Resistance selection and biochemical mechanism of resistance to two Acaricides in Tetranychus cinnabarinus (Boiduval)

A Tetranychus cinnabarinus strain was collected from Chongqing, China. After 42 generations of selection with abamectin and 20 generations of selection with fenpropathrin in the laboratory, this T. cinnabarinus strain developed 8.7- and 28.7-fold resistance, respectively. Resistance to abamectin in AbR (abamectin resistant strain) and to fenpropathrin in FeR (fenpropathrin resistant strain) was partially suppressed by piperonyl butoxide (PBO), diethyl maleate (DEM) and triphenyl phosphate (TPP), inhibitors of mixed function oxidase (MFO), glutathione S-transferases (GST), and hydrolases, respectively, suggesting that these three enzyme families are important in conferring abamectin and fenpropathrin resistance in T. cinnabarinus. The major resistant mechanism to abamectin was the increasing activities of carboxylesterases (CarE), glutathione-S-transferase (GST) and mixed function oxidase (MFO), and the activity in resistant strain developed 2.7-, 3.4- and 1.4-fold contrasted to that in susceptible strain, respectively. The activity of glutathione-S-transferase (GST) in the FeR strain developed 2.8-fold when compared with the susceptible strain, which meant the resistance to fenpropathrin was related with the activity increase of glutathione-S-transferase (GST) in T. cinnabarinus. The result of the kinetic mensuration of carboxylesterases (CarE) showed that the structure of CarE in the AbR has been changed.     

The sodium channel gene in Tetranychus cinnabarinus (Boisduval): identification and expression analysis of a mutation associated with pyrethroid resistance

BACKGROUND: The carmine spider mite (CSM), Tetranychus cinnabarinus, is the most harmful mite pest of various crops and vegetable plants. Pyrethroid insecticide fenpropathrin has been used to control insects and mites worldwide, but CSM has developed resistance to this compound. RESULTS: Three synergists together eliminated about 50% resistance against fenpropathrin in the CSM. A point mutation was identified from the sodium channel gene of fenpropathrin‐resistant CSM (FeR) by comparing cDNA sequences between FeR and susceptible (S) sodium channel genes, which caused a phenylalanine (F) to isoleucine (I) change at amino acid 1538 position in IIIS6 of the sodium channel and has been proven to confer strong resistance to pyrethroid in other species. The mRNA expression of the sodium channel gene in the FeR and abamectin‐resistant strain (AbR), which was included as a control, were both relatively lower than in the S. CONCLUSION: These results demonstrate that a mutation (F1538I) is present in the sodium channel gene in FeR of CSM, likely playing an important role in fenpropathrin resistance in T. cinnabarinus, but that decrease in the abundance of sodium channel did not confer this resistance. The F1538I mutation could be used as a molecular marker for detecting kdr resistance in Arachnida populations. Copyright © 2011 Society of Chemical Industry     

柑橘全爪螨对甲氰菊酯和阿维菌素的抗性选育及交互抗性

通过室内抗性品系选育,研究了柑橘全爪螨对甲氰菊酯和阿维菌素的抗性发展情况,并就其与柑橘园常用11种杀螨剂的交互抗性进行了分析。结果表明:在柑橘全爪螨19代中用甲氰菊酯和阿维菌素分别不连续汰选16次和11次后,柑橘全爪螨对两者的抗性分别为29.92和3.80倍;甲氰菊酯抗性品系(FeR)对哒螨灵、三氯杀螨醇和三唑锡产生了明显的交互抗性,阿维菌素抗性品系(AbR)对甲维盐产生了明显的交互抗性。试验结果可为柑橘全爪螨抗性治理提供参考。     

