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中国甘薯病毒种类的血清学和分子检测 总被引:7,自引:1,他引:6
2009~2010年,从我国18个省(市)采集了176份表现病毒病症状的甘薯样品。利用血清学、PCR和核苷酸序列测定的方法,对上述样品中的病毒种类进行了鉴定。血清学检测结果表明,供试样品中甘薯羽状斑驳病毒(SPFMV)的阳性率最高,达56.3%,其次为甘薯G病毒(SPVG)和甘薯类花椰菜花叶病毒(SPCaLV),阳性率分别为34.1%和33.5%。PCR和核苷酸序列测定结果表明,我国甘薯上至少存在SPFMV、SPVG、甘薯潜隐病毒(SPLV)、甘薯褪绿斑病毒(SPCFV)、甘薯褪绿矮化病毒(SPCSV)、黄瓜花叶病毒(CMV)、甘薯脉花叶病毒(SPVMV)和甘薯卷叶病毒(SPLCV)8种病毒。此外,供试样品中没有检测出甘薯轻斑驳病毒(SPMMV),是否存在甘薯轻斑点病毒(SPMSV)、SPCaLV和C 6病毒尚不能确定。 相似文献
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制备免疫吸附电镜检测甘薯羽状斑驳病毒样品 总被引:1,自引:0,他引:1
甘薯羽状斑驳病毒(Sweet potato feathery mottle virus,SPFMV)可经蚜虫、摩擦、嫁接方式传播,是Y病毒组的一个成员。受此病毒感染的甘薯叶片上形成羽状褪绿斑,脉间褪绿斑点以及紫色环斑,有的品种出现紫色条纹。在甘薯块根上,有的呈严重纵向褐色龟裂,有的呈横向螺纹状木质化,有的块根内部形成木栓化,是危害甘薯最严重的病毒病害,可使甘薯严重退化及减产。无论是甘薯的抗病毒育种、病毒病害的防治,还是脱毒、无病毒甘薯种薯生产都离不开病毒的检测。灵敏的免疫吸附电镜(ISEM)检测方法被应用于各种病毒的检测中。 相似文献
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在吉林省7个主要甘薯种植区共采集85份甘薯叶片样品,利用小RNA深度测序技术对混合样品进行检测,经RT-PCR和测序验证,鉴定出样品中存在10种病毒,包括6种RNA病毒和4种DNA病毒。分别是马铃薯Y病毒科马铃薯Y病毒属的甘薯羽状斑驳病毒Sweet potato feathery mottle virus (SPFMV)、甘薯潜隐病毒Sweet potato latent virus (SPLV)、甘薯G病毒Sweet potato virus G (SPVG)、甘薯C病毒Sweet potato virus C (SPVC)、甘薯2号病毒Sweet potato virus 2 (SPV2);长线形病毒科毛形病毒属的甘薯褪绿矮化病毒Sweet potato chlorotic stunt virus (SPCSV);双生病毒科菜豆金色花叶病毒属的甘薯曲叶病毒Sweet potato leaf curl virus(SPLCV);玉米线条病毒属的甘薯无症状1号病毒Sweet potato symptomless virus 1 (SPSMV1);花椰菜花叶病毒科杆状DNA病毒属的甘薯杆状DNA病毒B Sweet potato badnavirus B (SPBV-B)和甘薯隐症病毒Sweet potato pakakuy virus (SPPV)。 相似文献
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湖北甘薯病毒病的检测与鉴定 总被引:2,自引:0,他引:2
2013—2015年采集了湖北黄冈、鄂州、武汉、荆州以及宜昌等5个地区的甘薯病毒病样品,通过双生病毒通用引物PCR扩增、ds RNA技术和序列分析等方法,鉴定了这5个地区甘薯病毒病的病原。结果显示,甘薯羽状斑驳病毒(Sweet potato feathery mottle virus,SPFMV)、甘薯褪绿矮化病毒(Sweet potato chlorotic stunt virus,SPCSV)、黄瓜花叶病毒(Cucumber mosaic virus,CMV)和甘薯卷叶病毒(Sweet potato leaf curl Georgia virus,SPLCGV)等4种病毒被检出。其中,SPFMV SPLCGV这两种病毒在湖北皆为首次报道。 相似文献
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甘薯由于甘薯病毒的普遍存在而造成大幅度减产。甘薯病毒种类复杂,主要有甘薯羽状斑驳病毒(SPFMV)、甘薯潜隐病毒(SPLV)、黄瓜花叶病毒(CMV)、烟草花叶病毒(TMV)。 相似文献
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广西局地西番莲病毒病的病原鉴定及优势病毒分析 总被引:3,自引:3,他引:0
在广西采集表现斑驳、花叶症状疑似病毒病的西番莲叶片样品,利用小RNA测序技术,结合生物信息学分析,鉴定侵染西番莲的病毒种类。参考测序结果采用DAS-ELISA和RT-PCR方法对2015~2018年间采集的385份疑似病毒病样品进行检测,分析引发广西西番莲病毒病的优势病毒种类。结果显示:小RNA共获得20 921 061 clean reads,拼接获得560个contigs,其中99个contigs被注释为夜来香花叶病毒(telosma mosaic virus,TeMV),97个contigs被注释为黄瓜花叶病毒(cucumber mosaic virus,CMV),69个contigs被注释为东亚西番莲病毒(East Asian passiflora virus,EAPV),12个contigs被注释为大豆花叶病毒(soybean mosaic virus,SMV)。提取送测序的同批样品叶片的总RNA进行RT-PCR验证,可检测出TeMV、EAPV和CMV 3种病毒,未检出SMV。采用DAS-ELISA和RT-PCR对采集的样品进行检测,结果发现284份样品为阳性样品,检出率为73.76%,其中TeMV的检出率最高为64.16%,其次为EAPV和CMV,检出率分别为41.30%和11.43%;3种病毒存在复合侵染现象,其中TeMV+EAPV的检出率最高为24.94%,TeMV+CMV的检出率为4.16%,EAPV+CMV的检出率为0.26%,3种病毒复合侵染的检出率为4.94%。 相似文献
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湖北省甘薯病毒病主要有皱缩花叶型、卷叶型、叶片斑点型(含黄斑型和紫环斑型)等三种症状类型。对三种类型的病株样本进行了电镜观察,结果表明,卷叶型、黄斑型和紫环斑型的病株叶片中均有长线形病毒粒子,长度为1 050m~1 650m,形态和大小无明显差异,皱缩花叶型病株叶片中有时也可观察到长线形病毒。用三种症状类型病株与巴西牵牛靠接,巴西牵牛和甘薯植株成活率达90%以上,巴西牵牛染病率可达80%以上。嫁接后的巴西牵牛叶片表现皱缩而且褪绿症状者,电镜检测均有病毒,因此,巴西牵牛可以用作甘薯病毒病诊断的指示植物。 相似文献
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山东甘薯主要病毒的鉴定及多样性分析 总被引:6,自引:2,他引:4
