Comparison of catalytic properties and inhibition kinetics of two acetylcholinesterases from a lepidopteran insect

Acetylcholinesterase (AChE) is the primary target of organophosphate (OP) and carbamate (CB) insecticides. Many insect species have been shown to have two different AChE genes. The amino acid identity between the two lepidopteran AChEs is lower than 40%, and potential differences in enzymatic function have not been characterized. In this study, the cDNAs encoding two AChEs (Boma-AChE1 and Boma-AChE2) from Bombyx mandarina were sequenced, and the corresponding proteins were heterologously expressed to compare their enzymatic properties and interactions with insecticides in vitro. Both of these enzymes had high specific activities for acetylthiocholine iodide. Studies on substrate and inhibitor specificities confirmed that both enzymes belong to AChE. Insecticide inhibition assays indicated that Boma-AChE1 was more sensitive than Boma-AChE2 to eight of the nine insecticides tested. However, Boma-AChE2 was more sensitive than Boma-AChE1 to one of the OP insecticides, heptenophos. The results suggested that two AChEs from a lepidopteran insect have distinct catalytic properties and responses to different inhibitors.     

Aryl N-hydroxy- and N-methoxy-N-methylcarbamates as potent reversible inhibitors of acetylcholinesterase

Several aryl N-hydroxy- and N-methoxy-N-methylcarbamates were examined as inhibitors of bovine erythrocyte acetylcholinesterase (AChE). These carbamate derivatives were generally strong inhibitors of AChE, but, unlike the typical N-methyl- and N,N-dimethylcarbamates which are carbamylating agents, they proved to be reversible, competitive inhibitors of the enzyme. The values for the dissociation constant (K_a) for the enzyme-inhibitor complex to enzyme and inhibitor were in the range of 2 × 10^?5?1 × 10^?7M.     

Functional analysis of mutations in expressed acetylcholinesterase that result in azinphosmethyl and carbofuran resistance in Colorado potato beetle

The functional attributes of specific point mutations, R30K, S291G, and I392T, associated with full-length acetylcholinesterase (AChE) cDNAs of organophosphate (OP)- and carbamate-resistant Colorado potato beetles (CPB), were determined using site-directed mutagenesis and baculovirus expression. Enzymatic and inhibitory properties of altered recombinant acetylcholinesterases (rAChEs) were examined. S291G increased the hydrolysis of substrates with larger substituted alkyl groups (e.g., BTC vs ATC) and increased the inhibitory action of inhibitors with larger alkyl groups (e.g., paraoxon, DFP, and N-propyl carbofuran vs. azinphosmethyl-oxon and N-methyl carbofuran). R30K in conjunction with S291G enhanced the hydrolysis activity of larger substrates and the inhibitory action of larger inhibitors. I392T attenuated the effects of S291G in that the altered rAChE with both S291G and I392T elicited substrate specificity and inhibitory properties more similar to the susceptible form of AChE without mutations.     

Phosphorylation rate constants and esteratic subsite normality employing the fluorescent organophosphate Maretin: A new approach to the study of the acylation mechanism of acetylcholinesterase and butyrylcholinesterase

The fluorescent organophosphate Maretin, O,O-diethyl O-(1–6 naphthaloximido)phosphate, is an optimum analytical reagent for measurement of acetylcholinesterase (AChE) and butyrylcholinesterase cholinesterase (BuChE) normality. It also permits direct measurement of the second-order kinetics of inhibition. Maretin is fluorescent in aqueous solution with excitation at 346 nm and emission at 398 nm. On phosphorylation, the N,N-naphtholoylhydroxylamine leaving group is nonfluorescent. Experimental advantages of this methodology include: readily correctable hydrolysis rate, commercial availability of pure analytical grade Maretin, ease of handling, and no significant side reactions. The bimolecular rate constant (K_i), equilibrium binding constant (K_eq), and phosphorylation rate constant (k₂) are measured as a function of pH and compared for the two enzymes. Phosphorylation rate data and enzyme activity studies indicate an independent pH functionality between acylation and deacylation for AChE.     