Genetic analysis of abamectin resistance in Tetranychus cinnabarinus

The carmine spider mite is the most serious crop mite pests in China. Abamectin has been used to control insects and mites worldwide but carmine spider mites, Tetranychus cinnabarinus, had developed resistance to it. Genetic research on insecticide resistance has been fundamental for understanding the resistance development, studying resistance mechanisms, and designing appropriate resistance management strategies to control insect pests. A resistant colony of T. cinnabarinus, RRG42, was established to examine the inheritance of abamectin resistance in T. cinnabarinus. The females of T. cinnabarinus were selected for bioassay using a slide dip method. After 42 generations of selection, the RRG42 strain was 8.7-fold resistant to abamectin compared with the susceptible strain (SS). The logarithm (log) concentration–probit response curve for F₁s from reciprocal crosses, of F₁RS and F₁SR, were inclined to that for SS and the degree of dominance (D) values for F₁s were −0.81 and −0.17. There was a significant difference in values of LC₅₀ and slope of log concentration–probit lines between F₁RS and F₁SR. The observed mortalities of BC1 (F₁RS♀ × RRG42♂) and BC1′ (F₁SR♀ × SS♂) were significantly different from the expected mortalities based on a monogenic resistance in the chi-square tests. The inheritance of abamectin resistance in T. cinnabarinus is incompletely recessive and may be controlled by more than one gene. The maternal or cytoplasmic effect may exist in the inheritance of resistance to abamectin in T. cinnabarinus.     

Genetic analysis of abamectin resistance in Tetranychus cinnabarinus

The carmine spider mite is the most serious crop mite pests in China. Abamectin has been used to control insects and mites worldwide but carmine spider mites, Tetranychus cinnabarinus, had developed resistance to it. Genetic research on insecticide resistance has been fundamental for understanding the resistance development, studying resistance mechanisms, and designing appropriate resistance management strategies to control insect pests. A resistant colony of T. cinnabarinus, RRG42, was established to examine the inheritance of abamectin resistance in T. cinnabarinus. The females of T. cinnabarinus were selected for bioassay using a slide dip method. After 42 generations of selection, the RRG42 strain was 8.7-fold resistant to abamectin compared with the susceptible strain (SS). The logarithm (log) concentration–probit response curve for F₁s from reciprocal crosses, of F₁RS and F₁SR, were inclined to that for SS and the degree of dominance (D) values for F₁s were −0.81 and −0.17. There was a significant difference in values of LC₅₀ and slope of log concentration–probit lines between F₁RS and F₁SR. The observed mortalities of BC1 (F₁RS♀ × RRG42♂) and BC1′ (F₁SR♀ × SS♂) were significantly different from the expected mortalities based on a monogenic resistance in the chi-square tests. The inheritance of abamectin resistance in T. cinnabarinus is incompletely recessive and may be controlled by more than one gene. The maternal or cytoplasmic effect may exist in the inheritance of resistance to abamectin in T. cinnabarinus.     

Hydrolysis of permethrin by pyrethroid esterases from resistant and susceptible strains of Amblyseius fallacis (Acari: Phytoseiidae)

Pyrethroid-hydrolyzing activity in whole body homogenates of three insecticide-resistant and one susceptible strain of the predator mite, Amblyseius fallacis Garman has been examined in vitro. The highest esterase activity was found in the synthetic pyrethroid-resistant GH-1 strain body homogenate. All three pyrethroid-resistant strains had esterases that hydrolyzed trans-permethrin two times faster than cis-permethrin but isomer specificity was not observed in the susceptible strain. The pyrethroid esterases of the GH-1 strain were very sensitive to inhibition by dichlorovos, S,S,S-tributhylphosphorotrithioate, and 3-octylthio-1,1,1-trifluoro-2-propanone. Carbaryl and tetraethylpyrophosphate exhibited moderate inhibition in the GH-1 strain. Eserine sulfate and piperonyl butoxide only inhibited permethrin hydrolysis at higher concentrations. Fifteen esterase bands were resolved from body homogenates by gradient gel electrophoresis in the GH-1 strain, and were identified as carboxylesterases. The major pyrethroid-hydrolyzing activity was located in E5–E12 bands from GH-1 and composite susceptible strain esterases. Six esterase bands exhibiting low pyrethroid-hydroloyzing activity were also obtained from the two spotted spider mite, Tetranychus urticae (Koch).     

