Skip to main content

Acetylcholinesterase of the sand fly, Phlebotomus papatasi (Scopoli): construction, expression and biochemical properties of the G119S orthologous mutant

Abstract

Background

Phlebotomus papatasi vectors zoonotic cutaneous leishmaniasis. Previous expression of recombinant P. papatasi acetylcholinesterase (PpAChE1) revealed 85% amino acid sequence identity to mosquito AChE and identified synthetic carbamates that effectively inhibited PpAChE1 with improved specificity for arthropod AChEs compared to mammalian AChEs. We hypothesized that the G119S mutation causing high level resistance to organophosphate insecticides in mosquitoes may occur in PpAChE1 and may reduce sensitivity to inhibition. We report construction, expression, and biochemical properties of rPpAChE1 containing the G119S orthologous mutation.

Methods

Targeted mutagenesis introduced the G119S orthologous substitution in PpAChE1 cDNA. Recombinant PpAChE1 enzymes containing or lacking the G119S mutation were expressed in the baculoviral system. Biochemical assays were conducted to determine altered catalytic properties and inhibitor sensitivity resulting from the G119S substitution. A molecular homology model was constructed to examine the modeled structural interference with docking of inhibitors of different classes. Genetic tests were conducted to determine if the G119S orthologous codon existed in polymorphic form in a laboratory colony of P. papatasi.

Results

Recombinant PpAChE1 containing the G119S substitution exhibited altered biochemical properties, and reduced inhibition by compounds that bind to the acylation site on the enzyme (with the exception of eserine). Less resistance was directed against bivalent or peripheral site inhibitors, in good agreement with modeled inhibitor docking. Eserine appeared to be a special case capable of inhibition in the absence of covalent binding at the acylation site. Genetic tests did not detect the G119S mutation in a laboratory colony of P. papatasi but did reveal that the G119S codon existed in polymorphic form (GGA + GGC).

Conclusions

The finding of G119S codon polymorphism in a laboratory colony of P. papatasi suggests that a single nucleotide transversion (GGC → AGC) may readily occur, causing rapid development of resistance to organophosphate and phenyl-substituted carbamate insecticides under strong selection. Careful management of pesticide use in IPM programs is important to prevent or mitigate development and fixation of the G119S mutation in susceptible pest populations. Availability of recombinant AChEs enables identification of novel inhibitory ligands with improved efficacy and specificity for AChEs of arthropod pests.

Background

Leishmaniasis is a widespread debilitating and neglected disease of intertropical and temperate regions affecting millions of people throughout the world. The most common form is cutaneous leishmaniasis, with an estimated 0.7 to 1.3 million new cases annually, caused by flagellated protozoans in the genus Leishmania transmitted by the bite of several sand fly species [1]-[3]. Leishmania major is the predominant pathogen of zoonotic cutaneous leishmaniasis that is vectored (transmitted) in the Middle East, Asia, Africa and Southern Europe by Phlebotomus papatasi (Scopoli) [4]-[6]. The vector of cutaneous leishmaniasis, P. papatasi, impacted U.S. military readiness and operations in Iraq and Afghanistan [7]-[10], and the ability to control P. papatasi is important to millions of people in endemic areas of the world. The primary means to control zoonotic leishmaniasis transmission is through reduction of rodent habitat or rodent treatment to reduce local sand fly populations and the use of chemical insecticides and insecticide-treated bednets to reduce human bites by sand flies [2],[11]-[17]. Organophosphate and carbamate insecticides may be used for control of insect vectors of infectious disease, acting through the inhibition of acetylcholinesterase in the central nervous system. We previously reported genetic and biochemical properties of recombinant acetylcholinesterase (AChE) of P. papatasi(rPpAChE1), and noted that PpAChE1 had 85% amino acid sequence identity to AChEs of Culex pipiens and Aedes aegypti mosquito species [18]. Point mutations resulting in production of an altered, insensitive AChE comprise a major mechanism of resistance to organophosphate and carbamate insecticides [19]-[21], and preliminary evidence of organophosphate resistance has been reported in sand flies [22]-[24]. It was previously hypothesized that the major mutation responsible for high level resistance to organophosphate inhibition in mosquito AChE (G119S, Torpedo AChE nomenclature [25]) [26]-[28] may occur in P. papatasi[18]. Here, we report the construction, baculoviral expression, and biochemical properties of recombinant PpAChE1 (rPpAChE1) containing the G119S orthologous mutation.

Methods

Targeted mutagenesis and baculoviral expression of rPpAChE1-G119S

A baculovirus expression vector containing the cDNA encoding PpAChE1 [18] was used as the template for targeted mutagenesis. A serine codon (AGC) was substituted for the glycine codon (GGA) at nucleotide positions 837-839[GenBank: JQ922267] to generate the G119S orthologous mutation (Torpedo AChE nomenclature) in PpAChE1 cDNA. Essentially, high-fidelity PCR utilized phosphorylated primers (SigmaGenosys, St. Louis, MO) PpAChE768U25-GGC (5′Phos-CTTCTACTCAGGAACATCCACACTC-3′) and PpAChE748L20-OPR (5′Phos-CTACCACCGAAGATCCATAG-3′) with Phusion HotStart DNA polymerase (New England BioLabs, Ipswich, MA) and template DNA (pBlueBac4.5/V5-His containing PpAChE1 coding sequence [18]) preincubated at 98°C for 30 sec followed by 25 cycles of 10 sec at 98°C, 45 sec at 65°C, and 5 min at 72°C with a final 10 min incubation at 72°C. The amplified product was ligated using a Quick Ligation™ Kit (New England BioLabs) according to the manufacturer’s instructions, transformed into chemically competent TOP10 E. coli cells (Life Technologies, Carlsbad, CA) and plated onto L-agar plates containing 100 μg/ml carbenicillin (Sigma Chemical Co, St. Louis, MO). Transformant colonies were selected, plasmid DNA sequenced to verify correct construction of the PpAChE1 containing the G119S orthologous mutation, cotransfected with Bac-N-Blue DNA into Sf21 insect cell culture for baculovirus expression, and initially characterized in microplates using a modified Ellman’s assay as described previously [18].

