感染马铃薯Y病毒烟株对烟蚜取食行为及烟蚜茧蜂适应性的影响

为探明烟蚜茧蜂Aphidius gifuensis Ashmead对烟蚜Myzus persicae(Sulzer)取食感染马铃薯Y病毒(Potato virus Y,PVY)烟株的适应性,利用刺探电位图谱(EPG)技术记录了烟蚜在感病烟株与健康烟株上的取食行为,并测定了烟蚜茧蜂对取食2种烟株烟蚜的寄生率以及烟蚜茧蜂的羽化率、发育时间及性比等指标。结果表明,与健康烟株相比,烟蚜在感染PVY烟株上的第1次刺探取食持续时间显著延长,且口针遇到阻力的次数(F波)和总持续时间均显著减少。烟蚜在感病烟株木质部的吸食时间(G波)显著长于健康烟株。感病烟株上烟蚜在韧皮部阶段的分泌唾液时间(E1波)较在健康烟株上显著缩短,而被动吸食汁液时间(E2波)显著延长。烟蚜茧蜂寄生取食感染PVY烟株的烟蚜,虽然能成功完成其生活史,但适应性与寄生取食健康烟株烟蚜的蚜茧蜂存在差异。在感染PVY烟株上,烟蚜茧蜂对烟蚜的寄生率为33.67%,显著低于对照的64.67%;且僵蚜体重明显下降,羽化的成蜂个体较小;成蜂存活时间1.48 d也极显著短于对照组的2.25 d。表明烟蚜茧蜂对取食感染PVY烟株烟蚜的适应性较低,PVY可通过烟蚜为介体间接降低烟蚜茧蜂的适应力。     

不同体色生物型烟蚜的取食特性分析

为探究不同体色生物型烟蚜Myzus persicae取食行为的差异,明确其在烟田的分布特征,利用刺探电位图谱(EPG)技术测定了红色型、绿色型和褐色型3种体色生物型烟蚜在烟草上的取食行为。结果表明:红色型烟蚜刺探取食之前对烟草寄主所花费的识别时间最短,为2.20 min,极显著短于褐色型烟蚜的10.09 min。绿色型烟蚜在刺探过程中pd波平均持续时间为7.45 s,显著长于红色型烟蚜的6.85 s,极显著长于褐色型烟蚜的3.95 s,但3种体色生物型烟蚜的pd波次数无显著差异。首次刺吸至第1次出现E2波所需时间,绿色型和褐色型烟蚜均约为红色型烟蚜的2倍。韧皮部取食阶段,3种体色生物型烟蚜分泌唾液(E1波)的时间无显著差异;红色型烟蚜被动吸食汁液(E2波)时间为112.28 min,显著长于绿色型烟蚜的70.02 min和褐色型烟蚜的75.15 min。褐色型烟蚜在木质部主动摄取汁液(G波)的时间最短为8.58 min,与另外2种体色生物型烟蚜差异显著。表明3种体色生物型烟蚜各自具有不同的取食策略,但总体而言红色型烟蚜对烟草的适应性最强。     

基于EPG分析无翅型和有翅型柑橘蚜虫的取食行为

为明确无翅型、有翅型柑橘蚜虫取食行为的差异,采用EPG技术对褐色橘蚜Toxoptera citricida(Kirkaldy)和棉蚜Aphis gossypii Glover的有翅型、无翅型成蚜在柑橘苗上的取食行为进行测定。结果表明,褐色橘蚜无翅型和有翅型的EPG均记录到7种取食波形,依次为非刺探波np、路径波A、B和C、电位下降波pd、韧皮部取食波E1和E2;棉蚜无翅型和有翅型的EPG记录到9种取食波形,除上述7种外,还包括木质部主动吸食波G和口针阻碍波F。褐色橘蚜有翅型和无翅型的np波持续时间为25.73 min和8.39 min,二者间差异显著;棉蚜有翅型的np波持续时间、刺探次数、C波次数分别为27.34 min、19.16次、20.21次,显著高于无翅型,而刺探总持续时间为332.66 min,显著低于无翅型。棉蚜的C波次数及总持续时间、刺探次数、pd波次数及总持续时间均显著高于褐色橘蚜,而E2波总持续时间及平均持续时间均显著小于褐色橘蚜。表明棉蚜无翅型比有翅型在柑橘上更容易取食,影响有翅型蚜虫取食的抗性因子可能位于柑橘表面;褐色橘蚜比棉蚜对柑橘的适应性更强。     

