Insecticide resistance in the tropical bedbug Cimex hemipterus

Insecticide resistance in the bedbug Cimex hemipterus was investigated using 4211 bedbugs collected from three districts of Sri Lanka. Insecticide bioassays were carried out with discriminating dosages of deltamethrin, permethrin, DDT, malathion, and propoxur. Activity levels of insecticide metabolizing enzymes and the insecticide target site acetylcholinesterase were monitored using biochemical assays. Percentage survivals after DDT, malathion, and propoxur exposure were 41-88%, 18-64%, and 11-41%, respectively. For deltamethrin and permethrin, KT₅₀/KT₉₀ (time to knock-down 50%/90% of the population) values were 0.5-24/1.0-58 and 1.3-10/2.5-47 h, respectively. Both elevated esterase and malathion carboxylesterase mechanisms were present in bedbug populations. Monooxygenase levels were heterogeneous. Organophosphate and carbamate target site acetylcholinesterase, was insensitive in 29-44% of the populations. High DDT resistance was probably due to glutathione S-transferases. Malathion carboxylesterases are mainly responsible for high malathion resistance. High tolerance to both DDT and pyrethroids suggests the presence of ‘kdr’ type resistance mechanism in one population.     

Biochemical characteristics of insecticide resistance in the fall armyworm, Spodoptera frugiperda (J.E. Smith)

A strain of the fall armyworm, Spodoptera frugiperda (J.E. Smith), collected from corn in Citra, Florida, showed high resistance to carbaryl (562-fold) and methyl parathion (354-fold). Biochemical studies revealed that various detoxification enzyme activities were higher in the field strain than in the susceptible strain. In larval midguts, activities of microsomal oxidases (epoxidases, hydroxylase, sulfoxidase, N-demethylase, and O-demethylase) and hydrolases (general esterase, carboxylesterase, β-glucosidase) were 1.2- to 1.9-fold higher in the field strain than in the susceptible strain. In larval fat bodies, various activities of microsomal oxidases (epoxidases, hydroxylase, N-demethylase, O-demethylases, and S-demethylase), glutathione S-transferases (CDNB, DCNB, and p-nitrophenyl acetate conjugation), hydrolases (general esterase, carboxylesterase, β-glucosidase, and carboxylamidase) and reductases (juglone reductase and cytochrome c reductase) were 1.3- to 7.7-fold higher in the field strain than in the susceptible strain. Cytochrome P450 level was 2.5-fold higher in the field strain than in the susceptible strain. In adult abdomens, their detoxification enzyme activities were generally lower than those in larval midguts or fat bodies; this is especially true when microsomal oxidases are considered. However, activities of microsomal oxidases (S-demethylase), hydrolases (general esterase and permethrin esterase) and reductases (juglone reductase and cytochrome c reductase) were 1.5- to 3.0-fold higher in the field strain than in the susceptible strain. Levels of cytochrome P450 and cytochrome b₅ were 2.1 and 1.9-fold higher, respectively, in the field strain than in the susceptible strain. In addition, acetylcholinesterase from the field strain was 2- to 85-fold less sensitive than that from the susceptible strain to inhibition by carbamates (carbaryl, propoxur, carbofuran, bendiocarb, thiodicarb) and organophosphates (methyl paraoxon, paraoxon, dichlorvos), insensitivity being highest toward carbaryl. Kinetics studies showed that the apparent K_m value for acetylcholinesterase from the field strain was 56% of that from the susceptible strain. The results indicated that the insecticide resistance observed in the field strain was due to multiple resistance mechanisms, including increased detoxification of these insecticides by microsomal oxidases, glutathione S-transferases, hydrolases and reductases, and target site insensitivity such as insensitive acetylcholinesterase. Resistance appeared to be correlated better with detoxification enzyme activities in larval fat bodies than in larval midguts, suggesting that the larval fat body is an ideal tissue source for comparing detoxification capability between insecticide-susceptible and -resistant insects.     

