Decreased preference and reproduction, and increased mortality of Frankliniella occidentalis on thrips-resistant pepper plants

The effect of thrips resistance in pepper (Capsicum annuum L.) – previously shown to result in impeded thrips population development (Maris PC, Joosten NN, Goldbach RW & Peters D (2003a) Restricted spread of Tomato spotted wilt virus in thrips‐resistant pepper. Phytopathology 93: 1223–1227. Maris PC, Joosten NN, Goldbach RW & Peters D (2003b) Spread of Tomato spotted wilt virus and population development of Frankliniella occidentalis in pepper resistant to thrips. Proceedings of the Section Experimental and Applied Entomology Netherlands Entomological Society (NEV) Amsterdam 14: 95–101.) – on thrips’[Frankliniella occidentalis Pergande (Thysanoptera: Thripidae)] reproduction, mortality, host preference, and behaviour was investigated. Reproduction, studied by oviposition and larval survival, was negatively affected by the thrips‐resistant (TR) phenotype, whereas the offspring's developmental rate did not differ on TR and the thrips‐susceptible (TS) phenotype. While thrips’ behaviour was hardly affected by thrips resistance, a significant preference for TS plants over the TR plants was found in different tests. When released on either a TR or a TS plant, thrips dispersed at significantly higher rates from the TR plants, demonstrating that not only an impeded reproduction, but also a reduced residence time adds to the reported lower thrips numbers on TR plants.     

光谱和光强度对西花蓟马雌虫趋光行为的影响

利用行为学方法研究了光谱、光强对西花蓟马Frankliniella occidentalis (Pergande)雌成虫的趋、避光行为的影响。结果显示：（1）在340~605nm波谱内14个波长其光谱趋光行为反应为多峰型,峰间主次较明显。趋光行为反应中,蓝绿区498~524nm有一较宽峰,趋光率20.31%;其它各峰依大小次序分别位于紫光380nm、蓝光440nm;（２）避光行为反应中,蓝光440nm处略高,避光率17.19%;紫外340nm处亦有一峰,避光率15.63%;（３）随光强增强其趋光反应率增大,白光、380nm和524nm刺激时其光强趋光行为反应呈一倒“L”型式样,498nm为峰型,440nm时为一较缓的平直线型;光强最弱时仍均有一定趋光率 ,最强时均未出现高端平台;（４）随光强增强其避光反应率增大,440nm为较平缓直线;340nm刺激时为较缓波动线。结果表明：光谱对其趋光行为有很大影响,光强度的影响较大且影响大小与波长因素有关。     

温度对西花蓟马(Frankliniella occidentalis)生长发育和存活率的影响

在15、20、25℃和30℃,RH75％的条件下,分析了温度与西花蓟马发育速率的关系,并测定了西花蓟马的发育起点温度、有效积温和存活率。结果表明：在15～30℃范围内,西花蓟马各虫期的发育速率随温度的升高而加快;用直接最优法对发育起点温度和有效积温进行估算,求得西花蓟马的卵、若虫、预蛹和伪蛹及世代发育起点温度分别为5．70、7．04、4．49、6．84℃和6．23℃;世代的有效积温为219．73d·℃。西花蓟马的世代存活率在25℃时最高,为40．12％;30℃时西花蓟马的存活率最低,为17．80％。     

