湖南省马铃薯病毒病发生情况调查

为了解湖南省马铃薯种薯质量和主要病毒病发生情况,2019年-2020年马铃薯秋作和冬作期间,对长沙、益阳、湘潭、澧临等马铃薯生产区的155个马铃薯样品,运用反转录-聚合酶链式反应(RT-PCR)和双抗体夹心酶联免疫吸附检测(DAS-ELISA)技术,筛查6种主要马铃薯病毒,包括马铃薯X病毒Potato virus X(PVX)、马铃薯Y病毒Potato virus Y(PVY)、马铃薯M病毒Potato virus M(PVM)、马铃薯S病毒Potato virus S(PVS)、马铃薯A病毒Potato virus A(PVA)、马铃薯卷叶病毒Potato leaf roll virus(PLRV)。检测结果表明:6种马铃薯病毒病在湖南均有不同程度的发生,单一和两种病毒复合感染植株占比最高,其次是3种病毒复合感染,存在极少数植株复合感染4～5种病毒病情况。在秋作马铃薯中,PVY检出率达到29.41%;PVS和PVA检出率均为27.94%;PVM、PVX、PLRV的检出率分别为20.59%、19.12%、17.65%。在冬作马铃薯中,PVX检出率最高,达到31.03%;其次是PLRV,...     

马铃薯主产区病毒病发生情况调查分析

在我国马铃薯主产区黑龙江、内蒙古、甘肃、贵州采集了752份具有典型病毒病症状的样品和疑似样品,应用DAS ELISA方法进行检测。主要筛查6种病毒：PVX、PVY、PVS、PLRV、PVM、PVA。结果显示: 270份样品检测到病毒,总体上,PVY的检出率最高,PVS次之,33份样品是由多种病毒混合侵染造成的,田间PVY+PLRV混合侵染率最高,PVS+PVY次之。试管苗PVS病毒发生较多,原原种和大田种薯PVY病毒发生比例最高。     

甘肃省马铃薯主要病毒病发生情况调查

2015年-2016年,在甘肃省10个地市24个马铃薯主栽县(区)146个生态区域(乡镇)采集了757份具有典型症状的马铃薯样品,应用DAS-ELISA法进行检测,筛查6种主要病毒(PVX、PVY、PLRV、PVA、PVS和PVM)。结果表明:631份样品检测到病毒,PVS的检出率最高,达47.03%,PVY次之,为33.82%,PVA最低,只有0.63%;发生复合侵染的病毒主要为PVY+PVS,复合侵染率达到10.13%,三种病毒复合侵染主要是PVY+PVS+PVM;病毒种类和感病程度与品种、地域有关。     

基于小RNA深度测序和RT-PCR检测侵染广东省冬种马铃薯的病毒

为明确侵染广东省冬种马铃薯的病毒种类及优势病毒,结合小RNA深度测序技术及RTPCR检测方法,对采集于广东省冬种马铃薯7个主产区的189份疑似病样进行检测分析。结果表明,经小RNA深度测序技术检测马铃薯病毒病混合样,发现存在马铃薯Y病毒(Potato virus Y,PVY)、马铃薯S病毒(Potato virus S,PVS)和马铃薯卷叶病毒(Potato leaf-roll virus,PLRV)3种病毒。进一步设计3种病毒的特异性引物并利用国内已报道的其它5种马铃薯病毒的特异性引物进行RT-PCR检测,发现189份马铃薯病毒病疑似病样中仅检测到PVY、PVS和PLRV这3种病毒,检出率依次为75.13%、10.05%和4.76%,且3种病毒在马铃薯上还存在复合侵染,复合侵染率为14.19%,其中PVY在各马铃薯产区均可检测到。表明侵染广东省冬种马铃薯的病毒为PVY、PVS和PLRV,其中PVY是优势病毒。     