Sand flies, RNA, cDNA synthesis, and agarose gel electrophoresis

Sand flies used in this study were from a laboratory colony of P. papatasi maintained at the USDA-ARS, Knipling-Bushland U.S. Livestock Insects Research Laboratory in Kerrville, Texas. Sand fly colony derivation, maintenance, preparation of RNA, cDNA synthesis and agarose gel electrophoresis were as previously described [18].

Anticholinesterases as probes of enzyme function

The experimental anticholinesterases used in this study for enzyme characterization are shown in Figure 1. They were synthesized and purified via established methods [29]-[31] and had purities of at least 95%. The synthesized experimental carbamates were as follows: 1, 2-((2-ethylbutyl)thio)phenyl methylcarbamate; 2, 3-(tert-butyl)phenyl methylcarbamate; 3, 1-(sec- butyl)-1H-pyrazol-4-yl methylcarbamate; 4, 1-isopentyl-1H-pyrazole-4-yl methylcarbamate; 5, 1-isobutyl-1H-pyrazol-4-yl methylcarbamate; 6, N1,N6-bis(1,2,3,4-tetrahydroacridin-9-yl)hexane-1,6-diamine; and 7, N1,N7-bis(1,2,3,4-tetrahydroacridin-9-yl)heptane-1,7-diamine. In addition, a range of commercially available AChE inhibitors were purchased. The inhibitors eserine (99% pure), propoxur (99%), carbofuran (99%), donepezil (98%), tacrine (99%), and ethidium bromide (95%) were all purchased from Sigma–Aldrich (St. Louis, MO, USA). D-Tubocurarine (99%) was obtained from Alfa Aesar (Ward Hill, MA, USA).

Figure 1
figure 1

Chemical structures and names of experimental anticholinesterases used in this study. Bold numbers beside the names denote the compounds as presented in the text. For the bis(n)-tacrines, “n” refers to the number of methylene groups in the linker. Each compound was assigned to an inhibitor class as given in Table 1.

Biochemical characterization and inhibition assays

In this study, three categories of AChE inhibitors were chosen to define the pharmacological profiles of wild type and G119S rPpAChEs. They included catalytic site inhibitors (organophosphates, carbamates, tacrine, and eserine), peripheral site inhibitors (tubocurarine and ethidium bromide), and bivalent inhibitors (bis(8)-tacrine, bis(12)-tacrine, and donepezil). Note that tacrine differs from the other catalytic site inhibitors in that it is reversible, and does not covalently bind the catalytic serine. Tacrine binds in the choline-binding site, and does not extend into the oxyanion hole or acyl pocket [32]. The compounds were made into stock solutions by dissolving in DMSO, and all enzyme assays were run in constant 0.1% DMSO as a carrier. Inhibition of rPpAChE by these inhibitors was determined using the Ellman assay in a 96-well plate configuration [33]. The rPpAChE cell lysates were pre-incubated with at least six concentrations of inhibitors for 30 minutes at room temperature prior to adding 300 μM 5,5′-dithiobis-(2-nitrobenzoic acid) (DTNB) and 400 μM acetylthiocholine enzyme substrate (AcSCh), which were both dissolved in 0.1 M sodium phosphate buffer, pH 7.0. The kinetic reading of absorbance at 405 nm was started immediately after adding DTNB and AcSCh with a Dynex Triad multimode plate reader (Dynex Technologies, Chantilly, VA, USA). Inhibitor concentration-response curves and inhibition parameters were constructed by nonlinear regression to a four parameter logistic equation using GraphPad Prism 4.0c software (GraphPad Software, San Diego, CA, USA).

Construction of a ligand docking molecular homology model of PpAChE1

A molecular homology model of P. papatasi AChE1 (wild type) was built in ICM [34] by homology [35] based on a 2.6 Å resolution mouse AChE X-ray structure, Protein Data Base code 4B84 [36]. The template enzyme has 48% overall identity with the target sequence. Local homology in the active site region was significantly stronger. Seven tightly bound water molecules in the vicinity of the active site in the template structure were transferred into the model and their positions were refined by energy optimization (water molecules number 46, 49, 52, 55, 71, 72 and 146). The G119S mutation (position 256 in PpAChE1 sequence, GenBank: AFP20868.1) was next introduced into the model (in ICM). After optimization of the side chain conformation within the otherwise rigid protein, residual clashes of S256 with F425 and Y258 (P. papatasi numbering) were detected. The F425 clash was relieved by relaxation of its side-chain, while the Y258 clash could not be relieved by side chain relaxation alone but was resolved after backbone relaxation within the G255-S259 residue window (i.e., a loop including ±1 residue around S256 and Y258 each). Relaxation resulted in 1.1 Å /0.6 Å RMSD displacement of, respectively, all heavy atoms/only backbone atoms within this region. Docking of representative ligands was performed in ICM Docking module [37],[38]. For ligands with a covalent inhibition mechanism (carbamates), the tetrahedral transition state on the reaction pathway between non-covalently bound inhibitor and acylated enzyme was modeled, using ‘covalent docking’ protocol in ICM [34]. Because observed AChE ligand-bound conformations often vary in the sidechain conformation of residue F/Y330 (T. californica numbering) in the active site gorge, a multiple receptor conformation ‘4D docking’ approach [39] was applied to sample two rotamers of Y465 (P. papatasi numbering). Three lowest-scoring conformations were retained in each docking simulation, visually inspected and compared to available X-ray structures of the same or similar ligands bound to AChE (of other species such as mouse and T. californica). The final models chosen were either the lowest or second-lowest conformation (the latter was selected if it was in a significantly better agreement with experimentally observed interaction modes). To identify potentially adverse interactions caused by the G119S (Torpedo californica numbering) mutation, docked ligand/PpAChE (wt) complexes were superimposed with PpAChE1-G119S model and superimposed structures were analyzed for ligand/PpAChE-G119S clashes.