南方水稻黑条矮缩病株对非介体稻飞虱-褐飞虱取食行为的影响

为明确感染南方水稻黑条矮缩病毒(Southern rice black-streaked dwarf virus,SRBSDV)水稻对非介体褐飞虱取食行为的影响,在人工气候室通过刺探电位监测技术对褐飞虱在感染SRBSDV水稻植株和健康水稻植株上的取食行为进行持续监测和比较分析。结果表明,与对照相比,在感染SRBSDV水稻植株上取食的褐飞虱其取食路径波Nc(N2+N3)(口针在维管束组织移动)的总持续时间显著延长了116.69%,Nc(N2+N3)波形持续时间占总监测时间的百分数也显著提高了100.42%;而口针刺探次数和刺探时间、在韧皮部及木质部取食次数和持续时间等均无显著差异。表明水稻感染SRBSDV后对褐飞虱的取食行为影响不大,仅显著延长了其到达取食位点的时间。     

柑橘三种蚜虫取食行为的EPG分析

为探究柑橘3种蚜虫取食行为差异,利用刺吸电位图谱(electrical penetration graph,EPG)技术对褐色橘蚜Toxoptera citricida(Kirkaldy)、棉蚜Aphis gossypii Glover和绣线橘蚜Aphis citricola van der Goot在椪柑上的取食行为进行了测定。结果表明:3种蚜虫均产生8种取食波形,依次为非刺探波(np波)、路径波(A、B、C波)、电位下降波(pd波)、韧皮部分泌唾液波(El波)、韧皮部被动吸食波(E2波)以及木质部主动吸食波(G波)。棉蚜开始取食的第1次刺探时间最早,绣线橘蚜刺探的次数最多,且C波时间最长。褐色橘蚜pd波出现的次数最少,棉蚜次之,绣线橘蚜最多,显著高于褐色橘蚜。与其它2种蚜虫相比,绣线橘蚜于木质部主动吸食汁液(G波)时间最长,有G波的个体比例最高。3种蚜虫E1波次数和总持续时间差异均不显著,但褐色橘蚜E2波的持续时间217.01±27.56 min显著长于棉蚜142.49±27.85 min和绣线橘蚜116.64±20.05 min。初步推断3种蚜虫对柑橘衰退病毒的传毒效率与E2波有关。     

马铃薯Y病毒HC-Pro第182位赖氨酸残基参与引起烟草叶脉坏死

马铃薯Y病毒(potato virus Y,PVY)是侵染烟草的最重要病毒之一.不同PVY株系侵染烟草可引起不同症状,有些PVY株系可引起烟草叶脉坏死,严重影响烟草的产量和品质.PVY A12分离物属于NTN-NW株系,但侵染珊西烟(Nicoti-ana tabacum cv.Xanthi)不能引起叶脉坏死.分析发现,...     

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。     

不同病毒接种烟株对烟蚜生长发育和繁殖的影响

在室内25±0．5℃、RH 75%±5%、L:D=14:10条件下,研究了单独和混合接种黄瓜花叶病毒(CMV)、烟草花叶病毒(TMV)的烟株对烟蚜生长发育和繁殖的影响。结果表明,烟蚜取食健康烟株CK、CMV病株、TMV病株及CMV TMV病株叶碟后,若虫历期分别为6．04、6．26、6．79和8．04天,存活率分别为75．71%、55．84%、70．59%和32．00%,雌成蚜理论最大累积产仔数分别为22．44、6．35、4．99和5．49头,而种群内禀增长率r_m则分别为0．23、0．17、0．15和0．11。与健康烟株相比,接种各类型病毒的烟株对烟蚜种群有明显抑制作用,其中抑制作用最大的是CMV TMV混合接种的烟株。     

烟草马铃薯Y病毒病系统控制技术

烟草马铃薯Y病毒病(Potato virus Y,简称PVY),是由马铃薯Y病毒引起的一种系统侵染烟草的病害。近年来,该病在我国各烟区为害呈上升态势,对烟草的产量和品质造成严重影响,局部地区损失惨重。结合烟叶生产,介绍烟草马铃薯Y病毒病的发生特点和系统控制技术。     

