Copy Number Variation and Transposable Elements Feature in Recent, Ongoing Adaptation at the Cyp6g1 Locus

Schmidt, Joshua M.; Good, Robert T.; Appleton, Belinda; Sherrard, Jayne; Raymant, Greta; Bogwitz, Michael; Martin, Jon; Daborn, Phillip J.; Goddard, Michael E.; Batterham, Philip; Robin, Charles

doi:10.1371/journal.pgen.1000998

Cited by 277 publications

(394 citation statements)

References 52 publications

(76 reference statements)

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“…While the link between gene amplification and insecticide resistance is commonly encountered for esterases and glutathione Significance levels are indicated by two asterisks (P \ 0.0001), one asterisk (P \ 0.001) or pound sign (P = 0.0016) S-transferases, gene duplication is often less associated with insecticide resistance and cytochrome P450 monooxygenases, though some cases have been documented (Bass and Field 2011). In D. melanogaster, Cyp6g1 has been found as a duplication in wild populations throughout Europe, Asia, and the United States, but increased transcription of Cyp6g1 cannot be dissociated from the presence of a transposable element within the 5 0 promoter region, a common mechanism of overexpression of P450 genes (Schmidt et al 2010). Overexpression of Cyp12d1 in a transgenic fly system resulted in flies with tolerance to DDT, ostensibly due to the increased metabolism of the compound, but other P450 genes associated with DDT resistance (Cyp6a2, Cyp6a8) do not seem to increase DDT metabolism (Daborn et al 2001).…”

Section: Discussionmentioning

confidence: 99%

“…The Cyp12d1 duplication has been estimated to occur within *80 % of the individuals within a wild population, but the proportion of individuals carrying the duplication was not different between unexposed field populations and survivors of DDT exposure (Schmidt et al 2010). If the Cyp12d1 duplication does not seem to increase detoxification activity toward DDT, as posited by the positive dosage model (Kondrashov et al 2002), then why does it seem to be so prevalent in the wild?…”

Section: Introductionmentioning

confidence: 99%

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Evolutionary Toxicogenomics: Diversification of the Cyp12d1 and Cyp12d3 Genes in Drosophila Species

et al. 2012

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Evolutionary Toxicogenomics: Diversification of the Cyp12d1 and Cyp12d3 Genes in Drosophila Species

et al. 2012

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“…In D. melanogaster, an allelic series at the cytochrome P450 Cyp6g1 locus involves a gene duplication and a variety of transposable element (TE) insertions. The most derived alleles are correlated with increased enzyme production and multiinsecticide resistance, including dichlorodiphenyltrichloroethane (DDT) (24).…”

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confidence: 99%

“…For the Rdl duplicated lines, our data suggest ectopic recombination in neighboring Roo TEs initiated the genome rearrangement. TEs and genome rearrangements have previously been implicated in adaptation to environmental pressures such as insecticide resistance (24,37,38). TEs contribute substantially to adaptive evolution and have the capacity to generate deletions, duplications, and regulatory changes with wide-ranging phenotypic effects that cannot be achieved by point mutations (39).…”

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confidence: 99%

Gene duplication in the major insecticide target site,Rdl, inDrosophila melanogaster

Remnant

Good

Schmidt

et al. 2013

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

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The Resistance to Dieldrin gene, Rdl, encodes a GABA-gated chloride channel subunit that is targeted by cyclodiene and phenylpyrazole insecticides. The gene was first characterized in Drosophila melanogaster by genetic mapping of resistance to the cyclodiene dieldrin. The 4,000-fold resistance observed was due to a single amino acid replacement, Ala 301 to Ser. The equivalent change was subsequently identified in Rdl orthologs of a large range of resistant insect species. Here, we report identification of a duplication at the Rdl locus in D. melanogaster. The 113-kb duplication contains one WT copy of Rdl and a second copy with two point mutations: an Ala 301 to Ser resistance mutation and Met 360 to Ile replacement. Individuals with this duplication exhibit intermediate dieldrin resistance compared with single copy Ser 301 homozygotes, reduced temperature sensitivity, and altered RNA editing associated with the resistant allele. Ectopic recombination between Roo transposable elements is involved in generating this genomic rearrangement. The duplication phenotypes were confirmed by construction of a transgenic, artificial duplication integrating the 55.7-kb Rdl locus with a Ser 301 change into an Ala 301 background. Gene duplications can contribute significantly to the evolution of insecticide resistance, most commonly by increasing the amount of gene product produced. Here however, duplication of the Rdl target site creates permanent heterozygosity, providing unique potential for adaptive mutations to accrue in one copy, without abolishing the endogenous role of an essential gene.T he single point mutation in the Resistance to dieldrin (Rdl) gene represents one of the most significant cases of target site resistance to an insecticide yet observed. Cyclodiene resistance was reported in 62% of insecticide resistant species in the 1980s, following widespread use of cyclodiene insecticides, including dieldrin, which started in the 1950s (1). The nature of the genetic target, Rdl, was discovered after dieldrin was discontinued because of the widespread evolution of resistance in many species. Rdl was first discovered in Drosophila melanogaster using a positional cloning approach. High homology to human GABA receptors confirmed it was the first insect ligand-gated chloride channel subunit identified (2-4). A point mutation in the chloride channel pore-lining domain, replacing alanine 301 with serine, was present in all resistant D. melanogaster strains (5). This mutation provided 4,000-fold resistance when homozygous and lower levels of resistance in heterozygotes (2, 6). The homologous mutation was subsequently found in a large number of cyclodiene-resistant species from many insect orders (7-9), as well as a glycine replacement at the homologous site in some resistant strains of Drosophila simulans and other species (5, 10, 11).Characterization of deficiency lines and inversions in D. melanogaster showed that Rdl is an essential gene (3). Thus, the Ala 301 to Ser or Gly mutation in Rdl exhibits unique properties, p...

