Evaluating the importance of residual effects from previous years' treatment on the efficiency of different strategies for control of Sahelian grasshoppers with Metarhizium anisopliae var. acridum

A model for the residual effect of previous years' treatment with the mycoinsecticide Metarhizium anisopliae var. acridum has been constructed based on field data from treatment of two different grasshopper species in east Niger. This model was incorporated in an earlier developed simulation model to evaluate control strategies for the grasshopper Oedaleus senegalensis in West Africa and the model system was used to assess the potential importance of second year's residual effects for the efficiency of different treatment strategies. It has earlier been hypothesized that the persistence of M. anisopliae and the ability of this agent to impose long-term control on grasshopper populations through secondary cycling in some cases might render the use of M. anisopliae more efficient than the use of chemical insecticides like fenitrothion. Results show that this effect is possible if M. anisopliae is used in a repetitive treatment strategy where control operations are concentrated in the main millet production areas.     

Pathogenicity of entomopathogenic fungus,Metarhizium anisopliae MET-GRA4 isolate on dengue vectors,Aedes albopictus and Aedes aegypti mosquito larvae (Diptera: Culicidae)

Considering the rapid transmission of the dengue virus, substantial efforts need to be conducted to ward-off the epidemics of dengue viruses. The control effort is depending on chemical insecticides and had aroused undesirable conflicts of insecticide resistance. Here, we study the entomopathogenic fungus, Metarhizium anisopliae as a promising new biological control agent for vector control. The pathogenicity effects of Metarhizium anisopliae against field and laboratory strains of Aedes albopictus and Aedes aegypti larvae were tested using the larvicidal bioassay technique. The results demonstrate that the treatments using M. anisopliae isolate MET-GRA4 were highly effective and able to kill 100% of both Ae. albopictus and Ae. aegypti mosquito larvae at a conidia concentration of 1 × 10?/ml within 7 days of the treatment period. The fungus displayed high larvicidal activity against laboratory and field strain of Ae. aegypti larvae with LC₅₀ values (9.6 × 10³/ml, 1.3 × 10³/ml) and LC₉₅ values (1.2 × 10?/ml, 5.5 × 10⁵/ml) respectively. For Ae. albopictus, LC₅₀ values for laboratory and field strains were (1.7 × 10⁴/ml, 2.7 × 10⁴/ml) and the LC₉₅ values were (2.1 × 10?/ml, 7.0 × 10⁵/ml) respectively. Interestingly, the susceptibility of field strain towards M. anisopliae was higher as compared to the laboratory strain Aedes larvae. In which, the causative agents of all the dead larvae were verified by the virulence of M. anisopliae and caused morphological deformities on larval body. The findings from this study identify this isolate could be an effective potential biocontrol agent for vector mosquitoes in Malaysia.     

金龟子绿僵菌(Metarhizium anisopliae HN1)几丁质酶基因的克隆及高效表达

几丁质酶是昆虫病原真菌金龟子绿僵菌致病力的主要因子之一。本实验用RT-PCR方法,从本实验室分离筛选到的高毒力金龟子绿僵菌Metarhizium anisopliae HN1中,扩增得到几丁质酶基因全长,此基因全长为1275bp,登录号为DQ011865,经Blastn分析此基因序列与M. anisopliae E6的chi1基因（AF02749）同源率为96% 。以pET-22b(+)为基础载体,构建pET-chi重组表达载体,在大肠杆菌（Escherichia. coli ）BL 21中进行表达。经SDS-PAGE分析,获得了42kDa大小的重组目的蛋白,目的蛋白占表达总蛋白含量的63.3%。菌体经冷冻与超声波破碎后,按DNS法可测得几丁质酶的活性。     

