不同温湿度下白僵菌对松毛虫的侵染致病效应

采用荧光显微技术和电镜扫描技术 ,对 33个温湿度组合条件下球孢白僵菌孢子在马尾松毛虫活体上的萌发、侵染进程和致病效果进行了观察与测定 ,分析了三者之间的关系 .揭示了孢子萌发速率与环境温度的关系 :V =(T - 4.2 5) /2 7.2 .其中 ,孢子萌发的起点温度为 4.2 5℃ ,有效积温为 2 7.2日度 .湿度是孢子萌发和侵染致病的主要制约因子 ,且温度和湿度具有互补与综合作用 .温度达 1 0℃以上 ,相对湿度达 95% ,侵染致病效应更为显著 .     

白僵菌在松毛虫体上宿存侵染的电镜扫描观察

通过扫描电子显微镜,观察了几种人工的或自然的环境下白僵菌在马尾松毛虫体上的宿存与侵染过程,描述了分生孢子的萌发和菌丝形成中的形态变化,讨论了致病效果与环境的关系,对林间应用提出了建议。结果表明：在２５℃和９５％的温湿度条件下,分生孢子萌发较快,萌发率和侵入率较高;白僵病的发生需要８５％以上的相对湿度,这是自然环境中防治效果的制约因子;在松毛虫每年发生２～３代的我国林区,冬季放菌做法不宜提倡,６月份放菌更为适宜。     

球孢白僵菌对温室蚜虫的侵染生物学

研究了球孢白僵菌在不同浓度、施菌方式、温度和相对湿度下对温室蚜虫的侵染力以及接种后对蚜虫的侵染速率。结果表明,高(109个孢子.mL-1)、中(108个孢子.mL-1)、低(107个孢子.mL-1)3个浓度剂量对蚜虫都有较强的致病力,且浓度越大,蚜虫的死亡率越高,死亡时间越提前。用浸渍法和孢子浴法接种蚜虫,6 d的累积死亡率分别为100%和31.1%。在测试的3个温度(22、26、30℃)中,26℃时蚜虫侵染力最强,第3天出现死亡高峰,第5天时累积死亡率就达到100%,明显高于22、30℃的处理。相对湿度越大,球孢白僵菌的致病力越强,蚜虫死亡速度越快。在温湿度组合中相对湿度为95%时,温度对白僵菌的侵染力几乎无影响,但影响发病速度,相对湿度低于95%时,26℃的侵染力始终高于22和30℃时的侵染力。通过接种后不同时间段用0.2%百菌清处理蚜虫测定该菌株的侵染速率,结果表明接种后24 h是该球孢白僵菌有效侵染蚜虫的关键时期。     

应用白僵菌与溴氰菊酯混合防治马尾松毛虫研究

通过应用白僵菌粉与4种浓度溴氰菊酯粉混合后不同时间孢子萌发情况测定,以及用纯菌粉、药粉和菌药不同比例混合粉,对马尾松毛虫室内毒力测定和林间防治试验比较,筛选出菌粉与0．05％溴氰菊酯粉按4：1比例混合,防治效果最好,并经大面积推广防治示范,平均防治效果达95％以上,分别较纯菌粉和药粉效果提高14．9％和29．5％,具有明显的增效作用,马尾松毛虫死亡高峰期提前5－7天,减少松针损失量,能及时控制住高虫口林分害虫的严重危害、经济、社会和生态效益显著。     

球孢白僵菌的侵染特性及应用研究进展

球孢白僵菌是一种重要的虫生真菌,具有致病力强、侵染范围广、安全无污染等优点,其制剂可作为一种真菌类杀虫剂应用于农林业害虫的防治,也可用于人工生产中药材僵蚕。本文综述了球孢白僵菌的培养性状、侵染特性、应用生产和存在的问题,并提出了发展对策,为球孢白僵菌的进一步开发应用提供参考。     

白僵菌、绿僵菌对雷公藤丽长角巢蛾的侵染力测定

经室内侵染力测定,球孢白僵菌Beauveria bassiana和金龟子绿僵菌Metarhizium anisopliae皆能侵染雷公藤丽长角巢蛾Xyrosaria lichneuta幼虫,不同菌株的侵染力存在显著差异。3株白僵菌中,Bb27菌株毒力最强,菌液为1×10^5～1×10^9个·mL^-1五个不同浓度梯度的孢子悬浮液时,害虫15d校正死亡率在58．3％-100％之间;LT50分别为9．36d,6．26d,3．89d、2．54d．2．10d;LC50为4．87×10^4个·ML^-1。3株绿僵菌中,MaZPTP01菌株毒力最强,5种孢子浓度15d校正死亡率分别为52．4％、69．0％、76．2、92．9％、95．2％;LT50分别为11．47d、6．89d、4．36d、2．68d、2．13d;LC50为7．39×10^4个·mL^-1。Bb27和MaZFIT01菌株可应用于林间作进一步防治试验。     