Esterase-mediated malathion resistance in the human head louse, Pediculus capitis (Anoplura: Pediculidae)

Resistance in a dual malathion- and permethrin-resistant head louse strain (BR-HL) was studied. BR-HL was 3.6- and 3.7-fold more resistant to malathion and permethrin, respectively, compared to insecticide-susceptible EC-HL. S,S,S-Tributylphosphorotrithioate synergized malathion toxicity by 2.1-fold but not permethrin toxicity in BR-HL. Piperonyl butoxide did not synergize malathion or permethrin toxicity. Malathion carboxylesterase (MCE) activity was 13.3-fold and general esterase activity was 3.9-fold higher in BR-HL versus EC-HL. There were no significant differences in phosphotriesterase, glutathione S-transferase, and acetylcholinesterase activities between strains. There was no differential sensitivity in acetylcholinesterase inhibition by malaoxon. Esterases from BR-HL had higher affinities and hydrolysis efficiencies versus EC-HL using various naphthyl-substituted esters. Protein content of BR-HL females and males was 1.6- and 1.3-fold higher, respectively, versus EC-HL adults. Electrophoresis revealed two esterases with increased intensity and a unique esterase associated with BR-HL. Thus, increased MCE activity and over-expressed esterases appear to be involved in malathion resistance in the head louse.     

Pesticide resistance in glasshouse whitefly (Trialeurodes vaporariorum west

A survey in SE England showed that seven out of 17 populations of glasshouse whitefly were resistant to DDT. Resistance to malathion occurred in 15 populations and to resmethrin in eight. Mecarbam and methiocarb gave good kills in screening tests but some insect growth regulators gave variable results. The synthetic pyrethroid permethrin was slightly more effective against a population of whitefly resistant to both DDT and malathion than against a susceptible population. Parthenogenetic females from a population susceptible to DDT and malathion produced almost entirely male progeny. An unsuccessful attempt was made to lower the resistance level of a DDT/malathion resistant strain by introducing these males to resistant females.     

The biochemical nature of malathion resistance in Anopheles stephensi from Pakistan

Malathion resistance in Anopheles stephensi from Pakistan was synergized by triphenyl phosphate, primarily a carboxylesterase inhibitor. There was a slight degree of antagonism with piperonyl butoxide. The major metabolite of malathion in larvae of both the resistant and susceptible strains was malathion monocarboxylic acid. Resistant larvae produced about twice as much of this product as the susceptible larvae. This suggests that a qualitative or a quantitative change in a carboxylesterase enzyme may be the basis of malathion resistance in this strain. Analysis of general esterase levels to α- and β-naphthyl acetate showed that there was no quantitative change in the amount of carboxylesterase enzyme present in the resistant strain as compared to the susceptible.     

Dual role of esterases in insecticide resistance in the green rice leafhopper

The role of esterases as related to insecticide resistance was studied in an organophosphorus (OP)-resistant strain of the green rice leafhopper. As judged by p-nitrophenyl acetate hydrolysis, 21, 5, and 74% of the esterase activity was located in nuclei/mitochondria, microsomes, and the soluble fraction, respectively. All the fractions were active in hydrolyzing malathion, paraoxon, and fenvalerate. Hydrolysis of malathion and fenvalerate increased with time while that of paraoxon reached a plateau within 15 min. Since a considerable amount of p-nitrophenol was detected in the paraoxon reaction at 0°C and at zero time, the formation of p-nitrophenol may be due to phosphorylation of the esterases rather than phosphorotriesterase action. The results suggest a dual role for esterases in resistance mechanisms; a catalyst for hydrolysis of malathion and fenvalerate, and a binding protein for the oxygen analogs of other OP insecticides, both of which would protect the intrinsic target, acetylcholinesterase, from inhibition. Chromatofocusing of the soluble fraction resolved five esterase peaks, I–V. These esterases were active toward the three general substrates as well as for the three insecticides tested, except for Peak I in which the overall activity was too low. Thin-layer agar gel electrophoresis showed that the chromatofocusing peaks I–V corresponded to the electrophoretic bands E₁–E₅, some of which were previously shown to be associated with OP resistance. The dual role of these esterases may explain the cross-resistance between malathion and other OP insecticides as well as synergism between OP and carbamate insecticides.     