Test for G119S codon sequence in P. papatasi laboratory colony PpAChE1

The PCR-RFLP assay of Weill et al. [28] was modified to test for the presence of the G119S orthologous mutation in our laboratory colony of P. papatasi. A segment of P. papatasi genomic or cDNA was amplified by PCR using primers PpAChE-793U17 (5′-CCACGTCCCAAAAACTC-3′) and PpAChE-842 L23 (5′-GAGTGTGGATGTTCCTGAGTAGA-3′) and the 72 bp amplicon was tested for the presence of the G119S orthologous codon by incubation with Alu I restriction endonuclease (New England BioLabs) followed by gel electrophoresis. Positive (G119S orthologous rPpAChE1, this report) and negative (wild type rPpAChE1, [18]) control templates were used to validate the assay. If the G119S orthologous codon was present in the template, Alu I digestion resulted in cleavage of the DNA amplicon to 25 bp and 47 bp segments. A similar PCR-RFLP test was used to test for sequence polymorphisms (GGA vs GGC) in the G119S orthologous codon, using PCR primers PpAChE-814U26AluC (5′-GTTATGCTATGGATCTTCGGTGGTAG-3′) and PpAChE-854 L22 (5′-TCGTACACATCGAGTGTGGATG-3′). Alu I digestion of the 54 bp amplicon produced 28 bp +36 bp fragments if position 839 [GenBank: JQ922267] was the C nucleotide. Positive and negative control templates were used to validate the assay.

Results

Targeted mutagenesis and baculoviral expression of rPpAChE1-G119S

The rPpAChE1 constructed by targeted mutagenesis (rPpAChE1-G119S) was completely sequenced and verified to contain the G119S orthologous codon (AGC) at nucleotide positions 837–839 [GenBank: JQ922267] of rPpAChE1 cDNA (Figure 2). As shown in Figure 3, the single amino acid substitution (G119S) in rPpAChE1-G119S resulted in greater than 1000-fold reduction in sensitivity to paraoxon inhibition compared to rPpAChE1 (wild type). The G119S orthologous substitution also exhibited a 4-fold increased Km (Michaelis-Menten constant; i.e., concentration of substrate producing ½ maximal velocity) for the substrate acetylthiocholine (AcSCh), where the Km (μM) values were 24 and 98 for rPpAChE1and rPpAChE1-G119S, respectively.

Figure 2
figure 2

Partial PpAChE1 cDNA sequence containing G256S codon identified as OP-R in An. gambiae (G119S) and other insects. Numbers designate beginning and ending nucleotide sequence numbers from GenBank JQ922267.1.

Figure 3
figure 3

Relative sensitivity of the altered rPpAChE1-G119S enzyme to paraoxon inhibition was reduced by over 1000-fold as a result of the single amino acid substitution.

Biochemical characterization and inhibition assays

As shown in Figure 3, paraoxon was a potent inhibitor of wild type enzyme (rPpAChE1), but not rPpAChE1-G119S. The other anticholinesterases (Figure 1) demonstrated a wide range of potencies as well as resistance ratios for the inhibition of both strains of rPpAChE (Table 1). The calculated IC50 values and confidence limits had correlation coefficients, R2, of at least 0.95, except those curves with very wide confidence limits due to the high resistance of the G119S rPpAChE to OPs and carbamates. For wild type rPpAChE, all of the catalytic site inhibitors and bivalent inhibitors showed moderate to high potencies to inhibit enzyme activity, with IC50 values from the middle nanomolar (e.g., propoxur and paraoxon) to sub nanomolar concentrations (compound 7), although most compounds fell in the range of 3–76 nM (Table 1). On the other hand, the two peripheral site inhibitors had low potencies for rPpAChE inhibition of 17 μM (ethidium bromide) and 143 μM (tubocurarine) analogous to similarly low affinity of the peripheral site inhibitor propidium for mammalian AChE [40].

Table 1 Inhibition of rPpAChE1 and rPpAChE1-G119S by different classes of AChE inhibitors

In contrast, the G119S rPpAChE showed strong resistance to the organophosphates (paraoxon and malaoxon) and all phenyl-substituted methylcarbamates (compounds 1, 2) with resistance ratios over 450. Interestingly, a group of alkyl-substituted pyrazole carbamates (compounds 3, 4, and 5), which include a smaller ring than phenyl methylcarbamates, had much lower resistance ratios (18–64 fold) compared to phenyl methylcarbamates (Table 1). All other peripheral site inhibitors, bivalent inhibitors, and a catalytic site inhibitor, tacrine, showed the lowest resistance ratios, which were ≤7.

An exception was eserine, which despite having a large pyrroloindole ring system, displayed much less cross resistance than the phenylcarbamates, but a bit more than tacrine and the bivalent inhibitors (Table 1). Current data with wild type rPpAChE showed good correlation to that previously published for 11 compounds (eserine, propoxur, carbofuran, tacrine, d-tubocurarine, ethidium bromide, donepezil, 1, 2, 6, and 7), which differed only in that a shorter 10 min preincubation with inhibitor was used [29]. The data sets collected in both studies for rPpAChE were not normally distributed (D’Agostino & Pearson omnibus normality test), but were highly correlated with nonparametric Spearman r = 0.884 (0.59-0.97; 95% CL) and two-tailed P < 0.0006.