球孢白僵菌对桃蚜接种后特定时间内的侵染率

用球孢白僵菌 (Beauveriabassiana)BBSG870 2菌株的分生孢子悬液 (5× 10 6个·ml-1孢子 )对桃蚜 (Myzuspersicae)始产若蚜的成蚜进行表面接种 ,在接种后 5 6h内 ,每隔 8h取样用 0 .2 %百菌清处理蚜虫 ,使其体表残存的孢子全部失活 ,分别置于 10℃和 2 0℃下逐日观察感染引起的死亡 .结果表明 ,10℃下接种后 5 6h、2 0℃下接种后 40h内各时间段有效侵染引起的死亡率相互间存在显著差异 ,并与不用杀菌剂的对照处理差异显著 (P <0 .0 5 ) .与对照相比 ,接种后 8、16、2 4、32、40和 5 6h内 ,10℃下的有效侵染率分别为 2 2 .9、48.8、6 4.9、80 .4、72 .7和 98.3% ,2 0℃下分别为 31.6、48.8、5 8.6、86 .9、97.2和 98.7% .由此表明 ,在 10～ 2 0℃范围内 ,接种后 2 4h内是该菌有效侵染桃蚜的关键时段 ,有效侵染率达 5 9～ 6 5 % .     

球孢白僵菌在红火蚁体表侵染的扫描电镜观察

利用扫描电镜观察了球孢白僵菌Beauveria bassiana Bb04菌株分生孢子对红火蚁Beauveria bassiana 工蚁体壁的侵染过程。结果表明: 分生孢子多分布在红火蚁工蚁节间膜、胸部的褶皱、气门、体壁的凹陷部位、刚毛窝附近, 以及着生较密刚毛的足上。萌发的分生孢子在节间膜以及体表缝隙、刚毛窝及刚毛稀少的凹陷部位、胸部褶皱和足胫节处入侵。分生孢子在附着12 h后开始萌发, 接种后18 h附着在节间膜处的孢子首先侵入成功, 接种后24 h刚毛窝附近孢子萌发入侵, 接种后60 h胸、腹和足等部位的孢子均成功穿透侵入表皮。分生孢子可以直接以芽管侵入表皮, 也可以产生附着胞再侵入。     

转换寄主对马尾松毛虫生长发育与繁殖的影响

在室内条件下,分别用马尾松针叶(Pinus massoniana Lamb.)、湿地松针叶(Pinus elliottii Engelm)、以及在不同的幼虫龄期从用马尾松针叶转移到用湿地松针叶饲养马尾松毛虫Dendrolimus punctatus Walker,观察转换寄主对马尾松毛虫生长发育与繁殖的影响。结果表明:(1)从用马尾松针叶饲养转换到用湿地松针叶饲养,可显著影响马尾松毛虫生长发育和繁殖参数;而且当在马尾松毛虫幼虫老龄期进行转换寄主饲养比低龄期转换寄主饲养,可显著缩短马尾松毛虫幼虫的发育历期,降低死亡率,同时,可显著增加幼虫体重、蛹重和化蛹率;对食物的营养效应也越强。(2)取食马尾松的松毛虫较取食湿地松的马尾松毛虫发育历期短,死亡率低,幼虫及蛹重增加,产卵量高。结果说明,马尾松毛虫从马尾松转换移到湿地松上取食对其生长发育与繁殖是不利的。     

应用球孢白僵菌防治马尾松毛虫的策略及其生物多样性基础的研究

对３种不同方式应用球孢白僵菌防治马尾松毛虫的结果表明,３个林场的虫口在连续４年内均被抑制在低水平,但松毛虫种群动态不同：以淹没式施放白僵菌为主,但有时也淹没式施放化学杀虫剂的麻姑山林场平均虫口密度为３．１６±４．９４条·株－１,波动最大;长期接种式应用白僵菌的戴公山林场平均虫口密度只有０．０９±０．１４条·株－１,一直处于低密度状态;以化学农药处理小面积虫源地结合不频繁地淹没式施放白僵菌的金寺山林场平均虫口密度为１．４５±２．２９条·株－１,偶可达防治指标．对群落组成的调查结果表明,从麻姑山、金寺山到戴公山,动物和虫生真菌群落各物种的总个体数递减,而总物种数、总物种数与总个体数的比值,天敌与害虫种数和个体数的比值以及群落多样性指数皆递增,表明群落多样性渐趋丰富,食物链网渐趋复杂,群落稳定性和对害虫的自然控制能力逐渐增强．对群落动态的主成分分析进一步表明,从麻姑山、金寺山到戴公山,动物和虫生真菌群落的演化时序分明,趋于稳定,自我调节力强．     

白僵菌固态发酵试验研究

以产孢量为指标,筛选出白僵菌固态发酵的培养基为：90％麦麸＋5％玉米粉＋5％黄豆粉,原孢粉的产孢量可达244．7亿／g。在25m^3发酵罐内进行浅盘固态发酵,培养基的最适起始含水率为60％～65％;最佳通气条件为：前12h不通气,12～48h通气量为1：2,48～144h的通气量为1：1;而温度只需在12～48＋8h内进行控制。常温干燥能最大限度地维持白僵菌的活孢率。     

Beauveria bassiana infection of eggs of stored-product beetles

Beauveria bassiana (Balsamo) Vuillemin was tested under maximum challenge conditions with an estimated dose of 1.1 × 10⁵ conidia/mm² for its effects on eggs of four of the major beetle pests of stored grain and grain products. When ambient relative humidity (RH) was 92%, hatch of fungus-treated Rhyzopertha dominica (Fabricius) eggs was 13% versus 58% for control eggs, and hatch of treated Tribolium castaneum (Herbst) was 17% versus 51% for controls. There was no fungus effect at RH of 48 and 73%. Fungus treatment of Cryptolestes ferrugineus (Stephens) and Oryzaephilus surinamensis (Linnaeus) eggs had no effect. Sectioned T. castaneum eggs demonstrated that the fungus penetrates and infects them.     

