初报

 于1981年-1985年研究了黄瓜花叶病毒(CMV)对烟草花叶病毒(TMV-T)的干扰作用.用CMV向日蔡环斑花叶分离物(CMV-SRS)为诱导病毒,接种枯斑三生烟十天后,对攻击病毒TMV-T的保护率为85.6%.反之,用TMV-T为诱导病毒,接种枯斑三生烟十天后,对攻击病毒CMV-SRS的保护率为95%(70-100%)证明在CMV-SRS和TMV-T之间,有较强的相互干扰作用.含有卫星核酸的黄瓜花叶病毒CMVS51、及CM-VS52两个分离物以及CMVS51+TMVN-14(烟草花叶病毒弱株系)免疫心叶烟和枯斑三生烟十天后,对强病毒TMV-P有明显的干扰作用.     

我国部分省市草莓种苗中黄瓜花叶病毒的检测分析

 为明确黄瓜花叶病毒(cucumber mosaic virus,CMV)在草莓上的发生和危害情况,利用RT-PCR方法对不同产地的不同品种草莓种苗进行检测,并对CMV草莓分离物的部分核苷酸序列进行了分析。结果表明,CMV侵染草莓后产生的症状主要为植株不同部位的畸形、变色,但有些无明显症状的植株也可以检测出CMV。共检测了我国7个不同省市的220个草莓种苗样品,其中北京、云南、辽宁、河北、四川和陕西的草莓种苗样品中均可检出CMV,内蒙古的种苗中未检出CMV。检测的6个不同草莓品种均含CMV,但北京和内蒙古的‘红颜'种苗未检出CMV,云南的‘圣诞红'种苗CMV检出率仅为2.6%。利用RT-PCR技术扩增草莓种苗中CMV的特异性核苷酸片段并对PCR产物测序,得到包含部分外壳蛋白基因及3'端非编码区共430 bp的2个草莓分离物序列。获得的2个分离物序列的核苷酸序列同源性为90.97%,序列比对分析结果表明2个分离物分属于CMV不同亚组,其中北京草莓分离物Bjcmz归属于亚组IA,河北分离物Hbcmc归属于亚组IB。     

我国部分省市草莓种苗中黄瓜花叶病毒的检测分析

 为明确黄瓜花叶病毒(cucumber mosaic virus,CMV)在草莓上的发生和危害情况,利用RT-PCR方法对不同产地的不同品种草莓种苗进行检测,并对CMV草莓分离物的部分核苷酸序列进行了分析。结果表明,CMV侵染草莓后产生的症状主要为植株不同部位的畸形、变色,但有些无明显症状的植株也可以检测出CMV。共检测了我国7个不同省市的220个草莓种苗样品,其中北京、云南、辽宁、河北、四川和陕西的草莓种苗样品中均可检出CMV,内蒙古的种苗中未检出CMV。检测的6个不同草莓品种均含CMV,但北京和内蒙古的‘红颜'种苗未检出CMV,云南的‘圣诞红'种苗CMV检出率仅为2.6%。利用RT-PCR技术扩增草莓种苗中CMV的特异性核苷酸片段并对PCR产物测序,得到包含部分外壳蛋白基因及3'端非编码区共430 bp的2个草莓分离物序列。获得的2个分离物序列的核苷酸序列同源性为90.97%,序列比对分析结果表明2个分离物分属于CMV不同亚组,其中北京草莓分离物Bjcmz归属于亚组IA,河北分离物Hbcmc归属于亚组IB。     

黄瓜花叶病毒两个甜瓜分离物的基因组及其侵染性克隆

为明确黄瓜花叶病毒（cucumber mosaic virus,CMV）甜瓜分离物的分子变异情况及其侵染性,对2个甜瓜分离物CH99和XH18的基因组进行克隆、测序和分析,并通过构建全长cDNA克隆分析其侵染性。结果显示,黄瓜花叶病毒甜瓜CH99分离物3条RNA长度分别为3 356、3 049和2 211 nt,甜瓜XH18分离物3条RNA长度分别为3 381、3 048和2 217 nt。分离物CH99与XH18的核苷酸序列一致性为89.40%～95.80%,氨基酸序列一致性为90.00%～97.80%,CH99分离物与其他CMV分离物的核苷酸和氨基酸序列一致性平均值分别为79.23%～89.29%和73.52%～93.90%,XH18分离物与其他CMV分离物的核苷酸和氨基酸序列一致性平均值分别为79.81%～89.83%和74.02%～95.14%。遗传发育分析显示,这2个分离物均属于亚组IB成员。接种试验结果显示,分离物CH99和XH18的侵染性克隆构建成功,这2个分离物均能系统侵染本生烟、甜瓜和黄瓜,并在本生烟和甜瓜上引起较严重的症状,在黄瓜上引起的症状较弱,而二者均不能侵染西...     