西花蓟马诱导的番茄植株防御反应对B型烟粉虱行为的影响

【目的】明确外来入侵害虫西花蓟马Frankliniella occidentalis (Pergande)取食诱导的番茄植株防御反应对B型烟粉虱Bemisia tabaci (Gennadius) B-biotype行为的影响, 探讨西花蓟马与B型烟粉虱的种间竞争机制。【方法】利用“Y”型嗅觉仪行为分析法、 选择性试验法, 研究了不同处理组合（健康植株CK vs烟粉虱为害植株B、 健康植株CK vs西花蓟马为害植株F、 烟粉虱为害植株B vs烟粉虱和西花蓟马共同为害植株B+F）下, 烟粉虱对不同处理植株的取食行为反应及寄主偏好的差异性, 并利用GC-MS分析了不同处理植株挥发性物质的差异性。【结果】“Y”型嗅觉仪行为分析结果表明, 在CK vs B和CK vs F两个组合中, 烟粉虱雌成虫对健康植株和昆虫为害植株的偏好性差异不显著; 而在B vs B+F组合中, 烟粉虱为害株对烟粉虱雌成虫具有极显著的引诱作用（P<0.01）。选择性试验结果表明, 在CK vs B和CK vs F这两个组合中, 烟粉虱成虫均偏好健康株并喜好在其上产卵（P<0.01）, 在B vs B+F组合中, 烟粉虱成虫偏好烟粉虱单独为害株并喜好在其上产卵（P<0.01）。GC-MS分析结果显示, 本实验收集到9种挥发性物质, 其中有5种烯萜类物质, 其相对含量高达90%以上。与烟粉虱单独为害株相比, 烟粉虱和西花蓟马共同为害株所释放的挥发性物质中, 对烟粉虱具有排斥作用的β-水芹烯显著升高, 而对其具有吸引作用的β-月桂烯却显著减少。【结论】综合分析认为, 西花蓟马诱导的番茄植株防御反应可以显著影响B型烟粉虱的寄主选择行为及产卵选择性。     

外源茉莉酸诱导菜豆对西花蓟马和南方小花蝽的行为反应

【目的】为明确茉莉酸诱导的菜豆对西花蓟马Frankliniella occidentalis和南方小花蝽Orius similis的行为反应。【方法】采用四臂嗅觉仪测定了西花蓟马和南方小花蝽对不同浓度茉莉酸诱导菜豆后的行为反应,并用气相色谱-质谱联用仪测定了不同浓度茉莉酸处理后菜豆挥发物的成分。【结果】不同浓度茉莉酸处理的菜豆植株对西花蓟马和南方小花蝽分别有不同程度的驱避和吸引作用,以1 mmol/L的茉莉酸处理植株对西花蓟马的驱避作用最强,0.1 mmol/L的茉莉酸处理植株对南方小花蝽的吸引作用最强。不同处理菜豆的挥发物在含量和成分上存在显著差异,(Z)-3-己烯丙酸酯、2-异丙基-甲氧基毗嗦只有在茉莉酸处理植株中检测到。结合不同浓度茉莉酸处理植株对西花蓟马和南方小花蝽的行为反应及菜豆挥发物含量的变化趋势,推测(E)-2-己烯醛对西花蓟马有驱避作用,(E)-2-乙酸叶醇酯对南方小花蝽具有引诱作用。【结论】茉莉酸处理菜豆后,植物挥发物种类和含量发生了变化,在增强菜豆植株抗虫性的同时,还可增强捕食性天敌南方小花蝽的搜索和捕食能力。     

CO2浓度升高对西花蓟马和花蓟马成虫体内解毒酶和保护酶活性的影响

【目的】阐明大气CO₂浓度升高对外来入侵昆虫西花蓟马Frankliniella occidentalis及其本地近缘种花蓟马F. intonsa的影响机制。【方法】测定和分析了CO₂人工气候箱内不同CO₂浓度（400 μL/L和800 μL/L）下饲养3代的这两种蓟马体内3种解毒酶［羧酸酯酶（CarE）、乙酰胆碱酯酶（AchE）和微粒体多功能氧化酶(MFO）］和3种保护酶［超氧化物歧化酶(SOD)、过氧化氢酶(CAT)和过氧化物酶(POD）］的活性。【结果】西花蓟马成虫体内的CarE, AchE, MFO, CAT和POD酶活性随着CO₂浓度的升高而显著上升（P＜0.05）,其中800 μL/L CO₂浓度下CarE和MFO酶活性分别比400 μL/L CO₂浓度下增加了24.78%和16.05%;800 μL/L CO2浓度下花蓟马成虫体内的CarE, MFO和CAT酶活性显著高于400 μL/L CO₂浓度下花蓟马成虫体内的相应酶活性,而AchE和POD酶活性在两种CO2浓度间差异不显著（P＞0.05）。800 μL/L CO₂浓度下西花蓟马和花蓟马成虫体内的SOD酶活性均显著低于400 μL/L CO₂浓度下的相应蓟马酶活性（P＜0.05）,分别下降了65.22%和42.20%。【结论】CO₂浓度升高是导致两种蓟马成虫体内CarE,MFO和SOD酶活性上升的主要原因,而AchE, CAT和POD酶活性的变化主要受蓟马种类的影响。两种蓟马可能通过改变体内解毒酶或保护酶的活性来适应高浓度CO₂的环境。     

