Resistance mechanisms to DDT and transpermethrin in Aedes aegypti

Penetration, metabolism and excretion of [¹⁴C]DDT and [³H]transpermethrin were studied in three strains of Aedes aegypti L. after topical application of 10 nl of a solution of the insecticide in 2-ethoxyethanol. The standard susceptible strain was compared with a DDT-selected strain (BKS) and a permethrin-selected strain (BKPM). No significant penetration resistance was observed in either resistant strain, but both showed high DDT-dehydrochlorinase activity which contributed to the DDT resistance. A non-metabolic factor was also involved. Rates of transpermethrin metabolism were very similar in all three strains and substantially higher internal concentrations of transpermethrin were required to produce toxic effects in both BKS and BKPM mosquitoes. By analogy with other insect species, it is concluded that transpermethrin resistance in these strains is of the kdr type, while the DDT resistance is a mixture of kdr and DDT-dehydrochlorinase.     

抗性甜菜夜蛾Na-K-ATP酶、Ca-ATP酶和Ca-Mg-ATP酶对高效氯氟氰菊酯的敏感性

分别测定了甜菜夜蛾Spodoptera exigua敏感和抗高效氯氟氰菊酯品系神经系统Na-K-ATP酶、Ca-ATP酶和Ca-Mg-ATP酶的活力。结果表明,敏感和抗性品系Na-K-ATP酶活力差异不显著,而抗性品系Ca-ATP酶和Ca-Mg-ATP酶活力明显低于敏感品系。在浓度为1.0×10-8~1.0×10-3 mol/L时,高效氯氟氰菊酯对敏感和抗性品系Na-K-ATP酶、Ca-ATP酶和Ca-Mg-ATP酶的活力均有抑制,并且对敏感品系的抑制作用高于对抗性品系。高效氯氟氰菊酯浓度为1.0×10-4 mol/L 时,对敏感品系Na-K-ATP酶活力的抑制率为29.6%,对抗性品系的为21.8%,对敏感品系Ca-ATP酶活力的抑制率为34.3%,对抗性品系为21.9%,对敏感品系Ca-Mg-ATP酶活力的抑制率为22.3%,对抗性品系为16.9%,存在显著差异。表明甜菜夜蛾抗性品系上述3种ATP酶对高效氯氟氰菊酯的敏感性已明显下降。     

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.     

Comparative metabolism of six ethoxychlor analogs and DDT in DDT-resistant and susceptible strains of the house fly Musca domestica L

The metabolic fate of six ³H-ring-substituted ethoxychlor analogs with altered aliphatic moieties and [¹⁴C]p,p′-DDT was investigated in susceptible and DDT-resistant strains of the house fly Musca domestica Linnaeus. The chloroalkane analogs, dichloroethane, chloropropane, and dichloropropane were primarily metabolized to the corresponding dehydrochlorinated products. This pathway was relatively more prominent in the resistant strain than in the susceptible strain. Biotransformation and detoxication of the isobutane, nitropropane, and neopentane derivatives was through microsomal oxidation (O-deethylation) of aryl ethoxy degradophores, and oxidation of the aliphatic moieties to produce the corresponding benzophenones, with no substantial differences between the resistant and susceptible strain. There was a strong correlation between the Taft ($\text{σ}{}^1$) values for the altered aliphatic moieties of chloroalkane analogs and their rate of dehydrochlorination in both the strains. These results suggest the importance of altered aliphatic moieties in developing resistance-proof DDT derivatives.     

转基因棉和常规棉叶片对抗Cry1Ac近等基因系棉铃虫生长发育的影响

利用室内饲喂法,以抗Cry1Ac近等基因系棉铃虫为材料,比较转基因棉花33B和SGK321及其对照亲本DP5415和石远321对抗、感棉铃虫生长发育的影响。结果表明,抗性棉铃虫在取食常规棉叶后表现出一定的适合度代价。取食DP5415和石远321两种常规棉花后,抗性品系棉铃虫的幼虫存活率显著低于敏感品系,取食33B和SGK321两种转基因棉花的抗性棉铃虫,不仅其幼虫存活率显著高于敏感品系,而且致死中时间也比敏感品系延长。取食9天后,抗性品系在常规棉花石远321和DP5415上发育到3龄和4龄幼虫的比例显著低于敏感品系,取食33B和SGK321转基因棉花的抗性品系发育到3龄幼虫的比例均显著高于敏感品系。抗性品系在常规棉上的蛹重均显著低于敏感品系,部分取食转基因棉花的抗性品系棉铃虫可以化蛹,而敏感品系不能在转基因棉花上化蛹。     

