Q型烟粉虱成虫传播番茄褪绿病毒的能力

为明确Q型烟粉虱Bemisia tabaci成虫对番茄褪绿病毒(Tomato chlorosis virus,ToCV)的传毒特征,应用RT-PCR技术检测了ToCV在Q型烟粉虱成虫体内的存留时间、Q型烟粉虱成虫对ToCV的获毒效率及传毒效率。结果表明,Q型烟粉虱成虫离开带毒番茄植株后,其带毒率随时间的延长逐渐降低,最初为85.73%,96 h后仅为17.14%。在相同温度下,Q型烟粉虱成虫的获毒率先随着取食时间的延长而提高,而后处于相对稳定状态,当温度为21、26、31℃时,Q型烟粉虱成虫获毒率达到峰值的时间分别为72、48、6 h,最高获毒率分别为56.52%、54.17%和61.64%。当温度为26℃时,Q型烟粉虱成虫的传毒效率随着取食时间的延长而提高,取食时间为0.5 h时,番茄植株带毒率为25.00%,取食时间为48 h时,番茄植株带毒率达91.67%;温度对Q型烟粉虱成虫的传毒效率有极显著影响,取食48 h后,在21~31℃条件下番茄植株带毒率为83.33%~91.67%,在16℃条件下仅为16.67%。表明Q型烟粉虱成虫对ToCV具有较强的获毒和传毒能力,对其进行有效控制可以防止ToCV的扩散和蔓延。     

烟粉虱取食感染TYLCV番茄对其解毒酶和保护酶活性的影响

为了明确感染番茄黄化曲叶病毒(Tomato yellow leaf curl virus,TYLCV)的番茄对烟粉虱生理防御的影响,本文采用生化分析法研究了烟粉虱取食感染TYLCV的番茄植株后解毒酶和保护酶活性的变化。结果表明,B型烟粉虱在带毒番茄上取食72h及30d(长期饲养种群)后,其谷胱甘肽S-转移酶(GSTs)和羧酸酯酶(CarE)活性呈现先升高后下降的趋势,而P450酶活性则持续上升,取食30d种群是对照种群的1.99倍;三大保护酶系超氧化物歧化酶(SOD)、过氧化氢酶(CAT)、过氧化物酶(POD)则在取食72h后,酶活性高于对照,而在感染TYLCV番茄上取食30d后,保护酶活性则持续高于72h及对照处理,分别是对照种群的1.45倍、8.42倍和5.03倍,差异显著;Q型烟粉虱表现趋势与B型烟粉虱相似。研究结果为进一步明确入侵烟粉虱与双生病毒之间的互作、揭示烟粉虱的适应性机制等补充了资料。     

番茄黄化曲叶病毒与番茄褪绿病毒复合侵染对番茄黄化曲叶病毒传播的影响

番茄黄化曲叶病毒(tomato yellow leaf curl virus, TYLCV)是一种由烟粉虱传播的单链环状DNA病毒, 在田间可与多种病毒发生复合侵染, 如番茄褪绿病毒(tomato chlorosis virus, ToCV)等?本文对比了TYLCV单独侵染和TYLCV与ToCV复合侵染对烟粉虱获取和传播TYLCV的影响?结果表明, 与取食TYLCV单独侵染的番茄相比, 取食复合侵染番茄的烟粉虱对TYLCV的传毒率显著提高, 且番茄植株和烟粉虱体内TYLCV的病毒积累量也显著提高?试验结果说明复合侵染会提高烟粉虱的传毒率, 促进TYLCV的发生与流行?     

B型烟粉虱携带传播烟草曲茎病毒的能力

B型烟粉虱近20年来入侵许多国家和地区,已成为重要的世界性作物害虫,其主要危害方式之一是传播双生病毒,造成作物病毒病大发生.应用PCR技术,研究了入侵我国的B型烟粉虱个体获取、存留及传播烟草曲茎病毒（Tobacco curly shoot virus,TbCSV）的能力.B型烟粉虱在感染TbCSV的普通烟毒株上饲毒30 min时,就可在40%的个体内检测到TbCSV DNA,个体带毒率随饲毒时间延长而增加,饲毒12 h后,带毒率达100%;TbCSV DNA在B型烟粉虱体内可存留10天左右,但不能终身存留;传毒处理植株的发病症状及PCR检测结果表明,B型烟粉虱是TbCSV的传播媒介.     