西花蓟马取食不同豆科蔬菜的实验种群生命表

西花蓟马Frankliniella occidentalis(Pergande)是传入我国的重要入侵害虫,在贵阳地区对豆科蔬菜为害十分严重。在25℃条件下,组建了西花蓟马取食大豆叶片、豇豆叶片、四季豆叶片和四季豆豆荚时的实验种群生命表。结果表明:西花蓟马未成熟期取食四季豆豆荚时存活率最高,取食其它3种豆科蔬菜时存活率相差不大。西花蓟马取食四季豆豆荚时内禀增长力最高为0.1626,取食豇豆叶片时最低为0.0834,净增值率也是取食四季豆豆荚时最高,取食大豆叶片时最低,表明四季豆豆荚最有利于西花蓟马的生长发育和繁殖。在不同豆科蔬菜上的稳定年龄组配中未成熟期所占的比例很大,而成虫期所占的比例相对较小。     

Cadmium hyperaccumulation protects Thlaspi caerulescens from leaf feeding damage by thrips (Frankliniella occidentalis)

Metal hyperaccumulation has been proposed as a plant defensive strategy. Here, we investigated whether cadmium (Cd) hyperaccumulation protected Thlaspi caerulescens from leaf feeding damage by thrips (Frankliniella occidentalis). Two ecotypes differing in Cd accumulation, Ganges (high) and Prayon (low), were grown in compost amended with 0-1000 mg Cd kg(-1) in two experiments under glasshouse conditions. F2 and F3 plants from the Prayon x Ganges crosses were grown with 5 mg Cd kg(-1). Plants were naturally colonized by thrips and the leaf feeding damage index (LFDI) was assessed. The LFDI decreased significantly with increasing Cd in both ecotypes, and correlated with shoot Cd concentration in a log-linear fashion. Prayon was more attractive to thrips than Ganges, but the ecotypic difference in the LFDI was largely accounted for by the shoot Cd concentration. In the F2 and F3 plants, the LFDI correlated significantly and negatively with shoot Cd, but not with shoot zinc (Zn) or sulphur (S) concentrations. We conclude that Cd hyperaccumulation deters thrips from feeding on T. caerulescens leaves, which may offer an adaptive benefit to the plant.     

Plants protect their roots by alerting the enemies of grubs

Plant roots in the soil are under attack from many soil organisms. Although many ecologists are aware of the presence and importance of natural enemies in the soil that protect the plants from herbivores, the existence and nature of tritrophic interactions are poorly understood. So far, attention has focused on how plants protect their above-ground parts against herbivorous arthropods, either directly or indirectly (i.e. by getting help from the herbivore's enemies). This article is the first in showing that indirect plant defences also operate underground. We show that the roots of a coniferous plant ( Thuja occidentalis ) release chemicals upon attack by weevil larvae ( Otiorhynchus sulcatus ) and that these chemicals thereby attract parasitic nematodes ( Heterorhabditis megidis ).     

The spread of the western flower thrips Frankliniella occidentalis (Pergande)

Abstract 1 Since the late 1970s, the western flower thrips has spread from its original distribution in western North America to become a major worldwide crop pest. 2 A wide range of data sources have been used to map the original distribution in the U.S.A. and Canada, and the progress of the spread in the U.S.A., Canada, Europe, northern Africa and Australia. 3 The possible reasons for the start of the spread are discussed. The most likely reason is that intensive insecticide use in horticulture in the 1970s and 1980s selected an insecticide resistant strain or strains. These then established in glasshouses across North America and spread from there to Europe, Asia, Africa and Australia. 4 The international spread of the western flower thrips occurred predominantly by the movement of horticultural material, such as cuttings, seedlings and potted plants. Within Europe, an outward spread from the original outbreak in the Netherlands is discernible. The speed of spread was 229 ± 20 km/year. 5 The spread has not been restricted to glasshouses. The western flower thrips has established outdoors in areas with milder winters; for example, across the southern U.S.A., southern Europe and Australia. It also overwinters in some regions with colder winters. 6 Polyphagous phytophagous thrips have many factors predisposing them to become worldwide crop pests, particularly in glasshouses. Some other species that might spread in a similar way to the western flower thrips are listed.