Insect glutathione S-transferase: Separation of transferases from fat bodies of American cockroaches active on organophosphorus triesters

Several glutathione S-transferases which catalyze the conjugation of reduced glutathione with organophosphorus triesters were separated from fat bodies of adult female American cockroaches, Periplaneta americana (L.). Two transferases (I, V) were active on diazinon and three transferases (II, III, IV) were active on methyl parathion. The transferase (I) active on the pyrimidinyl moiety of diazinon was distinguishable from the other transferases on the O-methyl portion of methyl parathion, as shown by chromatographic properties, and additionally it was almost inactive or less active on 3,4-dichloronitrobenzene, methyl iodide, p-nitrobenzyl chloride, trans-cinnamaldehyde, and 1,2-epoxy-3-(p-nitrophenoxy)propane. Transferase II had high activities with “aryl” and “aralkyl” compounds, transferase III with “epoxide” and “alkene,” and transferase IV with “alkyl,” “aryl,” and “aralkyl” compounds. This indicated that the transferases had overlapping substrate specificities. The molecular weight was 35,000–37,000 for both of the enzymes active on methyl parathion and diazinon. The pH optima with methyl parathion and diazinon were about 8.5 and 6.5, respectively. At a glutathione concentration of 5 mM, Michaelis constants were 0.28 and 0.13 mM for methyl parathion and diazinon, respectively.     

Genetic studies on glutathione-dependent reactions in resistant strains of the house fly,Musca domestica L

Genetic studies of glutathione-dependent reactions were conducted with a diazinon-resistant house fly strain in which resistance is controlled primarily by genes on chromsome II. The resistant strain was crossed with a susceptible strain which had mutant markers on chromosomes II, III, and V, and the F₁ was backcrossed to the susceptible strain. Glutathione transferase activities of the resultant eight phenotypes were measured using 3,4-dichloronitrobenzene, methyl iodide, and γ-benzene hexachloride as substrates. High levels of all these activities are controlled by gene(s) on chromosome II. Further analysis was made by introducing diazinon resistance into a susceptible strain via genetic crossing-over. Intermediate activity levels for 3,4-dichloronitrobenzene and methyl iodide conjugations were introduced along with intermediate levels of resistance. Assays of individual flies of the synthesized strain revealed they were heterogeneous for glutathione-dependent activities, consisting of individuals with low, intermediate, and high transferase activity. Based on these results, high levels of the glutathione-dependent enzymes are not a major biochemical mechanism responsible for diazinon resistance. It was also demonstrated that glutathione S-aryltransferase and S-alkyltransferase in the house fly, as measured with 3,4-dichloronitrobenzene and methyl iodide, are inseparable genetically and may, therefore, be the same enzyme.     

The effect of phenobarbital induction on glutathione conjugation of diazinon in susceptible and resistant house flies

The relationship between glutathione S-transferase activity toward 3,4-dichloronitrobenzene and O-alkyl or O-aryl conjugation of diazinon was investigated in eight strains of house flies. No significant difference was found in the amount of O-aryl conjugation. In contrast, house flies which had higher glutathione S-transferase activity toward 3,4-dichloronitrobenzene also had higher O-alkyl conjugating activity toward diazinon. The glutathione S-transferase(s) in phenobarbital-pretreated flies degraded diazinon faster than those in the nontreated ones. The present results showed that the formation of the O-alkyl conjugate was enhanced by phenobarbital pretreatment, while the formation of the O-aryl conjugate was not affected by induction. Based on these findings, it would appear that one of the multiple forms of glutathione S-transferase is specifically induced and responsible for the increase in O-alkyl conjugation.     

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.     

Insect metabolism of a phenyl epoxygeranyl ether juvenoid and related compounds

1-(4′-Ethylphenoxy)-3,7-dimethyl-6,7-epoxy-trans-2-octene (the ethyl-epoxide), a potent insect morphogenetic agent, is converted to 6,7-diol and other derivatives in living cockroaches and mealworms. Enzyme preparations of these organisms, and of houseflies and several other insect species, also carry out these hydration and/or oxidation reactions. In addition, housefly microsomes epoxidize the ethyl-epoxide to a diepoxide. The diepoxide and diol are then converted by microsomes to at least six cyclic diols, probably via an epoxy-diol intermediate, the major ones being the cis- and trans-tetrahydrofurandiol derivatives. The metabolites formed by these reactions have little or no morphogenetic activity in Tenebrio assays. Attempts to find potent inhibitors for housefly epoxide hydratases were unsuccessful. The corresponding ethylphenyl geranyl ether is epoxidized by housefly microsomes, forming the more morphogenetically active ethyl-epoxide, but the major reaction is oxidation on the geranyl moiety to an unidentified olefinic carboxylic acid. The chemical modifications needed for improved stability and morphogenetic activity in this juvenoid series depend on the insect species and strain and the relative activities of their enzymes involved in various inactivation pathways.     