为明确山东省甘薯病毒病发生现状,在重病区调查采样,通过鉴别寄主、电镜和分子检测技术明确主要病毒种类;并克隆病毒外壳蛋白基因序列,利用Mega 5.0构建系统进化树进行遗传分析。结果显示,巴西牵牛嫁接甘薯染病枝条后叶片黄化、褪绿及皱缩;病样组织中存在大量600~900 nm的线状病毒粒子和柱状内含体。24份病样中检测到甘薯羽状斑驳病毒、甘薯潜隐病毒、甘薯G病毒、甘薯曲叶病毒和甘薯褪绿矮化病毒5种病毒,其中23份为复合侵染,存在11种侵染类型。遗传分析显示山东省甘薯羽状花叶病毒主要为EA、O和C株系,甘薯潜隐病毒与周边省份分离物相近,甘薯G病毒与中国海南和美国分离物相近,甘薯曲叶病毒分属3个株系。表明山东地区甘薯病毒种类繁多,侵染模式复杂,病毒遗传结构具有多样性。 相似文献
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葫芦种子传黄瓜绿斑驳花叶病毒的检测* 总被引:1,自引:0,他引:1
从感染黄瓜绿斑驳花叶病毒(Cucumber green mottle mosaic virus, CGMMV)的葫芦植株上收取种子,通过苗期症状观察法、双抗体夹心酶联免疫吸附法(DAS-ELISA)、免疫捕获反转录PCR(IC-RT-PCR)法测定葫芦种子的带毒情况,并用生物学接种方法测定葫芦种子携带病毒的侵染活性。苗期症状观察法结果表明,199株幼苗有2株表现花叶斑驳症状,种子传毒率为1.01%;而利用DAS-ELISA和IC-RT-PCR法随机检测30粒葫芦病株种子,CGMMV检出率为100%。种子各部位携带的CGMMV接种葫芦表现典型的花叶斑驳症状,表明葫芦种子携带的CGMMV具有侵染活性。DAS-ELISA检测葫芦种子CGMMV的灵敏度为1/5120种子研磨液。 相似文献
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Xing-Guang Deng Feng Zhu Ying-Juan Chen Jian Liu Tong Zhu Jing-Yi Li De-Hui Xi Hong-Hui Lin 《European journal of plant pathology / European Foundation for Plant Pathology》2014,140(1):111-117
An improved multiplex RT-PCR assay combined with magnetic nanobeads (MNB-RT-PCR) was developed for simultaneous detection of four sweet potato viruses, Sweet potato virus G (SPVG), Sweet potato feathery mottle virus (SPFMV), Sweet potato virus C (SPVC) and Sweet potato chlorotic fleck virus (SPCFV). Four primer pairs specific for each virus were designed and the corresponding PCR products were 169, 357, 516 and 900 bp in length for SPVG, SPFMV, SPVC and SPCFV, respectively. The specificity of the method was tested using different combinations of virus templates, and the identities of the amplification products were confirmed by sequencing. The limits of detection for all four viruses by single and multiplex MNB-RT-PCR assays were comparable. The assay was further evaluated using laboratory and field samples compared with a conventional CTAB-RT-PCR assay, and the comparative results showed that the MNB-RT-PCR assay was more rapid and sensitive. These results suggest that the multiplex MNB-RT-PCR assay is an effective and preferable method for virus detection in sweet potato. 相似文献
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Francis W. Kiemo Pál Salamon Ahmad Jewehan Zoltán Tóth Zoltán Szabó 《Plant pathology》2022,71(4):1001-1009
Sweet potato has been grown in Hungary for the last three decades, and its popularity is increasing among farmers and consumers. Its production is hampered by pests and diseases due to poor agricultural practices, such as the use of virus-infected propagation materials. We tested the presence of 15 viruses by PCR and quantitative PCR in 110 sweet potato plants collected from seven regions in Hungary. Seven viruses in single or multiple infections associated with a wide range of foliar symptoms were detected: sweet potato chlorotic stunt virus (SPCSV), sweet potato virus G (SPVG), sweet potato virus C (SPVC), sweet potato feathery mottle virus (SPFMV), sweet potato virus 2 (SPV2), sweet potato leaf curl virus (SPLCV), and sweet potato pakakuy virus (SPPV). This is the first report on the occurrence of the begomovirus SPLCV in sweet potatoes in Hungary. The infectivity and identity of these viruses were confirmed through bioassays (grafting to Ipomoea setosa) and sequencing of the PCR-amplified sections of their genomes, respectively. Due to the necessity for