航天诱变对昆虫病原真菌的生物学效应

8个昆虫病原真菌菌株经过航天搭载后,有5个菌株的孢子在航天搭载后全部死亡,菌株M2029和MR8的存活率仅约10-7,菌株M189的存活率可达到20%以上。分离得到航天诱变的单菌落菌株,检测表明航天诱变使昆虫病原真菌的形态、生长速度、产孢量、致病力等多项生物学特性发生了不同程度的变异,变异率高,变异趋向有正负双向性。测定结果表明航天诱变菌株HM189-68s、HM189-32c、HM189-127和HM189-17的生长特性和致病力优于原始菌株。航天诱变为选育生物防治优良菌株提供了新途径。     

Metarhizium anisopliae var. Anisopliae Pr1A基因的克隆表达及抗血清研究

采用RT-PCR方法从本实验室分离筛选到的金龟子绿僵小孢变种Metarhizium anisopliae vat．anisopliae中,扩增得到PrlA基因全长,此基因全长为1242bp,经Blastn分析此基因序列与M．anopliae的PrlA基因(M73795)同源率为98%。以pET- 22b( )为基础载体,构建pET-PrlA重组表达载体,在大肠杆菌(Escherichia．coli)BL 21(DE3)中进行表达。经SDS—PAGE分析,获得了约42kDa大小的重组目的蛋白,目的蛋白占表达总蛋白含量的63．2%。将表达的PrlA蛋白切胶回收后制备成抗原,免疫家兔4次后,采血收集抗血清,用ELISA测定效价为1/10000。结果表明,获得的抗体可用于更进一步的研究,将有利于我们进一步了解M．anisopliaeis的侵染机理,弄清楚各Pr蛋白酶的作用方式和对寄主的选择优势,提高生防控制的有效性。     

Biological control of insects in Brazil and China: history,current programs and reasons for their successes using entomopathogenic fungi

Brazil and China have been successful in the use of microbial control methods to manage several agricultural and forest insects. In both countries, entomopathogenic fungi (EF) have been used for pest management since the 1970s. However, EF production and commercialization have not been constant in either country. Several companies and cooperatives suspended their activities or shut down from the 1970s to the 1990s. This was due to loss of confidence in available mycoinsecticides by Brazilian farmers or due to reduced involvement and government subsidies for biological control in China; and, consequently, mycoinsecticides were largely replaced by inexpensive chemical insecticides. Starting in the 1990s and continuing until today, however, new Brazilian and Chinese private companies have arisen. In Brazil, the area treated with M. anisopliae for spittlebug control alone is estimated to be approximately one million hectares in 2008, 75% of which was for control of spittlebugs in sugarcane plantations and the remainder for spittlebugs in pasture grass (primarily Brachiaria spp.) and other smaller programs. In China, the fungus Beauveria bassiana was used annually in 0.8–1.3 million ha until the 1980s. Several factors were important for the success of these programs, such as: governmental support (at least during the initial steps of biocontrol programs); availability of indigenous virulent fungal isolates; low-cost substrates for mass production; retail prices of mycoinsecticides lower than their chemical counterparts; and sale by contract which allows the products to be immediately available for use, rather than stored. In this report, we discuss the current biocontrol programs using insect fungi in these two developing countries, as well as the future and main challenges they must face to further encourage the adoption of mycoinsecticides.     

Pathogenicity of entomopathogenic fungi to eggs and larvae of Spodoptera litura,the common cutworm

The eggs and second instar larvae of Spodoptera litura were treated with different concentrations of conidial suspensions of six isolates of fungi belonging to five species, Metarhizium anisopliae var. anisopliae (Metschnikov) Sorokin (ARSEF 7487), Lecanicillium muscarium (Petch) Zare & W Gams (ARSEF 7037 and ARSEF 6118), Cordyceps cardinalis (ARSEF 7193), Fusarium lateritium Nees (ARSEF 8291/MTCC 9050) and Aspergillus sp. (ARSEF 8519). In bioassay with unscaled eggs, M. anisopliae, C. cardinalis, F. lateritium and Aspergillus sp. resulted in 100% mortality above 10⁶ conidia/mL. However, with scaled egg masses, the highest hatching rate (56%) was observed with L. muscarium (ARSEF 6118) whereas the lowest hatchings were observed in the case of M. anisopliae followed by L. muscarium (ARSEF 7037), Aspergillus sp., F. lateritium, and C. cardinalis. The larvae were also found susceptible to all isolates in a dose dependent manner. Three promising isolates against larvae, viz. M. anisopliae, F. lateritium and L. muscarium (ARSEF 7037) resulted in average percent mortalities of 88, 89 and 77%, respectively at ≈10⁸ conidia/mL. When both larvae and the leaves (provided as food) were treated with ≈10⁸ conidia/mL, mortality further increased for these isolates. Based on the mortality data and the LC₅₀ values, we suggest that M. anisopliae, F. lateritium and L. muscarium (ARSEF 7037) could be developed as potential biocontrol agents against rice cutworm in IPM programs.     

