粘虫核型多角体病毒在同源寄主细胞系内复制的研究

对MsNPV在同源寄主细胞系NEAU Ms 94 7311内复制进行了研究。结果表明 ,接种MsNPV后 72h ,细胞核内开始有成熟的多角体形成 ,病毒接种后 2 4 0h感染率最大 ,达 36.2 % ,至2 64h多角体完全成熟 ,达 2 5.0PIB/感染细胞。病毒增殖曲线表明 ,接毒后 2 4h在培养基中开始检测出MsNPV NOV ,2 4 0h滴度达最大值 ,为 6.32× 10 5TCID50 /mL。病毒连续传代至第 7代或第 8代以后 ,其感染率、病毒滴度及多角体产量均有显著下降。     

文山松毛虫质型多角体病毒杀虫剂的研制

报道了文山松毛虫质型多角体病毒杀虫剂的研制 ,包括多角体的纯化、辅助剂的筛选、剂型研制、产品包装以及病毒杀虫剂的产品质量检测及生产等。该杀虫剂为乳剂 ,多角体浓度达 2 .5×10 9PIB/mL ;所选辅助剂取材方便、容易配制 ,对环境没有污染。经安全检测证明 ,无致病菌 ,符合国家卫生标准 ,对试验动物小白鼠无毒性和致病性。生物测定用 1× 10 6PIB/mL感染 2龄文山松毛虫幼虫 ,其死亡率平均为 85 .5 %     

茶尺蠖病毒杀虫剂田间使用技术的研究

茶尺蠖病毒杀虫剂应在每年茶尺蠖第1、2代和第5、6代的1～2龄幼虫期使用.在7.5×109 ～ 15.0×109 PIB/hm2的使用剂量下,幼虫期的防治效果可达98%以上.采用不同的喷雾器、不同的用水量及不同的喷施方式喷施,对防治效果无影响.但挑治和丛面喷施可大幅度节约防治成本费.     

茶尺蠖病毒杀虫剂田间使用技术的研究

茶尺蠖病毒杀虫剂应在每年茶尺蠖第1、2代和第5、6代的1～2龄幼虫期使用。在7.5×10~9～15.0×10~9PIB/hm~2的使用剂量下,幼虫期的防治效果可达98％以上。采用不同的喷雾器、不同的用水量及不同的喷施方式喷施,对防治效果无影响。但挑治和丛面喷施可大幅度节约防治成本费。     

根据中肠病变程度估计松毛虫CPV产量和采收时机

将感染质型多角体病毒的松毛虫中肠分为四种类型 ,研究各型所占比例与病毒产量间的关系 ,结果显示单位虫重的病毒产量随Ⅰ、Ⅱ类比例的增大而增高 ,Ⅰ、Ⅱ类比例为 2 1% - 80 %时 ,每公斤虫的病毒产量为 5.59× 10 10 PIB - 55.2 1× 10 10 PIB ,适宜的采收时机为Ⅰ、Ⅱ类比例为 60 % -80 %时 ,此时采收 ,每公斤虫可产出质型多角体病毒 37.2 1× 10 10 PIB～ 55.2 1× 10 10 PIB     

思茅松毛虫生物学特性与防治研究

思茅松毛虫是福建省高海拔地区危害马尾松的重要害虫之一 ,该虫在福建一年发生 2代 ,以幼虫越冬。林间试验表明 ,选用复合生物杀虫剂 DCPV 5× 10 7PIB/ ml+苏云金杆菌 1.6× 10 7个孢子 / ml+白僵菌 1.2×10 5个孢子 / ml对该虫有良好的防治效果 ,林间大面积预防性防治可施放白僵菌粉炮 ,严重发生林分可施放林丹烟剂     

体外组织培养增殖的油桐尺蠖核型多角体病毒毒力的生物测定

活体增殖和体外组织培养增殖的BsNPV悬液稀释成不同浓度,分别喷于人工饲料上,使其自然渗入饲料内,接3龄幼虫取食感染,感染剂量与幼虫死亡率的回归直线方程分别为;y=3.1815+0.679x和y=3.2000+0.665x,由回归直线方程推算的LD_(50)值及95％置信界限为4.0753×10~2[9.6075×10~2][1.7301×10~2]PIB/克饲料及5.0898×10~2[1.2411×10~3][2.0874×10~2]PIB/克饲料。感染剂量为4×10~5PIB/克饲料的LT_(50)值分别为4.7168天和4.8083天。比较两种来源的BsNPV,其多角体的感染力无明显差异。     