Inhibitor docking in a molecular homology model of PpAChE1

A molecular homology model of PpAChE1 (Figure 4) was constructed based on murine AChE. Selected inhibitors were docked into the model which was then adjusted for the G119S (T. californica numbering) mutation at PpAChE1 position 256. As shown in Figure 4, propoxur (4a) docked into the molecular homology model exhibits a fairly large region of Van der Waals overlap, suggesting that the G119S mutation (S256 in the model) results in a large interference with propoxur docking, in agreement with the results presented in Table 1 (resistance ratio 19,213). Eserine (4b) appears to exhibit a similarly large region of Van der Waals overlap, suggesting that it should also exhibit a significantly high resistance ratio in the G119S mutant; however, the experimentally measured resistance ratio (Table 1) is only 27. Compound 4 (4c) exhibits a significantly reduced Van der Waals overlap, in relative agreement with the measured resistance ratio of only 64. Tacrine (4d) is not directly impacted by the G119S substitution, but may be somewhat affectedby desolvation of the catalytic serine (S336) exhibiting a resistance ratio of only 5.8. Donepezil (4e) also shows no direct impact with the G119S substitution and provides a minimal resistance ratio of only 5. Similarly, ethidium (4f) exhibits no interaction with the G119S substitution (S256) and exhibits a resistance ratio of 0.4.

Figure 4
figure 4

Representative inhibitors (from Table 1) docked into PpAChE1 (wild type) and superimposed into the G119S (PpAChE position S256) mutant: 4a) propoxur, a phenylcarbamate; 4b) eserine, a cationic carbamate; 4c) pyrazolecarbamate (compound 4), a ‘small core’ carbamate; 4d) tacrine, a non-covalent active site inhibitor; 4e) donepezil, a bivalent inhibitor; 4f) ethidium, a peripheral site inhibitor. Van der Waals surfaces of the inhibitor (green) and mutated serine S256 (PpAChE1 sequence numbering) hydroxyl (red) are shown. Red contour lines delineate the overlap (clash) region (where present). Key residues such as W221 (active site ‘floor’), W417 (peripheral site wall), catalytic serine S336 and histidine H576, as well as sidechains F425 and Y258 most affected by the mutation at G/S256 are shown in ball-and-stick representation.

Test for G119S codon sequence in P. papatasi laboratory colony PpAChE1

The PCR-RFLP assay adapted from Weill et al. [28] failed to demonstrate the presence of the G119S orthologous mutation in our laboratory colony of P. papatasi; however, direct sequencing of a small percentage of cDNA clones that included the codon corresponding to the G119S orthologous site in PpAChE1 and a PCR-RFLP assay designed to detect the presence of a GGC codon at nucleotide positions 837–839 [GenBank: JQ922267] both indicated the presence of polymorphic GGC/GGA sequence at the codon position orthologous to the G119S mutation in mosquitoes (Figure 5). Preliminary data suggests that the GGC codon at this locus is present in our laboratory flies at an estimated frequency between 10-20%.

Figure 5
figure 5

PCR-RFLP assay for polymorphism in laboratory P. papatasi . Template DNA (as indicated for each lane) was amplified by PCR then subjected to digestion with Alu I and electrophoretically separated on a 4% Metaphor agarose gel. Lane: Std, DNA size standards; 1, no template negative control; 2, wild type PpAChE1 plasmid; 3, PpAChE1-G119S plasmid; 4–6, genomic DNA extracted from individual P. papatasi colony females fed sugar water only, no blood.

Discussion

The G119S mutation of rPpAChE has significant effects on the catalytic properties and inhibitor sensitivity of the enzyme. The four-fold increase seen in Km is similar to the two-fold increase in Km seen in the G119S mutant of Anopheles gambiae AChE [30]. Furthermore, high enzyme resistance ratios are seen for aryl methylcarbamate (e.g., propoxur, carbofuran), as was seen for AgAChE-G119S [30],[41]. High resistance ratios are also seen for paraoxon and malaoxon. Like the aryl methycarbamates, these compounds acylate the active site serine (acylation site inhibitors) and extend into the oxyanion hole, where G119 is located. In contrast, the pyrazol-4-yl methylcarbamates (Table 1, compounds 35) possess significantly smaller insensitivity ratios, as we previously observed for AgAChE-G119S [30]. The smaller volume of pyrazol-4-yl core inhibitors (Figure 1, compounds 35) relative to aryl methylcarbamates presumably allows them to effectively enter the crowded active sites of G119S mutant Anopheles gambiae AChE and rPpAChE1-G119S. Tacrine is also a catalytic site inhibitor, but unlike carbamates and organophosphates, binds in the choline-binding site, rather than the oxyanion hole. Thus, tacrine inhibition is largely unaffected by the G119S mutation and the resistance ratio is only 5.8 (Table 1). Similarly low resistance ratios are seen for bivalent inhibitors (compounds 6,7, and donepezil) and peripheral site inhibitors. Since neither class of inhibitor bind AChE near G119S, the mutation does not affect inhibition by these compounds.

The molecular homology model docking of selected inhibitors (Figure 4) is in good general agreement with the measured resistance ratios of selected inhibitors. The G119S mutation (S256) in the PpAChE1 model (Figure 4) interferes with positioning of phenylcarbamates for acylation transition state, while for non-covalent inhibitors there are no direct steric issues. Desolvation of serine OH might explain small residual resistance. The exception is the docking model for eserine (Figure 4b), which is a special case among carbamates because as a bulky cationic lipophilic moiety, it may function as a non-covalent inhibitor even if acylation (i.e., covalent inhibition mechanism) is impaired by the mutation. For the three carbamates, docking was done assuming a covalent inhibition mechanism (actual models are of the acylation transition state). If eserine is modeled non-covalently, it could still have hydrophobic and cation-pi interactions at least as extensive as tacrine, therefore this discrepancy may not have so much to do with homology model accuracy as with more complex mechanistic issues.

In summary, results indicate that the single amino acid substitution orthologous to the G119S mutation responsible for high level resistance to organophosphate and carbamate insecticides in mosquitoes can also generate high level resistance to inhibition by acylation site inhibitors in recombinant P. papatasi AChE1. The recent reports of aryl methylcarbamates that were shown to have improved targeting of pest AChEs relative to mammalian AChEs [41],[42], suggests that use of the recombinant enzymes with various amino acid substitutions may offer platforms for SAR modeling and in vitro screening to design and identify novel inhibitors with specific targeting of insecticide-insensitive AChEs that also exhibit improved mammalian safety profile. Further studies are planned or underway to evaluate the effects of additional mutations in PpAChE1, to evaluate the presence of G119S orthologous codon polymorphism in natural populations of P. papatasi, to evaluate additional synthetic ligands to assess their efficacy against wild type and “mutant” forms of rPpAChE1, and to utilize molecular modeling and structure activity relationships (SARs) to improve construction and selection of inhibitory lead chemical structures.