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。     

Intraspecific tolerance of Metarhizium anisopliae conidia to the upper thermal limits of summer with a description of a quantitative assay system

Conidial tolerance to the upper thermal limits of summer is important for fungal biocontrol agents, whose conidia are formulated into mycoinsecticides for field application. To develop an efficient assay system, aerial conidia of eight Metarhizium anisopliae, four M. anisopliae var. anisopliae, and six M. anisopliae var. acridum isolates with different host and geographic origins were wet-stressed for ≤180 min at 48 °C or incubated for 14 d colony growths at 10-35 °C. The survival ratios (relative to unstressed conidia) of each isolate, examined at 15-min intervals, fit a logistic equation (r² ≥ 0.975), yielding median lethal times (LT₅₀s) of 14.3-150.3 min for the 18 isolates stressed at 48 °C. Seven grasshopper isolates from Africa had a mean LT₅₀ of 110 (73-150) min, but could not grow at 10 or 15 °C. The mean LT₅₀ of five non-grasshopper isolates capable of growing at 10-35 °C was 16 (10-26) min only. Three isolates with typically low (type I), medium (type II), and high (type III) levels of tolerance to 48 °C were further assayed for ≤4-d tolerance of their conidia to the wet stress at 38, 40, 42, or 45 °C. The resultant LT₅₀s decreased to 20, 53 and 167 min at 48 °C from 507, 1612, and 8256 min at 38 °C for types I, II and III, respectively. For the distinguished types, the logarithms of the LT₅₀s were significantly correlated to the temperatures of 38-48 °C with an inverse linearity (r² ≥ 0.88). The method developed to assay quantitatively fungal thermotolerance would be useful for screening of fungal candidates for improved pest control in summer.     

Synergies between biological and neonicotinoid insecticides for the curative control of the white grubs Amphimallon majale and Popillia japonica

Synergistic combinations of biological and chemical insecticides might yield promising alternatives for soil insect pest management. In turfgrass of the Northeast U.S., control of root-feeding scarab larvae is highly dependent on conventional insecticides. Studies on interactions between entomopathogenic nematodes and neonicotinoid insecticides, however, demonstrate the feasibility of synergies as an approach for reduced-risk curative control. To understand the breadth of potential synergies, we screened numerous combinations of biological control agents with sublethal doses of neonicotinoids against third instars. Interactions were characterized as synergistic, additive or antagonistic. The most promising combinations identified in laboratory bioassays were advanced to greenhouse pot studies and then to field trials featuring microplots with artificially infested populations. To reveal variation across scarab species, trials were conducted on Amphimallon majale and Popillia japonica. Synergies were consistent across trials and specific to white grub species. For A. majale, synergistic combinations of Heterorhabditis bacteriophora with imidacloprid and clothianidin were discernible in laboratory, greenhouse and field trials. For P. japonica, synergistic combinations of Beauveria bassiana and Metarhizium anisopliae with both neonicotinoids were discernible in the laboratory and greenhouse, but not in the field. For both species, antagonistic interactions were discernible between Bt-products and both neonicotinoids. While nematode-neonicotinoid synergies among scarab larvae have been examined before, fungi-neonicotinoid synergies are unreported. In the context of previous studies, however, no patterns emerge to explain variation across target species or control agent. Further study of non-additive interactions will guide how biological and chemical products could be combined to enhance soil insect pest management.