The epizootiology of a Metarhizium infection in mini-nests of the leaf-cutting ant Atta sexdens rubropilosa

There is growing interest in the use of entomopathogenic organisms to control leaf-cutting ants (Hymenoptera: Formicidae: Attini). However, the way leaf-cutting ants react as a colony to biohazards is poorly understood. We investigated the effects of Metarhizium anisopliae (Metschnikoff) (Deuteromycotina: Hyphomycetes) applied to the foraging arenas of mini-nests (queenless sub-colonies) of the leaf-cutting ant Atta sexdens rubropilosa (Forel). Dry spores were applied either alone or mixed with citrus powder, at 0.5 g or 0.05 g per mini-nest. The spores were removed four days after application, and all dead ants removed every three days. Ant numbers near the Metarhizium increased as the ants attempted to clean up the biohazard. The ants attempted to place the spores in piles, which they then covered over with other material. They were able to deal with the low doses in this way, but the high doses overwhelmed them. All treated mini-nests suffered increased ant mortality during the first ten days after application. This mortality was particularly high in the media worker caste which had played the major role in attempting to clean up the spores. Foraging activity decreased, as did the health of the fungus gardens. The mini-nests exposed to the low dose of spores mixed with citrus powder then recovered fully. The health of the other treated mini-nests declined gradually until around 26 days after application, when they began deteriorating sharply. However, the decline of these mini-nests after day 26 was not due directly to the pathogenic action of the Metarhizium, nor to the initial ant mortality it had caused. The results suggest that the social stress caused by even such a short-lived Metarhizium epizootic was sufficient to cause the decline and ultimate death of the mini-nests. This has important implications for the control of leaf-cutting ants. It also demonstrates how important the social homeostasis of the colony is to leaf-cutting ants.     

Behavioural changes in Schistocerca gregaria following infection with a fungal pathogen: implications for susceptibility to predation

1. Field observations have indicated that infection of locusts and grasshoppers by the fungal entomopathogen Metarhizium anisopliae var. acridum may result in a substantial increase in the host's susceptibility to predation, before death is caused directly by the disease. 2. Laboratory experiments were conducted to examine how the behaviour of the desert locust Schistocerca gregaria Forskål changes following infection by M. anisopliae var. acridum to explore some potential mechanisms underlying this phenomenon. 3. In the first experiment, which involved monitoring general locust activity in small cages throughout the disease incubation period, infected locusts were observed to increase locomotion and bodily movement from 3 days after infection until death (average survival time of 11 days). There was some evidence of reduced feeding and mating behaviour following infection. 4. In a second experiment, locusts were exposed individually to a simulated predator attack and the initiation and strength of any escape responses were measured. Infected locusts were observed to have a reduced escape capability (both the propensity to escape and the strength of the response). In contrast to the relatively early changes in general activity observed in the first experiment, this was only apparent at the late stages of infection shortly before death. 5. Both an increase in movement and general apparency early in the infection process, and reduced escape capability late on, suggest mechanisms whereby the susceptibility of locusts and grasshoppers to predation might be enhanced following infection with M. anisopliae var. acridum.     

Laboratory and glasshouse evaluation of entomopathogenic fungi against the two-spotted spider mite, Tetranychus urticae (Acari: Tetranychidae), on tomato, Lycopersicon esculentum