两个马铃薯Y病毒不同株系分离物在三种寄主上的致病性分析

马铃薯是重要的粮食和经济作物。马铃薯Y病毒(potato virus Y,PVY)是危害马铃薯安全生产的重要病毒。近年来,危害我国马铃薯的PVY株系组成发生了显著变化。PVY重组型株系尤其是PVY^NTN-NW SYRI和SYRII型成为优势株系,但与传统株系分离物相比,优势株系分离物在不同寄主上的侵染性及其致病力还不清楚。本研究分析了PVY^N株系代表性分离物PVY^N605和PVY^NTN-NWSYRI型分离物GZ在本氏烟、普通烟和辣椒上的侵染性,比较了二者在本氏烟和普通烟上的致病力。结果表明,PVY^N605和PVY^NTN-NWSYRI-GZ分离物均能侵染本氏烟和普通烟,并在普通烟上引起叶脉坏死;PVY^N605不能系统侵染辣椒品种‘特大牛角王’,而PVY^NTN-NWSYRI-GZ可系统侵染辣椒品种特大牛角王。PVY^NTN-NWSYRI-GZ在本氏烟细胞间的移动速度明显慢于PVY^N     

桃蚜体内次生共生菌沙雷氏菌对宿主抵御寄生蜂和高温胁迫的影响

为明确桃蚜Myzus persicae体内次生共生菌沙雷氏菌Serratia symbiotica对宿主抵抗不良环境的影响,利用叶碟法测定短翅蚜小蜂Aphelinus asychi对自然感染沙雷氏菌桃蚜、自然未感染沙雷氏菌桃蚜和人工感染沙雷氏菌桃蚜的寄生特性和取食特性,并测定烟蚜茧蜂Aphidius gifuensis对这3种处理桃蚜的寄生特性及这3种处理桃蚜经高温胁迫后的生长繁殖特性。结果显示,短翅蚜小蜂在人工感染沙雷氏菌桃蚜上的产卵率比在自然未感染沙雷氏菌桃蚜上的下降近1/2,羽化率下降1/3左右,致死率、取食率、僵蚜率均无显著差异;烟蚜茧蜂对这3种处理桃蚜的致死率、过寄生率、僵蚜率及其产卵率和羽化率等均无显著差异;这3种处理桃蚜的2龄若蚜经高温胁迫后,发育时间和寿命均显著延长,开始产蚜时间明显推迟,繁殖力和日繁殖率显著降低,繁殖历期无明显变化;高温胁迫后,人工感染沙雷氏菌桃蚜比自然未感染沙雷氏菌桃蚜开始产蚜时间提前3.9 d,繁殖力增加7.0头。表明人工感染沙雷氏菌可以提高桃蚜对短翅蚜小蜂和高温胁迫的防御作用,对烟蚜茧蜂的寄生无明显效果。     

短翅蚜小蜂对桃蚜的取食和寄生功能反应

为评估短翅蚜小蜂对桃蚜的搜寻及控害潜能,采用叶碟法研究了短翅蚜小蜂对甘蓝和辣椒2种植物上桃蚜2龄若虫的取食与寄生行为。结果表明,短翅蚜小蜂对甘蓝桃蚜和辣椒桃蚜的取食和寄生功能反应均符合Holling II及Holling III型方程。短翅蚜小蜂的取食和寄生搜寻效应均随蚜虫密度的增加而降低,当桃蚜密度小于35头时,短翅蚜小蜂对甘蓝桃蚜的取食搜寻效应大于辣椒桃蚜,而当桃蚜密度大于35头时,短翅蚜小蜂对辣椒桃蚜的取食搜寻效应大于甘蓝桃蚜;短翅蚜小蜂在所有密度下对辣椒桃蚜的寄生搜寻效应均大于甘蓝桃蚜。短翅蚜小蜂取食甘蓝桃蚜的瞬间攻击率a'为0.3289,处理时间T_h为0.2597,均大于辣椒桃蚜,寄生甘蓝桃蚜的瞬时攻击率a'为0.8213,小于辣椒桃蚜,而处理时间T_h为0.0275,大于寄生辣椒桃蚜;短翅蚜小蜂对甘蓝桃蚜的理论最大取食量和寄生量均小于辣椒桃蚜。研究表明,短翅蚜小蜂对不同密度的桃蚜均有一定的控制能力,且对辣椒桃蚜的控制作用大于甘蓝桃蚜。     