In mosquitoes, the G119S substitution produces high level organophosphate and carbamate insecticide resistance but also a high fitness cost (in the absence of insecticide) when homozygous [43]-[45], presumably due to 30-fold reduction in turnover number for substrate and approximately 70% decrease in cholinergic activity [46]. Reduction in G119S allele frequency was reported in Lebanon over a 3–4 year period presumably resulting from switching to pyrethroids for mosquito control and loss of the G119S allele due to fitness cost in the absence of inhibitor selection pressure [47]. In spite of the fitness cost, the G119S-containing ace-1 allele is widespread throughout the world [48] and the fitness cost may be reduced in the presence of kdr-resistance to pyrethroids [49] or by duplication of the ace-1 allele to permit maintenance of a heterozygous state, essentially fixing it in the population [50]-[52]. Agricultural pesticide use and mosquito control efforts have largely resulted in the spread of the ace-1 duplication in West Africa [53]. Together, these findings provide strong warnings about the need for careful use of insecticides that provide strong selection for resistance to organophosphates and carbamates. Once the G119S substitution occurs, pyrethroid use may allow reduction of the frequency of the G119S allele [47], or selection for kdr-based resistance to pyrethroids may result in multiple-resistant pest populations by reducing fitness cost of the G119S allele [49]. The finding of G119S orthologous codon polymorphism in a laboratory colony of P. papatasi strongly suggests that a single nucleotide transversion (GGC → AGC) might readily occur, causing relatively rapid development of resistance to organophosphate insecticides if subjected to strong selection. Careful management of pesticide use in IPM programs is important to prevent or mitigate development and fixation of the G119S mutation in susceptible pest populations. Availability of the recombinant AChEs may enable identification of novel inhibitory ligands with improved efficacy and specificity for AChEs of arthropod pests.

Conclusions

We demonstrated that the G119S orthologous substitution in PpAChE1 produces high levels of resistance to OP and carbamate inhibitors, suggesting a strong likelihood of resistance development if the subject codon is polymorphic (GGA + GGC) in natural populations of P. papatasi. PCR and sequencing tests indicate that the G119S orthologous codon is polymorphic (GGA or GGC) in our laboratory P. papatasi colony. We are currently seeking P. papatasi specimens from natural populations worldwide to determine if the G119S orthologous codon is polymorphic in natural populations.

As noted by Weill et al., “The development of new insecticides that can specifically inhibit the G119S mutant form of acetylcholinesterase-1 will be crucial in overcoming the spread of resistance” [26]. Use of the recombinant P. papatasi AChE1 and revised molecular models may facilitate rapid screening in silico and in vitro to identify novel PpAChE1 inhibitor ligands, and comparative studies on biochemical kinetics of inhibition. Construction and expression of mutant forms of PpAChE1 will facilitate the development of rapid molecular assays and other tools to screen and characterize mutations giving rise to organophosphate-insensitive PpAChE1. Addition of new molecular data on PpAChE1may also be used in modeling studies to predict in vivo insecticidal activity for novel inhibitors as described by Naik et al. [54]. Availability of the recombinant PpAChE1 will enable the creation of mechanism-based screens to discover more effective inhibitors that may be developed to innovate safer vector control technologies.

Endnotes

aThis article reports the results of research only. Mention of a proprietary product does not constitute an endorsement by the USDA for its use.

bUSDA is an equal opportunity provider and employer.

cCopyright statement: Copyright protection is not available for any work of the United States Government.

dDisclaimer: "The views expressed in this article are those of the authors and do not necessarily reflect the official policy or position of the Department of Agriculture, Department of Defense, nor the U.S Government”.

Abbreviations

AChE:

Acetylcholinesterase

DTNB:

Dithiobisnitrobenzoic acid

AcSCh:

Acetylthiocholine

BuSCh:

Butyrylthiocholine

rPpAChE1:

Recombinant P. papatasi AChE1

References

  1. World Health Organization: Cutaneous leishmaniasis: Why are you neglecting me? 2007 [http://whqlibdoc.who.int/hq/2007/WHO_CDS_NTD_IDM_2007.3_eng.pdf?ua=1.]

  2. World Health Organization: Control of the leishmaniases . WHO Technical Report Series; no. 949: Report of a meeting of the WHO Expert Committee on the Control of Leishmaniases, Geneva, 22–26 March 2010; 2010 [http://whqlibdoc.who.int/trs/WHO_TRS_949_eng.pdf]

  3. World Health Organization: Leishmaniasis Fact sheet No375, updated January 2014 [http://www.who.int/mediacentre/factsheets/fs375/en/]

  4. Jaffe CL, Baneth G, Abdeen ZA, Schlein Y, Warburg A: Leishmaniasis in Israel and the Palestinian authority. TRENDS Parasitol. 2004, 20: 328-332. 10.1016/j.pt.2004.05.001.

    Article  PubMed  Google Scholar 

  5. Kravchenko V, Wasserberg G, Warburg A: Bionomics of phlebotomine sandflies in the Galilee focus of cutaneous leishmaniasis in northern Israel. Med Vet Entomol. 2004, 18: 418-428. 10.1111/j.0269-283X.2004.00527.x.

    Article  CAS  PubMed  Google Scholar 

  6. Killick-Kendrick R, Leaney AJ, Peters W, Rioux J-A, Bray RS: Zoonotic cutaneous leishmaniasis in Saudi Arabia: the incrimination of Phlebotomus papatasi as the vector in the Al-Hassa oasis. Trans R Soc Trop Med Hyg. 1985, 79: 252-255. 10.1016/0035-9203(85)90350-5.