山东寿光地区Q型烟粉虱对番茄褪绿病毒的传播

为明确山东寿光地区Q型烟粉虱对番茄褪绿病毒(Tomato chlorosis virus,To CV)感病流行的影响及其传毒特性,于2014年调查了该地区设施番茄上烟粉虱种群动态与To CV发病情况,利用特异引物对烟粉虱体内To CV进行了RT-PCR检测;并在室内测定了带毒Q型烟粉虱取食时间和种群数量对To CV感病株率的影响。结果表明,在番茄发病植株上采集的烟粉虱种群体内可检测到To CV;春茬番茄To CV发病株率随烟粉虱种群数量增加而逐渐升高,4—6月是To CV发生高峰期,6月22日发病株率达100%;秋茬番茄烟粉虱种群数量从10月下旬明显下降,而To CV发病株率升高,11月12日发病株率达100%;室内试验表明,To CV感病株率随着带毒Q型烟粉虱数量与取食时间的增加而明显升高。研究表明,Q型烟粉虱能有效传播To CV,且其种群数量对To CV发病株率存在显著影响,可通过防控烟粉虱以控制To CV的危害。     

不同种植环境夏番茄上烟粉虱及其优势天敌的种群动态

为明确不同种植环境番茄田中烟粉虱及其天敌的发生规律,于云南省元谋县番茄种植区选取露地和大棚番茄田,采用五点取样法进行系统调查,并使用时间生态位指数和灰色关联度指数分析烟粉虱及其优势天敌在时空上的跟随关系。结果表明：露地番茄田中烟粉虱若虫和成虫的种群密度均高于大棚番茄田。在整个调查期内大棚番茄田中雌性烟粉虱占比均显著高于露地番茄田。露地和大棚番茄田中烟粉虱若虫在番茄植株中部叶片的种群密度均最高,烟粉虱成虫在植株上部叶片的种群密度均最高。两种番茄田中烟粉虱的优势天敌均包括烟盲蝽、六斑月瓢虫、丽蚜小蜂和海氏桨角蚜小蜂,其中露地番茄田中优势天敌还包括异色瓢虫,且露地番茄田中优势天敌的种群密度均高于大棚番茄田。露地番茄田中天敌与烟粉虱的个体数量益害比均大于大棚番茄田。在露地和大棚番茄田中,六斑月瓢虫与烟粉虱的时间生态位重叠指数均最大,其值分别为0.96和0.99,六斑月瓢虫与烟粉虱的空间跟随关系最密切,其灰色关联度值分别为0.33和0.36。针对烟粉虱的聚集习性,在防治时可以重点防治烟粉虱聚集的植株中部和上部。露地番茄田中烟粉虱自然天敌资源丰富应加以保护,同时在大棚内烟粉虱发生早期释放优势天敌创...     

日光温室番茄褪绿病毒病的发生规律及其与Q型烟粉虱种群动态关系

为有效控制日光温室番茄褪绿病毒病,于2014—2015年通过RT-PCR检测方法研究了济南市日光温室番茄褪绿病毒(Tomato chlorosis virus,ToCV)的发生规律、其与Q型烟粉虱Bemisia tabaci种群动态的关系及防虫网对该病毒病的防控效果。结果表明,春季日光温室番茄植株上Q型烟粉虱成虫数量呈增长趋势,5月下旬最高达到0.10头/叶,秋季日光温室番茄植株上Q型烟粉虱成虫数量9月上旬达最高7.42头/叶,后逐渐下降;日光温室Q型烟粉虱带毒率随着定植时间的延长而逐渐上升,之后维持相对稳定状态,即春季为20.00%~24.14%,秋季为30.00%~40.00%。日光温室ToCV发生与Q型烟粉虱成虫数量和带毒率密切相关,春季番茄最高发病率为12.00%;秋季番茄植株最高发病率为93.02%。番茄育苗和生长期用100目防虫网隔离可显著降低番茄植株带毒率。因此,秋季是日光温室ToCV防控关键期,覆盖防虫网阻隔烟粉虱可有效防治ToCV,推荐在日光温室使用。     

携带TYLCV的B型和Q型烟粉虱对非传毒寄主的选择差异

<正>烟粉虱Bemisia tabaci寄主范围广、适应性强,可通过直接取食、分泌蜜露和传播植物病毒危害蔬菜和园艺作物。目前,B型和Q型烟粉虱是国内发生的主要生物型,也是传播番茄黄化曲叶病毒(Tomato yellow leaf curl virus,TYLCV)的主要媒介。TYLCV不仅影响B型和Q型烟粉虱取食行为、生殖和寿命,而且影响其对传毒寄主的选择(卫静等,2015)。烟粉虱对适宜寄主的准确选择有利于其种     