基于EPG技术分析杭菊两主栽品种对三种菊蚜抗性及其相关抗性物质

为比较杭白菊主栽品种早、晚小洋菊对菊小长管蚜Macrosiphoniella sanborni、棉蚜Aphis gossypii、桃蚜Myzus persicae的抗性,通过刺吸电位技术(electrical penetration graph,EPG)研究菊蚜在菊顶叶上刺吸行为,并检测了菊顶叶主要化合物。结果表明:在晚小洋菊上,菊小长管蚜的E1、E2波平均持续时间4.31、3.47 min,分别短于在早小洋菊上的4.63、3.75 min;棉蚜、桃蚜的E1、E2波平均持续时间分别为4.32、4.72 min和4.92、4.64 min;3种蚜虫的平均刺探次数均大于在早小洋菊上的平均刺探次数。聚类分析结果显示,2个主栽品种之间抗性存在差异。早小洋菊顶叶平均可溶性糖和可溶性蛋白含量分别为2.71 mg/g和25.36 mg/g,均高于晚小洋菊;早小洋菊顶叶总酚含量为0.24 mg/g,显著低于晚小洋菊;早、晚小洋菊总黄酮含量分别为3.46 mg/g和3.37 mg/g。早小洋菊顶叶可溶性糖、可溶性蛋白含量基本上与每种菊蚜的E1、E2波持续时间显著正相关,总酚含量、总黄酮含量与每种菊蚜的E1或E2波持续时间显著负相关。推测早小洋菊对于菊长管蚜的抗性稍弱于晚小洋菊,2种杭白菊对棉蚜或桃蚜的抗性相当,且菊叶中的这4种物质含量与抗蚜性相关。     

金龟子绿僵菌对苜蓿生长的影响及对苜蓿抗蚜性的诱导作用

为明确金龟子绿僵菌Metarhizium anisopliae在促进植物生长和提高植物抗性方面的作用,以金龟子绿僵菌拌土种植紫花苜蓿Medicago sativa,于室内测定植株的生长参数、苜蓿斑蚜Therioaphis trifolii的取食选择性及其发育历期和繁殖力。结果表明,金龟子绿僵菌处理后7 d,植株株高比对照显著增加了0.87 cm;处理后14 d,植株分枝数为3.88个,根长为54.67 mm,均显著高于对照。株龄14 d的植株接入苜蓿斑蚜,至株龄28 d时,金龟子绿僵菌处理的植株株高、分枝数和根长均较对照显著增加;同时生物量、叶绿素含量和类胡萝卜素含量也有不同程度的升高。选择性试验结果显示,24 h内选择并驻留在金龟子绿僵菌处理植株叶片上的苜蓿斑蚜数量较对照显著减少28.57%。以金龟子绿僵菌处理的植株叶片饲喂苜蓿斑蚜,1～4龄若虫的发育均有所减缓,各龄若虫的发育历期均较对照叶片饲喂的各龄若虫有所延长,而成虫寿命较以对照叶片饲喂时显著缩短了30.09%,总生命历期显著缩短了18.83%。表明金龟子绿僵菌促进了紫花苜蓿植株的生长,同时增强了植株对苜蓿斑蚜的耐害性、排趋性与...     

Virus transmission by aphids in potato crops

This paper reviews the contribution of vector activity and plant age to virus spread in potato crops. Determining which aphid species are vectors is particularly important for timing haulm destruction to minimize tuber infection by potato virus Y (PVY). Alate aphids of more than 30 species transmit PVY, and aphids such asRhopalosiphum padi, that migrate in large numbers before flights of the more efficient vector,Myzus persicae, appear to be important vectors. Differences in methodology, aphid biotypes and virus strains prevent direct comparisons between estimates of vector efficiencies obtained for aphids in different countries in north western Europe. M. persicae is also the most efficient vector of potato leafroll virus (PLRV), but some clones ofMacrosiphum euphorbiae transmit PLRV efficiently toNicotiana clevelandii and potato test plants. The removal of infected plants early in the season prevents the spread of PLRV in cool regions with limited vector activity. The proportion of aphids acquiring PLRV from infected potato plants decreases with plant age, and healthy potato plants are more resistant to infection later in the season. Severe symptoms of secondary leafroll developed on progeny plants of cv. Maris Piper derived from mother plants inoculated with PLRV in June or July of the previous year. Progeny plants derived from mother plants inoculated in August showed only mild symptoms, but the concentration of PLRV in these plants was as high as that in the plants with severe symptoms.     