二重RT-PCR快速检测马铃薯病毒的方法

本研究采用传统的蛋白酶K法和病毒RNA简易浸提法,从马铃薯块茎、茎干、叶梗、叶片中提取马铃薯X病毒,马铃薯Y病毒,马铃薯A病毒及马铃薯卷叶病毒RNA,并设计了4种马铃薯病毒引物,优化了二重RT-PCR反应条件,可以同步扩增出上述4种病毒,扩增产生的靶带分别为562bp(PVX)、480bp(PVY)、336bp(PLRV)、255bp(PVA).应用病毒RNA简易制样技术和优化的二重RT-PCR反应条件,可以同步快速检测田间自然感染的马铃薯病毒,此研究还可适合于检测马铃薯脱毒种薯及试管苗,对马铃薯病毒病早期监测有一定的作用.     

马铃薯4种病毒多重PCR检测体系的建立

我国马铃薯病毒主要有马铃薯Y病毒(PVY)、马铃薯X病毒(PVX)、马铃薯S病毒(PVS)、马铃薯卷叶病毒(PLRV),常发生复合侵染。根据GenBank中4种马铃薯病毒的外壳蛋白(coat protein,CP)基因全长设计引物,通过RT-PCR扩增得到4种病毒CP基因全长片段,测序结果显示序列同源性96%以上;针对4种病毒CP基因的保守序列分别设计引物,在一个PCR体系中同步对4种病毒进行扩增,得到421、202、516、330bp的特异性条带,优化建立了能同步检测PVY、PVX、PVS和PLRV的多重RT-PCR检测体系。检测结果证明优化后的多重RT-PCR体系能在田间样品中快速、高效地检测出4种病毒。     

矿物油和维生素B1对马铃薯病毒病的防效研究

多数马铃薯病毒可以借助蚜虫传播, 并通过块茎世代积累, 导致马铃薯种性退化, 严重影响块茎的产量和品质?为了筛选新型?环保的马铃薯病毒病防治药剂, 本研究通过3个季节的田间试验, 对矿物油?维生素B1和杀虫剂吡虫啉在防治马铃薯病毒病中的效果进行了评价?结果表明, 通过马铃薯出苗后间隔10 d连续3次喷施, 矿物油能够控制马铃薯卷叶病(potato leaf-roll virus, PLRV)的发生, 对马铃薯M病毒(potato virus M, PVM)和马铃薯S病毒(potato virus S, PVS)的平均防效也分别达到66.72%和70.40%, 但对马铃薯Y病毒(potato virus Y, PVY)和马铃薯A病毒(potato virus A, PVA)在不同的年份和季节的防效不稳定, 平均防效为27.34%和65.02%?维生素B1对PLRV?PVM和PVS的防效也比较明显, 分别达83.36%?83.33%和73.32%, 而对PVY同样防效不稳定, 对PVA防效不明显?杀虫剂吡虫啉对PLRV?PVS和PVM的防效也不稳定, 且对PVY和PVA的防效均不显著?本研究中马铃薯X病毒(potato virus X, PVX)发生频率极低, 未进行病毒病的防效比较?综上所述, 矿物油和维生素B1对马铃薯主要病毒病的综合防效较吡虫啉好, 同时它们的增产效果更明显, 产投比高于化学药剂, 值得推广?     

