Comparative molecular modeling of
            <i>Anopheles gambiae</i>
            CYP6Z1, a mosquito P450 capable of metabolizing DDT

Chiu, Ting Lan; Wen, Zheng; Rupasinghe, Sanjeewa G.; Schuler, Mary A.

doi:10.1073/pnas.0709249105

Cited by 166 publications

(143 citation statements)

References 50 publications

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“…One involves mutations in regulatory systems controlling general responses to chemical stresses which upregulate the expression of many gene/enzyme systems with a range of detoxification functions. 15,16) The other involves a population genetic process called 'hitchhiking,' whereby strong positive selection such as that which operates on insecticide resistance mechanisms necessarily entrains large gene frequency changes in other polymorphisms that are genetically linked to those causally involved in resistance. The key point here is that genes encoding detoxifying systems are often arranged in tightly linked clusters in insect genomes.…”

Section: Heliothine Resistance To Opsmentioning

confidence: 99%

Esterase-based metabolic resistance to insecticides in heliothine and spodopteran pests

et al. 2010

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IntroductionCarboxylesterases have been implicated in metabolic resistance to several classes of insecticide in a wide variety of pest insect species. [1][2][3] The classes most commonly involved are synthetic pyrethroids (SPs) and organophosphates (OPs), and carbamates (CBs) are also involved in several cases. There are also occasional reports of carboxylesterase phenotypes associated with resistance to benzoylureas, the oxadiazine indoxacarb, the diacylhydrazine tebufenozide, the organochlorine endosulfan and the proteinaceous Cry1Ac toxin of Bacillus thuringiensis that is expressed in transgenic crops. Figure 1 gives structures for some key compounds among these various classes of insecticide.It might be expected that carboxylesterases would be involved in SP resistance because the great majority of SPs are carboxylesters. However, no precise molecular mechanisms for esterase-based SP resistance have yet been elucidated in any insect. OPs are generally phosphotriesters rather than carboxylesters but nevertheless they bind many carboxylesterases with high affinity and this provides a basis for two forms of resistance, both now elucidated at a molecular level in several species. One form involves substantial overexpression of the esterase, allowing for effective sequestration of the insecticide. The other involves specific mutations in the active site of the enzyme which convert it to an OP hydrolase (the so-called "mutant ali-esterase" mechanism). CBs are carbamic acid (NH 2 COOH) derivatives, in which a functional group has been added as an ester; these esters are chemically similar to carboxylesters. Carbamates bind carboxylesterases with quite high affinity, but as yet the molecular mechanisms by which a (mutant) carboxylesterase confers CB resistance have not been elucidated in any species. Of the other insecticide classes occasionally linked to esterase-based resistance only indoxacarb has ester bonds (two Elevated esterase activities and increased band intensities of multiple esterase isozymes after electrophoresis are commonly associated with resistance to organophosphate, pyrethroid and carbamate insecticides in various heliothine and spodopteran pests. One possible explanation for this involves a 'master regulator' mutation in a more general chemical stress response. An association between elevated esterase activities and isozyme intensities has also been reported for resistance to the Cry1Ac toxin of Helicoverpa armigera. The basis for this is unclear albeit some involvement of esterases could be mediated by the toxin's affinity for N-acetyl galactosamine glycans on certain gut-expressed esterases in this species.

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Section: Heliothine Resistance To Opsmentioning

confidence: 99%

Esterase-based metabolic resistance to insecticides in heliothine and spodopteran pests

et al. 2010

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“…Confirmatory evidence of a direct role in resistance must come from in vitro metabolism of insecticides with heterologously expressed CYP450, and for a limited number of 4 CYP450s this evidence has been attained (Chiu et al, 2008;Mitchell et al, 2012;Muller et al, 2008;Stevenson et al, 2011). However, whilst gene expression differences coupled with in vitro metabolic activities have confirmed the roles of a number of CYP450s in metabolic resistance to insecticides, to date, the causal mutations that result in this over-expression have remained elusive.…”

Section: Introductionmentioning

confidence: 99%

A cis-regulatory sequence driving metabolic insecticide resistance in mosquitoes: Functional characterisation and signatures of selection