土耳其斯坦叶螨对杀螨剂的抗性选育及解毒酶活力变化

为探索土耳其斯坦叶螨的抗药性及其生化机理,在室内对敏感系土耳其斯坦叶螨分别用螺螨酯、甲氰菊酯和阿维菌素逐代处理,选育出抗性种群。结果表明,选育至15代,土耳其斯坦叶螨对螺螨酯、甲氰菊酯和阿维菌素的抗性指数分别达到268.63、37.98和112.68倍。分别测定敏感品系(SS)、抗螺螨酯(RS)、抗甲氰菊酯(RF)、抗阿维菌素(RA)品系的解毒酶活性显示,3种不同抗性品系相对SS品系的羧酸酯酶(CarE)、谷胱甘肽S-转移酶(GSTs)和多功能氧化酶(MFO)的比活力均有不同程度的提高,差异均达到显著水平(P0.05)。其中,RF品系的MFO比活力上升最快,是SS品系的12.7倍;RA品系的MFO比活力次之,是SS品系的5.76倍;RS品系的3种解毒酶比活力均增长较慢,其中CarE比活力上升最慢,是SS品系的1.31倍。由此表明,CarE、GSTs、MFO的活性增大可促进土耳其斯坦叶螨对3种杀虫剂的抗性形成;螺螨酯的抗性增强可能与CarE关系甚微;MFO活性的增加可能与甲氰菊酯抗性升高密切相关;GSTs、MFO的活性升高可能是土耳其斯坦叶螨对阿维菌素产生抗性的主要原因。     

Cloning of a sodium channel gene and identification of mutations putatively associated with fenpropathrin resistance in Tetranychus urticae

Tetranychus urticae Koch is the most serious mite pest to various orchard trees and garden plants. Biochemical and molecular analyses were conducted to elucidate resistance mechanisms in a fenpropathrin-resistant mite strain (FenR). No significant differences were found in the activities of carboxylesterase and glutathione-S-transferase between the susceptible (UD and PyriF) and FenR strains. Cytochrome P450 activity was highest in PyriF, followed by FenR and UD. Analysis of detoxification enzyme assays, therefore, suggested that metabolic detoxification plays little role, if any, in fenpropathrin resistance. However, the FenR strain showed approximately 104- and 33.3-fold slower knockdown responses than UD and PyriF strains, respectively, suggestive of sodium channel insensitivity as a major resistance mechanism. We cloned cDNA fragments of the para-homologous sodium channel α-subunit gene (Tuvssc) and determined its full-length nucleotide sequences. The complete open reading frame of Tuvssc was 6627 nucleotides, encoding 2209 amino acids. The amino acid sequences of Tuvssc were 47.5% and 51.2% identical to the fruit fly and varroa mite, respectively. Amino acid sequence comparison between the three strains revealed two mutations (L1022V and A1376D) and one deletion (HisDel^1278-1280) found only in FenR mites, among which the L1022V mutation was proposed to play a major role in knockdown resistance to fenpropathrin.     

Biochemical mechanisms conferring cross-resistance between tebufenozide and abamectin in Plutella xylostella

Experiments have been carried out to confirm the cross-resistance between abamectin and tebufenozide in Plutella xylostella and demonstrate its mechanism. The results showed that the resistant strain of P. xylostella selected by tebufenozide (RF 99.38) really showed high cross-resistance to abamectin (RF 29.25). When this strain was subjected to resistance decaying treatment, breeding without contacting any insecticides, and abamectin resistance selection for 20 generations, the former resulted in decrease of its resistance to both tebufenozide and abamectin to about one third of the original (RF 35.03 and 11.67, respectively), and the later enhanced its resistance to abamectin dramatically (RF 303.77), but not to tebufenozide(RF 50.04). PBO showed high synergism to abamectin (SR 2.11-12.23), and the synergism ratio positively related to the resistance level among different strains. Enzyme analysis also proved that the activity of cytochrome P450 monooxygenase (MFO) was notable enhanced in the strains resistant to both tebufenozide and abamectin (1.71- to 3.01-fold). Based on discussion, it was concluded that tebufenozide selection could resulted in significant cross-resistance of P. xylostella to abamectin. The major mechanism for the cross-resistance should be the enhancement of MFO activity. For resistance management, tebufenozide and abamectin would not recommend for rotational use.     