黄瓜花叶病毒(CMV)2个山西分离物CP序列测定及亚组分类分析

 在生物学检测的基础上,利用酶联免疫检测、非序列依赖性PCR(sequence-independent amp-lification, SIA)对感病番茄进行分子鉴定,表现卷叶和花叶症状的番茄均被黄瓜花叶病毒(Cucumber mosaic virus,CMV)侵染,分离物分别命名为SXFQ(GenBank登录号为JX993914)和FQ(GenBank登录号为JX993912)。为明确其分类地位,对二者外壳蛋白(coat protein, CP)进行克隆和测序分析。应用DNAMAN软件对本课题组前期检测的7个CMV山西分离物、SXFQ、FQ以及其他3个CMV典型分离物CP序列进行比较分析,发现核苷酸和氨基酸序列最大相似性分别为77.1%~100%和81.6%~100%。氨基酸序列系统进化分析表明,9个CMV山西分离物属于CMV亚组I B的2个分支,其中在指示植物上表现较强症状的SXFQ与其他5个分离物为一分支,在指示植物上表现较弱症状的FQ与其他2个分离物为另一分支。对9个山西分离物CP进行亚组分类分析,结果表明其理化性质、稳定性、疏水性与预测结果相近,2个分支的分离物分别出现相近的氨基酸变异和蛋白结构,存在一定规律性。     

Cucumber mosaic virus populations in Tunisian pepper crops are mainly composed of virus reassortants with resistance‐breaking properties

Cucumber mosaic virus is one of the most prevalent viruses in Tunisian pepper crops, where it has been detected in 68% of plants developing mosaic symptoms, making it essential to characterize the molecular and biological properties of local CMV populations. Two hundred and seventy‐eight isolates collected in the late 1990s, 2006 and 2008–2010 were characterized genetically. Isolates belonging to the three phylogenetic subgroups of CMV (IA, IB and II) were detected, but surprisingly, 90% of the isolates were reassortants between subgroups IA and IB, with two predominant haplotypes, IB‐IA‐IA and IB‐IA‐IB (nomenclature according to the subgrouping of the three genomic RNAs). The IB‐IA‐IA haplotype was present in all regions surveyed, while IB‐IA‐IB was observed only in northern Tunisia. This situation was unexpected, because CMV reassortants were previously thought to be counterselected in nature, and this raises the questions of the origin of IB strains in Tunisia and of the widespread distribution of these two reassortant types. Phylogenetic studies revealed low diversity within haplotypes, whatever the locality or the year of sampling. However, analysis of haplotype frequencies revealed a high genetic differentiation between CMV populations, which was better explained by the localities of sampling than by years. Geographic distances affected the differentiation of CMV populations, mainly between north and central Tunisia. When tested against a polygenic resistance to CMV movement in pepper, 55 of 57 isolates tested were able to break the resistance, indicating that this resistance would not be useful for controlling CMV in Tunisian pepper fields.     

Note: Occurrence and distribution ofCucumber mosaic virus infecting danshen (Salvia miltiorrhiza) in China

Cucumber mosaic virus (CMV) has resulted in much damage to Danshen (Salvia miltiorrhiza Bunge) crops in China. A 5-year survey was conducted in Hebei, Shandong, Sichuan, Shanxi, Henan and Gansu Provinces, all major Danshen-growing areas. A total of 156 Danshen plant samples with CMV symptoms were collected and tested for the presence of CMV by a double-antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA) using polyclonal antibodies against CMV and a positive control, according to the supplier’s instructions (Agdia). They were confirmed to be CMV by amplification of complete coat protein gene and analysis of the gene sequence. The results showed that 122 samples were infected by CMV and all of these CMV isolates belonged to subgroup IB. http://www.phytoparasitica.org posting May 19, 2008. Joint first authors.     

Molecular characterization of Cucumber mosaic virus strain causing severe mosaic disease on petunia in India

Severe mosaic, yellowing and stunting symptoms were observed on petunia (Petunia hybrida L.) growing in pots at NBRI and in various gardens of Lucknow, India. The association of Cucumber mosaic virus (CMV) with the mosaic disease was detected based on positive bioassay on susceptible hosts, isometric cored virus particles of ~28?nm during electron microscopic observations in leaf dip preparations and positive amplification of expected size (~650?bp) during RT-PCR using coat protein gene specific primers. Further, the complete RNA 3 genomic fragment of virus isolate was amplified by RT-PCR using RNA 3 specific primers. The obtained amplicons of ~2.2 Kb were cloned and sequenced. The analysis of sequence data of RNA 3 revealed highest sequence identities (96%) with several CMV strains which belong to subgroup IB. The virus isolate also showed closest phylogenetic relationships with banana strain of CMV of subgroup IB (Acc. EF178298) reported from India. To the best of our knowledge, we report the first molecular characterization of CMV strain of subgroup IB causing severe mosaic disease on petunia in India.     