Molecular characterization of two acetylcholinesterase genes from the brown planthopper, Nilaparvata lugens (Hemiptera: Delphacidae)

Acetylcholinesterase (AChE), which is encoded by the ace gene, catalyzes the hydrolysis of the neurotransmitter acetylcholine to terminate nerve impulses at the postsynaptic membrane. AChE is a primary target of many insecticides including organophosphates (OP) and carbamates (CB). In this study, full-length cDNA sequences of two ace genes (Nlace1 and Nlace2) were sequenced from the brown planthopper (BPH) Nilaparvata lugens, the most destructive insect pest of rice crops. Nlace1 cDNA is 2842 nucleotides long and contains an ORF potentially encoding a 790 amino acid peptide. Nlace2 cDNA is 2852 bp in length and contains an ORF that potentially encodes a 672 amino acid peptide. NlAChE1 has an identity of 40% with NlAChE2 at the amino acid sequence level. Phylogenetic analysis of 59 AChEs from 32 animal species showed that NlAChE1 is most closely related to AChE1s from Blattella germanica and Nephotettix cincticeps, while NlAChE2 is most closely related to AChE2 from N. cincticeps. Quantitative RT-PCR analysis showed that Nlace1 is expressed at a much higher level than Nlace2 in all developmental stages and tissues, demonstrating that NlAChE1 may be the dominant AChE form of the two enzymes. This result will help reveal the resistance mechanism of N. lugens to organophosphorous and carbamate insecticides and promote development of more selective insecticides targeting the main NlAChE1.     

Selectivity, acetylcholinesterase inhibition kinetics, and quantitative structure-activity relationships of a series of N-(2-oxido-1,3,2-benzodioxa-phosphol-2-yl) amino acid ethyl or diethyl esters

The inhibitory effects of a recently introduced series of the titled compounds on insect and mammalian acetylcholinesterase (AChE) activity were examined, where the median inhibition concentration (I₅₀) and the inhibition kinetic parameters, bimolecular inhibition rate constant (k_i), affinity constant (K_a), and phosphorylation rate constant (k_p), were determined for each compound. Results indicated that all examined dioxaphospholenes had less inhibitory effects on mammalian AChE than fenitrothion, a commercial pesticide with moderate mammalian toxicity. The highest selectivity was obtained with compounds containing glutamic and leucine moieties (2.70 and 2.18, respectively) while selectivity of fenitrothion was 0.93. The low inhibitory effects of the examined dioxaphospholenes on mammalian AChE were attributed to their low phosphorylation rates (k_p < 2.2 min⁻¹) compared to that of fenitrothion (k_p = 4.84 min⁻¹). QSAR equations indicated that the inhibition process is controlled mainly by both the phosphorylation rate (direct effect) and the affinity of compounds toward the enzyme (inverse effect). Although the compounds’ hydrophobicity had no effects on the inhibition process, it affects the compounds’ toxicity since it affects the ability of compounds to penetrate insects to reach the enzyme active site.     

Cholinesterase (ChE) inhibition in pumpkinseed (Lepomis gibbosus) as environmental biomarker: ChE characterization and potential neurotoxic effects of xenobiotics

Inhibition of cholinesterases (ChEs) has been widely used as an environmental biomarker of exposure to organophosphates (OP) and carbamate (CB) pesticides. More recently, this biomarker has been suggested as a putative biomarker for exposure to detergents. The use of cholinesterase inhibition as effect criterion in Ecotoxicology requires the previous characterization of the specific enzymatic forms that may be present in different tissues or organs. Different ChEs isoforms may be present in the same tissue and may exhibit distinct sensitivities towards environmental contaminants. This work intended to characterize the soluble ChEs present in pumpkinseed sunfish (Lepomis gibbosus) total head and dorsal muscle homogenates, through the use of different substrates and selective inhibitors of cholinesterasic activity. Also, the in vitro effects of sodium dodecylsulphate (SDS - anionic detergent) and chlorfenvinphos (organophosphate pesticide) on the enzymatic activity of the mentioned species were investigated. In general terms, the predominant cholinesterasic form present in both tissues was acetylcholinesterase. Chlorfenvinphos was responsible for inhibitory effects on AChE activity, while SDS did not cause any significant effect. These results suggest that in environmental monitoring programs, L. gibbosus head and dorsal muscle AChE can be an adequate diagnostic tool for exposure to OP pesticides; this conclusion however is not applicable to detergent residues. We also discuss the usefulness of L. gibbosus as an alternative model system and valuable option for freshwater ecotoxicological monitoring programs.     

