The
            <i>Anopheles gambiae</i>
            detoxification chip: A highly specific microarray to study metabolic-based insecticide resistance in malaria vectors

David, Jean‐Philippe; Strode, Clare; Vontas, John; Nikou, Dimitra; Vaughan, Ashley M.; Pignatelli, Patricia; Louis, Christos; Hemingway, Janet; Ranson, Hilary

doi:10.1073/pnas.0409348102

Cited by 294 publications

(321 citation statements)

References 32 publications

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“…Afterward, the development of mosquito DNA microarrays allowed screening for resistance genes based on their differential transcription, leading to the identification of detoxification genes conferring resistance (David et al 2005Strode et al 2008;Vontas et al 2010;Edi et al 2014). However, these screenings focused on differential transcription while genomic changes such as CNVs and polymorphisms were neglected.…”

Section: Discussionmentioning

confidence: 99%

Identifying genomic changes associated with insecticide resistance in the dengue mosquito Aedes aegypti by deep targeted sequencing

et al. 2015

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The capacity of mosquitoes to resist insecticides threatens the control of diseases such as dengue and malaria. Until alternative control tools are implemented, characterizing resistance mechanisms is crucial for managing resistance in natural populations. Insecticide biodegradation by detoxification enzymes is a common resistance mechanism; however, the genomic changes underlying this mechanism have rarely been identified, precluding individual resistance genotyping. In particular, the role of copy number variations (CNVs) and polymorphisms of detoxification enzymes have never been investigated at the genome level, although they can represent robust markers of metabolic resistance. In this context, we combined target enrichment with high-throughput sequencing for conducting the first comprehensive screening of gene amplifications and polymorphisms associated with insecticide resistance in mosquitoes. More than 760 candidate genes were captured and deep sequenced in several populations of the dengue mosquito Ae. aegypti displaying distinct genetic backgrounds and contrasted resistance levels to the insecticide deltamethrin. CNV analysis identified 41 gene amplifications associated with resistance, most affecting cytochrome P450s overtranscribed in resistant populations. Polymorphism analysis detected more than 30,000 variants and strong selection footprints in specific genomic regions. Combining Bayesian and allele frequency filtering approaches identified 55 nonsynonymous variants strongly associated with resistance. Both CNVs and polymorphisms were conserved within regions but differed across continents, confirming that genomic changes underlying metabolic resistance to insecticides are not universal. By identifying novel DNA markers of insecticide resistance, this study opens the way for tracking down metabolic changes developed by mosquitoes to resist insecticides within and among populations.

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Section: Discussionmentioning

confidence: 99%

Identifying genomic changes associated with insecticide resistance in the dengue mosquito Aedes aegypti by deep targeted sequencing

et al. 2015

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“…In Drosophila this technique has been used to identify responses to chemical stressors such as paraquat, H 2 O 2 and tunicamycin (Zou et al, 2000;Girardot et al, 2004). Similarly, DNA microarrays have been used to detect genes that are constitutively overexpressed in insecticide-resistant strains from Drosophila and mosquitoes obtained from the fi eld or selected further in the laboratory (Daborn et al, 2002;David et al, 2005;Le Goff et al, 2003;Pedra et al, 2004;Vontas et al, 2005). The design of microarrays that selectively represent all members of the detoxifi cation gene families and appropriate controls genes can provide a useful tool to identify inducible genes.…”

Section: Introductionmentioning

confidence: 99%

Xenobiotic response in Drosophila melanogaster: Sex dependence of P450 and GST gene induction

Goff

Hilliou

Siegfried

et al. 2006

Insect Biochemistry and Molecular Biology

146

109

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“…In addition, the availability of the genome sequence facilitates the development of high-throughput genome wide technologies such as high density expression micro-array, genome tiling array, or chipchip methodology. David et al (2005), for example, developed the first micro-array to study insecticide resistance in malaria vectors. More recently, Vontas et al (2007) monitored gene expression in insecticide resistant and susceptible strains of A. stephensi and identify a small number of genes putatively differentially expressed between the strains.…”

Section: The Use Of Genomic Datamentioning

confidence: 99%

“…A better understanding of the biology of the vector can lead to a faster identification of new targets and ultimately new control measures. For example, David et al (2005) used the A. gambiae annotations and expression profiling using micro-arrays to identify genes involved in insecticide resistance. A potential list of 230 genes was reduced to just five that were highly regulated in insecticide resistant mosquito strains.…”

Section: The Use Of Genomic Datamentioning

confidence: 99%

Genomic resources for invertebrate vectors of human pathogens, and the role of VectorBase

Mégy

Hammond

Lawson

et al. 2009

Infection, Genetics and Evolution

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High-throughput genome sequencing techniques have now reached vector biology with an emphasis on those species that are vectors of human pathogens. The first mosquito to be sequenced was Anopheles gambiae, the vector for Plasmodium parasites that cause malaria. Further mosquitoes have followed: Aedes aegypti (Yellow fever and Dengue fever vector) and Culex pipiens (lymphatic filariasis and West Nile fever). Species that are currently in sequencing include the body louse Pediculus humanus (Typhus vector), the triatomine Rhodnius prolixus (Chagas disease vector) and the tick Ixodes scapularis (Lyme disease vector). The motivations for sequencing vector genomes are to further understand vector biology, with an eye on developing new control strategies (for example novel chemical attractants or repellents) or understanding the limitations of current strategies (for example the mechanism of insecticide resistance); to analyse the mechanisms driving their evolution; and to perform an exhaustive analysis of the gene repertory. The proliferation of genomic data creates the need for efficient and accessible storage. We present VectorBase, a genomic resource centre that is both involved in the annotation of vector genomes and act as a portal for access to the genomic information (http://www.vectorbase.org).

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The Anopheles gambiae detoxification chip: A highly specific microarray to study metabolic-based insecticide resistance in malaria vectors

Cited by 294 publications

References 32 publications

Identifying genomic changes associated with insecticide resistance in the dengue mosquito Aedes aegypti by deep targeted sequencing

Identifying genomic changes associated with insecticide resistance in the dengue mosquito Aedes aegypti by deep targeted sequencing

Xenobiotic response in Drosophila melanogaster: Sex dependence of P450 and GST gene induction

Genomic resources for invertebrate vectors of human pathogens, and the role of VectorBase

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