Resistance risk assessment: realized heritability of resistance to methrin,abamectin, pyridaben and their mixtures in the spider mite,Tetranychus cinnabarinus

The heritability of resistance has an important bearing on the management of pest resistance, especially for evaluating the sustainability of a chemical on a particular pest population. The susceptibility of pests to insecticides may change depending on the selection pressure of these compounds on populations. Tetranychus cinnabarinus, a very important mite pest of many crops in China, was continuously selected with methrin, abamectin, pyridaben and mixtures of pyridaben and abamectin (pyidaben:abamectin?=?7.4:0.1?m/m), and methrin and abamectin (methrin:abamectin?=?8.9:0.1?m/m). After 16 generations, the resistance increased to 25.8-, 3.7-, 1.3-, 4.0- and 2.5-fold to methrin, abamectin, pyridaben, pyridaben?+?abamectin and methrin?+?abamectin, respectively. The more generations selected, the higher was the resistance level, except in the case of the strain selected with pyridaben. The realized heritabilities of resistance to methrin, abamectin, pyridabe, pyridaben?+?abamectin and methrin?+?abamectin were: 0.20, 0.15, 0.03, 0.18 and 0.08, respectively. Higher values of heritability occurred during the second eight generations selected than through the first eight generations except in the case of the strain selected with the mixture pyridaben?+?abamectin.     

Resistance mechanisms and associated mutations in acetylcholinesterase genes in Sitobion avenae (Fabricius)

Wheat aphid, Sitobion avenae (fabricius), is one of the most important wheat pests and has been reported to be resistant to commonly used insecticides in China. To determine the resistance mechanism, the resistant and susceptible strains were developed in laboratory and comparably studied. A bioassay revealed that the resistant strain showed high resistance to pirimicarb (RR: 161.8), moderate reistance to omethoate (32.5) and monocrotophos (33.5), and low resistance to deltamethrin (6.3) and thiodicarb (5.5). A biochemistry analysis showed that both strains had similar glutathione-S-transferase (GST) activity, but the resistant strain had 3.8-fold higher esterase activity, and its AChE was insensitive to this treatment. The I₅₀ increased by 25.8-, 10.7-, and 10.4-folds for pirimicarb, omethoate, and monocrotophos, respectively, demonstrating that GST had not been involved in the resistance of S. avenae. The enhanced esterase contributed to low level resistance to all the insecticides tested, whereas higher resistance to pirimicarb, omethoate, and monocrotophos mainly depended on AChE insensitivity. However, the AChE of the resistant strain was still sensitive to thiodicarb (1.7-fold). Thus, thiodicarb could be used as substitute for control of the resistant S. avenae in this case. Furthermore, the two different AChE genes cloned from different resistant and susceptible individuals were also compared. Two mutations, L436(336)S in Sa.Ace1 and W516(435)R in Sa.Ace2, were found consistently associated with the insensitivity of AChE. They were thought to be the possible resistance mutations, but further work is needed to confirm this hypothesis.     

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.     

Purification and partial characterization of a glutathione S-transferase from the two-spotted spider mite, Tetranychus urticae

Glutathione S-transferases (GSTs) are known to catalyze conjugations by facilitating the nucleophilic attack of the sulfhydryl group of endogenous reduced glutathione on electrophilic centers of a vast range of xenobiotic compounds, including insecticides and acaricides. Elevated levels of GSTs in the two-spotted spider mite, Tetranychus urticae Koch, have recently been associated with resistance to acaricides such as abamectin [Pestic. Biochem. Physiol. 72 (2002) 111]. GSTs from acaricide susceptible and resistant strains of T. urticae were purified by glutathione-agarose affinity chromatography and characterized by their Michaelis-Menten kinetics towards artificial substrates, i.e., 1-chloro-2,4-dinitrobenzene and monochlorobimane. The inhibitory potential of azocyclotin, dicumarol, and plumbagin was low (IC₅₀ values > 100 μM), whereas ethacrynic acid was much more effective, exhibiting an IC₅₀ value of 4.5 μM. GST activity is highest in 2-4-day-old female adults and dropped considerably with progressing age. Furthermore, molecular characteristics were determined for the first time of a GST from T. urticae, such as molecular weight (SDS-PAGE) and N-terminal amino acid sequencing (Edman degradation). Glutathione-agarose affinity purified GST from T. urticae strain WI has a molecular weight of 22.1 kDa. N-terminal amino acid sequencing revealed a homogeneity of ≈50% to insect GSTs closely related to insect class I GSTs (similar to mammalian Delta class GSTs).     