番茄褪绿病毒病在山东设施西葫芦上的发生及潜在危害

番茄褪绿病毒tomato chlorosis virus (ToCV)是我国蔬菜生产的重要新发病毒,其寄主范围逐年扩大。2019年10月项目组在山东寿光西葫芦温室调查时发现部分叶片呈现黄化、脉间褪绿,类似于ToCV侵染症状,并伴有烟粉虱发生。利用特异性引物检测发现,扩增的目的片段与GenBank中登录的侵染番茄的ToCV基因序列(登录号：KC887998.1)同源性高达99.58%,充分说明西葫芦植株已被ToCV侵染。通过对病毒病发生规律和烟粉虱虫口数量调查发现,西葫芦定植后1个月表现侵染症状的植株为2.0%,定植后2个月达到4.2%,定植后4个月后高达68.2%,病毒发生呈指数增长,而烟粉虱虫口数量却维持较低密度。从济南和德州采集的西葫芦疑似病叶和烟粉虱中也检出ToCV病毒,说明该病毒可能已经在山东省设施西葫芦主要种植区普遍发生,并经烟粉虱广泛传播,需引起高度重视。     

L-阿拉伯糖对B型和Q型烟粉虱毒性及取食行为的影响

为明确L-阿拉伯糖对B型和Q型烟粉虱毒性及其取食行为的影响,调查了饲喂含有L-阿拉伯糖人工饲料后烟粉虱的死亡率,利用刺吸电位技术(EPG)记录其取食行为,并观察了饲喂后其在人工饲料膜上的刺孔数量及直径。结果表明,B型和Q型烟粉虱的校正死亡率均随L-阿拉伯糖浓度及饲喂时间的增加而升高;在3种浓度下,B型烟粉虱校正死亡率均显著高于Q型烟粉虱;在5%、10%浓度下,Q型烟粉虱校正死亡率分别在第5天和第3天达100%,B型烟粉虱分别在第3天和第2天达到100%;5%L-阿拉伯糖对B型烟粉虱取食行为影响比Q型大;在5%浓度下,B型和Q型烟粉虱在膜上的刺孔数量总体少于对照组。研究表明,L-阿拉伯糖对烟粉虱具有杀虫活性,且对B型和Q型烟粉虱的毒性效果不同。     

寄生Q型烟粉虱的丽蚜小蜂生长发育特性

为了阐明丽蚜小蜂Encarsia formosa对Q型烟粉虱的寄生特性及寄主植物携带病毒对其寄生的影响,采用微虫笼饲养法研究了寄生Q型烟粉虱的丽蚜小蜂生物学特性。结果显示,丽蚜小蜂寄生Q型烟粉虱3龄若虫时,其生长发育显著优于寄生Q型烟粉虱2龄若虫。丽蚜小蜂在感染黄化曲叶病毒（TYLCV）番茄和健康番茄上寄生Q型烟粉虱（分别为VW和NVW）3龄若虫时,其生长发育特性发生了明显变化。丽蚜小蜂以VW若虫为寄主时的寿命为10.25 d,显著长于寄生NVW的丽蚜小蜂寿命（5.90 d）;对VW和NVW后代3龄若虫的寄生率分别为23.81%和17.62%,致死率分别为38.95%和26.52%,差异均显著;而丽蚜小蜂的羽化率和发育历期不存在显著差异。说明丽蚜小蜂寄生Q型烟粉虱3龄若虫时更适宜其生长发育,寄主植物番茄携带TYLCV显著提高丽蚜小蜂对烟粉虱的寄生效果。     

The virus-vector relationship of the tomato leafcurl virus (TLCV) and its vector,Bemisia tabaci gennadius (Hemiptera: aleyrodidae)

Basic studies carried out in India showed that the incubation period of TLCV in plants varied from 8 days in August to 90 days in winter. The acquisition threshold for the whitefly,Bemisia tabaci Gen., was 31 min; it resulted in 3% transmission. An acquisition access of 24 h for a female whitefly on a TLCV source resulted in 30% transmission. A minimum feeding period of 32 min was required by a viruliferous whitefly to cause infection on tomato test plants; this gave 4% transmission. With inoculation access of 24 h on tomato test plants, the transmission rose to 24%. Starving the vector for 1 h pre-acquisition or 1 h pre-inoculation resulted in higher levels of transmission of TLCV: 36 and 40%, respectively, compared with 20% for non-starved whiteflies. Extending the fasting period beyond 1 h resulted in a reduced transmission level. The whiteflies could acquire the virus from the cotyledonary leaves of an infected tomato plant, with a resultant 28% transmission; but infection did not occur when the whiteflies had an inoculation access to such leaves. Higher transmission rates were obtained when the younger leaves on tomato plants were used for acquisition and inoculation. Transmission was 8 and 38% when five whiteflies per plant were allowed 24 h of acquisition access to 11- and 2-month-old virus sources, respectively. After an acquisition access of 24 h to a TLCV source, male and female whiteflies retained their infectivity for 5 and 53 days, respectively. Nymphs can acquire and transmit the virus. When ten whiteflies of each sex were given 24 h of acquisition and of inoculation access, the subsequent transmission rate of males and females was 56 and 86%, respectively. This virus is not transovarially transmitted. Whitefly colonies raised on brinjal were more efficient (70 and 84% transmission in two experiments) than those raised on chilli, cotton, cowpea, tobacco or tomato.     