Oxidative cleavage of a carboxyester bond as a mechanism of resistance to malaoxon in houseflies

The synergistic effect of triphenyl phosphate (a carboxyesterase inhibitor), sesamex (inhibitor of microsomal oxidation) and O,O-diethyl O-phenyl phosphorothioate on the toxicity of malathion and malaoxon for one susceptible and two resistant strains of housefly was studies. It was found that in the resistant strain G (characterized by high carboxyesterase activity) both malathion and malaoxon were synergized by triphenyl phosphate, but only malaoxon (and not malathion) by sesamex. The other resistant strain E 1, moderately tolerant for malathion but highly resistant to malaoxon, differed from strain G in that triphenyl phosphate had no effect; its response to sesamex was similar to that of strain G. The third synergist, O,O-diethyl O-phenyl phosphorothioate, combined the properties of triphenyl phosphate and sesamex. It was found to be the best of the three compounds used.Biochemical in vitro studies showed that both resistant strains could degrade malaoxon oxidatively at a rate at least 10 × higher than that of the susceptible strain. This oxidation could be inhibited by very low concentrations of the thiono analogue; a malaoxon to malathion ratio of 10:1 gave an inhibition of about 70% at a malaoxon concentration of 5 × 10^?6M. The product of this oxidation is malaoxon β-monocarboxylic acid. This metabolite was also found 1 hr after application of malaoxon in vivo.The results mentioned in this paper indicate that houseflies may become resistant to malaoxon by an increased rate of oxidative carboxyester bond cleavage.     

Metabolism of methyl bromide by susceptible and resistant strains of the granary weevil, Sitophilus granarius (L.)

Methyl bromide was metabolized by susceptible and resistant strains of adult granary weevil, Sitophilus granarius (L.), mainly by conjugation with glutathione. S-Methyl glutathione and S-methyl cysteine were produced by both strains and S-methyl glutathione sulfoxide was identified as a metabolite in the resistant strain. In the untreated insects, no significant difference was observed in glutathione S-transferase activity but the resistant contained approximately twice as much glutathione per insect as the susceptible strain. When the insects were treated with methyl bromide, the glutathione content of both strains was lowered; proportionally, however, the decrease was considerably higher in the susceptible than in the resistant strain. These results indicate that conjugation of methyl bromide with glutathione is a major detoxication pathway and tolerance to this fumigant is related, in part at least, to the level of glutathione in the granary weevil.     

The biochemical basis of malathion resistance in the sheep blowfly,Lucilia cuprina

The in vivo and in vitro metabolism of [¹⁴C]malathion was studied in susceptible (LS) and malathion resistant (RM) strains of the sheep blowfly, Lucilia cuprina (Wiedemann). No difference was found between strains in the penetration, excretion, storage, or inhibitory potency of the insecticide. However, RM degraded malathion to its α- and β-monocarboxylic acid metabolites more rapidly than LS, both in vivo and in vitro. This enhanced degradation of [¹⁴C]malathion occurred in vitro in both mitochondrial and microsomal fractions of resistant flies. Kinetic analysis revealed that these fractions degraded malathion by discrete mechanisms. The enzymes from the mitochondria of both strains had the same K_m, whereas the microsomal enzyme from the RM strain had a fivefold higher K_m than that from the LS strain. Studies of esterase activities and the effect of enzyme inhibitors showed that both the mitochondrial and microsomal resistance mechanisms were the result of enhanced carboxylesterase activity. It was concluded that increased carboxylesterase detoxification of malathion adequately explained the high level of malathion resistance in RM if rate-limiting factors such as cuticular penetration were taken into account.     