Synergism of diazinon toxicity and inhibition of diazinon metabolism in the house fly by tridiphane: Inhibition of glutathione S-transferase activity

Diazinon toxicity to a susceptible strain of house fly (Musca domestica L.) was synergized by tridiphane [2-(3,5-dichlorophenyl)-2-(2,2,2-trichloroethyl)oxirane], a herbicide synergist. Both diazinon and tridiphane were partially metabolized in the house fly by glutathione (GSH) conjugation. Synergism appeared to be due to inhibition of diazinon metabolism/detoxification. Crude glutathione S-transferase (GST) preparations from the house fly catalyzed GSH conjugation of diazinon, tridiphane, 3,4-dichloronitrobenzene (DCNB), and chloro-2,4-dinitrobenzene (CDNB). Tridiphane and the GSH conjugate of tridiphane appeared to inhibit diazinon GSH conjugation, but diazinon did not inhibit tridiphane GSH conjugation. The enzymatic rate of tridiphane GSH conjugation was 22 times the rate of diazinon GSH conjugation; therefore, attempts to assay tridiphane as an inhibitor of diazinon GSH conjugation were inconclusive because of the high concentration of tridiphane GSH conjugate produced during the assay. CDNB underwent enzymatic GSH conjugation at a rate 240 times faster than that of tridiphane and 5000 times faster than that of diazinon. GSH conjugation of CDNB was not inhibited by tridiphane, but was inhibited by the GSH conjugate of tridiphane. In vivo, the GSH conjugate of tridiphane was produced in sufficient concentration to cause the observed inhibition of diazinon metabolism and synergism of diazinon toxicity. However, the possibility that parent tridiphane caused or contributed to the inhibition of diazinon metabolism and synergism of diazinon toxicity could not be excluded. Inhibition of diazinon metabolism did not appear to be due to depletion of either GSH or GST.     

Insecticide metabolism by multiple glutathione S-transferases in two strains of the house fly,Musca domestica (L)

Glutathione S-transferases from two strains of house fly have been prepared in a high degree of homogeneity by a procedure involving affinity chromatography and isoelectrofocusing. They fall into two groups in each strain. One group, of isoelectric point greater than pH 6.5, catalyzes the glutathione-dependent degradation of lindane, diazinon and methyl parathion. The other group, of low isoelectric point, has conjugating activity with the model substrate CDNB, but very little activity with the insecticide substrates. In the Cornell R strain the three isoenzyme forms in the high pI group appear to be almost identical in their substrate specificities. In the A strain, it is apparent that the enzyme forms falling into this group vary markedly in substrate specificity. The dehydrochlorination of DDT paralleled very closely the conjugation of the other insecticides catalyzed by the three high pI enzymes in the Cornell R strain. In the A strain, DDT dehydrochlorinase was most strongly associated with a glutathione S-transferase isoelectric at pH 7.1. It is tentatively concluded that multiple genes are involved in the production of the glutathione S-transferases involved in pesticide metabolism in the house fly and that DDT dehydrochlorinase may be derived from some, but not all, of these same genes.     

Beta-cypermethrin resistance associated with high carboxylesterase activities in a strain of house fly, Musca domestica (Diptera: Muscidae)

A housefly strain, originally collected in 1998 from a dump in Beijing, was selected with beta-cypermethrin to generate a resistant strain (CRR) in order to characterize the resistance and identify the possible mechanisms involved in the pyrethroid resistance. The resistance was increased from 2.56- to 4419.07-fold in the CRR strain after 25 consecutive generations of selection compared to a laboratory susceptible strain (CSS). The CRR strain also developed different levels of cross-resistance to various insecticides within and outside the pyrethroid group such as abamectin. Synergists, piperonyl butoxide (PBO) and S,S,S-tributyl phosphorotrithioate (DEF), increased beta-cypermethrin toxicity 21.88- and 364.29-fold in the CRR strain as compared to 15.33- and 2.35-fold in the CSS strain, respectively. Results of biochemical assays revealed that carboxylesterase activities and maximal velocities to five naphthyl-substituted substrates in the CRR strain were significantly higher than that in the CSS strain, however, there was no significant difference in glutathione S-transferase activity and the level of total cytochrome P450 between the CRR and CSS strains. Therefore, our studies suggested that carboxylesterase play an important role in beta-cypermethrin resistance in the CRR strain.     