Transmission of the Pepino mosaic virus by whitefly

Two experiments were conducted to investigate the transmission of the Pepino mosaic virus (PepMV) by the greenhouse whitefly (Trialeurodes vaporariorum) from tomato to tomato. In the 1:1 system (in which a single virus-contaminated plant was placed next to a healthy plant in a cage containing 469 whiteflies on average) the virus was transmitted to three out of 10 plants. In the 1:4 system (in which a virus-contaminated plant was surrounded by four healthy plants in a cage with 601 whiteflies on average) the virus was transmitted to five out of 32 plants. In order to investigate the mechanism involved in the transmission, the insect bodies were washed to determine the external presence of viral particles. The results showed that the number of PepMV particles carried on whitefly bodies was low, with an average occurrence of 1.33 on the 55 whiteflies tested after the insects were in contact with infected plants for 5 days. This low occurrence was confirmed by observation under microscope, which showed an absence of PepMV-contaminated tomato sap on the insect bodies, suggesting that PepMV transmission by whiteflies could occur when they feed on the plant.     

Effect of Cotton leaf curl virus infected plants on the biology of the whitefly,Bemisia tabaci (Hemiptera: Aleyrodidae): Vector–virus mutualism

Cotton leaf curl virus (CLCuV) (Geminiviridae : Begomovirus), the causative agent of leaf curl disease in cotton plants (Gossypium hirsutum), is exclusively transmitted by whitefly species Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae). CLCuV transmission occurs in Sriganganagar (Rajasthan), an area endemic with cotton leaf curl disease. The relationships between plant viruses, their herbivore vectors and host plants can be beneficial, neutral, or antagonistic, depending on the species involved. To further understand these relationships, fecundity and life history parameters of an indigenous non- b (Asia II genetic group) biotype whitefly, B. tabaci, were compared on 10, 25, and 40 days post-inoculation (DPI), in CLCuV-infected and healthy cotton plants to determine the effect of virus on its vector. The development time of the immature stages of whiteflies was significantly reduced on CLCuV-infected plants. The development time of the immature stages did not change with severity of symptoms at 25 and 40 DPI (45- and 60-d-old plants). Cotton leaf curl virus infection increased percent egg viability of B. tabaci. Whiteflies deposited significantly fewer eggs on virus-infected plants than on healthy plants. Whiteflies had better egg viability on younger plants than older plants, whereas plant age did not affect the fecundity. Male and female whiteflies had shorter longevity on CLCuV-infected plants than on healthy plants.     

Potato, an experimental and natural host of the crinivirus Tomato chlorosis virus

Tomato chlorosis virus (ToCV, genus Crinivirus, family Closteroviridae) causes yellowing of tomatoes in many countries worldwide. Symptoms of ToCV infections in tomatoes include inter-veinal yellow chlorotic areas that develop first on lower leaves and then advance towards the upper part of the plant. ToCV is transmitted in nature by the whiteflies Bemisia tabaci, Trialeurodes vaporariorum, and Trialeurodes abutilonea in a semi-persistent manner. In the summer of 2006, a few potato (Solanum tuberosum) volunteer plants heavily infested with the whitefly B. tabaci were found growing within a pepper crop in the province of Málaga, southern Spain. Leaf samples from volunteer plants were tested for the presence of ToCV by molecular hybridization and RT-PCR, and were shown to be infected. Furthermore, potato plants were readily infected by ToCV after experimental transmission using B. tabaci biotype Q as vector. ToCV was also detected in the tubers from infected plants that subsequently produced infected plants. Potato also served as virus source for tomato infection via B. tabaci transmission.     