A Severe Hellenic CMV Tomato Isolate: Symptom Variability in Tobacco, Characterization and Discrimination of Variants

A severe strain of Cucumber mosaic virus (CMV) originating from an infected tomato plant (Gastouni-Olympia, Greece) was isolated in tobacco (Nicotiana tabacum cv. Xanthi nc), after three serial local lesion passages in Chenopodium quinoa and designated CMV-G. CMV-G induces yellow mosaic (YM) symptoms in tobacco. When CMV-G was passed mechanically through C. quinoa, phenotypic variants inducing YM or green mild mosaic (MM) in tobacco were isolated. Aphid transmission, from different hosts, appears to be an effective approach for separating MM variants of CMV-G from YM variants. In particular, aphid transmission from zucchini proved to be very efficient in selecting for MM variants. In contrast, aphids transmitted only YM variants from tomato plants. Molecular characterization of CMV-G and its progeny resulted in their classification in the CMV subgroup IB, free of satellite RNA, being the first discovery of the subgroup IB in Greece. In the Solanaceae family (tobacco, tomato, pepper) YM variants induced more severe symptoms than the MM variants. YM and MM phenotype was stable in tobacco for all seven passages tried using the obtained YM and MM variants. Cross-protection experiments showed that an isolated MM variant was able to protect tobacco plants against a challenge infection by a YM variant.     

<Emphasis Type="Italic">Cucumber mosaic virus</Emphasis> isolated from Amazon lily (<Emphasis Type="Italic">Eucharis grandiflora</Emphasis>)

Cucumber mosaic virus (CMV) was isolated from a mosaic diseased plant of Eucharis grandiflora. The virus caused mosaic symptoms on leaves and slight distortion of flower petals in E. grandiflora by either mechanical or aphid inoculation. The virus was identified as a strain of CMV subgroup I from its biological and serological characteristics.     

Survey of viruses infecting open‐field pepper crops in Côte d'Ivoire and diversity of Pepper veinal mottle virus and Cucumber mosaic virus

The prevalence of viruses in pepper crops grown in open fields in the different agro‐ecological zones (AEZs) of Côte d'Ivoire was surveyed. Pepper veinal mottle virus (PVMV; genus Potyvirus) and Cucumber mosaic virus (CMV; genus Cucumovirus) were the most frequent viruses among those surveyed, while tobamoviruses (genus Tobamovirus) were detected at low frequency. PVMV showed a high heterogeneity across AEZs, which may be related to climatic, ecological or agronomical conditions, whereas CMV was more homogeneously distributed. The molecular diversity of CMV and PVMV were analysed from partial genome sequences. Despite the low number of CMV isolates characterized, two molecular groups were revealed, one corresponding to subgroup IA and the other to reassortants between subgroups IA and IB. RNAs 1 and 3 of the reassortants clustered with the IB subgroup of CMV isolates, whereas their RNA 2 clustered with the IA subgroup. Importantly, RNA 1 of CMV isolates of the IB subgroup has been shown to be responsible for adaptation to pepper resistance. The diversity of PVMV in the VPg‐ and coat protein‐coding regions revealed multiple clades. The central part of the VPg showed a high level of amino acid diversity and evidence of positive selection, which may be a signature of adaptation to plant recessive resistance. As a consequence, for efficient deployment of resistant pepper cultivars, it would be desirable to examine the occurrence of virulent isolates in the CMV or PVMV populations in Côte d'Ivoire and to follow their evolution as the resistance becomes more widely deployed.     

Evolutionary Characterization of Two Lily Isolates of Cucumber mosaic virus Isolated in Japan and Korea

We analyzed the evolutionary histories of two lily strains of Cucumber mosaic virus (CMV) isolated in Japan and Korea (HL- and Ly2-CMVs). They share common biological characteristics in that their host ranges are very restricted perhaps from a unique adaptation to lily plants. Although HL and Ly2 were isolated independently from different lily species in separate countries, their RNA3 sequences had a very high sequence similarity (97%). The evolutionary relationships between the two isolates were characterized by comparing their phylogenetic trees for the 3a and CP genes. The two lily CMVs always formed a distinct cluster within subgroup IB in 3a, but within IA in CP. Together, the phylogenetic tree topology and the sequence identity between the two lily CMVs suggest that they evolved from a common progenitor. Received 5 November 2001/ Accepted in revised form 11 January 2002