绿僵菌毒素的提取

用金龟子绿僵菌的液物培养体,提取绿僵菌素。每升培养液得绿僵菌素0.7mg。用绿僵菌素注射青杨天牛幼虫,每克虫体用量10.6μg,3d内死亡率达100％。     

Biological control of the Western flower thripsFrankliniella occidentalis in cucumber using the entomopathogenic fungusMetarhizium anisopliae

Biological control of the western flower thrips (WFT)Frankliniella occidentalis, using the entomopathogenicMetarhizium anisopliae-7 (M. a-7) strain was studied in three consecutive seasons under greenhouse conditions. Cucumber plants infested with WFT were sprayed with spore suspension of the fungusM. a-7 (0.5 g m^-2), or the soil was treated with dry powder of the fungus (0.5 g m^-2); the control was without fungus application. In the 1997 spring experiment, when the cucumber plants were initially infested with only three or four insects per leaf, the spore suspension spray caused a significant reduction in growth of the thrips population compared with the other treatments and the control. However, in the 1997 summer experiment, when the plants were initially heavily infested with WFT (10–15 insects per leaf), the spray treatment caused only a modest reduction in WFT population growth, and only after 4 weeks of treatment was the reduction significant. In the 1999 experiment, with a low initial WFT population of three or four insects per leaf, the spray treatment was effective in reducing the population growth to a lower level than in the other treatments or control. TheM. a-7 strain was found to be effective in reducing the population growth of WFT under greenhouse conditions, particularly when the initial thrips population was low to moderate. http://www.phytoparasitica.org posting Nov. 4, 2001.     

金龟子绿僵菌固态培养生物变量优化研究

金龟子绿僵菌属于真菌类生物杀虫剂,本文研究了接种量、种龄、菌种代数等生物因素对金龟子绿缰菌生长及产孢量的影响,并对液—固两步发酵工艺进行了研究。经过优化,得到金龟子绿僵菌产孢的最佳生物参数是:接种量为2.5g/100g、种龄为5-6天;采用固体二代种,培养6天,孢子产量可达1.531×10~(10)孢子/g干培养基。     

绿僵菌治蝗研究进展

介绍了目前对防治多种蝗虫效果较好的虫生真菌--绿僵菌的种类、株系,以及绿僵菌对蝗虫的致病机理、 对环境的安全性等,并讨论了国内外应用绿僵菌防治蝗虫的田间试验效果、剂型研制、产业化和推广应用前景。     

生物杀虫剂组合在有机水稻种植中的作用效果

针对上海市崇明区有机水稻生产过程中病虫害防治效果不佳的问题,在水稻无化肥、无化学农药种植条件下开展了生物杀虫剂对水稻主要害虫稻纵卷叶螟和稻飞虱的田间防控效果评价。在崇明区的2个试验基地,于水稻不同生长时期,以绿僵菌、白僵菌产品分别与病毒杀虫剂MbNPV、植物源杀虫剂苦参碱和细菌杀虫剂Bt组合进行施药处理。结果表明,应用绿僵菌/白僵菌与MbNPV组合,能够有效防治稻纵卷叶螟,在稻纵卷叶螟发生较早的基地,施药后7 d和14 d的防效可达58.2%～81.2%,而在稻纵卷叶螟发生较晚的另一基地,施药后7 d防效可达61.3%和65.6%;绿僵菌/白僵菌与苦参碱组合,可用于防治稻飞虱,7 d和14 d的防效达64.7%～76.1%;绿僵菌/白僵菌与苏云金杆菌组合防治稻纵卷叶螟的14 d防效分别达64.0%和75.4%,优于对稻飞虱的防效;各组合试验结果显示,白僵菌有相对较长的持效作用,且在害虫迁入早期阶段(水稻发育分蘖盛期至拔节期)施用生物农药比在中后期(抽穗期及之后)施用的防效高。可见,生物杀虫剂组合可作为农作物绿色防控的有效手段。     

Screening of field performance of entomopathogenic fungi and nematodes against cabbage root flies (Delia radicum l. and d. floralis (fall.); Diptera,Anthomyiidae)