Parasitization by Cotesia plutellae enhances detoxifying enzyme activity in Plutella xylostella

Insecticidal tests using diazinon showed that the mortality of Plutella xylostella larvae parasitized by Cotesia plutellae was reduced by 4.6-fold compared to that of the nonparasitized hosts. The use of chemicals with synergistic effect to insecticides in toxicity assay helps to elucidate the kind of enzyme involved in lowering insect mortality. Synergism of diethyl maleate and piperonyl butoxide with diazinon resulted to 2.4- and 1.9-fold increase, respectively, in susceptibility of parasitized larvae compared to those of nonparasitized larvae. These results indicated the possibility that the decrease in susceptibility to diazinon was due to the elevated activities of glutathione-S-transferase (GST) and cytochrome P450 monooxygenase (CYP), respectively. The GST activities in parasitized larvae were significantly higher than those of nonparasitized ones starting from three days post-parasitization until emergence of parasitoid larva. High GST activities during late parasitism could be attributed to both enzyme activities toward diazinon of parasitized P. xylostella larva itself and C. plutellae larva inside larval host. High GST activity one day after parasitization, although statistical significance was not detected, was caused by polydnavirus (PDV) and the venom of C. plutellae not by parasitoid larvae. Artificial injection of PDV plus venom demonstrated that the resulting increase in GST activity is similar to the increase brought by parasitization. High CYP activity after 3 days post-parasitization in parasitized larva was attributed mainly to the activity of parasitoid larva. Carboxylesterase activity in the parasitized host remained at a high level, while that in the nonparasitized host decreased slightly as pupation approaches. On the other hand, acetylcholinesterase activity also remained constant after parasitization until larval emergence, while that of the nonparasitized hosts decreased gradually as the host larvae approach pupation. These results were supported by inhibition tests using diazoxon in vitro.     

Biochemical genetics of oxidative resistance to diazinon in the house fly

The genetics and biochemistry of oxidative resistance to diazinon were investigated in a diazinon-resistant strain of the house fly, Musca domestica L. The resistant strain was crossed with a multimarker susceptible strain and substrains containing portions of the resistant strain genome were prepared. Resistance, microsomal oxidase, and cytochrome P-450 spectral characteristics were then compared in the different strains. The major gene for resistance to diazinon is semidominant and is located on chromosome II, 13 crossing over units from the recessive mutant stubby wing. Additional resistance genes occur on chromosome II and on other chromosomes as well. Resistance to diazinon was introduced into a susceptible mutant-marked strain via genetic crossing over. Increases in parathion oxidase, total and P-450-specific N- and O-demethylase activity, and resistant strain type I binding spectrum were introduced along with resistance, indicating genes controlling these parameters and resistance are either identical or closely linked. No increase in activity of cytochrome P-450 itself was introduced into the mutant strain. Additional genes controlling the amount of cytochrome P-450 and several spectral changes characteristic of the resistant strains are apparently controlled by genes located at different loci on chromosome II. Resistance factors on other chromosomes are also present, but were not characterized.     

Factors affecting the sequential acquisition by Danish houseflies (musca domestica L.) of resistance to organophosphorus insecticides

The prolonged use of dimethoate, introduced into Denmark to control houseflies (Musca domestica L.) that had become resistant to parathion and diazinon, resulted ultimately in dimethoate resistance. Selection with dimethoate led to the disappearance of the hydrolytic phosphatase, a major mechanism of resistance to parathion and diazinon, and its replacement by the acetylcholinesterase AChER with somewhat decreased sensitivity to inhibition by organophosphorus (OP) insecticides. The hydrolytic phosphatase probably disappeared because low substrate turn-over made it ineffective against dimethoxon (O, O-dimethyl S-methylcarbamoylmethyl phosphorothioate, also known as omethoate). which accumulates at higher concentrations than paraoxon (diethyl4-nitrophenyl phosphate) in the haemolymph. Dimethoate selected AChER preferentially because it improved the chances of houseflies surviving against the relatively poor AChE inhibitor dimethoxon, whereas its relatively small insensitivity to OP insecticides, unimportant against good inhibitors such as paraoxon, prevented its selection by parathion.     