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.     

Frequencies and evolution of organophosphate insensitive acetylcholinesterase alleles in laboratory and field populations of the house fly, Musca domestica L.

Resistance to organophosphate (OP) and/or carbamate insecticides can be due to mutations in the acetylcholinesterase gene (Ace). Genotypes of house fly, Musca domestica L., Ace were determined in twelve laboratory maintained strains (originally from North America, Europe and Asia) and two field collected populations from New York and Florida. There were 15 Ace alleles found and 11 of the alleles coded for a susceptible form of the enzyme (i.e., V260, A316, G342 and F407). Three of the four resistance alleles were previously described, while one is new. Phylogenetic analysis of the alleles suggests multiple origins of the F407Y mutation and multiple origins of the G342A mutation that confer OP resistance. Genotyping of field collected house flies from New York and Florida populations revealed the presence of only one resistance allele, Acev10 (containing the non-synonymous mutations for A342 and Y407). All other alleles detected from the field-collected flies coded for a susceptible AChE. Thus, we were able to categorize individual flies as having homozygous susceptible (Ace^S/Ace^S), homozygous insensitive (Ace^I/Ace^I or Acev10/Acev10) or heterozygous AChE. The frequencies of Ace^S and Ace^I were not different between the NY2002 and FL2002 populations. Both populations were out of Castle-Hardy-Weinberg equilibrium, having an excess of Ace^S/Ace^I individuals and very few Ace^S/Ace^S individuals. Comparison of Ace, Vssc and CYP6D1 genotypes indicates individual house flies commonly have resistance alleles at multiple loci. Comparison of genotype data with bioassays, as well as the use of genotype data in resistance studies is discussed.     

Molecular and biochemical mechanisms of organophosphate resistance in laboratory-selected lines of the oriental fruit fly (Bactrocera dorsalis)

Genetic and biochemical factors leading to resistance to various organophosphate (OP) based insecticides were studied in lines selected for OP-resistance in the oriental fruit fly Bactrocera dorsalis. Lines were separately selected for resistance to naled, trichlorfon, fenitrothion, fenthion, formothion, and malathion. Overall, these lines showed increased resistance ratios ranging from 13.7- to 814-fold relative to a susceptible (S) line. Also, in these newly selected lines the same three point mutations in the ace gene, previously identified in resistance studies and designated as I214V, G488S and Q643R, were found. As expected, the enzyme from the resistant lines showed lower overall activity and reduced sensitivity to inhibition by fenitrothion, methyl-paraoxon and paraoxon compared to the wild type acetylcholinesterase (AChE) enzyme. The apparent V_max values for esterase from the resistant lines were 1.2-3.69 times higher than that of the S line. Although only the naled-, trichlorfon- and fenthion-r lines showed lower esterase affinities (based on apparent K_m values) compared with the S line, all of the V_max/K_m ratios were higher in the resistant lines compared to that of the S line. The OP-resistant lines also displayed an overall similar pattern of isozyme expression, except for one additional band found only in the naled-r line and one band that was absent in the trichlorfon-, malathion-, and fenthion-r lines. Our results also show that overall, multiple examples of high OP resistance in selected lines of B. dorsalis exhibiting the same genetic alterations in the ace gene seen previously resulted in different effects on esterase enzyme activity in relation to various OP compounds.     