    Article  CAS  PubMed  Google Scholar 

  7. Colacicco-Mayhugh MG, Grieco JP, Putnam JL, Burkett DA, Coleman RE: Impact of phlebotomine sand flies on United States Military Operations at Tallil Air Base, Iraq: 5. Impact of weather on sand fly activity. J Med Entomol. 2011, 48: 538-545. 10.1603/ME10128.

    Article  PubMed  Google Scholar 

  8. Coleman RE, Burkett DA, Sherwood V, Caci J, Dennett JA, Jennings BT, Cushing R, Cushing RJ, Ploch J, Hopkins G, Putnam JL: Impact of phlebotomine sand flies on United State military operations at Tallil Air Base, Iraq: 6. Evaluation of insecticides for the control of sand flies. J Med Entomol. 2011, 48: 584-599. 10.1603/ME10226.

    Article  CAS  PubMed  Google Scholar 

  9. Jacobson RL: Leishmaniasis in an era of conflict in the Middle East. Vector-Borne Zoonotic Dis. 2011, 11: 247-258. 10.1089/vbz.2010.0068.

    Article  PubMed  Google Scholar 

  10. Lay JC: Leishmaniasis among U.S. armed forces, January 2003-November 2004. Medical surveillance monthly report. U.S Army Center Health Promotion Prev Med. 2004, 10: 2-5.

    Google Scholar 

  11. Mascari TM, Mitchell MA, Rowton ED, Foil LD: Evaluation of juvenile hormone analogues as rodent feed-through insecticides for control of immature phlebotomine sandflies. Med Vet Entomol. 2011, 25: 227-231. 10.1111/j.1365-2915.2010.00919.x.

    Article  CAS  PubMed  Google Scholar 

  12. Mirzaei A, Rouhani S, Taherkhani H, Farahmand M, Kazemi B, Hedayati M, Baghaei A, Davari B, Parvizi P: Isolation and detection of Leishmania species among naturally infected Rhombomis opimus, a reservoir host of zoonotic cutaneous leishmaniasis in Turkeman Sahara. North East of Iran. Exp Parasitol. 2011, 129: 375-380. 10.1016/j.exppara.2011.08.020.

    Article  CAS  PubMed  Google Scholar 

  13. Rassi Y, Oshaghi MA, Azani SM, Abaie MR, Rafizaheh S, Mohebai M, Mohtarami F, Zeinali M: Molecular detection of Leishmania infection due to Leishmania major and Leishmania turanica in the vectors and reservoir host in Iran. Vector-Borne Zoonotic Dis. 2011, 11: 145-150. 10.1089/vbz.2009.0167.

    Article  PubMed  Google Scholar 

  14. Schlein Y, Müller GC: Experimental control of Phlebotomus papatasi by spraying attractive toxic sugar bait (ATSB) on vegetation. Trans R Soc Trop Med Hyg. 2010, 104: 766-771. 10.1016/j.trstmh.2010.08.014.

    Article  PubMed  Google Scholar 

  15. Wasserberg G, Poche R, Miller D, Chenault M, Zollner G, Rowton ED: Imidacloprid as a potential agent for the systemic control of sand flies. J Vector Ecol. 2011, 36 (Suppl. 1): S148-S156. 10.1111/j.1948-7134.2011.00125.x.

    Article  PubMed  Google Scholar 

  16. Alexander B, Maroli M: Control of phlebotomine sandflies. Med Vet Entomol. 2003, 17: 1-18. 10.1046/j.1365-2915.2003.00420.x.

    Article  CAS  PubMed  Google Scholar 

  17. Kassi M, Kasi PM, Marri SM, Tareen I, Khawar T: Vector control in cutaneous leishmaniasis of the old world: a review of literature. Dermatol Online J. 2008, 14: 1-

    PubMed  Google Scholar 

  18. Temeyer KB, Brake DK, Tuckow AP, Li AY, Pérez de León AA: Acetylcholinesterase of the sand fly, Phlebotomus papatasi (Scopoli): cDNA sequence, baculovirus expression, and biochemical properties. Parasit Vectors. 2013, 6: 31-10.1186/1756-3305-6-31.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  19. Hemingway J, Ranson H: Insecticide resistance in insect vectors of human disease. Annu Rev Entomol. 2000, 45: 371-391. 10.1146/annurev.ento.45.1.371.

    Article  CAS  PubMed  Google Scholar 

  20. Fournier D, Mutero A: Modification of acetylcholinesterase as a mechanism of resistance to insecticides. Comp Biochem Physiol C Toxicol Pharmacol. 1994, 108: 19-31.

    Google Scholar 

  21. Mutero A, Pralavorio M, Bride JM, Fournier D: Resistance-associated point mutations in insecticide insensitive acetylcholinesterase. Proc Natl Acad Sci U S A. 1994, 91: 5922-5926. 10.1073/pnas.91.13.5922.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  22. Faraj C, Ouahabi S, Adlaoui EB, Elkohli ME, Lakraa L, Rhazi ME, Ameur B: Insecticide susceptibility status of Phlebotomus (Paraphlebotomus) sergenti and Phlebotomus (Phlebotomus) papatasi in endemic foci of cutaneous leishmaniasis in Morocco. Parasit Vectors. 2012, 5: 51-10.1186/1756-3305-5-51.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  23. Surendran SN, Karunaratne SHPP, Adams Z, Hemingway J, Hawkes NJ: Molecular and biochemical characterization of a sand fly population from Sri Lanka: evidence for insecticide resistance due to altered esterases and insensitive acetylcholinesterase. Bull Entomol Res. 2005, 95: 371-380. 10.1079/BER2005368.