Finnish isolates of Beauveria bassiana (8 isolates), Metarhizium anisopliae (7), Tolypocladium sp. (2), Paecilomyces farinosus (2), P. fumosoroseus (1), Steinernema feltiae (3) and Bacillus thuringiensis ('Muscabac') were tested for efficacy against mixed populations of Delia radicum and D. floralis under field conditions in 1986–90. All pathogens were applied preventatively, the fungi as aqueous conidial or mycelial suspensions, dry conidia or dry mycelial powder. In only two of the nine experiments did B. bassiana or M. anisopliae give some control. In 1986, B. bassiana SF85–2 and Tolypocladium sp. SF85–4 (both at rate 1.2 x 10⁹ conidia plant‐ 1), and ‘Muscabac’ (25 g 1^?1, 1 dl plant^?1) reduced the number of pupae by 80%, 60% and 50%, respectively, as compared with untreated and chemical (isophenphos) controls. In 1990, M. anisopliae SF86–39 at rate 1.6 x 10⁹conidia plant^?1 and 1.5 x 10⁸ CFU plant^?1 and S. feltiae SFS‐22 (35000 plant^?1), increased the yield of cauliflower 2.2, 1.8, and 2.3‐fold, respectively, as compared with the untreated control, but these yields were only 19%, 15% and 19% of those of the chemical (diazinon) control. Paecilomyces isolates were ineffective in the 1986 experiment in which they were included. Our results suggest that it is difficult to find efficient control agents among the fungal and nematode species tested for use as biopesticides against cabbage root flies, but that the potential of M. anisopliae against these pests deserves further study.     

三种杀真菌剂对金龟子绿僵菌产孢及生长的影响

三种杀真菌剂在一定浓度范围为（氯硝胺在１００×１０￣（－６），孟加拉红在５００×１０￣（－６）和柯赛得在２０００×１０￣（－６）内）对金龟子绿僵菌的菌落形成没有明显影响，而柯赛得（含５０％氢氧化铜）和孟加拉红分别在１００×１０￣（－６）和５００×１０￣（－６）浓度时显著地增加金龟子绿僵菌的产孢量，柯赛得还具有缩短产孢时间的作用。氯硝胺在１～１００×１０￣（－６）浓度范围内，随着浓度增加，对产孢能力和菌落大小的抑制作用加强。柯赛得和孟加拉红随浓度的增加对菌落的抑制作用也有所加强，但没有像氯硝胺的抑制作用那么强。     

Risks to the aquatic ecosystem from the application of Metarhizium anisopliae for locust control in Australia

Laboratory tests of Metarhizium anisopliae var acridum Driver & Milner, at a dose of 1.3 x 10(6) conidia ml-1, had no adverse effects on nymphs of mayfly, Ulmerophlebia sp or 8-week-old fry of the rainbow fish, Melanotaenia duboulayi Castelnau. This dose was toxic to the cladoceran, Ceriodaphnia dubia Richard, causing 100% mortality in 48 h. When this test was repeated at doses of up to 6.7 x 10(3) conidia ml-1, there was only 5% mortality after 192 h. Spraying of artificial water sources with a very high dose of the fungus as an aqueous spray resulted in 80-130 conidia ml-1 at 15 cm depth in the first 24 h after spraying. The conidia rapidly settled out and were absent from the top 15 cm layer of water after about 50 h. A similar experiment using the oil formulation as used in field control resulted in a 2- to 20-fold lower level of conidia in the water. Finally, sampling actual water sources in spray areas revealed a very low level of contamination of the water, with a maximum mean level of 29 conidia ml-1 in the first 24 h after treatment. Thus the level of conidia likely to enter water during control campaigns is a small fraction of that required to kill cladocerans, the only sensitive non-target organism tested. It is concluded that the biopesticide is very unlikely to pose any hazard to aquatic organisms.     

黄绿绿僵菌对马铃薯瓢虫体内脯活性的影响

对感染黄绿绿僵菌后的马铃薯瓢虫幼虫体内几种酶进行测定，结果表明：黄绿绿僵菌对于马铃薯瓢虫幼虫体内的蛋白质含量、蛋白酶、谷胱甘肽-S-转移酶和乙酰胆碱酯酶的活性，都有不同程度的影响，其中对蛋白含量和谷胱甘肽-S-转移酶的影响较大。