利用RNA干扰介导抗病性获得兼抗四种病毒的转基因马铃薯

为获得兼抗马铃薯X病毒(Potato virus X,PVX)、马铃薯Y病毒(Potato virus Y,PVY)、马铃薯卷叶病毒(Potato leaf roll virus,PLRV)和马铃薯潜隐花叶病毒(Potato virus S,PVS)4种病毒的转基因马铃薯新材料,分别以这4种病毒全长CP基因为模板,通过设计PCR引物和亚克隆获得4种病毒CP基因相对保守区段的基因片段,并将其拼接成融合基因,以载体pHANNIBAL和pBI121为基础,构建RNA干扰(RNA interference,RNAi)载体,利用农杆菌介导的转基因体系进行马铃薯遗传转化,并对获得的转基因马铃薯进行病毒抗性检测。结果表明,所获得的融合基因片段RH1和RH2,酶切鉴定分别得到长度为1 200 bp的条带,与预期片段相符;构建了含pdk内含子和RH1、RH2融合基因的RNAi植物表达载体,经Bam H I/Sac I双酶切,获得长度约3 200 bp的片段,表明RNAi植物表达载体pBI121-pRH构建成功;转化易感病毒马铃薯品种陇薯11号,PCR检测和PCRSouthern杂交分析表明融合基因已整合到陇薯11号马铃薯基因组中;抗病性检测显示4株转基因马铃薯植株对4种病毒均免疫。表明利用RNAi可筛选出抗多种病毒的转基因马铃薯新种质。     

马铃薯种苗复合感染病毒多重RT-PCR同步快速检测

 基于马铃薯病毒ssRNA的快速制备方法,根据马铃薯病毒CP基因序列设计PVX、PVS、PVY和PLRV特异性引物对、P1基因序列设计PVA特异性引物对,建立了多重RT PCR快速检测体系,可以同步检出复合侵染马铃薯种苗主要病毒,灵敏度比传统的ELISA至少高100倍。结合生物活性稳定剂研制的固相化检测试剂盒,已用于四川和重庆等15个县市田间与苗圃248个马铃薯显症或无症样品的实际检测,表明四川和重庆地区2~3种马铃薯病毒往往复合侵染(PVX、PVA和PVS三种病毒复合侵染或PLRV和PVY二种病毒复合侵染)。     

Incidence of potato viruses and characterisation of <Emphasis Type="Italic">Potato virus Y</Emphasis> variability in late season planted potato crops in Northern Tunisia

Surveys were conducted of symptomatic potato plants in late season crops, from the major potato production regions in Northern Tunisia, for infection with six common potato viruses. The presence of Potato leafroll virus (PLRV), Potato virus Y (PVY), Potato virus X (PVX), Potato virus A (PVA), Potato virus S (PVS) and Potato virus M (PVM) was confirmed serologically with virus infection levels up to 5.4, 90.2, 4.3, 3.8, 7.1 and 4.8%, respectively. As PVY was prevalent in all seven surveyed regions, further biological, serological and molecular typing of 32 PVY isolates was undertaken. Only one isolate was shown to induce PVY^O-type symptoms following transmission to tobacco and to react only against anti-PVY^O-C antibodies. Typical vein necrosis symptoms were obtained from 31 samples, six of which reacted against both anti-PVY^N and anti-PVY^O-C antibodies showing they contained mixed isolates, while 25 of them reacted only with anti-PVY^N antibodies. An immunocapture RT-PCR molecular test using a PVY^NTN specific primer pair set in the 5’NTR/P1 genomic region and examination of recombinant points in three genomic regions (HC-Pro/P3, CI/NIa and CP/3’NTR) showed that all 25 serotype-N PVY isolates were PVY^NTN variants with similar recombinations to the standard PVYNTN-H isolate. This is the first report of the occurrence of the PVY^NTN variant and its high incidence in late season potatoes in Tunisia.     

从葎草中检出复合侵染的多种病毒

采用抗原直接包被酶联免疫吸附测定法（ELISA）对采自重庆近郊的34个葎草样品进行了主要病毒种类的检测。其中马铃薯Y病毒(Potato virus Y, PVY)的侵染最普遍,其阳性检出率达44.12%;马铃薯X病毒(Potato virus X, PVX)的阳性检出率最低,仅为26.47%,其余5种病毒,烟草花叶病毒(Tobacco mosaic virus, TMV)、黄瓜花叶病毒(Cucumber mosaic virus, CMV)、番茄花叶病毒(Tomato mosaic virus, ToMV)、芜菁花叶病毒(Turnip mosaic virus, TuMV)及蚕豆萎蔫病毒2号(Broad bean wilt virus 2, BBWV-2)的阳性检出率均为35.29%。葎草样品受多种病毒的复合侵染现象非常严重,15个阳性样品中病毒复合侵染率为80%,其中75%的样品检测到7种病毒复合侵染。     