荧光增白剂Tinopal LPW对蜀柏毒蛾核型多角体病毒增效作用研究

用1%TinopalLPW荧光增白剂作为蜀柏毒蛾核型多角体病毒增效剂对蜀柏毒蛾2龄幼虫进行室内毒力测定,结果表明1%Tinonal LPW对Parocneria orienta NPV有较强的增效作用.使用3.6×1011PIB/hm2+1%TinopalLPW、1.8×1011PIB/hm2+ 1%TinopalLPW、9.0×1010PIB/hm2+1%TinopalLPW和3.6×1011PIB/hm2、1.8×1011PIB/hm2、9.0×1010PIB/hm26种处理对林间越冬代2-3龄幼虫进行超低容量喷雾防治,结果表明除9.0×1010PIB /hm2+1%TinopalLPW 表现出显著的增效作用外,其余剂量有增效作用但不显著.     

茶毛虫核型多角体病毒制剂的防效

添加萤光素钠、656L乳化剂等的EpNPV制剂．其四号和五号配方对茶毛虫的LC70分别为4．42×10^5PIB／ml和1．75×10^6PIB／ml．与同浓度病毒悬液比．毒力系数(1)分别为4．39和1．11;用五号配方5～6×10^7PIB／ml可比同浓度NPV悬液提高防效11．2％．在700ha茶园应用平均防效达80%以上．经济效益1305元／ha;安全性检测表明．对人畜均安全无害。     

甜菜夜蛾核型多角体病毒中国分离株的分离鉴定及毒力测定

本文对分离自中国的甜菜夜蛾病毒进行提纯、鉴定。生物测定的结果表明其对二龄、三龄甜菜夜蛾的LC50 分别为 6 .6× 10 4,2 .6× 10 5PIB/mL .     

灰茶尺蠖核型多角体病毒对灰茶尺蠖的致病性研究

采取室内毒力测定和田间防效调查相结合的方法,对灰茶尺蠖核型多角体病毒(Ectropis grisescensnucleopolyhedrovir-us)的致病力进行了研究。毒力测定结果表明,该病毒对2龄灰茶尺蠖幼虫的剂量对数-死亡机率值回归方程为y=-0.8774 0.9498x,LC50=1.5417×106PIB.mL-1;田间用浓度为1×107、1.5×107和2×107PIB.mL-1的EgNPV防治灰茶尺蠖,防效分别达58.81%、89.51%和94.81%。     

茶核·苏云菌悬浮剂对灰茶尺蠖的田间防控应用

【目的】茶尺蠖核型多角体病毒EcobNPV是一种重要的昆虫病原微生物,可侵染茶尺蠖Ectropis obliqua和灰茶尺蠖Ectropisgrisescens2种宿主。为探明茶尺蠖核型多角体病毒制剂的田间应用技术,对影响防效的3个因子喷施方式、剂量和虫龄进行研究。【方法】采用植保无人机和人工喷施2种喷施方式,比较茶核·苏云菌悬浮剂（1×104 PIB·2 000 IU/μL）防治灰茶尺蠖的效果;设置75、150和375 mL/667 m²3种剂量,比较茶核·苏云菌悬浮剂对灰茶尺蠖的防治效果;并比较其对灰茶尺蠖1龄、2龄和3龄不同虫龄的防治效果。【结果】在相同剂量下,用植保无人机和人工喷施病毒制剂对灰茶尺蠖的总防效分别为69.0%和67.6%,两者无显著差异;在75、150和375 mL/667 m23种剂量,比较茶核·苏云菌悬浮剂对灰茶尺蠖的防治效果;并比较其对灰茶尺蠖1龄、2龄和3龄不同虫龄的防治效果。【结果】在相同剂量下,用植保无人机和人工喷施病毒制剂对灰茶尺蠖的总防效分别为69.0%和67.6%,两者无显著差异;在75、150和375 mL/667 m² 3种剂量下病毒制剂对灰茶尺蠖的防效差异显著,其中375 mL/667 m2 3种剂量下病毒制剂对灰茶尺蠖的防效差异显著,其中375 mL/667 m²剂量下的防效最高,150 mL/667 m2剂量下的防效最高,150 mL/667 m²其次,150 mL/667 m2其次,150 mL/667 m²和375 mL/667 m2和375 mL/667 m²剂量对灰茶尺蠖的总防效均在90%以上;病毒制剂对灰茶尺蠖1龄、2龄和3龄幼虫的防效分别为93.3%、78.7%和67.8%,对1龄幼虫的防效显著高于3龄。【结论】茶核·苏云菌悬浮剂防治灰茶尺蠖可选用植保无人机喷施,剂量可选用150-375 mL/667 m2剂量对灰茶尺蠖的总防效均在90%以上;病毒制剂对灰茶尺蠖1龄、2龄和3龄幼虫的防效分别为93.3%、78.7%和67.8%,对1龄幼虫的防效显著高于3龄。【结论】茶核·苏云菌悬浮剂防治灰茶尺蠖可选用植保无人机喷施,剂量可选用150-375 mL/667 m²,以1龄幼虫期喷施防效为最佳。     

