Martin Kaussmann scite author profile

Host plant shifts of herbivorous insects may be a first step toward sympatric speciation and can create new pests of agriculturally important crops; however, the molecular mechanisms that mediate this process are poorly understood. Certain races of the polyphagous aphid Myzus persicae have recently adapted to feed on tobacco (Myzus persicae nicotianae) and show a reduced sensitivity to the plant alkaloid nicotine and cross-resistance to neonicotinoids a class of synthetic insecticides widely used for control. Here we show constitutive overexpression of a cytochrome P450 (CYP6CY3) allows tobacco-adapted races of M. persicae to efficiently detoxify nicotine and has preadapted them to resist neonicotinoid insecticides. CYP6CY3, is highly overexpressed in M. persicae nicotianae clones from three continents compared with M. persicae s.s. and expression level is significantly correlated with tolerance to nicotine. CYP6CY3 is highly efficient (compared with the primary human nicotine-metabolizing P450) at metabolizing nicotine and neonicotinoids to less toxic metabolites in vitro and generation of transgenic Drosophila expressing CYP6CY3 demonstrate that it confers resistance to both compounds in vivo. Overexpression of CYP6CY3 results from the expansion of a dinucleotide microsatellite in the promoter region and a recent gene amplification, with some aphid clones carrying up to 100 copies. We conclude that the mutations leading to overexpression of CYP6CY3 were a prerequisite for the host shift of M. persicae to tobacco and that gene amplification and microsatellite polymorphism are evolutionary drivers in insect host adaptation.T oxic secondary metabolites produced by many plant species present barriers to host range expansion by phytophagous insects, and the evolution of mechanisms to circumvent or detoxify these antiherbivore defenses is often a prerequisite for a successful host shift (1-3). Several studies have elucidated the molecular basis of insect adaptation to plant allelochemicals (4-7); however, most of these studies have examined adaptation that has occurred over a long evolutionary time scale and so have been unable to make direct comparisons with nonadapted conspecific races. As a result, identifying the initial genetic changes that enable a host shift has proved elusive. The recent host shift to tobacco (Nicotiana tabacum) by the peach-potato aphid, Myzus persicae, represents one of the few opportunities to study this evolutionary process in action (8). M. persicae is a globally distributed highly polyphagous aphid with a host range of >400 species, including many economically important crop plants (9). Tobacco-adapted races, Myzus persicae nicotianae, are morphologically and genetically differentiated from M. persicae sensu stricto (s.s.), although there are clear examples of recent gene flow between the two taxa (10). M. persicae nicotianae have evolved enhanced tolerance to the pyridine alkaloid nicotine (11), a potent natural insecticide produced by tobacco and other members of the Solanaceae famil...

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A brain-specific cytochrome P450 responsible for the majority of deltamethrin resistance in the QTC279 strain of Tribolium castaneum

Zhu

Parthasarathy

Bai

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

278

195

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Cytochrome P450-mediated detoxification is one of the most important mechanisms involved in insecticide resistance. However, the molecular basis of this mechanism and the physiological functions of P450s associated with insecticide resistance remain largely unknown. Here, we exploited the functional genomics and reverse genetic approaches to identify and characterize a P450 gene responsible for the majority of deltamethrin resistance observed in the QTC279 strain of Tribolium castaneum. We used recently completed whole-genome sequence of T. castaneum to prepare custom microarrays and identified a P450 gene, CYP6BQ9, which showed more than a 200-fold higher expression in the deltamethrin-resistant QTC279 strain when compared with its expression in the deltamethrin-susceptible Lab-S strain. Functional studies using both double-strand RNA (dsRNA)-mediated knockdown in the expression of CYP6BQ9 and transgenic expression of CYP6BQ9 in Drosophila melanogaster showed that CYP6BQ9 confers deltamethrin resistance. Furthermore, CYP6BQ9 enzyme expressed in baculovirus metabolizes deltamethrin to 4-hydroxy deltamethrin. Strikingly, we also found that unlike many P450 genes involved in insecticide resistance that were reported previously, CYP6BQ9 is predominantly expressed in the brain, a part of the central nervous system (CNS) containing voltage-gated sodium channels targeted by deltamethrin. Taken together, the current studies on the brain-specific insect P450 involved in deltamethrin resistance shed new light on the understanding of the molecular basis and evolution of insecticide resistance.functional genomics | insecticide resistance | RNA interference | transgenic expression | insecticide metabolism

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Functional Characterization and Comparison of the Outer Blood–Retina Barrier and the Blood–Brain Barrier

Steuer

Jaworski

Elger

et al. 2005

Invest. Ophthalmol. Vis. Sci.

132

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Molecular and functional characterization of CYP6BQ23, a cytochrome P450 conferring resistance to pyrethroids in European populations of pollen beetle, Meligethes aeneus

Zimmer

Bass

Williamson

et al. 2014

Insect Biochemistry and Molecular Biology

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