    Article  CAS  PubMed  Google Scholar 

  24. Hassan MM, Widaa SO, Osman OM, Numiary MSM, Ibrahim MA, Abushama HM: Insecticide resistance in the sand fly, Phlebotomus papatasi from Khartoum State. Sudan. Parasit Vectors. 2012, 5: 46-10.1186/1756-3305-5-46.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  25. Massoulie J, Sussman JL, Doctor BP, Soreq H, Velan B, Cygler M, Rotundo R, Shafferman A, Silman I, Taylor P: Recommendations for nomenclature in cholinesterases.In: Shafferman A, Velan G (Eds), Multidisciplinary Approaches to Cholinesterase Functions, Plenum Press, New York, pp. 285–288.,

  26. Weill W, Lutfalla G, Mogensen K, Chandre F, Berthomieu A, Berticat C, Pasteur N, Philips A, Fort P, Raymond M: Insecticide resistance in mosquito vectors. Nature. 2003, 423: 136-137. 10.1038/423136b.

    Article  CAS  PubMed  Google Scholar 

  27. Weill W, Lutfalla G, Mogensen K, Chandre F, Berthomieu A, Berticat C, Pasteur N, Philips A, Fort P, Raymond M: Corrigendum:Insecticide resistance in mosquito vectors. Nature. 2003, 425: 366-

    CAS  Google Scholar 

  28. Weill W, Malcolm C, Chandre F, Mogensen K, Berthomieu A, Marquine M, Raymond M: The unique mutation in ace-1 giving high insecticide resistance is easily detectable in mosquito vectors. Insect Mol Biol. 2004, 13: 1-7. 10.1111/j.1365-2583.2004.00452.x.

    Article  CAS  PubMed  Google Scholar 

  29. Hartsel JA, Wong DM, Mutunga JM, Ma M, Anderson TD, Wysinski A, Islam RM, Wong EA, Paulson SL, Li J, Lam PC-H, Totrov M, Bloomquist JR, Carlier PR: Re-engineering aryl methylcarbamates to confer high selectivity for inhibition of Anopheles gambiae vs human acetylcholinesterase. Bioorg Med Chem Lett. 2012, 22: 4593-4598. 10.1016/j.bmcl.2012.05.103.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  30. Wong DM, Li J, Chen Q-H, Han Q, Mutunga JM, Wysinski A, Anderson TD, Ding H, Carpenetti T, Verma A, Islam RM, Paulson SL, Lam PC-H, Totrov M, Bloomquist JR, Carlier PR: Select small core structure carbamates exhibit high contact toxicity to “carbamate-resistant” strain malaria mosquitoes, Anopheles gambiae (Akron). PLoS ONE. 2012, 7: e46712-10.1371/journal.pone.0046712.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  31. Carlier PR, Du D-M, Han Y-F, Liu J, Pang Y-P: Potent, easily synthesized huperzine a-tacrine hybrid acetylcholinesterase inhibitors. Bioorg Med Chem Lett. 1999, 9: 2335-2338. 10.1016/S0960-894X(99)00396-0.

    Article  CAS  PubMed  Google Scholar 

  32. Harel M, Schalk I, Ehret-Sabatier L, Bouet F, Goeldner M, Hirth C, Axelsen PH, Silman I, Sussman JL: Quaternary ligand binding to aromatic residues in the active-site gorge of acetylcholinesterase. Proc Natl Acad Sci U S A. 1993, 90: 9031-9035. 10.1073/pnas.90.19.9031.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  33. Ellman GL, Courtney KD, Andres V, Feather-Stone RM: A new and rapid colorimetric determination of acetylcholinesterase activity. Biochem Pharmacol. 2009, 7: 88-95. 10.1016/0006-2952(61)90145-9.

    Article  Google Scholar 

  34. Abagyan R, Orry A, Raush E, Totrov M: ICM user manual. 2013, http://www.molsoft.com/browser/.

  35. Abagyan R, Batalov S, Cardozo T, Totrov M, Webber J, Zhou Y: Homology modeling with internal coordinate mechanics: deformation zone mapping and improvements of models via conformational search. Proteins. 1997, 1997 (Suppl. 1): 29-37. 10.1002/(SICI)1097-0134(1997)1+<29::AID-PROT5>3.0.CO;2-J.

    Article  Google Scholar 

  36. Andersson CD, Forsgren N, Akfur C, Allgardsson A, Berg L, Engdahl C, Qian W, Ekström J, Linusson A: Divergent structure-activity relationships of structurally similar acetylcholinesterase inhibitors. J Med Chem. 2013, 56: 7615-7624. 10.1021/jm400990p.

    Article  CAS  PubMed  Google Scholar 

  37. Totrov M, Abagyan R: Flexible protein-ligand docking by global energy optimization in internal coordinates. Proteins. 1997, 1997 (Suppl 1): 215-220. 10.1002/(SICI)1097-0134(1997)1+<215::AID-PROT29>3.0.CO;2-Q.

    Article  Google Scholar 

  38. Neves MA, Totrov M, Abagyan R: Docking and scoring with ICM: the benchmarking results and strategies for improvement. J Compu Aided Mol Des. 2012, 26: 675-686. 10.1007/s10822-012-9547-0.

    Article  CAS  Google Scholar 

  39. Bottegoni G, Kufareva I, Totrov M, Abagyan R: Four-dimensional docking: a fast and accurate account of discrete receptor flexibility in ligand docking. J Med Chem. 2009, 52: 397-406. 10.1021/jm8009958.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  40. Lappi S, Taylor P: Interaction of fluorescence probes with acetylcholinesterase. The site and specificity of propidium binding. Biochem. 1975, 14: 1989-1997. 10.1021/bi00680a029.

    Article  Google Scholar 

  41. Wong DM, Li J, Lam PCH, Hartsel JA, Mutunga JM, Totrov M, Bloomquist JR, Carlier PR: Aryl methylcarbamates: potency and selectivity towards wild-type and carbamate-insensitive (G119S) Anopheles gambiae acetylcholinesterase, and toxicity to G3 strain An. gambiae. Chem Biol Interact. 2013, 203: 314-318. 10.1016/j.cbi.2012.09.001.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  42. Swale DR, Tong F, Temeyer KB, Li A, Lam PC-H, Totrov MM, Carlier PR, Pérez de León AA, Bloomquist JR: Inhibitor profile of bis(n)-tacrines and N-methylcarbamates on acetylcholinesterase from Rhipicephalus (Boophilus) microplus and Phlebotomus papatasi. Pest Biochem Physiol. 2013, 106: 85-92. 10.1016/j.pestbp.2013.03.005.