Toxicity of ddt and malathion to various larval stages of Mamestra brassicae L.

The toxicity of DDT and malathion to the larvae of Mamestra brassicae was determined following several methods of application. The toxicity (LD₅₀), expressed as μg insecticide per g of insect, did not change significantly between larval instars (a) when either insecticide was injected into fourth to sixth instars; (b) when DDT was applied in the food of fifth and sixth instars; or (c) when malathion was applied topically to second to sixth instars. Significant changes in toxicity were found between successive instars when DDT was applied topically, but there was no clear trend. When malathion was applied in the food, the fifth instars were more susceptible than the sixth instars; it was found that the former consumed a toxic dose of malathion at a greater rate, and that probably malathion was degraded in the gut at a slower rate. In a contact test, the first to third instars were far more susceptible than the later instars to malathion; with DDT this trend was much less marked. Uptake studies with [¹⁴C]malathion showed that differences in the contact toxicity of malathion between instars could be explained, at least partly, by the decline in uptake per unit weight with increasing larval size.     

Characterization of acephate resistance in the diamondback moth Plutella xylostella

Decreased acetylcholinesterase (AChE) sensitivity and metabolic detoxification mediated by glutathione S-transferases (GSTs) were examined for their involvement in resistance to acephate in the diamondback moth, Plutella xylostella. The resistant strain showed 47.5-fold higher acephate resistance than the susceptible strain had. However, the resistant strain was only 2.3-fold more resistant to prothiofos than the susceptible strain. The resistant strain included insects having the A298S and G324A mutations in AChE1, which are reportedly involved in prothiofos resistance in P. xylostella, showing reduced AChE sensitivity to inhibition by methamidophos, suggesting that decreased AChE1 sensitivity is one factor conferring acephate resistance. However, allele frequencies at both mutation sites in the resistant strain were low (only 26%). These results suggest that other factors such as GSTs are involved in acephate resistance. Expression of GST genes available in P. xylostella to date was examined using the resistant and susceptible strains, revealing no significant correlation between the expression and resistance levels.     

Increased activity and reduced sensitivity of acetylcholinesterase associated with malathion resistance in a field population of the oriental migratory locust, Locusta migratoria manilensis (Meyen)

The susceptibility to malathion, and the activity and sensitivity of acetylcholinesterase (AChE, EC 1.1.1.7) were compared between two populations of the oriental migratory locust, Locusta migratoria manilensis (Meyen) collected from Wudi County of Shandong Province in East China and Huangliu County of Hainan Province in South China. Huangliu population showed 8.5-fold resistance to malathion compared with Wudi population. AChE from Huangliu population showed 4.8-fold higher activity than that from Wudi population toward the model substrate acetylthiocholine (ATC). Kinetic studies indicated that AChE from Huangliu population had 2.6-fold lower affinity, but 5.0-fold higher catalytic activity toward ATC than AChE from Wudi population. Significantly increased activity of AChE in Huangliu population was also confirmed by non-denaturing polyacrylamide gel electrophoresis. Inhibition kinetics revealed that AChE from Huangliu population was 9.8-, 2.4-, 8.0- and 7.7-fold less sensitive to inhibition by paraoxon, malaoxon, chlopyrifos oxon, demeton-S-methyl, respectively, than that from Wudi population. Our studies revealed that a mild resistance to malathion in Huangliu population was associated with reduced sensitivity and increased catalytic activity of AChE. Our results suggest that alterations of AChE may play an important role conferring or contribute to malathion resistance in Huangliu population of the locust.     

