CYP6B1 and CYP6B3 of the Black Swallowtail (Papilio polyxenes): Adaptive Evolution through Subfunctionalization

Wen, Zheng; Rupasinghe, Sanjeewa G.; Niu, Guodong; Berenbaum, May R.; Schuler, Mary A.

doi:10.1093/molbev/msl118

Cited by 79 publications

(58 citation statements)

References 47 publications

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“…Among plant P450s, spearmint CYP71D15 and peppermint CYP71D18 have different regiospecificities for limonene hydroxylation because of a single amino acid difference within the catalytic site (F363I in SRS5) (44,45). The closely related lepidopteran CYP6B1 and CYP6B3 also differ in their metabolism of plant allelochemicals (46). These metabolic variations highlight the fact that, even with high global sequence identity, only a small number of residues in each binding site define P450 substrate binding preferences.…”

Section: Discussionmentioning

confidence: 99%

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

Chiu

Wen

Rupasinghe

et al. 2008

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

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164

138

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One of the challenges faced in malarial control is the acquisition of insecticide resistance that has developed in mosquitoes that are vectors for this disease. Anopheles gambiae, which has been the major mosquito vector of the malaria parasite Plasmodium falciparum in Africa, has over the years developed resistance to insecticides including dieldrin, 1,1-bis(p-chlorophenyl)-2,2,2-trichloroethane (DDT), and pyrethroids. Previous microarray studies using fragments of 230 An. gambiae genes identified five P450 loci, including CYP4C27, CYP4H15, CYP6Z1, CYP6Z2, and CYP12F1, that showed significantly higher expression in the DDT-resistant ZAN/U strain compared with the DDT-susceptible Kisumu strain. To predict whether either of the CYP6Z1 and CYP6Z2 proteins might potentially metabolize DDT, we generated and compared molecular models of these two proteins with and without DDT docked in their catalytic sites. This comparison indicated that, although these two CYP6Z proteins share high sequence identity, their metabolic profiles were likely to differ dramatically from the larger catalytic site of CYP6Z1, potentially involved in DDT metabolism, and the more constrained catalytic site of CYP6Z2, not likely to metabolize DDT. Heterologous expressions of these proteins have corroborated these predictions: only CYP6Z1 is capable of metabolizing DDT. Overlays of these models indicate that slight differences in the backbone of SRS1 and variations of side chains in SRS2 and SRS4 account for the significant differences in their catalytic site volumes and DDT-metabolic capacities. These data identify CYP6Z1 as one important target for inhibitor design aimed at inactivating insecticide-metabolizing P450s in natural populations of this malarial mosquito.cytochrome P450 monooxygenases ͉ insecticides ͉ plant allelochemicals I n 2004, the World Health Organization reported that up to 2.7 million people die of malaria every year with 80-90% of these deaths occurring in Africa (ref. 1 and www.africanfront.com/ AIDS1.php). Many prevention and treatment strategies have been developed to tackle this life-threatening disease from the side of the mosquito vector and that of the human host (2, 3). These range from antimalarial drugs to indoor spraying of insecticides and use of bed nets treated with pyrethroid insecticides. Although these practices have helped reduce human mortality, various issues have emerged with mosquito vectors developing insecticide resistance and parasites developing drug resistance. Both of these significantly reduce the efficacy of current malarial prevention and treatment practices (2, 4-8).The development of insecticide resistance in mosquito vectors is illustrated by Anopheles gambiae, which has been the major mosquito vector of the malaria parasite Plasmodium falciparum in Africa (4, 6). Throughout the years, people have reported Anopheles resistance (albeit low-level resistance) to various insecticides including dieldrin (a cyclodiene-type insecticide), 1,1-bis(pchlorophenyl)-2,2,2-trichloroethane (DDT), and pe...