Evaluation of the status of capsicum viruses in the main growing regions of Turkey

The incidence, severity and distribution of six viruses infecting capsicum were determined in the main growing areas of Turkey during the 2004 growing season. The surveys covered 50 randomly selected capsicum fields from four different areas in south-east Anatolia and the eastern Mediterranean region. 515 samples were individually collected and tested by DAS-ELISA for Cucumber mosaic cucumovirus (CMV), Alfalfa mosaic alfamovirus (AMV), Potato X potexvirus (PVX), Potato Y potyvirus (PVY), Pepper mild mottle tobamovirus (PMMoV) and Tobacco etch potyvirus (TEV). 64.8% of ELISA-tested capsicum samples (334 out of 515) were infected by one (41.7%) or more (23.1%) viruses. PVY was the most widespread (26.4%), followed by PVX (25.8%), AMV (25.2%), TEV (23%), PMMoV (9.1%) and CMV (8.3%). Surprisingly high AMV infection was found in three areas (Kahramanmaraş, Şanlıurfa and Gaziantep) where AMV is reported for the first time in this study. However, AMV was not detected in Hatay. PMMoV is another new virus, in all the tested areas.     

福建省福清地区马铃薯病毒病病原的分子检测

2017年调查福建福清地区马铃薯病毒病的发生情况,以明确该地区马铃薯主要病毒病原。共采集了46份疑似感染病毒的马铃薯植株,提取总RNA,利用RT-PCR技术进行分子检测,结果表明,福清地区危害马铃薯的病毒有马铃薯Y病毒Potato virus Y(PVY)、马铃薯卷叶病毒Potato leaf roll virus(PLRV)、马铃薯S病毒Potato virus S(PVS),检出率分别为56.52%、17.39%和10.87%,以PVY检出率最高,说明PVY是危害该地区马铃薯样品的主要病毒病原。通过病毒复合侵染进行分析,发现该地区存在病毒复合侵染马铃薯现象。研究结果可为福清地区马铃薯种薯的引进和病毒病害防治提供参考依据。     

浙江省马铃薯病毒病检测分析

马铃薯病毒病是影响马铃薯产量和品质的主要因素之一,其症状表现为花叶、黄化和卷曲等。2019年4月-5月,在浙江省湖州、杭州、绍兴、宁波、金华、台州和丽水等7个地市的主要马铃薯产区采集了具有典型病毒病症状的马铃薯样品,采用转录组测序和RT-PCR验证的方法进行病毒检测,共筛查并验证出6种马铃薯病毒,包括马铃薯X病毒Potato virus X(PVX)、马铃薯Y病毒Potato virus Y(PVY)、马铃薯S病毒Potato virus S(PVS)、马铃薯H病毒Potato virus H(PVH)、马铃薯M病毒Potato virus M(PVM)以及马铃薯奥古巴花叶病毒Potato aucuba mosaic virus(PAMV)。检测结果表明,在调查的这7个地市中每个地市都具有2种以上的病毒发生,其中PVH作为一种新鉴定的麝香石竹潜隐病毒属成员在除宁波以外的各地区都有发生;此外杭州市、湖州市以及绍兴市均检测出了PAMV。对检测到的PVS、PVH、PVM和PAMV外壳蛋白(coat protein,CP)序列进行系统发育分析表明,这些病毒均存在地域差异性。本研究为浙江省马铃薯病毒的防控奠定了重要基础。     