Susceptibilities to methamidophos and enzymatic characteristics in 18 species of pest insects and their natural enemies in crucifer vegetable crops

The susceptibilities to methamidophos as well as the kinetic and inhibitory parameter of acetylcholinesterases (AChE) and the activities of carboxyestsrases (CarE) and glutathione-S-transferases (GST) were studied in 18 species field populations of insects collected in Fuzhou, China during April and May 2000 and 2001. The insect species included five hymenopteran endoparasitoids, one hymenopteran exoparasitoid, one hymenopteran hyperparasitoid, one dipteran predator, four coleopteran predator ladybirds, six herbivorous pest insects of lepidoptera, diptera, homoptera, and coleoptera, respectively. There existed significant correlations between the susceptibility to methamidophos and the k_i values of AChE to methamidophos, dichlorvos, and carbofuran and between the k_i and V_max values of AChE among 18 species of insects. The six herbivorous pests and four ladybirds showed significantly low k_i and V_max values of AChE compared to the seven parasitoids and predator Epistrophe balteate. It was difficult to correlate the susceptibility to methamidophos or the k_i values with the K_m values of AChE, or with the activity of CarE and GST. The activities of CarE and GST varied depending on the different insect species. Significant synergisms of piperonyl butoxide (PB), triphenyl phosphate (TPP), and diethyl maleate (DEM) with methamidophos were observed in 14 pest insects and their natural enemies. Synergisms of PB were found to be the greatest. Reduced k_i values suggested that insensitive AChE might play a critical role in the tolerance to methamidophos in the 18 insect species. The detoxification enzymes, mixed-function oxidase (MFO), CarE, and GST, were believed to be involved in the tolerance to methamidophos. MFO might play the most important role, and CarE or GST might be important in the tolerance in some insect species. Different models of tolerance to methamidophos and enzymatic potential were existed in parasitoids, predators, and herbivores based on the different selection of insecticide pressure (either directly by exposing to the spray in the field, or indirectly by the insecticides penetrated into the body of host insects) as well as different ecological and biological habitats.     

Status of insecticide resistance in Culex pipiens field populations from north-eastern areas of Italy before the withdrawal of OP compounds

BACKGROUND: Heavy and constant use of organophosphorus (OP) larvicides selected Culex pipiens L. resistant populations through two main mechanisms of genetic resistance, the increased activity of detoxifying esterase and the production of alterate acetylcholinesterase‐1 (AChE1) by G119S mutation. The aim of this study was the assessment of the distribution of Cx. pipiens populations resistant to temephos and chlorpyrifos in the north‐eastern regions of Italy and the occurrence of the insensitive AChE in these populations. Data describe the situation in the last years before European legislation prohibited the use of OP larvicides in mosquito control, up until 2007. RESULTS: For the first time a high level of OP resistance in the samples from Ravenna (182‐fold, 80% A4/B4 or A5/B5 esterases and 38.3% Ester⁵), Emilia Romagna region, was detected; therefore, new data from the Veneto and Friuli Venezia Giulia regions were obtained and reinforced existing knowledge about resistance previously studied along the Adriatic coast. Nearby, in the Villa Verucchio locality, the highest (87.5%) AChE1R was found. CONCLUSION: Cx. pipiens resistance esterases A5/B5 and A4/B4 spread southward along the Adriatic coastal plain while OPs were being used in mosquito control, as confirmed by the first molecular screening of the AChE1 gene in these populations. Copyright © 2010 Society of Chemical Industry     

Acetylcholinesterase point mutations in European strains of Tetranychus urticae (Acari: Tetranychidae) resistant to organophosphates