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“…Like Drosophila, most host genomes are occupied by multiple TE families, which are defined by sequence similarity (homology) and by replication and transposition mechanisms. Even though incidences of potentially adaptive individual TE insertions with high population frequencies have been reported (Daborn et al 2002; Aminetzach et al 2005;González et al 2008;Schmidt et al 2010), the mutagenic effects of TE insertions are typically deleterious because they disrupt gene structure and function (Finnegan 1992) and can lead to deleterious chromosomal rearrangement (Montgomery et al 1987(Montgomery et al , 1991Langley et al 1988). Supporting this, TEs in natural populations of Drosophila are generally found in intergenic regions (Aquadro et al 1986;Kaminker et al 2002; Bergman et al 2006) Because of these deleterious fitness impacts of TEs on their hosts, the interaction between host and TEs has been suggested to be analogous to an arms race between host and other more familiar pathogens (Kidwell and Lisch 2001;Aravin et al 2007;Siomi et al 2008;Obbard et al 2009a;Blumenstiel 2011).…”

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confidence: 99%

Long-Term and Short-Term Evolutionary Impacts of Transposable Elements onDrosophila

Lee

Langley

2012

Genetics

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Transposable elements (TEs) are considered to be genomic parasites and their interactions with their hosts have been likened to the coevolution between host and other nongenomic, horizontally transferred pathogens. TE families, however, are vertically inherited as integral segments of the nuclear genome. This transmission strategy has been suggested to weaken the selective benefits of host alleles repressing the transposition of specific TE variants. On the other hand, the elevated rates of TE transposition and high incidences of deleterious mutations observed during the rare cases of horizontal transfers of TE families between species could create at least a transient process analogous to the influence of horizontally transmitted pathogens. Here, we formally address this analogy, using empirical and theoretical analysis to specify the mechanism of how host-TE interactions may drive the evolution of host genes. We found that host TE-interacting genes actually have more pervasive evidence of adaptive evolution than immunity genes that interact with nongenomic pathogens in Drosophila. Yet, both our theoretical modeling and empirical observations comparing Drosophila melanogaster populations before and after the horizontal transfer of P elements, which invaded D. melanogaster early last century, demonstrated that horizontally transferred TEs have only a limited influence on host TE-interacting genes. We propose that the more prevalent and constant interaction with multiple vertically transmitted TE families may instead be the main force driving the fast evolution of TE-interacting genes, which is fundamentally different from the gene-for-gene interaction of host-pathogen coevolution. HOST-PATHOGEN interactions affect the population dynamics and the evolutionary trajectories of both species. In particular, coevolutionary dynamics will affect the pattern of polymorphism and divergence of genes underlying hostparasite interactions either through an arms race (Van Valen 1973;Dawkins and Krebs 1979) or through balancing selection (Haldane 1949;Hughes et al. 1990; Takahata et al. 1992;Hughes and Yeager 1998;Rose et al. 2004). In either case, accelerated rates of protein evolution and/or recurrent adaptive substitutions are expected in genes engaged in these interactions, which has been observed in both immunity genes (Schlenke and Begun 2003;Jiggins and Kim 2007;Sackton et al. 2007;Obbard et al. 2009b) and antivirus siRNA genes (Obbard et al. 2006(Obbard et al. , 2009a(Obbard et al. ,b, 2011 in Drosophila.Transposable elements (TEs) are ubiquitous genomic constituents that increase their copy number (the number of TEs in a host genome) by replicative transposition (copying to new genomic locations). Like Drosophila, most host genomes are occupied by multiple TE families, which are defined by sequence similarity (homology) and by replication and transposition mechanisms. Even though incidences of potentially adaptive individual TE insertions with high population frequencies have been reported (Daborn et al. 20...

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Copy Number Variation and Transposable Elements Feature in Recent, Ongoing Adaptation at the Cyp6g1 Locus

Cited by 277 publications

References 52 publications

Evolutionary Toxicogenomics: Diversification of the Cyp12d1 and Cyp12d3 Genes in Drosophila Species

Evolutionary Toxicogenomics: Diversification of the Cyp12d1 and Cyp12d3 Genes in Drosophila Species

Gene duplication in the major insecticide target site,Rdl, inDrosophila melanogaster

Long-Term and Short-Term Evolutionary Impacts of Transposable Elements onDrosophila

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