Delayed cuticular penetration and enhanced metabolism of deltamethrin in pyrethroid-resistant strains of Helicoverpa armigera from China and Pakistan

The penetration and metabolism of [14C]deltamethrin was studied in susceptible and resistant Chinese and Pakistani strains of Helicoverpa armigera (Hübner), which were resistant to deltamethrin by 330- and 670-fold, respectively. The penetration of deltamethrin into resistant individuals was significantly slower than into susceptible individuals over a 24-h period. The time taken for 50% penetration of the applied deltamethrin was 1 h for the susceptible strain and 6 h for both of the resistant strains. The internal radioactivity was reduced by the larvae of resistant strains much faster than by the susceptible larvae. After 48 h, 40% of the penetrated deltamethrin was still inside the larvae of the susceptible strain, in comparison with 1.5-5% in the Pakistani strain and 8-14% in the Chinese strain. Both of the resistant strains produced methanol-soluble and water-soluble metabolites, but the susceptible strain produced methanol-soluble metabolites only. By 12, 24 and 48 h after dosing, the amount of methanol-soluble metabolites excreted by the resistant strains was almost double that of the susceptible strain. Both of the resistant strains also excreted 5-7% of the penetrated dose as a water-soluble metabolite after 48 h. In comparison with the Chinese strain, the Pakistani strain exhibited slower penetration, lower internal content and faster excretion of deltamethrin, which correlated with the higher resistance of the Pakistani strain. These findings show that the resistant Pakistani and Chinese strains of H. armigera possess mechanisms of reduced cuticular penetration and enhanced metabolism of deltamethrin and perhaps other pyrethroids.     

Development of two strains of <Emphasis Type="Italic">Fusarium culmorum</Emphasis> with a different aggressiveness in the soil and on the roots of barley of two genotypes

Fusarium culmorum can affect plants including cereals or develop saprophytically in the soil. It is unknown whether its saprophytic ability is different in strains with a different aggressiveness. This knowledge could be used for effective breeding of resistant cultivars. Here, we aimed to study the development of two F. culmorum strains with a different aggressiveness in the soil under barley, to compare their saprophytic ability and to reveal the influence, if any, of the host plant on the development of strains in the soil and on the roots. Saprophytic development of the strains was studied on membranes inoculated with macroconidia and placed into non-sterile soil under barley of two genotypes. The fungus was identified on the membranes and on barley roots by indirect immunofluorescent method. Both strains could develop saprophytically. The more aggressive strain (Fc538) showed a lesser saprophytic fitness than the less aggressive strain (Fc885): its mycelial density was lower and the number of chlamydospores was greater. Barley genotypes influenced the development of the fungal strains. Interestingly, conditions for saprophytic development of both strains were more favourable in the soil under barley of the resistant genotype. The more aggressive strain colonized barley of the resistant genotype more actively. Rot symptoms appeared earlier in the barley of the resistant genotype, but the number of diseased plants was greater in the barley of the susceptible genotype. The presence of a saprophytic stage in life cycle should slow down the accumulation of aggressive races in field populations of F. culmorum. Possible interactions between F. culmorum strains and barley plants are discussed.     

Pyrethroid synergists suppress esterase-mediated resistance in Indian strains of the cotton bollworm, Helicoverpa armigera (Hübner)

The role of esterase in pyrethroid resistance was studied in the final larval instar of different strains of the cotton bollworm, Helicoverpa armigera. The resistant strains viz., Nagpur strain and the Delhi strain were found to have elevated midgut esterase activity in comparison to the susceptible strain. Nagpur strain and Delhi strain have 2.24 and 1.73-fold higher esterase activity, respectively, than that of the susceptible strain. The Native PAGE displayed important differences in the midgut esterase isozyme pattern between the susceptible and the pyrethroid-resistant strains. Out of the 10 esterase isozyme observed, susceptible strain lacked three bands, E2, E6 and E10 that were found in the resistant strains. The potency of the synergists piperonyl butoxide (PBO) and dihydrodillapiole (DDA) as esterase inhibitor were also studied both in vitro and in vivo. The in vitro results clearly show that both PBO and DDA inhibited esterase activity in the two resistant strains, while there was almost no esterase inhibition in the homogenate of the susceptible strain. The in vivo inhibition studies (topical application of PBO and DDA followed by biochemical analysis) illustrated that PBO- and DDA-esterase binding is rather slow and non permanent process. Esterase inhibition did not occur immediately after the synergist treatment but at 4 and 8 h post treatment in case of PBO and DDA, respectively. Native PAGE revealed that the in vivo esterase inhibition caused by both PBO and DDA was due to the binding of the synergist with the E6 isozyme which was not present in the susceptible strain.     