茶尺蠖和灰茶尺蠖内共生菌Wolbachia的分子检测及序列分析

【目的】对茶尺蠖Ectropis obliqua及其近缘种灰茶尺蠖E.grisescens体内共生菌Wolbachia进行分子鉴定,确定两者体内Wolbachia的感染率及其进化地位,为进一步探讨其对茶尺蠖和灰茶尺蠖的潜在影响提供科学依据。【方法】采用Wolbachia的16S r RNA、fts Z和wsp基因特异性引物,通过PCR扩增法检测了我国3个茶尺蠖地理种群(浙江杭州、余杭和江苏无锡)和3个灰茶尺蠖地理种群(浙江新昌、湖北浠水和江西南昌)中Wolbachia的感染情况,并进行测序和序列分析。【结果】茶尺蠖和灰茶尺蠖都感染了Wolbachia,灰茶尺蠖的Wolbachia感染率为100%,但茶尺蠖的Wolbachia感染率在22%~95%,且PCR产物电泳得到的条带微弱。wsp序列在茶尺蠖和灰茶尺蠖种间、种内无差异;但16S r RNA序列在茶尺蠖和灰茶尺蠖种间、种内差异为0.362%~0.727%之间;茶尺蠖样本未成功扩增出fts Z序列,灰茶尺蠖样本获得2条fts Z基因序列差异为1.647%。基于Wolbachia的16S r RNA和wsp基因构建的系统发育树表明,本研究中茶尺蠖和灰茶尺蠖种群所感染的Wolbachia全部属于B组的Pip亚组。【结论】茶尺蠖和灰茶尺蠖均被B组Pip亚组的Wolbachia感染,但感染率相差很大,这为研究Wolbachia对茶尺蠖和灰茶尺蠖生物学及生态学的影响奠定了基础。     

灰茶尺蛾核型多角体病毒某些生化特性的研究

灰茶尺蛾核型多角体病毒某些生化特性的研究李彦章,石正丽,陈棣华（中国科学院武汉病毒研究所,武汉４３００７１）关键词灰茶尺蛾,核型多角体病毒,结构多肽,限制性内切酶图谱灰茶尺蛾核型多角体病毒（Ｅｃｔｒｏｐｉｓｇｒｉｓｅｓｃｅｎｓｎｕｃｌｅａｒｐｏｌｙｈ...     

(Z)-3-Hexenol Induces Tea Defense against Ectropis grisescens in the Field

Russian Journal of Plant Physiology - The tea geometrid Ectropis grisescens is an important pest of tea plant (Camellia sinensis (L.) O. Kuntze). It feeds on the new leaves and tender...     

No-substrate and low-moisture conditions during pupating adversely affect Ectropis grisescens (Lepidoptera: Geometridae) adults

Ectropis grisescens Warren (Lepidoptera: Geometridae) is an important defoliator pest of the tea plant, Camellia sinensis L. Our previous studies showed that E. grisescens pupae had significantly lower body water content when they pupated in the dry soil (20%-moisture) than those that pupated in the wetter soil (50%- or 80%-moisture). However, it is still unclear whether low-moisture conditions during pupating would further influence the physiological and fitness traits of adults. In the present study, E. grisescens individuals were allowed to pupate in 20%-, 50%- or 80%-moisture soil (silt loam), or in containers without soil (no-substrate conditions) in the laboratory. No significant difference in emergence was detected among different pupating conditions. However, female moths that emerged from 20%-moisture soil had significantly lower body water content compared to 80%-moisture soil, whereas the body water content of males was similar among the four treatments. The paired moths that emerged from 20%-moisture soil laid significantly fewer eggs than those that emerged from 50%-moisture soil. In addition, the number of hatched offerings (larvae) were significantly less when the adults previously pupated in no-soil containers compared to 50%-moisture soil. The longevity of adults was shortest when they emerged from 20%-moisture soil. Our study showed that the no-substrate and low-moisture conditions during pupating adversely affected E. grisescens adults.     