Host plant induction of glutathione S-transferase in the fall armyworm

The influence of various host plants on glutathione S-transferase activity was studied in the fall armyworm, Spodoptera frugiperda (J. E. Smith). Fall armyworm larvae were maintained on a semidefined artificial diet until the end of the fifth instar. The newly molted sixth instar larvae were then fed fresh leaves of various host plants for 2 days prior to glutathione S-transferase assays using 3,4-dichloronitrobenzene as substrate. The order of the midgut glutathione S-transferase activity of larvae after the worms fed on these plants was: mustard > turnip > cowpeas > peanuts > cotton > corn > cucumber > potato > Bermudagrass > millet > sorghum > soybeans. The difference in the transferase activity between soybean- and mustard-fed larvae was 10-fold. Kinetic study revealed a quantitative, but no qualitative difference in the glutathione S-transferase between soybean- and cowpea-fed larvae. Monoterpenes, such as α-pinene, β-pinene, menthol, and peppermint oil, had no effect on the enzyme. Cowpea-fed larvae were more tolerant of the insecticides diazinon, methamidophos, and methyl parathion than soybean-fed larvae were. These new observations help explain what has been happening in the field and might be of use in the development of pest management programs.     

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.     

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.     

Deletion of Cyp6d4 does not alter toxicity of insecticides to Drosophila melanogaster

Cytochrome P450-dependent monooxygenases are important in the activation and detoxification of numerous insecticides. In this study, a Drosophila melanogaster Cyp6d4 null mutant was used to determine the role of this P450 in insecticide metabolism. This null mutant was generated by imprecise excision of a mobile P element located upstream to the P450 gene Cyp6d4. Comparative analysis between the non-functional mutant and relevant control strains shows that Cyp6d4 does not appear to be involved in the metabolism of chlorfenapyr, cypermethrin, diazinon, imidacloprid, malathion, oxamyl, parathion, or pyrethrum extract, even though these insecticides are known to be activated or detoxified by P450-monooxygenases. No obvious abnormalities in development were seen in the Cyp6d4 null mutant, indicating that Cyp6d4 is not critical for the metabolism of vital endogenous substrates.     

Partial purification and properties of S-cysteinyl-hydroxychlorpropham transferase from oat (Avena sativa L.)

S-Cysteinyl and glutathione conjugates of isopropyl-3′-chloro-4′-hydroxycarbanilate (4-hydroxychlorpropham) were synthesized directly in the presence of soluble enzyme systems isolated from etiolated shoots of oat seedlings. The enzyme systems responsible for these reactions were partially purified and charaterized. Enzyme A appeared to be a multicomponent system, equally reactive with either cysteine or glutathione. Enzyme B was twice as active as enzyme A in the formation of S-cysteinyl-hydroxychlorpropham. Affinity chromatography of enzyme A produced an enzyme fraction with properties similar to those of enzyme B. Both enzymes (A and B) were significantly inhibited by increased cysteine concentrations. The reaction of glutathione with enzyme B was limited. However, when low concentrations of a nonreacting effector, cysteine ethyl ether, were added, glutathione conjugation increased significantly. At higher concentrations, cysteine ethyl ester formed a conjugate with 4-hydroxychlorpropham. Isopropyl-5′-chloro-2′-hydroxycarbanilate (2-hydroxy-5-chlorpropham) did not conjugate with either cysteine or glutathione but did react with cysteine ethyl ester. Isopropyl-3′-chlorocarbanilate (chlorpropham) was not a substrate for thioether conjugation. These data suggest that para- and/or ortho-hydroxylated carbanilates and cysteine-related substrates may form thioether conjugates when incubated under appropriate conditions with these complex enzyme systems.     

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.     

