A cuticle-degrading protease (CDEP-1) of Beauveria bassiana enhances virulence

In order to investigate virulence enhancement of entomopathogenic fungi, a Beauveria bassiana-sourced Pr1 protease (CDEP-1) was expressed by a methylotrophic yeast Pichia pastoris and then used as an additive to three gradient sprays of B. bassiana strain (Bb0062) onto apterous green peach aphid Myzus persicae adults in six bioassays. The resultant data fit well to a time–concentration–mortality model. Generally, the LC₅₀ estimates of the fungal pathogen against the aphid species decreased with increasing CDEP-1 concentrations from 0 to 100 µg mL^?1. The LC₅₀s on days 5–7 after spray were reduced by 1.5–2.5-fold at the concentrations of 20–100 µg mL^?1. However, sprays of 20–100 µg CDEP-1 mL^?1 aqueous solution alone had no significant effect on aphid mortality compared to water spray only. Neither did inclusion of inactivated CDEP-1 at a concentration of 50 µg mL^?1 affect significantly the fungal virulence to aphids. Our results confirm for the first time that the cuticle-degrading protease CDEP-1 enhanced fungal virulence due to acceleration of conidial germination and cuticle penetration. This suggests a new approach to utilising the protease in microbial control.     

New methods for the detection of insecticide resistant Myzus persicae in the U.K. suction trap network

1  Myzus persicae is a highly polyphagous pest of U.K. agriculture. It presents particular control difficulties because it has developed resistance to several insecticide classes.
2 For almost 20 years, M. persicae collected in the U.K. suction trap network have been analysed for insecticide resistance and the data disseminated to growers via a resistance bulletin. These data are generated by the biochemical analysis of individuals for two major resistance phenotypes: (i) elevated carboxylesterase and (ii) modified acetylcholinesterase (MACE).
3 The development of new polymerase chain reaction (PCR)-based technologies using fluorescently labelled probes has allowed other resistance mechanisms, such as knockdown resistance to pyrethroids (kdr/super-kdr), to be detected and has greatly increased the speed and accuracy of resistance monitoring. Unfortunately, these newer PCR-based assays are incompatible with the older biochemical assays.
4 The present study describes the development and testing of new compatible methods for detecting elevated carboxylesterases and MACE for use on M. persicae caught in the field or suction traps.
5 These new tests have significant advantages over present methodologies by allowing individual aphids to be tested for three resistance mechanisms quickly and accurately on a single platform.     

杀虫剂不同施用方式对烟蚜抗药性发展和羧酸酯酶活力的影响

室内模拟田间杀虫剂施药方式,研究3种杀虫剂连用及其顺序轮用对烟蚜Myzus persicae(Sulzer)抗药性发展和羧酸酯酶活力的影响。结果表明,氧化乐果、灭多威、高效氟氯氰菊酯连续施药9次后,其抗性分别增长73.3,8.9,10.4倍;氧化乐果→灭多威→高效氟氯氰菊酯顺序轮用3次(施药9次)后,氧化乐果抗性指数增长了47.3倍,灭多威抗性指数增长了6.7倍,高效氟氯氰菊酯抗性指数增长了5.0倍。羧酸酯酶活力检测结果表明,3种杀虫剂连用9次后,烟蚜种群的α-NACarE活力分别增长了20.0,24.0和15.6倍,酶活力在0.6(OD600nm/aphid/min)以上的个体比例分别增加了73.4%,87.6%和43.8%;而3种杀虫剂顺序轮用3次(施药9次)后,烟蚜种群的α-NACarE活力增长了10.2倍,酶活力在0.6以上的个体比例增加了4.8%。结果证实杀虫剂轮换施用能延缓烟蚜抗药性的发展和烟蚜种群α-NACarE活力及高活力个体频率的增加。     

An Aphid-Secreted Salivary Protease Activates Plant Defense in Phloem

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Survival, growth, and reproduction of two aphid species on sucrose solutions containing host or non-host honeydews

Aphids, like most phloem-feeding insects, commonly exhibit a high degree of host specificity. Plant-specific chemical compounds are likely to serve as important host selection cues for monophagous aphids and such substances could be present in aphid honeydew. Apterous virginoparae ofMyzus persicae (Sulzer) andPhorodon humuli (Schrank) were reared on a buffered sucrose solution containing various aphid honeydews or a mixture of amino acids. In two separate experiments, the host-specificP. humuli (hop aphid) could grow and reproduce only on diets containing honeydew collected from hop (Humulus lupulus L.).M. persicae (the green peach aphid, GPA) did not perform well on diets containing hop honeydew, perhaps because hop is a poor GPA host. Honeydew collected from preferred GPA host plants rape,Brassica napus L., and jimsonweed,Datura stramonium L., allowed GPA growth and reproduction. Hop aphids, however, performed poorly on rape and jimsonweed honeydew diets. Bell pepper,Capsicum annuum L., honeydew supported neither the hop aphid nor GPA. The study of aphid honeydew components may contribute towards a more complete understanding of host preference and selection phenomena in aphids.     