Resistance in the highly DDT-resistant 91-R strain of Drosophila melanogaster involves decreased penetration,increased metabolism,and direct excretion

Resistance to 4,4′-dichlorodiphenyltrichloroethane (DDT) in the 91-R strain of Drosophila melanogaster is extremely high compared to the susceptible Canton-S strain (>1500 times). In addition to enhanced oxidative detoxification, the 91-R strain also has a reduced rate of DDT penetration, increased levels of reductive and conjugative metabolism, and substantially more excretion than the Canton-S strain. Contact penetration of DDT was ∼30% less with 91-R flies, which also had significantly more cuticular hydrocarbons and a thicker, more laminated cuticle compared to Canton-S flies, possibly resulting in penetration differences. DDT was metabolized ∼1.6-fold more extensively by 91-R than Canton-S flies, resulting in dichlorodiphenyldichloroethane (DDD), two unidentified metabolites and polar conjugates being formed in significantly greater amounts. 91-R flies also excreted ∼4-fold more DDT and metabolites than Canton-S flies. Verapamil pretreatment reduced the LD₅₀ value for 91-R flies topically dosed with DDT by a factor of 10-fold, indicating that the increased excretion may involve, in part, ATP-binding cassette (ABC) transporters. In summary, DDT resistance in 91-R is polyfactorial and includes reduced penetration, increased detoxification and direct excretion.     

Selection of Anopheles stephensi with DDT and dieldrin and cross-resistance spectrum to pyrethroids and fipronil

The field strain of Anopheles stephensi, the main malaria vector in south of Iran, was colonized in laboratory and selected with DDT and dieldrin in two separate lines for 3 generations to a level of 19.5- and 14-fold for DDT and dieldrin resistance, respectively. Synergist tests with chlorofenethol (DMC) and piperonyl butoxide (PBO) on the selected strains indicated that dehydrochlorination and oxidative detoxification might be the underlying mechanisms involved in the resistance to dieldrin and DDT in selected strains. DDT selection decreased susceptibility to DDT and pyrethroids including lambdacyhalothrin, permethrin deltamethrin and cyfluthrin. The result also showed that selection with dieldrin caused negative and positive cross-resistance to pyrethroid and fipronil, respectively. Based on these results, it can be concluded that besides metabolic resistance mechanisms, other factors such as mutation in γ aminobutyric acid (GABA) and voltage-gated sodium channels (Kdr) might be involved.     

The in vitro degradation of [14C]malathion by enzymatic extracts from resistant and susceptible strains of Drosophila melanogaster

Enzyme preparations from Drosophila melanogaster flies degraded [¹⁴C]malathion to α- and β-malathion monoacids and, hence, were considered to contain malathion carboxylesterase (ME) activity. Although ME- activity was stable during preincubation in the absence of malathion, it decreased dramatically during the course of the reaction, and could not be completely recovered by Sephadex G-25 chromatography. Furthermore, the protein fraction after chromatography still contained ¹⁴C, suggesting that the enzyme had become inhibited by a bound, ¹⁴C-labeled derivative. Extracts from a resistant (malathion-selected), an intermediate control, and the susceptible Canton S strains of D. melanogaster differed in the lability of ME activity during the reaction. This difference was partly attributed to the production of small amounts of malaoxon (2–8%) by the extracts from the more resistant strains. No consistent strain differences were found when the rate of malathion degradation was measured during the first minute of reaction, either with or without a microsomal oxidase inhibitor (metyrapone) present. These results, together with the cross-resistance of the malathion-selected strain to other insecticides and the lack of a synergistic effect of two carboxylesterase inhibitors (triphenyl phosphate and S,S,S-tributylphosphorotrithioate) suggested that malathion carboxylesterase does not contribute significantly to the observed differences in malathion resistance between strains.     

In vitro metabolism of insecticides during midgut penetration

A study of the metabolism of ¹⁴C-labeled dieldrin, DDT, malathion, and carbaryl during penetration of the isolated midgut of two insects (Blaberus discoidalis and Manduca sexta) and a section of the intestine of a mammal (Mus musculus) is reported. There was appreciable metabolism of malathion during penetration, including differences in the activation reaction to malaoxon, between insects and mammals. Metabolism was relatively slow during penetration of carbaryl and the chlorinated hydrocarbon insecticides, and little difference in metabolic patterns was noted among the three species. The penetration studies were supported by experiments in which insecticides were incubated with intact and homogenized midgut preparations.     