    Article  CAS  Google Scholar 

  43. Djogbénou L, Noel V, Agnew P: Costs of insensitive acetylcholinesterase insecticide resistance for the malaria vector Anopheles gambiae homozygous for the G119S mutation. Malaria J. 2010, 9: 12-10.1186/1475-2875-9-12.

    Article  Google Scholar 

  44. Rivero A, Magaud A, Nicot A, Vézilier J: Energetic cost of insecticide resistance in Culex pipiens mosquitoes. J Med Entomol. 2011, 48: 694-700. 10.1603/ME10121.

    Article  CAS  PubMed  Google Scholar 

  45. Alout H, Djogbénou L, Berticat C, Chandre F, Weill M: Comparison of Anopheles gambiae and Culex pipiens acetylcholinesterase 1 biochemical properties. Comp Biochem Physiol B. 2008, 150: 271-277. 10.1016/j.cbpb.2008.03.008.

    Article  PubMed  Google Scholar 

  46. Alout H, Labbé P, Berthomieu A, Pasteur N, Weill M: Multiple duplications of the rare ace-1 mutation F290V in Culex pipiens natural populations. Insect Biochem Mol Biol. 2009, 39: 884-891. 10.1016/j.ibmb.2009.10.005.

    Article  CAS  PubMed  Google Scholar 

  47. Osta MA, Rizk ZJ, Labbé P, Weill M, Knio K: Insecticide resistance to organophosphates in Culex pipiens complex from Lebanon. Parasit Vectors. 2012, 5: 132-10.1186/1756-3305-5-132.

    Article  PubMed Central  CAS  PubMed  Google Scholar 

  48. Labbé P, Berticat C, Berthomieu A, Unal S, Bernard C, Weill M, Lenormand T: Forty years of erratic insecticide resistance evolution in the mosquito Culex pipiens. PLoS Genet. 2007, 3: e205-10.1371/journal.pgen.0030205.

    Article  PubMed Central  PubMed  Google Scholar 

  49. Berticat C, Bonnet J, Duchon S, Agnew P, Weill M, Corbel V: Costs and benefits of multiple resistance to insecticides for Culex quinquefasciatus mosquitoes. BMC Evol Biol. 2008, 8: 104-10.1186/1471-2148-8-104.

    Article  PubMed Central  PubMed  Google Scholar 

  50. Labbé P, Berthomieu A, Berticat C, Alout H, Raymond M, Lenormand T, Weill M: Independent duplications of the acetylcholinesterase gene conferring insecticide resistance in the mosquito Culex pipiens. Mol Biol Evol. 2007, 24: 1056-1067. 10.1093/molbev/msm025.

    Article  PubMed  Google Scholar 

  51. Djogbénou L, Labbé P, Chandre F, Pasteur N, Weill M:Ace-1 duplication in Anopheles gambiae: a challenge for malaria control. Malaria J. 2009, 8: 70-10.1186/1475-2875-8-70.

    Article  Google Scholar 

  52. Alout H, Labbé P, Pasteur N, Weill M: High incidence of ace-1 duplicated haplotypes in resistant Culex pipiens mosquitoes from Algeria. Insect Biochem Mol Biol. 2011, 41: 29-35. 10.1016/j.ibmb.2010.09.009.

    Article  CAS  PubMed  Google Scholar 

  53. Essandoh J, Yawson AE, Weetman D: Acetylcholinesterase (Ace-1) target site mutation 119S is strongly diagnostic of carbamate and organophosphate resistance in Anopheles gambiae s.s. and Anopheles coluzzii across southern Ghana. Malaria J. 2013, 12: 404-10.1186/1475-2875-12-404.

    Article  Google Scholar 

  54. Naik PK, Sindhura TS, Singh H: Quantitative structure-activity relationship (QSAR) for insecticides: development of predictive in vivo insecticide activity models. SAR QSAR Environ Res. 2009, 20: 551-566. 10.1080/10629360903278735.

    Article  CAS  PubMed  Google Scholar 

Download references

Acknowledgements

The authors thank Kristie Schlechte for excellent technical assistance. This work was funded by U.S. Department of Agriculture [USDA] appropriated funds (USDA-ARS CRIS number 6205-32000-033000D, Molecular biology and physiology of biting flies affecting livestock) and USDA-ARS CRADA number 60-0208-9-601 (Project number 6201-32000-033017R, Deployed Warfighter Protection Research Program [DWFP] of the U.S. Department of Defense through the Armed Forces Pest Management Board [AFPMB]). Additional funding was provided by USDA Specific Cooperative Agreement 108-0128-098 to JRB as part of the DWFP and the AFPMB.

GenBank

JQ922267, AFP20868.

Author information

Authors and Affiliations

Authors

Corresponding author

Correspondence to Kevin B Temeyer.

Additional information

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

KBT conceived and designed experiments to construct, clone, sequence, and express rPpAChE in the baculovirus system. PRC and Q-hC constructed the synthetic carbamates. APT and FT conducted biochemical assays and data analysis of rPpAChE1 and rPpAChE1-G119S. MMT constructed the molecular homology model. All authors contributed to writing and revision of the manuscript and approved the final version.

Authors’ original submitted files for images

Rights and permissions

This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Temeyer, K.B., Tong, F., Totrov, M.M. et al. Acetylcholinesterase of the sand fly, Phlebotomus papatasi (Scopoli): construction, expression and biochemical properties of the G119S orthologous mutant. Parasites Vectors 7, 577 (2014). https://doi.org/10.1186/s13071-014-0577-4

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI: https://doi.org/10.1186/s13071-014-0577-4

Keywords