The production of different morphs by alate viviparae of the aphid Myzus persicae temporarily exposed to long scotophases

The development of alatae of the green peach aphid, Myzus persicae, as gynoparae rather than as virginoparae was investigated with regard to the number of exposures to a long-night (LN) regime of 15 h darkness per diem which the aphids experienced before and/or after their birth. The minimum number of exposures to LN that resulted in all of the alatae developing into gynoparae was two prenatal plus one postnatal or one prenatal plus two postnatal, provided the scotophases in these treatments were at least 12 h long. A cumulative effect of several successive exposures to LN was also evident when the presumptive alatae were exposed to LN either from birth or not until several days after birth. Fewer exposures to LN were needed in the former case.

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Zusammenfassung Die Entwicklung von Alatae der grünen Pfirsichblattlaus, Myzus persicae, hauptsächlich zu Gynoparae, eher als zu Virginoparae, wurde im Hinblick auf den Einfluss der Anzahl an Langnächten (LN: 15 Studen Dunkelheit pro Tag), denen die Aphiden vor und/oder nach der Geburt ausgesetzt waren, untersucht. Zur ausschliesslichen Entwicklung aller Alatae zu Gynoparae waren mindestens 2 prenatale und eine postnatale LN-Exposition oder eine prenatale und 2 postnatale LN-Expositionen notwendig, vorausgesetzt die Dunkelphasen betrugen mindestens 12 Stunden. Ausserdem zeigte sich ein kumulativer Effect durch mehrere, aufeinanderfolgende LN-Expositionen, wenn die Alatae diesen von Geburt an, oder einige Tage nach der Geburt, ausgesetzt waren. Im ersten Fall waren weniger LN-Expositionen notwendig.

     

MALE PEACH APHID ATTRACTION IN THE FIELD BY SEX PHEROMONES1)

Abstract Field trials by sex pheromone of aphid to trap peach aphids Myzus persicae have been carried out in 1995 and in 1996. Suitable time and the effect of ratio of two components nepetalactone and nepetalactol to apply the lure have been observed.     

Mechanisms of host discrimination and intraspecific competition in the aphid parasitoid Ephedrus cerasicola

The aphid parasitoid Ephedrus cerasicola Starý (Hymenoptera: Aphidiidae) discriminates between parasitized and unparasitized aphid hosts (Myzus persicae (Sulzer), Homoptera: Aphididae) in two different ways. By antennal contact with the parasitized host, it can detect an external marking pheromone which is effective only for a few hours. The behaviour of the parasitoid also indicated that it responded to an internal marker, probably by means of chemoreceptors on the ovipositor. The parasitoid behaviour was studied in encounters with parasitized hosts 0–10 min, 2–3 h, 6–7 h and 23–24 h after the first parasitization. Aphids were superparasitized within 1 h or after 24 h, and aphids in each experiment were later dissected at two different times. It is suggested that the supernumerary offspring were eliminated by chemical means, whether the time between the two ovipositions was 0–1 h or 24 h.

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Résumé Le parasitoïde de puceron, E. cerasicola Starý (Hym.: Aphidiidae) sélectionne les pucerons, Myzus persicae (Sulzer), parasités ou non, de deux façons différentes. Il peut percevoir une phéromone externe de marquage perceptible seulement pendant quelques heures par contact antennaire. Son comportement montre qu'il réagit aussi à un marquage interne, probablement par des chémorécepteurs de sa tarière. Le comportement du parasitoïde a été étudié en le mettant en contact avec des hôtes parasités depuis 0–10 min, 2–3 h, 6–7 h et 23–24 h. Les pucerons ont été surparasités pendant la première heure ou après 24 heures. Les pucerons de toutes les expériences ont été disséqués à deux moments différents. Ceci a conduit à estimer que les descendants en surnombre ont été éliminés chimiquement quand la période entre deux pontes successives était inférieure à 1 h ou supérieure à 24 h.

     

Intercropping oilseed rape as a potential relay crop for enhancing the biological control of green peach aphids and aphid‐transmitted virus diseases

Tobacco viruses transmitted by green peach aphids, Myzus persicae (Sulzer) (Hemiptera: Aphididae), cause severe disease in flue‐cured tobacco, Nicotiana tabacum L. (Solanaceae), in China and throughout the world. Field experiments were conducted in 2016 and 2017 in Longyan City, Fujian Province, China, to determine whether M. persicae and aphid‐transmitted virus diseases are affected by intercropping of oilseed rape, Brassica napus L. (Brassicaceae), in tobacco fields. The results showed that, compared with those in monocultured fields, the densities of M. persicae and winged aphids in intercropped fields significantly decreased in both 2016 and 2017. In particular, the appearance of winged aphids was delayed by ca. 7 days. Moreover, the densities of Aphidius gifuensis Ashmead (Hymenoptera: Aphidiidae), a parasitoid of the aphid, significantly increased in 2016 and 2017. Accordingly, the incidence rates of aphid‐transmitted virus diseases (those caused by the cucumber mosaic virus, potato virus Y, and tobacco etch virus) significantly decreased in the intercropped fields in 2016 and 2017. Tobacco yields and monetary value significantly increased in 2016 (by 10–25 and 14–29%, respectively) and 2017 (by 17–22 and 22–34%, respectively). Consequently, our results suggest that intercropping oilseed rape in tobacco fields is a good approach to regulating and controlling aphids and tobacco mosaic viruses, for example potyvirus, and this intercropping can help control aphid‐transmitted virus diseases in tobacco.