Insensitive acetylcholinesterase,high glutathione-S-transferase,and hydrolytic activity as resistance factors in a tetrachlorvinphos-resistant strain of house fly

The gene producing insensitive acetylcholinesterase in a tetrachlorvinphos-resistant strain of house fly was introduced into the genome of a susceptible strain. The resistance to a number of organophosphorus insecticides, which was high in the original strain (234- and more than 800-fold for paraoxon and tetrachlorvinphos, respectively), was much lower in the resulting strain, ranging from 53-fold for paraoxon to 3.9-fold for tetrachlorvinphos. Synergists further decreased these factors. The reduction in sensitivity of the acetylcholinesterase in vitro was about 20-fold for both inhibitors. The Michaelis parameters for hydrolysis of acetylcholine and acetylthiocholine of the mutant and normal acetylcholinesterase showed only minor differences. An increased rate of metabolism of the insecticides was found in the original strain. In vitro, glutathione-dependent detoxication was from 9- to 120-fold that of a susceptible strain, depending on the insecticide and the conditions used. The enzyme de-alkylated parathion and methylparaoxon, but there was no de-arylation of parathion, although it is important in other strains. In vitro, paraoxon and methylparaoxon were also hydrolysed, and this is not so in the susceptible strain. The high resistance present in the original strain seems to be due to joint action of at least three mechanisms.     

Present status and countermeasures of insecticide resistance in agricultural pests in China

Of the 23 species of agricultural pest known to resist insecticides in China, 4 are cotton pests, 4 rice pests and 5 are pests of brassicae. In the green rice leafhopper, malathion resistance is caused by increased carboxylesterase (CarE) activity, which plays a more important role in the resistance to dimethoate than the mixed-function oxidases (mfos). The in-vitro and in-vivo results are in agreement with studies of synergism of malathion and dimethoate by TPP and EBP. These synergists delay the development of resistance, and EBP when added to malathion has limited the development of resistance to malathion in the green rice leafhopper. In the cotton aphid, resistance to organophosphates involves several factors: acetylcholinesterase (AChE) insensitivity, high CarE activity, slight (× 2) increase in glutathione S-transferases (GSH-ases), mfo activity as well as reduced penetration. In vitro, the I₅₀ of the insensitive AChE is × 14 that of S aphids, and anaphthyl-acetate CarE hydrolysing activity is 70 times greater in R than in S aphids. Insecticide mixtures, alternation or rotation can delay build-up of resistance; resistance to malathion and trichlorfon was delayed in Culex pipiens pallens when the two insecticides were used together. Used singly each insecticide selected for high resistance within 25 generations. Mosaic rotation of dimethoate and fenvalerate delayed the onset of insecticide resistance in Lipaphis erysimi pseudobrassicae.     

in vitro metabolism of azinphosmethyl in susceptible and resistant houseflies

The in vitro metabolism of [¹⁴C-methoxy] or [³²P]azinphosmethyl by subcellular fractions of abdomens from a resistant and a susceptible strain of houseflies was studied. The degradative activity in both strains was associated with the microsomal and soluble fractions and required NADPH and glutathione, respectively. The resistant strain possessed higher activity for both the mixed-function oxidases and the glutathione transferase than the susceptible strain, and both systems appear to be important in the resistance mechanism. The mixed-function oxidases were involved in the oxidative desulfuration as well as the dearylation of azinphosmethyl. A glutathione transferase located in the soluble fraction catalyzed the formation of desmethyl azinphosmethyl and methyl glutathione. This enzyme also demethylated azinphosmethyl oxygen analog. Although the soluble fraction exhibited both glutathione S-alkyltransferase and S-aryltransferase activity against noninsecticidal substrates, no evidence of the transfer of the benzazimide moiety from azinphosmethyl to glutathione was obtained. Sephadex G-100 chromatography of the soluble enzymes revealed a common eluting fraction responsible for both types of transferase activity.     