BACKROUND: In Tetranychus urticae Koch, acetylcholinesterase insensitivity is often involved in organophosphate (OP) and carbamate (CARB) resistance. By combining toxicological, biochemical and molecular data from three reference laboratory and three OP selected strains (OP strains), the AChE1 mutations associated with resistance in T. urticae were characterised. RESULTS: The resistance ratios of the OP strains varied from 9 to 43 for pirimiphos‐methyl, from 78 to 586 for chlorpyrifos, from 8 to 333 for methomyl and from 137 to 4164 for dimethoate. The insecticide concentration needed to inhibit 50% of the AChE1 activity was, in the OP strains, at least 2.7, 55, 58 and 31 times higher for the OP pirimiphos‐methyl, chlorpyrifos oxon, paraoxon and omethoate respectively, and 87 times higher for the CARB carbaryl. By comparing the AChE1 sequence, four amino acid substitutions were detected in the OP strains: (1) F331W (Torpedo numbering) in all the three OP strains; (2) T280A found in the three OP strains but not in all clones; (3) G328A, found in two OP strains; (4) A201S found in only one OP strain. CONCLUSIONS: Four AChE1 mutations were found in resistant strains of T. urticae, and three of them, F331W, G328A and A201S, are possibly involved in resistance to OP and CARB insecticides. Among them, F331W is probably the most important and the most common in T. urticae. It can be easily detected by the diagnostic PCR‐RLFP assay developed in this study. Copyright © 2009 Society of Chemical Industry     

Synergism of resistance to phosalone and comparison of kinetic properties of acetylcholinesterase from four field populations and a susceptible strain of Colorado potato beetle

The susceptibility to phosalone and biochemical characteristics of acetylcholinesterase (AChE) were compared between susceptible (SS) strain and four field populations of Colorado potato beetle (CPB) collected from commercial potato fields of Hamedan Province in west of Iran. Bioassays involving topical application of phosalone to fourth instars revealed up to 252 fold resistance in field populations compared with the SS strain. Synergism studies showed that although esterase and/or glutathione S-transferase metabolic pathways were present and active against phosalone, they were not selected for and did not have a major role in resistance. It is likely that piperonyl butoxide (PBO) reduced phosalone toxicity by inhibiting bio-activation of phosalone. The affinity (K_m) and hydrolyzing efficiency (V_max) of AChE to selected substrates, namely, acetylthiocholine iodide (ATC), propionylthiocholine iodide (PTC), and butyrylthiocholine iodide (BTC) were examined. AChE inhibition by higher substrate concentration was evident only in the SS strain. In resistant field populations, Aliabad (Aa), Bahar (B) and Dehpiaz (Dp), substrate inhibition at higher concentrations was not seen. There was no definite optimal concentration found for any of the substrates examined. When ATC, PTC, and BTC were used as substrate, the reaction rates of AChE from Yengijeh (Yg) population increased as the concentration of all three substrates were increased, but were almost constant at concentration of ATC ? 3.98, PTC ? 2.8, and BTC ? 5 mM. The susceptible form of AChE had the most efficient ATC hydrolysis but very low BTC hydrolysis activity. In contrast, AChEs from field populations elicited relatively reduced ATC hydrolysis, but relatively increased BTC hydrolysis. The in vitro inhibition potency of some organophosphates (OPs), on AChEs of the field populations and SS strain was determined. The rank order from the most potent inhibitor to the least as determined by their bimolecular reaction constants (K_i) was ethyl paraoxon > diazoxon > methyl paraoxon for AChE from Aa, B, Dp, and Yg populations, respectively, whereas the rank order for the susceptible strain was methyl paraoxon > ethyl paraoxon > diazoxon.     

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.     

Activated transformations of organophosphorus insecticides in the case of non-AChE inhibitory oxons