Comparison of male antennal morphology and sensilla physiology for sex pheromone olfactory sensing between sibling moth species: Ectropis grisescens and Ectropis obliqua (Geometridae)

Ectropis grisescens and Ectropis obliqua (Lepidoptera: Geometridae) are sibling pest species that co‐occur on tea plants. The sex pheromone components of both species contain (Z,Z,Z)‐3,6,9‐octadecatriene and (Z,Z)‐3,9‐cis‐6,7‐epoxy‐octadecadiene. E. obliqua has (Z,Z)‐3,9‐cis‐6,7‐epoxy‐nonadecadiene as an additional sex pheromone component, which ensures reproductive segregation between the two species. To ascertain the detection mechanism of olfactory organs for sex pheromone components of E. grisescens and E. obliqua, we applied scanning electron microscopy and single sensillum recording to compare antennal morphology and sensillum physiology in the two species. There was no apparent morphological difference between the antennae of the two species. Both species responded similarly to all three sex pheromone components, including, E. obliqua specific component. The distribution patterns of antennal sensilla trichodea differed between the two species. Sex pheromone olfactory sensing in these sibling species appears to be determined by the density of different types of olfactory sensing neurons. Dose‐dependent responses of sensilla trichodea type 1 to (Z,Z)‐3,9‐cis‐6,7‐epoxy‐octadecadiene, the most abundant component, showed an “all or none” pattern and the other two components showed sigmoidal dose‐response curves with a half threshold of 10^?4 (dilution equal to the concentration of 10 μg/μl). These results suggest that the major sex pheromone component functions as an on–off controller while secondary components function as modulators during olfactory transmission to the primary olfactory center.     

Feeding on tea GH19 chitinase enhances tea defense responses induced by regurgitant derived from Ectropis grisescens

Multiple isoforms of chitinases participate in plant defense against outside invaders. However, the functions of hydrolase family 19 (GH19) chitinases on pest control remain largely unknown. Here we reported the isolation and functional analysis of a gene CsChi19, which encodes a GH19 endochitinase protein of 332 amino acid residues from tea plant (Camellia sinensis). CsChi19 expression levels were upregulated in response to mechanical wounding, infestation by two important pests: the tea geometrid Ectropis grisescens and the tea green leafhopper Empoasca (Matsumurasca) onukii, a fungal pathogen Colletotrichum fructicola, and treatment with two phytohormones: jasmonic acid (JA) and salicylic acid. CsChi19 was heterologously expressed in Escherichia coli, and its catalytic function was further elucidated. The protein could hydrolyze colloidal chitin, and the optimum temperature and pH for its activity was 40°C and pH 5.0. CsChi19 were found to be toxic to tea pests when they were fed on artificial diets containing this protein. Interestingly, the regurgitant derived from E. grisescens fed with artificial diets containing CsChi19 protein induced stronger expression of CsMPK3, more JA burst, more accumulation of defense-related secondary metabolites, and more emission of volatiles than the regurgitant derived from E. grisescens fed only with artificial diets. Our results provide first evidence that CsChi19 is involved in mediating a novel defense mechanism of tea plant through altering the composition of the regurgitant.     

灰茶尺蠖成虫触角及幼虫头部感器超微结构

【目的】明确灰茶尺蠖Ectropis grisescens成虫触角及幼虫头部感器的种类、形态、数量和分布,以探讨灰茶尺蠖的行为机制。【方法】利用扫描电镜技术观察灰茶尺蠖雌、雄成虫触角和5龄幼虫头部感器的超微结构。【结果】灰茶尺蠖成虫触角上分布有8种感器,分别是栓锥形感器、耳形感器、毛形感器(Ⅰ-Ⅳ)、B?hm氏鬃毛、腔锥形感器(Ⅰ和Ⅱ)、鳞形感器、锥形感器(Ⅰ和Ⅱ)和刺形感器。其中,栓锥形感器仅分布在雌蛾触角上,耳形感器、毛形感器(STⅠ-Ⅲ)仅分布在雄虫触角上。5龄幼虫触角上着生1个栓锥形感器、1个锥形感器和2个刺形感器;上唇着生有6对刺形感器,内唇着生有3对刺形感器和1对指形感器;上颚基部外侧着生有2个刺形感器;下颚及下颚须着生有5个刺形感器、9个锥形感器和2个栓锥形感器;下唇须着生有1个锥形感器和1个刺形感器;吐丝器前端着生有1对刺形感器。【结论】灰茶尺蠖雌、雄成虫触角感器存在性二型性,且雄虫上感器种类和数量较多,据此推测雄虫感受寄主植物或性信息素的能力较强;幼虫头部感器具有嗅觉和味觉功能,在其判断食物的种类和适应性等生态行为中发挥重要作用。