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Section: Discussionmentioning

confidence: 99%

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

Chiu

Wen

Rupasinghe

et al. 2008

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

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164

138

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“…A molecular model of CYP6AB3v1 contains three-dimensional elements similar to those predicted in the catalytic sites of the furanocoumarin-metabolizing CYP6B proteins in P. polyxenes, P. glaucus, and H. zea (25)(26)(27)31) including residues in the B-helix and BЈ-C loop of SRS1, the I-helix of SRS4, and the ␤-turn in ␤-sheet 4 of SRS6 (30). Amino acids are also conserved in SRS1, SRS4, and SRS5 that contribute to form the catalytic site of CYP6B1 from the specialist P. polyxenes, CYP6B4 from the generalist P. (25,31,32).…”

Section: Much Of What Is Known Of Allelic Variation In Insect P450smentioning

confidence: 99%

Allelic Variation in the Depressaria pastinacella CYP6AB3 Protein Enhances Metabolism of Plant Allelochemicals by Altering a Proximal Surface Residue and Potential Interactions with Cytochrome P450 Reductase

Mao

Rupasinghe

Zangerl

et al. 2007

Journal of Biological Chemistry

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CYP6AB3v1, a cytochrome P450 monooxygenase in Depressaria pastinacella (parsnip webworm), is highly specialized for metabolizing imperatorin, a toxic furanocoumarin in the apiaceous host plants of this insect. Cloning and heterologous expression of CYP6AB3v2, an allelic variant identified in D. pastinacella, reveals that it metabolizes imperatorin at a rate (V max of 10.02 pmol/min/pmol of cytochrome P450 monooxygenase (P450)) significantly higher than CYP6AB3v1 (V max of 2.41 pmol/min/pmol) when supplemented with even low levels of cytochrome P450 reductase. Comparisons of the NADPH consumption rates for these variants indicate that CYP6AB3v2 utilizes this electron source at a faster rate than does CYP6AB3v1. Molecular modeling of the five amino acid differences between these variants and their potential interactions with P450 reductase suggests that replacement of Val 92 on the proximal face of CYP6AB3v1 with Ala 92 in CYP6AB3v2 affects interactions with P450 reductase so as to enhance its catalytic activity. Allelic variation at this locus potentially allows D. pastinacella to adapt to both intraspecific and interspecific variation in imperatorin concentrations in its host plants. Cytochrome P450 monooxygenases (P450s) 2 are hemecontaining enzymes that catalyze the NADPH-dependent reductive cleavage of molecular oxygen to produce functionalized organic products and a molecule of water, making them crucial for phase I metabolism in a wide range of organisms. Although considerable allelic variation in both the coding and the regulatory regions is known to occur in many vertebrate P450 genes (1-3), the extent of allelic variation in insect P450 loci is not clear. Much of what is known of allelic variation in insect P450sresults from studies of insecticide resistance. Here, most examples of P450-mediated resistance to insecticides involve regulatory changes, often transposon-mediated (4). Only a few examples exist where point mutations in coding regions affect reactivities toward insecticides. Perhaps the best evidence of such allelic variation is the existence of three amino acid variations in CYP6A2 (R335S, L336V, V476L) in the DDT-resistant RDDT R strain of Drosophila melanogaster; these substitutions occur near the CYP6A2 active site and increase catalytic efficiency of the CYP6A2 enzyme against DDT, 7-ethoxycoumarin, and 7-benzoyloxycoumarin (5). Allelic variation in the form of amino acid substitutions has also been documented in CYP6D1, CYP6D3, and CYP6X1 as well as CYP6A2 (6 -8), but the functional contributions of these to resistance have not yet been determined.In addition to contributing to insecticide resistance, P450s play an important role in mediating resistance to plant allelochemicals (defense compounds) in herbivorous insects (9). However, these allelochemicals present a toxicological challenge to insects that differs in several fundamental ways from that presented by insecticides. Although insecticides are generally single compounds designed to kill and applied in a broadcast fashion, plant d...