球孢白僵菌Bb174固态发酵产几丁质酶产酶及酶学特征研究

对球孢白僵菌(Beauveria bassiana)Bb174产几丁质酶进行了固态发酵条件及酶学特征的研究．结果表明,以4：1麸皮：蚕蛹粉、蛋白胨1g·L^-1作为产酶最适培养基,在7．5g培养基中接种3ml液态种子,自然pH下28℃培养2d,酶活可达最高,为126U·g^-1(干培养基)．粗酶液的最适反应温度为40℃,最适反应pH5．0,在30-70℃保温1h,得半失活温度48℃．在30--40℃、pH4～6范围内,酶的性质最稳定．根据Lineweaver-Burk作图法,得到该酶的动力学参数Km为0．52mg·ml^-1,Vm为0．7△E680·h^-1．     

Transformation of cinoxacin by Beauveria bassiana

The ability of the fungus Beauveria bassiana ATCC 7159 to transform the antibacterial agent cinoxacin was investigated. Cultures in sucrose-peptone broth were dosed with cinoxacin, grown for 20 days, and then extracted with ethyl acetate. Two metabolites were detected and purified by high-performance liquid chromatography. The major metabolite was identified by mass and proton nuclear magnetic resonance spectra as 1-ethyl-1,4-dihydro-3-(hydroxymethyl)[1,3]dioxolo[4,5-g]cinnolin-4-one and the minor metabolite was identified as 1-ethyl-1,4-dihydro-6,7-dihydroxy-3-(hydroxymethyl)cinnolin-4-one. B. bassiana also reduced quinoline-3-carboxylic acid to 3-(hydroxymethyl)quinoline.     

Review on safety of the entomopathogenic fungi Beauveria bassiana and Beauveria brongniartii

The commercial use of entomopathogenic fungi and their products as mycoinsecticides necessitates their registration. Worldwide, several registration guidelines are available, however, most of them focus on similar or even the same safety issues. With respect to the two entomopathogenic fungi, Beauveria bassiana (Bals.-Criv.) Vuill. and Beauveria brongniartii (Sacc.) Petch, many commercial products have been developed, and numerous papers on different biological, environmental, toxicological and other safety aspects have been published during the past 30-40 years. The aim of the present review is to summarise these data. The following safety issues are presented: (1) identity of Beauveria spp.; (2) biological properties of Beauveria spp. (history, natural occurrence and geographical distribution, host range, mode of action, production of metabolites/toxins, effect of environmental factors); (3) analytical methods to determine and quantify residues; (4) fate and behaviour in the environment (mobility and persistence in air, water and soil); (5) effects on non-target organisms (non-target microorganisms, plants, soil organisms, aquatic organisms, predators, parasitoids, honey bees, earth worms and nontarget arthropods); (6) effects on vertebrates (fish, amphibia, reptiles and birds); and (7) effects on mammals and human health. Based on the present knowledge it is concluded that both Beauveria species are considered to be safe.     

Modelling Beauveria bassiana horizontal transmission

1 We modelled horizontal transmission of Beauveria bassiana in Colorado potato beetle (CPB) between larval cadavers and soil inhabiting prepupae. 2 The rate of disease transmission, based on the probability of a prepupa contacting sporulating cadavers on the soil surface, is a non‐linear function of cadaver density and also dependent upon temperature. 3 The spatial pattern of cadavers is needed to estimate prepupal contacts with cadavers. Observational field studies determined Johnson distributions to model the spatial pattern of cadavers and prepupae in the field. The model also implicitly incorporates within‐field larval spatial pattern into estimates of field‐level horizontal transmission. 4 Potential for horizontal transmission is higher in simulations using weather data from the warmer year of 1995, than in simulations of the cooler growing season of 1993. 5 Simulations of CPB populations under northern Maine climatic conditions recorded in 1993 and 1995 suggest that horizontal transmission can range from 3 to 24% depending upon the timing of primary infection of larvae in the field. 6 Two simulated sequential applications of B. bassiana targeted at peak first instars resulted in maximum horizontal infection in both years. 7 Sensitivity analysis suggests that horizontal transmission is most sensitive to changes in the proportion of cadavers that sporulate and least sensitive to changes in the time between larval death and the onset of cadaver sporulation. 8 Field validation of the model indicates good prediction of one measure of horizontal infection, the proportion of prepupae which eventually sporulated after being released in controlled field experiments.