Forty isolates of entomopathogenic fungi from six genera were assessed against the two-spotted spider mite, Tetranychus urticae, in a single dose, direct application laboratory bioassay on tomato leaflets. Only three isolates caused greater mortality than the control: these were Metarhizium anisopliae 442.99, Hirsutella spp. 457.99, and Verticillium lecanii 450.99. These isolates were assessed in a multiple dose bioassay, together with three isolates cultured from commercial biopesticides as follows: Beauveria bassiana 432.99 (cultured from 'Naturalis-L', Troy Biosciences, Phoenix, TX, USA); Hirsutella thompsonii 463.99 (cultured from 'Mycar', Abbott Laboratories USA); and V. lecanii 19.79 (used in 'Mycotal' Koppert BV, The Netherlands). Beauveria bassiana 432.99, H. thompsonii 463.99, M. anisopliae 442.99, and V. lecanii 450.99 were all pathogenic to T. urticae in this bioassay. In addition, it was found that the mortality caused by B. bassiana 432.99 and Naturalis-L was increased when the mites were exposed to tomato leaflets sprayed previously with conidia suspensions, compared to spraying the mites directly. In a glasshouse experiment, sprays of B. bassiana 432.99, H. thompsonii 463.99, M. anisopliae 442.99, V. lecanii 450.99 and Naturalis-L reduced T. urticae populations in a tomato crop grown according to commercial practice. Naturalis-L reduced T. urticae numbers by up to 97%. In a second glasshouse experiment, single sprays of Naturalis-L and the acaricide fenbutatin oxide (Torq) were compared as supplementary treatments to release of the predatory mite, Phytoseiulus persimilis. Supplementary sprays of fenbutatin oxide reduced the numbers of T. urticae nymphs (80% reduction), while Naturalis-L reduced numbers of T. urticae adults, nymphs and eggs (98% reduction in all three cases). It is concluded that Naturalis-L has the potential to be used against T. urticae on glasshouse tomato crops.     

Cuticle degrading proteases from insect moulting fluid and culture filtrates of entomopathogenic fungi

Insects degrade their own cuticle during moulting, a process which is catalysed by a complex mixture of enzymes. Entomopathogenic fungi infect the insect host by penetration of the cuticle, utilizing enzymatic and/or physical mechanisms. Protein is a major component of insect cuticle and a major recyclable resource for the insect and, therefore, represents a significant barrier to the invading fungus. To this end, both insects and entomopathogenic fungi produce a variety of cuticle degrading proteases. The aim of this paper is to review these proteases and to highlight their similarities, with particular reference to the tobacco hornworm, Manduca sexta, and the entomopathogenic fungus, Metarhizium anisopliae     

Control of Bemisia tabaci by entomopathogenic fungi isolated from arid soils in Argentina

Entomopathogenic Hypocreales were isolated from arid soils in Argentina using Tenebrio molitor as bait and tested for their biological performance at 30°C and 45–65% RH. Conidial germination was tested in three vegetable oils (sunflower, olive and maize) at two concentrations (1% and 10%) to evaluate their compatibility for further liquid formulations. According to radial growth and germination results, we selected four isolates to test their pathogenicity against second instar B. tabaci nymphs with the selected oil formulations at 30°C. CEP381 and CEP401 showed the highest radial growth. Isolates CEP381, CEP401, CEP413 and CEP409 (Metarhizium spp.) had similar germination percentages as compared with water control when germinated on either sunflower, olive or maize oils at 10% v/v. The highest mortality of B. tabaci was observed for the isolates CEP381 in sunflower oil and CEP401 in olive oil. Molecular identification of isolates was performed using ITS4–5 primers. All isolates belong to the Metarhizium core group. Tested isolates could grow and infect B. tabaci nymphs at 30°C in some of the vegetable oils as carriers, providing new possibilities for integrated pest management of Bemisia tabaci.     

A Mutant of Metarhizium anisopliae var. acridum with Enhanced Submerged Conidiation

Summary An insertional mutant of Metarhizium anisopliae is described with enhanced submerged conidiation. In a 500 ml submerged culture, this mutant produces a mean of 4.05 × 10⁸ propagules ml⁻¹ from an inoculum of 1 × 10⁶ conidia, where the parental strain accumulates only 3.75 × 10⁴ propagules ml⁻¹.     

人趋化因子MIP-3α的原核可溶性表达及趋化活性分析

目的:克隆人趋化因子MIP3α,进行原核表达并初步鉴定其趋化活性。方法:从人扁桃体中提取总RNA,进行RTPCR,扩增MIP3α成熟蛋白基因,重组于pET32a(+)载体,转化大肠杆菌BL21TrxB(DE3),进行融合表达,Westernblot验证融合蛋白,金属离子亲和层析,肠激酶酶切,弱阳离子交换层析,得到纯化的MIP3α蛋白,趋化试验鉴定其趋化活性。结果:成功构建了MIP3α天然蛋白的硫氧还蛋白融合表达载体,表达并纯化出MIP3α蛋白,Westernblot证明融合蛋白能与羊抗人MIP3α抗体结合,纯化的MIP3α蛋白能趋化HEK293CCR6稳定转染细胞。结论:构建的天然MIP3α融合表达载体以可溶性蛋白的方式稳定表达MIP3α,初步纯化得到的MIP3α具有趋化HEK293CCR6稳定转染细胞的活性。     