virus-free sweet potato propagation material in Hungary, virus elimination was carried out successfully in five out of six genotypes important for Hungarian farmers using heat treatment and meristem tip culture. All five viruses detected in the plants before heat treatment were removed except SPPV, which persists after heat treatment. Production and strict regulation of virus-free sweet potato propagation materials are recommended to avoid exacerbating the virus situation and protect Hungarian farmers from further losses. 相似文献
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Abstract The distribution of two sweet potato potyviruses, FMV and SPLV, was assessed in three plants infected with both viruses and in one plant infected with FMV only. All leaves, the top and basal sections of the main stem, and branch sections were tested by ELISA. Both symptomless leaves and leaves showing symptoms including purple rings, chlorotic spots, mottle or discoloration were found to contain the viruses. However, neither could be detected in every leaf or stem piece. SPLV was found in a lower proportion of leaf and stem samples than FMV. This indicates that the two viruses are either very unevenly distributed within sweet potato plants or that the virus concentration in some parts is below the detectable level. Testing of each leaf is recommended for reliable virus indexing of small, meristem‐derived sweet potato plantlets, if the ELISA method is used. Additional indexing of all ELISA‐negative materials by grafting to susceptible indicator plants is nevertheless still necessary. 相似文献
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Symptoms, aetiology and serological analysis of sweet potato virus disease in Uganda 总被引:4,自引:0,他引:4
R. W. Gibson I. Mpembe T. Alicai E. E. Carey R. O. M. Mwanga S. E. Seal & H. J. Vetten 《Plant pathology》1998,47(1):95-102
Sweet potato virus disease (SPVD) is the name used to describe a range of severe symptoms in different cultivars of sweet potato, comprising overall plant stunting combined with leaf narrowing and distortion, and chlorosis, mosaic or vein-clearing. Affected plants of various cultivars were collected from several regions of Uganda. All samples contained the aphid-borne sweet potato feathery mottle potyvirus (SPFMV) and almost all contained the whitefly-borne sweet potato chlorotic stunt closterovirus (SPCSV). SPCSV was detected by a mix of monoclonal antibodies (MAb) previously shown to react only to a Kenyan isolate of SPCSV, but not by a mixture of MAb that detected SPCSV isolates from Nigeria and other countries. Sweet potato chlorotic fleck virus (SPCFV) and sweet potato mild mottle ipomovirus (SPMMV) were seldom detected in SPVD-affected plants, while sweet potato latent virus (SPLV) was never detected. Isolates of SPFMV and SPCSV obtained by insect transmissions together induced typical symptoms of SPVD when graft-inoculated to virus-free sweet potato. SPCSV alone caused stunting and either purpling or yellowing of middle and lower leaves when graft-inoculated to virus-free plants of two cultivars. Similarly diseased naturally inoculated field plants were shown consistently to contain SPCSV. Both this disease and SPVD spread rapidly in a sweet potato crop. 相似文献