Selection for abamectin resistance in colorado potato beetle (coleoptera: Chrysomelidae)

There was no difference in dose response to abamectin between a laboratory strain of Colorado potato beetle (Leptinotarsa decemlineata (Say))from North Carolina and a multiple resistant strain from Massachusetts (LD₅₀= 1.95 and 1.98 ng larva^?1, respectively). Two abamectin-resistant strains were generated by separate means. The mutagen, ethyl methanesulfonate, was used to generate an abamectin-resistant strain (LD₅₀= 29.4 ng larva^?1) from the susceptible laboratory strain. The other resistant strain (LD₅₀ = 45.3 ng larva^?1) was generated through an intense selection with abamectin of a field strain contained in cages set up in existing potato fields. Resistance ratios calculated from LD₅₀values for the two abamectin-resistant strains were 15-fold and 23-fold, respectively. Resistance ratios calculated from LD₉₇values (21-fold and 38-fold, respectively) were higher than those calculated at LD₅₀. Also, there were larvae in both resistant strains which were capable of surviving doses up to 100 ng larva^?1, while the susceptible strain had no survivors at 10 ng larva^?1. Although the logit mortality regression analysis produced statistically different lines for the two abamectin-resistant strains, the slopes of each appear to be the same. Both resistance factors were determined to be autosomal and incompletely recessive (0.26 to 0.4, respectively) via reciprocal F₁crosses to the susceptible laboratory strain.     

On the mode of action of 3-phenylindole towards Aspergillus niger

3-Phenylindole is an antimicrobial compound active towards many fungi and gram-positive bacteria. At 5 μg/ml it inhibits growth of Aspergillus niger. Higher concentrations (50 μg/ml) also suppress spore germination; they do not kill the fungus. Dry weight of the fungus still increases for 1 or 2 days after fungicide treatment. The toxicant has no effect on O₂ uptake even at higher concentrations (100 μg/ml). The compound markedly affects composition of the lipid fraction of A. niger inducing a decrease in phospholipid concentration with a coincident increase in free fatty acids. Sterol pattern and sterol concentration were not affected. Antifungal activity was reversed by phospholipids added to the medium. 3-Phenylindole induced a slight leakage of ³²P-labeled compounds from the treated cells under growth conditions but not under nongrowth conditions. A strain of A. niger resistant to 3-phenylindole had the same phospholipid and sterol pattern as the wild type, but the level of both components was higher (40–60%). The 3-phenylindole-resistant strain showed resistance to triarimol and pimaricin. The wild type and the resistant strain both took up 3-phenylindole quite rapidly and accumulated it in the mycelium. 3-Phenylindole possibly interferes with phospholipid function in cell membranes, although the specific site of action has not yet been elucidated.     