金龟子绿僵菌中性海藻糖酶基因的克隆及其表达特性分析

根据中性海藻糖酶NTL基因的同源序列设计引物,PCR扩增出杀蝗专一菌株———金龟子绿僵菌CQMa102NTL基因片段,利用5′_RACE和3′_RACE扩增出NTLcDNA的5′和3′端序列,经拼接得到CQMa102NTL基因cDNA全长。根据其全长cDNA序列,设计引物PCR扩增出CQMa102NTL的完整基因。为了解该基因的上游调控信息,采用PanhandlePolymeraseChainReactionAmplification方法扩增其上游序列。序列分析表明,CQMa102NTL全长DNA3484bp,cDNA全长2385bp,编码737个氨基酸的蛋白,推测蛋白分子量为83.1kD;含有3个内含子,包含一个依赖于cAMP的磷酸化作用位点(RRGS)和一个钙附着位点(DTDGNMQITIED);上游序列含有一个压力反应元件(CCCCT);与金龟子绿僵菌广谱性菌株ME1NTL的核苷酸序列和氨基酸序列分别具有93%和99%同源性,由此确定该序列为金龟子绿僵菌中性海藻糖酶基因序列。Southern杂交表明,NTL基因在CQMa102基因组中为单拷贝。Northern杂交表明,NTL基因转录出约2.5kb的mRNA单带,在液体培养条件下,对数生长前期表达水平最高,对数生长后期降到最低,进入稳定生长期后表达水平又有所提高。金龟子绿僵菌CQMa102中性海藻糖酶基因DNA全长和cDNA全长登录GenBank,登录号分别为:AY557613,AY557612。     

绿僵菌侵染小菜蛾体表过程的显微观察

采用扫描电镜研究了小菜蛾Plutella xylostella体表结构对绿僵菌入侵行为的影响及绿僵菌的侵染过程。结果表明: 绿僵菌孢子在小菜蛾体表萌发后可形成附着胞,寄主体表结构影响形成附着胞的快慢、多少及穿透体壁时芽管长度, 在平缓结构区和刺状结构区比嵴状结构区更易形成附着胞,且芽管较短。在所有结构区,LF68菌株穿透芽管均短于LD65菌株的芽管。接种后7 h,分生孢子在小菜蛾体表开始萌发,LF68与LD65菌株分别于接种后10 h和13 h出现侵染构造穿透体壁。     

Field studies of control of Anoplophora glabripennis (Coleoptera: Cerambycidae) using fiber bands containing the entomopathogenic fungi Metarhizium anisopliae and Beauveria brongniartii

The Asian longhorned beetle, Anoplophora glabripennis, was first found attacking urban street trees in the United States in 1996 and in Canada in 2003. This tree-killing invasive insect has long been a major pest in China and is difficult to control because immature stages live within wood and long-lived adults are often located high in tree canopies. A microbial control product (Biolisa Kamikiri) consisting of non-woven fiber bands impregnated with cultures of an entomopathogenic fungus, Beauveria brongniartii, is marketed in Japan for control of a congeneric orchard pest. Replicated field trials were conducted in Anhui, China to compare Biolisa Kamikiri with similarly prepared bands containing Metarhizium anisopliae for control of A. glabripennis. One fungal band was placed at 2–2.5 m height, around the stem or major scaffold branch on each of 40 willow trees (Salix spp.) per plot, with five plots for each fungal treatment and five control plots. Adult beetles collected from fungal-treated plots 7–22 days after bands were attached to trees died faster than adults from control plots. Beetles exposed to B. brongniartii bands consistently died faster than controls throughout this period, while results from plots with M. anisopliae bands were not as consistent in differing from controls. Numbers of adult beetles from plots of each fungal species dying in <10 days were greater than controls (16% of beetles) but did not differ between fungal treatments (34–35%). Oviposition in fungal-treated plots was approximately half that in control plots. Locations of adult beetles and oviposition scars within tree canopies were quantified to determine optimal locations for band placement. Most adult beetles were found >3.5-m high in trees, with adults in B. brongniartii-treated plots higher within trees than adults in other plots.