Biochemical studies on sheep body louse Bovicola ovis (Schrank) (Phthiraptera: Trichodectidae): comparison of pyrethroid and organophosphate resistant and susceptible strains

Strains of sheep louse Bovicola ovis (Schrank) with various levels of resistance to pyrethroid and one strain with high degree of resistance to organophosphate (OP) insecticides were used to investigate the biochemical mechanisms of insecticide resistance, i.e., enhanced levels of general esterases, specific acetylcholinesterases (AChE), glutathione S-transferase (GST), and mixed function oxidases. Native gel electrophoresis combined with quantitative enzyme assays showed analogous expression profiles of several esterase isozymes in all the strains tested. The determination of the sensitivity of each esterase isozyme to five inhibitors (acetylthiocholine iodide, butyrylthiocholine iodide, paraoxon eserine sulfate, and pCMB) led to the identification of nine esterases in the B. ovis strain. Gel electrophoresis results are supported by enzyme assay studies where, except for the OP resistant strain, no differences in esterase activities were detected in all the pyrethroid resistant and susceptible strains assayed. Statistical analyses demonstrated that some strains have elevated GST activities compared to the susceptible reference strain.     

Pyrethroid resistance and esterase activity in three strains of the cotton bollworm, Helicoverpa armigera (Hübner)

Microplate assay technique for estimation of esterase activity in a single insect was used in combination with dose mortality bioassays to detect pyrethroid resistance in three strains of Helicoverpa armigera and to study the frequency of pyrethroid resistant individuals within the population of the same strain at two larval stages, third and fifth instar. The third and fifth instar larvae of the field strains i.e., Nagpur strain and Delhi strain that displayed high degree of resistance towards deltamethrin, had higher esterase activity compared to a susceptible laboratory strain. The frequency distribution of individuals with elevated esterase activity above 1.00 absorbance unit was correlated with the resistance level of the strains. The frequency of resistant individuals in the third instar larvae of Nagpur strain and Delhi strain were 29% and 23%, respectively compared to 4% in the susceptible strain. The resistant individuals in the resistant strains have markedly increased in the fifth instar larvae with a frequency distribution of 63% and 90% in Delhi strain and Nagpur strain, respectively, while only 14% of individuals was found to have elevated esterase activity in the susceptible strain. The results demonstrated the role of esterase in pyrethroid resistance in H. armigera. Microplate assay proved to be a rapid and reliable biochemical technique for monitoring of pyrethroid resistance in H. armigera.     

Activity of abamectin against larval stages of Spodoptera littoralis boisduval and Heliothis armigera hübner (Lepidoptera: Noctuidae) and possible mechanisms determining differential toxicity

Marked changes in the relative toxicity of topically-applied abamectin were found between larval instars of Spodoptera littoralis, toxicity decreasing up to the fifth instar but increasing over 500-fold (at LD₅₀ level) in the sixth instar. By contrast, the toxicity of abamectin remained constant from fifth to sixth instar Heliothis armigera and there was an increase in the toxicity of two chemically unrelated insecticides, malathion (4-fold) and lambda-cyhalothrin (2.5-fold), from fifth to sixth instar S. littoralis. Prior topical application or injection of the microsomal oxidase inhibitor, piperonyl butoxide (PB) increased the toxicity of abamectin (6–8 and 16-fold respectively) against fifth instar S. littoralis, while topically-applied PB increased the proportion of radioactivity present as abamectin in the ventral nerve cord of this instar following topical application with [³H]abamectin. Topically-applied PB also enhanced the toxicity of abamectin against third (4-fold) and fourth instar (5-fold) S. littoralis but had no significant effect on sixth instar S. littoralis, fifth instar H. armigera, or on the toxicity of malathion and lambda-cyhalothrin against fifth instar S. littoralis. Topical application of the esterase inhibitor, S,S,S-tributyl phosphorothioate (DEF) significantly increased the toxicity of abamectin at the LD₅₀ level (3-fold) against fifth instar S. littoralis. The toxicity of injected abamectin against fifth instar S. littoralis was greater (20-fold) than with topical application but injected abamectin was less toxic (2-fold) against sixth instar S. littoralis and had no significant effect on fifth instar H. armigera. It is suggested that differential toxicity of abamectin is due in part to greater metabolism and reduced penetration in fifth instar S. littoralis than in sixth instar S. littoralis or fifth instar H. armigera.     