Mechanism of resistance to spinosyn in the tobacco budworm, Heliothis virescens

Topical laboratory selection of tobacco budworm larvae, Heliothis virescens, with technical spinosad for multiple generations resulted in larvae 1068-fold resistant to topical applications of the insecticide and 316.6-fold resistant to insecticide treated diet as compared to the parental strain. The penetration of 2′-O-methyl[¹⁴C]spinosyn A across the cuticle of the susceptible (parental) and selected (resistant) tobacco budworms increased with time 3-12 h after application. A trend of reduced penetration in the resistant strain was found but the differences were not statistically significant. 2′-O-methyl[¹⁴C]spinosyn A when injected into the hemocoel was not metabolized 96 h after treatment in both the susceptible and resistant strain, suggesting that a change in metabolism was not the mechanism of resistance. Electrophysiological studies indicated that dose-dependent spinosyn A-induced currents occurred in neurons from spinosyn resistant and susceptible (adult) tobacco budworms. At both 10 and 100 nM spinosyn A, however, the amplitude of these currents in the resistant insects was significantly smaller than the amplitude of currents observed from neurons from susceptible tobacco budworm adults. This suggests that neurons from resistant insects have decreased sensitivity to spinosyn A. However, the reduced inward currents in the resistant strain may or may not be related to the mode of action of the spinosyns. No statistically significant cross-resistance was noted for the spinosad resistant tobacco budworms for topical applications of permethrin (Pounce^®), profenofos (Curacron^®), emamectin benzoate (Denim^®), or indoxacarb (Steward^®). A statistically significant reduction in susceptibility to acetamiprid (Mospilan^®) in artificial diet as determined from a resistance ratio of 0.482 was found.     

General esterase,malathion carboxylesterase,and malathion resistance in Culex tarsalis

The role of esterases in malathion resistance in Culex tarsalis has been investigated. When larvae of a resistant and a sensitive strain were placed in water containing [¹⁴C]malathion, malathion penetrated to give initially similar internal levels. With resistant mosquitoes, after 15 min the internal malathion concentration decreased to low levels while the monoacid degradation products accumulated in the larvae and were excreted into the surrounding water, whereas in susceptible larvae the internal malathion level stayed high and was lethal. It is suggested that the decrease in internal malathion and the resulting resistance were caused by an active malathion carboxylesterase in the resistant strain. A specific assay for malathion carboxylesterase with [¹⁴C]malathion showed 55 times more activity in resistant than in susceptible larvae, whereas when general esterase activity was assayed with α-naphthyl acetate only 1.7 times the activity was found. Analyses by starch gel electrophoresis showed a peak of malathion carboxylesterase, 60-fold higher from resistant than from susceptible larvae, in a gel zone which did not stain for general esterase activity. General esterases that did not hydrolyze malathion showed different electrophoretic patterns in the two populations, which are likely due to the nonisogenic character of the strains. These results show that use of a specific assay and the demonstration of degradation of malathion in vivo are essential for assessment of the contribution of esterase activity to the malathion-resistant phenotype in mosquito populations.     

The epoxidation of aldrin by microsomes from the Fc strain of housefly: A genetic survey

The DDT-resistant housefly strain, Fe, known to resist DDT by biochemical oxidation, is also resistant to carbamate insecticides and has a high in vitro microsomal epoxidase activity. The purpose of this investigation was to determine whether the DDT resistance, associated with chromosome V, is also responsible for the resistance to carbamates and for the high epoxidase levels. Genetic procedures for segregating the R factors were employed using a multimarker insecticide susceptible strain designated acbco. The technique involved backcrossing the F₁ hybrid of the resistant and susceptible parents to the susceptible parent. The genotypes with a single R chromosome from the Fc parent were retained for further development as substrains and for toxicological and biochemical studies.These studies revealed that both resistance to the carbamate insecticide, propoxur, and the high in vitro microsomal epoxidation of aldrin were lost during the genetic isolation of the R factors. However, the resistance to DDT, associated with chromosome V, was present in the substrain carrying this chromosome from the Fc parent. All of the substrains were induced five- to seven-fold, by feeding phenobarbital at 1% in the diet for 3 days.Additional substrains synthesized from the substrains carrying chromosomes II and V or III and V from the Fc parent did not possess sufficient propoxur resistance or aldrin epoxidase activity to account for that present in the R parent.The interpretation of these rseults is that neither the carbamate resistance nor the microsomal epoxidase of the Fc strain is due to the factor which oxidizes DDT. Furthermore, the factor responsible for the high microsomal epoxidase activity is not due to a single chromosome such as chromosome II which is the case in other housefly strains with high oxidase activities.     