一种快速简便检测马铃薯病毒的方法——病毒细菌协同凝集法(VBA)的研究

在国内、外首次选用金黄色葡萄球菌(Staphylococc aureus)的No.180菌株用于病毒细菌协同凝集试验(Virobacterial agglutination test简称VBA)检测了来自马铃薯的4种不同形态粒子的病毒:马铃薯X病毒(PVX)、马铃薯丫病毒(PVY)、烟草花叶病毒(TMV)和马铃薯卷叶病毒(PLRV),其灵敏度达2.7～6.1ng/ml,检出病汁液的最大稀释度达10~4～10~5(PLRV1:500),较国内、外采用的Cown I菌株的灵敏度提高5～10倍。与血清学方法相比,VBA在2～3分种内就可获得结果,无假阳性反应,其灵敏度显著高于间接酶联法和免疫电镜,而接近于A蛋白酶联法。经抗血清致敏的菌体在4℃下保存4个月,对VBA检测的灵敏度没有影响。用VBA对采自田间的93个马铃薯病样进行检测,它们大多受2～3种病毒(PVX、PVY及PLRV)的复合侵染;和用间接酶联法及鉴别寄主检测的结果趋向一致。室内和田间试验均表明VBA灵敏度高、特异性强、快速简便和经济,尤其适合在基层单位中推广应用。     

一种快速简便检测马铃薯病毒的方法——病毒细菌协同凝集法(VBA)的研究

 在国内、外首次选用金黄色葡萄球菌(Staphylococc aureus)的No.180菌株用于病毒细菌协同凝集试验(Virobacterial agglutination test简称VBA)检测了来自马铃薯的4种不同形态粒子的病毒:马铃薯X病毒(PVX)、马铃薯丫病毒(PVY)、烟草花叶病毒(TMV)和马铃薯卷叶病毒(PLRV),其灵敏度达2.7~6.1ng/ml,检出病汁液的最大稀释度达10⁴~10⁵(PLRV1:500),较国内、外采用的Cown I菌株的灵敏度提高5~10倍。与血清学方法相比,VBA在2~3分种内就可获得结果,无假阳性反应,其灵敏度显著高于间接酶联法和免疫电镜,而接近于A蛋白酶联法。经抗血清致敏的菌体在4℃下保存4个月,对VBA检测的灵敏度没有影响。用VBA对采自田间的93个马铃薯病样进行检测,它们大多受2~3种病毒(PVX、PVY及PLRV)的复合侵染;和用间接酶联法及鉴别寄主检测的结果趋向一致。室内和田间试验均表明VBA灵敏度高、特异性强、快速简便和经济,尤其适合在基层单位中推广应用。     

Progress in aphid forecasting systems

Potato virus Y and many other viruses of potatoes cause major economic losses to seed potato production in many countries. Potato virus Y, which is transmitted in a non-persistent manner, is one of the most important virus diseases of potatoes in many countries in Europe and especially in the northern regions.During the last decade there has been an increasing interest in developing methods for potato virus forecasting. The abundance of virus vectors is often estimated by yellow water traps (YWT), suction traps or field surveys. In Sweden the relationship between occurrence of alate aphids and the proportion of PVY infected progeny tubers has been studied since 1975. A dynamic simulation model for PVY has been designed for predicting the incidence of PVY. The simulation model describes a system which includes e.g., healthy and PVY diseased potato plants, different aphid species as virus vectors an their efficiency as virus vectors, the susceptibility of the potato crop according to mature plant resistance and date of haulm destruction. There was a good correlation between model output and samples of progeny tubers tested for PVY.     

Localization of potato leafroll virus in leaves of secondarily-infected potato plants

Potato leafroll virus (PLRV) antigen was localized by immunogold labelling in semi-thin leaf sections of secondarily-infected potato plants cv. Bintje. Viral antigen was present in all cell types of the phloem tissue. but occurred most abundantly in the companion cells. Detectable amounts of PLRV antigen were found only in the sieve elements in veins with a large number of infected companion cells. Occasionally, parenchyma cells were also found to be infected. PLRV was not exclusively limited to the phloem tissue in the infected potato plants, but was also found in mesophyll cells neighbouring minor phloem vessles. Spread of virus from cell to cell in the mesophyll was not observed. The distribution of PLRV in the potato leaf tissue has implication on its availability, for acquisition by aphids.