Wilding

Smith

Lynd

et al. 2012

Insect Biochemistry and Molecular Biology

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Although cytochrome P450 (CYP450) enzymes are frequently up-regulated in mosquitoes resistant to insecticides, no regulatory motifs driving these expression differences with relevance to wild populations have been identified. Transposable elements (TEs) are often enriched upstream of those CYP450s involved in insecticide resistance, leading to the assumption that they contribute regulatory motifs that directly underlie the resistance phenotype. A partial CuRE1 (Culex Repetitive Element 1) transposable element is found directly upstream of CYP9M10, a cytochrome P450 implicated previously in larval resistance to permethrin in the ISOP450 strain of Cx. quinquefasciatus, but is absent from the equivalent genomic region of a susceptible strain. Via expression of CYP9M10 in E.coli we have now demonstrated time-and NADPH-dependant permethrin metabolism, prerequisites for confirmation of a role in metabolic resistance, and through qPCR shown that CYP9M10 is >20-fold over-expressed in ISOP450 compared to a susceptible strain. In a fluorescent reporter assay the region upstream of CYP9M10 from ISOP450 drove 10x expression compared to the equivalent region (lacking CuRE1) from the susceptible strain. Close correspondence with the gene expression fold-change implicates the upstream region including CuRE1 as a cis-regulatory element involved in resistance. Only a single CuRE1 bearing allele, identical to the CuRE1 bearing allele in the resistant strain, is found throughout Sub-Saharan Africa, in contrast to the diversity encountered in non-CuRE1 alleles. This suggests a single origin and subsequent spread due to selective advantage. CuRE1 is detectable using a simple diagnostic. When applied to Cx. quinquefasciatus larvae from Ghana we have demonstrated a significant association with permethrin resistance in multiple field sites (mean Odds Ratio = 3.86) suggesting this marker has relevance to natural populations of vector mosquitoes. However, when CuRE1 was excised from the allele used in the reporter assay through fusion PCR, expression was unaffected, indicating that the TE has no direct role in resistance and hence that CuRE1 is acting only as a marker of an as yet unidentified regulatory motif in the association analysis. This suggests that a re-evaluation of the assumption that TEs contribute regulatory motifs involved in gene expression may be necessary. 3 IntroductionThe control of a number of pernicious mosquito-borne diseases such as malaria, lymphatic filariasis Chanda et al., 2011;Himeidan et al., 2011; Mathias et al., 2011; Yewhalaw et al., 2011). Given that many resistance mutations are thought to be recessive in expression, development of DNA diagnostics enables disease and agricultural control programmes to identify resistance mechanisms when they are at low frequency and take ameliorating action before they cause economic or health impacts (Hemingway, 2009;Kelly-Hope et al., 2008). As shown in a number of recent studies, resistance alleles can rise towards fixation very rapidly (García et al., 2009;L...

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“…Four main clades (mitochondrial clade, CYP2, CYP3 and CYP4 clade) exist and in terms of pesticide metabolism the clade that is of interest is the CYP3 clade, a clade which includes the important mammalian CYP3A4 and insect homologues of this enzyme, namely the CYP6 and CYP9 families e.g. CYP6Z1 (Chiu et al, 2008) and CYP6P3 (Muller et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

Isolation of the monooxygenase complex from Rhipicephalus (Boophilus) microplus – clues to understanding acaricide resistance

Graham¹,

Sparagano²,

Finn³

2016

Ticks and Tick-borne Diseases

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This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. A c c e p t e d M a n u s c r i p t AbstractThe monooxygenase complex is composed of three key proteins, a cytochrome P450 (CYP), the cytochrome P450 oxidoreductase (CPR) and cytochrome b 5 and plays a key role in the metabolism and detoxification of xenobiotic substances, including pesticides. In addition, overexpression of these components has been linked to pesticide resistance in several important vectors of disease. Despite this, the monooxygenase complex has not been isolated from the Southern cattle tick Rhipicephalus (Boophilus) microplus, a major disease vector in livestock.Using bioinformatics 115 transcriptomic sequences were analyzed to identify putative pesticide metabolizing CYPs. RACE-PCR was used to amplify the full length sequence of one CYP; CYP3006G8 which displays a high degree of homology to members of the CYP6 and 9 subfamilies, known to metabolize pyrethroids. mRNA expression levels of CYP3006G8 were investigated in 11 strains of R. microplus with differing resistance profiles by qPCR, the results of which indicated a correlation with pyrethroid metabolic resistance.In addition to this gene, the sequences for CPR and cytochrome b 5 were also identified and subsequently isolated from R. microplus using PCR.CYP3006G8 is only the third CYP gene isolated from R. microplus and the first to putatively metabolize pesticides. The initial results of expression analysis suggest that CYP3006G8 metabolizes pyrethroids but further biochemical characterization is required to confirm this.Differences in the kinetic parameters of human and mosquito CPR in terms of NADPH binding have been demonstrated and could potentially be used to design species specific pesticides. Similar differences in the tick CPR would confirm that this is a characteristic of heamatophagous arthropods.

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Comparative molecular modeling of Anopheles gambiae CYP6Z1, a mosquito P450 capable of metabolizing DDT

Cited by 166 publications

References 50 publications

Esterase-based metabolic resistance to insecticides in heliothine and spodopteran pests

Esterase-based metabolic resistance to insecticides in heliothine and spodopteran pests

A cis-regulatory sequence driving metabolic insecticide resistance in mosquitoes: Functional characterisation and signatures of selection

Isolation of the monooxygenase complex from Rhipicephalus (Boophilus) microplus – clues to understanding acaricide resistance

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