Pyrethroid insecticide resistance and treated bednets efficacy in malaria control

Most of the studies on insecticide impregnated bednets efficacy in malaria control have been undertaken in areas where mosquitoes are pyrethroid susceptible. The efficacy of pyrethroid-treated bednets was not compromised even when mosquitoes were kdr resistant. Here, we evaluate a case in which mosquitoes have kdr-like pyrethroid resistance coupled with metabolic mechanisms. Metabolic and kdr-resistance mechanisms in Anopheles stephensi were characterised in our previous study and this easily colonised species was used as a model to examine the efficacy of pyrethroid-treated bednets in the laboratory. Bioassays performed on adults of susceptible (Beech) and resistant (DUB-S) strains using WHO 0.75% permethrin-impregnated papers showed a resistance ratio of 9.75. The recovery rate of the mosquitoes of the DUB-S strain was significantly higher than that of the susceptible strain Beech. The overall permethrin metabolism rates by DUB-S, measured by HPLC method, were 1.5-fold more than by Beech strain. Bioassays performed on DUB-S mosquitoes using different pyrethroid-treated bednets showed that only deltamethrin at 25 mg/m² and α-cypermethrin at 40 mg/m² produced adequate mortality rates. Four other pyrethroids, including permethrin, were ineffective. The deterrency test performed on susceptible and resistant An. stephensi showed that there are significant differences between the entry rates of susceptible and resistant mosquitoes into the exposure tube containing permethrin-treated bednet. These data show that when mosquitoes have both kdr-type and metabolic resistance mechanisms, the efficacy of pyrethroid-treated bednets is questionable.     

Synergism of insecticidal action and effects on detoxifying enzymes in vivo of lambda-cyhalothrin and malathion by some nitrogen heterocycles in resistant and susceptible strains of Tribolium castaneum

The interactions of the synthetic pyrethroid, lambda-cyhalothrin and malathion were studied with purines, pyrimidines, caffeine and some other related nitrogenous compounds in resistant and susceptible strains of Triboliurn castaneum (Herbst.) The results were compared with those obtained with a known synergist, piperonyl butoxide (PBO) and precocene I. Adenine, cytosine, guanine, thymine and uracil synergised lambda-cyhalothrin, especially in the susceptible strain, with maximum effect at a 1:1 mass ratio, with the effect decreasing with increasing proportion of the heterocycle. The order of synergism of lambda-cyhalothrin was; precocene I > PBO > the nitrogenous compounds, in both resistant and susceptible strains. On the other hand, caffeine (lethal effect increased about twice), barbital (about twice), isobarbituric acid (less than twice) and bromacil (up to eight times) synergised malathion in malathion-resistant strains and antagonised in the susceptible strains. Total in-vivo esterases, carbox-ylesterases and cytochrome P₄₅₀ of susceptible and resistant strains showed significantly increased activity or content when treated with either insecticide plus a heterocyclic compound. Exceptions were with bromacil and malathion and for the malathion-specific strain, Kano-C with malathion and the N-heterocycles.     

Purification and biochemical characterization of glutathione S-transferases from three strains of Liposcelis bostrychophila Badonnel (Psocoptera: Liposcelididae): Implication of insecticide resistance

Glutathione S-transferases (GSTs) catalyzing the conjugation of reduced glutathione (GSH) to a vast range of xenobiotics including insecticides were investigated in the psocid Liposcelis bostrychophila Badonnel. GSTs from susceptible and two resistant strains (DDVP-R for dichlorvos-resistant strain and PH₃-R for phosphine-resistant strain) of L. bostrychophila were purified by glutathione-agarose affinity chromatography and characterized by their Michaelis-Menten kinetics towards artificial substrates, i.e., 1-chloro-2,4-dinitrobenzene (CDNB), in a photometric microplate assay. The specific activities of GSTs purified from two resistant strains were significantly higher than their susceptible counterpart. For the resistant strains, GSTs both showed a significantly higher affinity to the substrate GSH while a declined affinity to CDNB than those of susceptible strain. The inhibitory potential of ethacrynic acid was very effective with highest I₅₀ value (the concentration required to inhibit 50% of GSTs activity) of 1.21 μM recorded in DDVP-R. Carbosulfan also exhibited excellent inhibitory effects on purified GSTs. The N-terminus of the purified enzyme was sequenced by Edman degradation, and the alignment of first 13 amino acids of the N-terminal sequence with other insect GSTs suggested the purified protein was similar to those of Sigma class GSTs.