Effects of diazinon at different doses on rat liver and pancreas tissues

Diazinon is one of the most widely used organophosphates in agriculture. Toxic effects of diazinon are due to the inhibition of acetylcholinesterase, an enzyme needed for proper nervous system function. This study was designed to investigate the effects of diazinon at different doses on pancreas and liver tissues and in which dose level diazinon shows its effects. Sixty male Wistar albino rats were included in this study. Animals were initially divided into control and diazinon given groups. There were 10 animals in the control group and 50 animals in diazinon administered group. The latter was divided into five equal subgroups: 25, 50, 100, 200 and 300 mg/kg of diazinon administered groups. Control group was given only saline. All animals in 300 mg/kg diazinon group died. After 24 h, rats were sacrificed under ether anesthesia. Tissue and blood samples were taken for biochemical and histopathological analysis. Sample tissues were examined under light microscope. In biochemical analysis, AST, ALT, LDH, amylase and lipase enzyme activities were measured. One-way ANOVA test was used to compare the groups. In 200 mg/kg diazinon given group, it has been observed some histopathological changes in pancreas and liver tissues. Cholinesterase activities were significantly decreased and alkaline phosphatase levels were increased in all diazinon given groups, when compared with the controls. There was statistically significant difference between the control and diazinon given groups by means of serum amylase, lipase, ALT and AST activities (p < 0.05). LDH activities were significantly increased in 100 and 200 mg diazinon given groups, when compared with the controls (p < 0.05). Histopathological changes were observed only in 200 mg diazinon given group. This evidence suggest that diazinon effect is dose dependent and this is possibly 10-15% of the LD₅₀ dose (200 mg/kg), which cause acute pancreatitis and histopathological changes in liver.     

Effect of dietary benzoxadiazole on larval development, cuticle enzyme and antioxidant defense system in housefly (Musca domestica L.)

The toxicity and influence on chronic development regulation of dietary benzoxadiazole as well as the subsequent action on cuticle enzyme and antioxidant defense system in feed-thru housefly larvae are investigated. Dietary benzoxadiazole shows limited larvicidal activity and weak interference on larval pupation, but strong blockage against the succedent eclosion process. It does not change the content ratio of protein/chitin in the larval cuticle, but strongly regulates the constituents of cuticle proteins. Moreover, chitinase activities in the integument of third-instar larvae, in vivo, are enhanced and gradually decreased whereas phenoloxidase activities are inhibited and the inhibitory rates are gradually increased. Glutathione S-transferase activities are strongly improved whilst peroxidase activities decrease from about 42.25% to 17.36%, catalase activities decrease from about 80.31% to 27.98% and superoxide dismutase activities are almost unchanged during the different treatment procedures. Peroxidase SDS-PAGE analysis shows that band photodensities of 200.0 and 10.3 kDa proteins in feed-thru larvae are significantly weaker than the corresponding control band. Results suggest that dietary benzoxadiazole might exert strong regulation on larvae cuticle metabolism, interfere with cuticle enzymatic browning and protein sclerotization and weaken the self-protection of larvae against endogenetic oxidative damages.     

Multiple Resistance in the Larger House Fly Musca domestica in Germany

Populations of the housefly Musca domestica isolated from farms in different German districts with strong resistance problems were compared to laboratory strains with varying resistance spectra. Resistance against pyrethroids, organophosphates and carbamates was tested using impregnated filter papers, and by topical application using a susceptible housefly strain (origin WHO) for comparison. The multi-resistant fly strains tested had a strong resistance against these insecticide groups, ranging from 37- to >10000-fold for organophosphates and 150- to >6600-fold for pyrethroids. The constituent enantiomer pairs of the α-cyano-pyrethroid cyfluthrin were tested, as was beta-cyfluthrin. With respect to multi-resistant fly strains, the isomers II and IV had the best activity, with LD₅₀ values of 0·012 and 0·014 μg per fly, respectively. In addition, different groups of insect growth regulators (juvenile hormone analogues, chitin synthesis inhibitors and one triazine derivative) were tested in a special larvicidal test. The chitin synthesis inhibitors were quite effective against multi-resistant M. domestica strains except for one strain with strong resistance against chitin synthesis inhibitors, developed after extensive treatments with benzoylphenylureas for several years. The fly strains tested were not resistant against cyromazine. Additionally, the insecticides were combined with the synergists piperonyl butoxide, tributylphosphorotrithioate (DEF) and Cibacron blue and tested against the fly strain with the strongest resistance spectrum (‘Grimm’) in comparison to the susceptible strain (‘WHO-N’). Piperonyl butoxide had the greatest effect on the efficacy of cyfluthrin followed by Cibacron blue and DEF. In a parallel investigation with susceptible and resistant house fly strains, different enzyme activities related with resistance mechanisms were tested, e.g. glutathione S-transferase (3·5-fold) and mixed-function oxidase (2·3-fold). Implications of these results for management of insecticide resistance in M. domestica are discussed.