Juvenile hormone analogs: Toxicity and cross-resistance in the housefly

The toxicity of several juvenile hormone analogs (JHAs) to susceptible and insecticide-resistant housefly (Musca domestica L.) strains was determined by an assay procedure in which larvae were exposed to residues of JHAs in glass vials. All JHAs tested were toxic and the most active compound, isopropyl 11-methoxy-3, 7, 11-trimethylododeca-2, 4-dienoate, was 100 times as toxic to the susceptible Orlando Regular strain as methyl parathion and 600 times as toxic as DDT.A 5- to 30-fold tolerance to the different JHAs was present in an insecticide resistant strain in which resistance is associated with a high level of NADPH-dependent microsomal oxidase activity controlled by a gene(s) on chromosome II. Cross-resistance was less marked in a strain with a chromosome V high oxidase gene and absent in strains with other resistance mechanisms.The data indicate that cross-resistance to JHAs in insects may occur in certain strains with high levels of oxidative detoxifying activity. Even so, the most active JHA was far more toxic to both susceptible and resistant strains than methyl parathion or DDT.     

Triazophos resistance mechanisms in the rice stem borer (Chilo suppressalis Walker)

A field population of the rice stem borer (Chilo suppressalis Walker) with 203.3-fold resistance to triazophos was collected. After 8-generation of continuous selection with triazophos in laboratory, resistance increased to 787.2-fold, and at the same time, the resistance to isocarbophos and methamidophos was also enhanced by 1.9- and 1.4-fold, respectively, implying some cross-resistance between triazophos and these two organophosphate insecticides. Resistance to abamectin was slightly enhanced by triazophos selection, and fipronil and methomyl decreased. Synergism experiments in vivo with TPP, PBO, and DEM were performed to gain a potential indication of roles of detoxicating enzymes in triazophos resistance. The synergism results revealed that TPP (SR, 1.92) and PBO (SR 1.63) had significant synergistic effects on triazophos in resistant rice borers. While DEM (SR 0.83) showed no effects. Assays of enzyme activity in vitro demonstrated that the resistant strain had higher activity of esterase and microsomal O-demethylase than the susceptible strain (1.20- and 1.30-fold, respectively). For glutathione S-transferase activity, no difference was found between the resistant and the susceptible strain when DCNB was used as substrate. However, 1.28-fold higher activity was observed in the resistant strain when CDNB was used. These results showed that esterase and microsomal-O-demethylase play some roles in the resistance. Some iso-enzyme of glutathione S-transferase may involve in the resistance to other insecticides, for this resistant strain was selected from a field population with multiple resistance background. Acetylcholinesterase as the triazophos target was also compared. The results revealed significant differences between the resistant and susceptible strain. The V_max and K_m of the enzyme in resistant strain was only 32 and 65% that in the susceptible strain, respectively. Inhibition tests in vitro showed that I₅₀ of triazophos on AChE of the resistant strain was 2.52-fold higher. Therefore, insensitive AChE may also involved in triazophos resistance mechanism of rice stem borer.     

Fipronil resistance mechanisms in the rice stem borer, Chilo suppressalis Walker

Fipronil resistance mechanisms were studied between the laboratory susceptible strain and the selective field population of rice stem borer, Chilo suppressalis Walker in the laboratory. The borer population was collected from Wenzhou county, Zhejiang province. After five generations of selection, fipronil resistance ratio was 45.3-fold compared to the susceptible strain. Synergism experiments showed that the synergistic ratios of PBO, TPP and DEF on fipronil in susceptible and resistant strains of C. suppressalis were 7.55-, 1.93- and 2.91-fold, respectively, and DEM showed no obvious synergistic action on fipronil. Activities of carboxylesterase and microsomal-O-demethylase in the resistant strain were 1.89- and 1.36-fold higher that in susceptible strain, and no significant difference of glutathione-S-transferase activity was found between the resistant and susceptible strains. The K_m and V_max experiments also demonstrated that fipronil resistance of C. suppressalis was closely relative to the enhanced activities of carboxylesterase and microsomal-O-demethylase. Moreover, cross-resistance between fipronil and other conventional insecticides and the multiple resistant properties of the original Wenzhou’s population were also discussed.