不同寄主植物上烟蚜DNA多态性的RAPD-PCR分析

用ＲＡＰＤ－ＰＣＲ技术研究了桃树,油菜和烟草上烟蚜的ＤＮＡ多态性。结果表明,用相似性指数和Ｎｅｉ的遗传距离及聚类分析对本研究筛选的三个引物ＯＰＸ－０４,ＰＯＸ－０６和ＯＰＸ－１９的扩增结果进行比较,除ＯＰＸ－０６的Ｄ值聚类可将各寄主植物上的烟蚜分开外,其余均可将样本分为两类,即来自桃树的烟蚜和来自油菜,烟草上的烟虾。     

Comparison ofPotato Virus Y andPlum Pox Virus transmission by two aphid species in relation to their probing behavior

Two different aphid species,Myzus persicae (Sulzer) andHyalopterus pruni (Geoffroy) (Homoptera: Aphididae), were used to analyze their ability to transmit two different potyviruses,Potato virus Y (PVY) andPlum pox virus (PPV), to pepper (Capsicum annuum) andNicotiana benthamiana plants, respectively. In parallel experiments,M. persicae consistently transmitted both viruses with high efficiency, whereasH. pruni always failed to transmit either virus. This is in contrast to previous reports describingH. pruni as a vector of these potyviruses. Different aphid probing behavior among individual aphids of each species was obtained in electrical penetration graph (EPG) experiments performed on pepper plants. This suggested thatH. pruni did not transmit these potyviruses due to behavioral differences during probing that impeded virus acquisition and/or inoculation. It was found thatM. persicae usually makes its first probe within the first 2 min, whereasH. pruni individuals remained for more than 10 min on the plant before starting to probe. Furthermore,M. persicae individuals displayed their first intracellular puncture during the first minute of probing whereasH. pruni needed ∼ 15 min to penetrate the cell plasmalemma with their stylets. In addition, intracellular stylet punctures occurred very frequently forM. persicae but was a rare event, never exceeding a single one, forH. pruni. The relevance of these findings for the epidemiological spread of potyviruses by different aphid species is discussed. http://www.phytoparasitica.org posting May 14, 2006.     

Seasonal abundance and spatial distribution of the predator<Emphasis Type="Italic">Macrolophus costalis</Emphasis> and its prey<Emphasis Type="Italic">Myzus persicae</Emphasis> on tobacco

Field studies were conducted to assess the population and the spatial dynamics of the predatory bugMacrolophus costalis Fieber (Hemiptera: Miridae) and of its prey, the aphidMyzus persicae (Sulzer) (Hemiptera: Aphidoidea), on tobacco. From an untreated tobacco field in Tithorea (central Greece), tobacco leaves were collected from the upper and the lower half of the plants from June until September, in 1999 and 2000. The numbers ofM. costalis andM. persicae individuals per leaf were counted. Most aphids were observed during July and August (early and mid season), with densities dropping markedly in September. In contrast,M. costalis population densities increased late in the season (September). Significantly higher numbers of aphids were found on the upper half of the plants than on the lower half. In contrast, significantly moreM. costalis individuals were observed on the lower half. Iwao’s Regression Analysis was used in order to characterize the spatial pattern of the two species. According to this model, in both sampling seasons, aphids andM. costalis nymphs displayed an aggregated spatial pattern, whileM. costalis adults were found to be randomly distributed among sampling units. Although moreM. costalis individuals were recorded on leaves with relatively high aphid densities, this species did not react numerically to changes in prey density. In addition, a significant number of bugs were found on leaves with low aphid densities or no aphids at all. http://www.phytoparasitica.org posting Dec. 18, 2002.