Pymetrozine interferes with transmission of<Emphasis Type="Italic">Tomato yellow leaf curl virus</Emphasis> by the whitefly<Emphasis Type="Italic">Bemisia tabaci</Emphasis>

Pymetrozine, a novel compound belonging to the class pyridine-azomethines, is a feeding inhibitor labeled for use against plant pests in the order Hemiptera. Pymetrozine was evaluated for its ability to interfere with whitefly transmission of the begomovirusTomato yellow leaf curl virus (TYLCV). Pymetrozine was applied as Fulfill ^TM 50 WG at two rates (0.291 and 0.582 g formulationl ⁻¹) to tomato seedlings with four to six true leaves. Viruliferous whiteflies (three to five per plant) were added 1, 4, 7 and 11 d after a single application of pymetrozine, and transmission rates were determined 4 wk after the addition of whiteflies. Pymetrozine provided protection against transmission of TYLCV by viruliferous whiteflies for up to 1 wk after a single apliation. No phytotoxicity was observed on tomato transplants. These results indicate that pymetrozine could be an effective tool for tomato transplant producers to protect susceptible transplants from infection by begomoviruses, such as TYLCV. Pymetrozine might also work well as part of an integrated approach to begomovirus management in greenhouse tomato fruit production. http://www.phytoparasitica.org positing Oct. 20, 2003.     

Temporal distribution and pathogenicity of the predominant tomato‐infecting begomoviruses in Taiwan

Between 1998 and 2009, the four tomato‐infecting begomovirus species detected in Taiwan were Ageratum yellow vein Hualien virus (AYVHuV), Tomato leaf curl Taiwan virus (ToLCTWV), Tomato yellow leaf curl Thailand virus (TYLCTHV) and a newly defined species Tomato leaf curl Hsinchu virus (ToLCHsV). AYVHuV was detected occasionally in 2003 and ToLCHsV only in 2000–2001, whilst ToLCTWV was detected throughout the period. TYLCTHV was first detected in 2005. Between 1998 and 2005, >99% of the begomovirus‐positive samples were infected with ToLCTWV. In 2007 in western Taiwan, 16% of the positive samples were infected with ToLCTWV, 35% with TYLCTHV and 49% with mixed infection (ToLCTWV/TYLCTHV). In contrast, in eastern Taiwan the proportions were 84% ToLCTWV, 2% TYLCTHV and 14% mixed infection. However, throughout Taiwan in 2008–2009, most positive samples were either identified as TYLCTHV (51%) or mixed infection (ToLCTWV/TYLCTHV; 41%), and only 8% were ToLCTWV. This shows a clear trend of shifting from ToLCTWV to TYLCTHV and mixed infection over a short time period in Taiwan. Sequence analyses indicated that tomato‐infecting AYVHuV, an apparent recombinant between ToLCTWV and AYVHuV from Ageratum, represents a new strain Hsinchu. TYLCTHV Taiwan isolates were highly similar to each other, whereas ToLCTWV isolates had greater diversity and were classified into three strains which had one country‐wide and two local distributions. ToLCTWV and TYLCTHV were confirmed as monopartite and bipartite begomoviruses, respectively, by agroinfection followed by transmission with Bemisia tabaci biotype B. In addition, TYLCTHV was found to be mechanically transmissible together with viral DNA‐B.     

巨大芽胞杆菌CJLC2菌株对盐胁迫下番茄生长及耐盐生理生化指标的影响

为增强番茄耐盐能力,采用菌液浸种、灌根以及蒽酮比色和钼锑抗显色等方法,研究巨大芽胞杆菌Bacillus megaterium CJLC2菌株增强番茄耐盐能力的效果及其作用机制。在非NaCl胁迫条件下,CJLC2菌株显著促进番茄的生长,对根长、株高和鲜重的促生率分别为14.33%、9.20%和17.75%。在NaCl胁迫条件下,随NaCl浓度增加对番茄的生长抑制作用增大,而CJLC2菌株在一定程度上提高了番茄对NaCl耐受能力。其中,番茄对100 mmol/L NaCl的耐受能力显著提高,加菌处理对根长、株高和鲜重的促生率分别为17.05%、18.04%和15.81%。CJLC2菌株可提高番茄叶片可溶性糖和可溶性蛋白含量,在200 mmol/L NaCl处理时效果显著,分别提高了40%和41%。CJLC2菌株还影响番茄矿物质元素的含量,其中在100 mmol/L NaCl胁迫下,加菌处理番茄根系磷、钾、铁、铜和锌的含量以及K⁺/Na⁺比值分别提高190%、12.88%、6.80%、34.78%、10.17%和50.72%,而根系钠的含量降低25.11%。此外,CJLC2菌株可降低受害番茄乙烯的含量。研究表明,巨大芽胞杆菌CJLC2菌株通过提高番茄耐盐相关生理生化指标,增强番茄的耐盐能力并促进其生长。