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“…While these examples highlight the breadth of compounds metabolized by insect P450s, comparisons of the predicted catalytic sites have provided more significant information on the amino acid variations between nonselective and selective P450s Recent reviews [291,305] provide numerous examples of the variations affecting particular P450 activities with most examples drawn from comparisons of closely related subfamily members and not from natural variations in individual insect P450s Not surprisingly, therefore, most of the highlighted variations map to residues in catalytic sites, substrate access channels, and proximal surfaces Highlighting a few of the important differences between closely related subfamily members, instances of catalytic site differences include A. gambiae CYP6Z2, where protrusions of Arg210 (SRS2), Ile298 and Glu302 (both in SRS4) are predicted to restrict its substrate range compared to CYP6Z1 [297], A. mellifera CYP9Q2, where protrusion of Arg246 (SRS3) into its catalytic site is predicted to prevent quercetin metabolism compared to CYP9Q1 [275] and the A. mellifera CYP6AS subfamily, where side chains on residues 107 (SRS1) and 217 (SRS2) and the carbonyl backbone between residues 302 and 303 (SRS4) moderate quercetin metabolism [306] Many other examples of catalytic site variations affecting activity exist in the Papilio and Helicoverpa CYP6B subfamily, where furanocoumarin metabolism rates are defined by the presence or absence of aromatic side chains in SRS1, SRS5, and SRS6 and other types of side chains in all six SRS regions [291] Instances of substrate access channel differences affecting activity include A. minimus CYP6P8, where Arg114 (SRS1) and Arg216 (SRS2) are predicted to extend into the CYP6P8 substrate access channel and prevent pyrethroid access compared to the closely related CYP6P7 that metabolizes this insecticide quite efficiently [307] Characteristic of the small number of natural and site-directed variants actually analyzed, some natural P. polyxenes CYP6B3 variants [263] and site-directed P. polyxenes CYP6B1 mutants [308][309][310] have identified particular SRS residues important in P450 folding, substrate turnover, and/or product exit Adding to this collection of important residues, natural D. pastinacella CYP6AB3 variants have identified proximal surface residues affecting catalytic efficiency with a single Val92Ala (B-helix on the proximal surface) switch substantially enhancing electron transfer from P450 reductase [265] And, several site-directed P. multicaudatus CYP6B33 mutants have identified residue 32 (in the linker preceding the proline-rich hinge) as important for folding of this P450 in insect cell expression systems [267] Not yet tested in site-directed mutants, other examples of potentially important residues likely exist in CYP6CM1 variants, where two changes in imidacloprid-resistant B. tabaci (His341Asn, Asn367Thr (numbered as in resistant compared to susceptible biotypes)) map to the proximal surface [282], CYP6A2 variants, where two changes...…”

Section: Critical Structural Regionsmentioning

confidence: 99%

P450s in Plants, Insects, and Their Fungal Pathogens

Schuler

2015

Cytochrome P450

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IntroductionCytochrome P450 monooxygenases (P450s) are integral components in pathways producing metabolites important for normal growth and development as well as for adaptive strategies that define biotic interactions, including trophic interactions between plants, insects, mammals, fish, and their respective pathogens Biosynthetic P450s in these pathways can be considered organism-general (fatty acids, sterols) versus organism-specific with examples of the latter including structural components (plant cell walls, insect cuticle, fungal spore walls), signaling networks (plant oxylipins and gibberellins, insect ecdysteroids, fungal gibberellins), and defense compounds (plant terpenoids, alkaloids, furanocoumarins, glucosinolates, insect cyanogenic glycosides, and pyrrolizidine alkaloids, fungal aflatoxins and trichothecenes) Detoxicative P450s are generally organism-specific and frequently evolved from those with catabolic functions In the interactions between plants and insect herbivores, the activities of synthetic and detoxicative P450s determine how effectively plants can synthesize toxins impeding the growth of insects and how effectively these herbivores can detoxify toxins present in their food sources and hosts This chapter attempts to highlight biochemical and structural features of the numerous P450s existing in plants, insects and their fungal pathogens Because it is impossible to do justice to over 18,000 P450 sequences already annotated in these three species groups, readers are guided to several excellent reviews included in each of the following chapter sections Plant P450s Gene CountsWith the range of compounds that plant species manufacture estimated at over 200,000

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CYP6B1 and CYP6B3 of the Black Swallowtail (Papilio polyxenes): Adaptive Evolution through Subfunctionalization

Cited by 79 publications

References 47 publications

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

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

Allelic Variation in the Depressaria pastinacella CYP6AB3 Protein Enhances Metabolism of Plant Allelochemicals by Altering a Proximal Surface Residue and Potential Interactions with Cytochrome P450 Reductase

P450s in Plants, Insects, and Their Fungal Pathogens

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