两种外源二型硫酯酶TEII对链霉菌NRRL8165产生阿维菌素的影响

利用接合转移的方法将不同来源的二型硫酯酶(TEII,type II thioesterase)导入链霉菌S.avermitilis NRRL8165中构建了两种突变株,同时研究比较了两种突变株与野生型在等量发酵时阿维菌素产量的变化。结果表明:导入Tetrocarcin A的TEII突变株阿维菌素的产量提高了96.52%;导入氯丝菌素(Chlorothricin)的TEII突变株阿维菌素的产量提高了38.06%。进一步验证了TEII对聚酮类次级代谢产物的生物合成具有编辑和纠错功能。     

二点叶螨对氧乐果、甲氰菊酯、四螨嗪及螨嗪菊酯混剂的抗药性

以兰州吐鲁沟公园金花忍冬植物上采集的二点叶螨为敏感种群,在室内盆栽菜豆苗上饲养繁殖后分别用氧乐果、甲氰菊酯、四螨嗪及螨嗪菊酯(甲氰菊酯 四螨嗪)混剂喷雾处理20代,获得二点叶螨抗氧乐果种群(抗性指数RF=35.84倍)、抗甲氰菊酯种群(RF=479.79倍)、抗四螨嗪种群(RF=67.26倍)以及抗混剂螨嗪菊酯种群(RF=26.75倍)。用生化法测定离体酶活性的结果表明,上述四个抗性种群的形成与体内羧酸酯酶、磷酸酯酶、谷胱甘肽转移酶的活力增加及乙酰胆碱酯酶的活性降低有关。4个抗性种群对常用15种供试药剂交互抗性测定结果表明,氧乐果、甲氰菊酯与联苯菊酯、三氟氯氰菊酯、水胺硫磷、久效磷、氰久合剂有交互抗性,甲氰菊酯还与螨蚧克有交互抗性;四螨嗪与三氯杀螨醇(RF=14.15倍)、齐螨素(RF=10.26倍)有交互抗性;螨嗪菊酯与双甲脒、氧乐菊酯有负交互抗性,RF值分别为0.85、0.71倍。     

Expression of esterase gene in yeast for organophosphates biodegradation

Organophosphates are esters of phosphoric acid and can be hydrolyzed and detoxified by carboxylesterase and phosphotriesterase. In this work esterase enzyme (Est5S) was expressed in yeast to demonstrate the organophosphorus hydrolytic activity from a metagenomic library of cow rumen bacteria. The esterase gene (est5S) is 1098 bp in length, encoding a protein of 366 amino acid residues with a molecular weight of 40 kDa. Est5S enzyme was successfully produced by Pichia pastoris at a high expression level of approximately 4.0 g L⁻¹. With p-nitrophenol butyrate as the substrate, the optimal temperature and pH for enzyme activity were determined to be 40 °C and pH 7.0, respectively. The esterase enzyme was tested for degradation of chlorpyrifos (CP). TLC results obtained inferred that CP could be degraded by esterase enzyme (Est5S) and HPLC results revealed that CP could be efficiently degraded up to 100 ppm. Cadusafos (CS), coumaphos (CM), diazinon (DZ) dyfonate (DF), ethoprophos (EP), fenamiphos (FM), methylparathion (MPT), and parathion (PT) were also degraded up to 68, 60, 80, 40, 45, 60, 95, and 100%, respectively, when used as a substrate with Est5S protein. The results highlight the potential use of this enzyme in the cleanup of contaminated insecticides.