Many organophosphorus (OP) compounds are of the thiono form and in insects or animals are converted by microsomal mixed function oxidases (MFO) into the oxon forms which inhibit acetylcholinesterase (AChE) and give toxic activity. However, certain S-alkyl phosphorothiolates (RS-P(O) <) such as methamidophos, profenophos and prothiophos oxon are strongly insecticidal, but very poor inhibitors of AChE in vitro. Their oxons are converted further to the S-oxides, which either inhibit AChE or decompose, depending on the alkyl substituents on the sulfur atom. It is also inferred in the case of prothiophos oxon that its S-oxide not only inhibits AChE but also conjugates with glutathione (GSH) by the action of glutathione S-transferase (GST), and the conjugate inhibits AChE. Certain phosphoramidates (R2N-P(O) <) such as isofenphos oxon, schradan and propetamphos oxon are weak AChE inhibitors, but strongly insecticidal. It is well known that isofenphos oxon is converted into the stable N-desalkyl form (H2N-P(O) <) by oxidative dealkylation to inhibit AChE. The authors have studied activation of phosphoramidates using 2,4-dichlorophenyl methyl N-alkylphosphoramidates as model compounds using various approaches including computational chemistry, and these studies indicated that the O-aminophosphate structure (R2N-O-P(O) <) is an activated form.     

Relation of acetylcholinesterase sensitivity to cross-resistance of a resistant house fly strain to organophosphates and carbamates

Acetylcholinesterase (AChE, E.C. 3.1.1.7) from an organophosphate-resistant strain of house fly, Musca domestica (L.) exhibited a decrease in sensitivity towards four organophosphates and two carbamates in comparison with enzyme from the parent susceptible strain. Sensitivity was less, as measured by the bimolecular reaction constant (k_i), by a factor of 117 for dichlorvos, 94 for paraoxon, 11 for diazoxon, 7 for Tetram, 62 for propoxur, and 50 for dimetilan. These differences in bimolecular reaction constants were attributed entirely to differences in their affinity for the enzyme, as measured by the dissociation constant, K_d. It is suggested that the cross resistance to these inhibitors is due at least in part to insensitive acetylcholinesterase.     

农药残留检测用新型碳纳米管固载酶生物传感器的制备及其电学传感性能分析

采用滴涂法、自组装法及化学键合法制备了基于碳纳米管(CNTs)修饰的乙酰胆碱酯酶(AChE)生物传感器,采用循环伏安法(CV)、计时电流法(CA)、交流阻抗法(EIS)和扫描电镜(SEM)对生物传感器的电化学性能和表面形貌进行表征,通过采用该生物传感器对异丙威(氨基甲酸酯类农药)进行分析的结果,考察了其检测性能,研究了各生物传感器的动力学性质及电化学行为,并构建了新型固载酶生物传感器的等效电路模型。结果表明:各生物传感器表观表面积比裸电极显著提高,其电子传递速率遵循以下顺序逐渐降低:乙酰胆碱酯酶(AChE)/壳聚糖(CS)/功能化碳纳米管(F-CNTs/GCE)生物传感器AChE/F-CNTs/GCE生物传感器CS/双醛纤维素固载酶(DAC-AChE)/F-CNTs/GCE生物传感器,各传感器表观电子传递速率常数分别为:k s AChE/CS/F-CNTs/GCE=0.24 s-1,k s AChE/F-CNTs/GCE=0.23 s-1和k s CS/DAC-AChE/F-CNTs/GCE=0.22 s-1。获得生物传感器电学阻抗谱等效电路模型为R1(CPE1(R2(CPE2(R3)))),计算得到等效电路模型中各具体元件参数,证明该有效电路能有效模拟生物传感器检测异丙威的传感机理。该研究结果可为农药残留检测用生物传感器分析机理研究提供有益参考。     

Affinity and phosphonylation constants for the inhibition of cholinesterases by the optical isomers of O-2-butyl S-2-(dimethylammonium)ethyl ethylphosphonothioate hydrogen oxalate

The synthesis of the four optical isomers of known absolute configuration of O-2-butyl S-2-(dimethylammonium)ethyl ethylphosphonothioate hydrogen oxalate is described. Values for the affinity constant (K_a), phosphonylation constant (k_p), and bimolecular inhibition rate constant (k_i) for the inhibition of bovine erythrocyte acetylcholinesterase, housefly-head acetylcholinesterase, and horse serum cholinesterase by the chiral isomers and the racemic mixture are reported. Using a relatively simple spectrophotometric technique, inhibition times as low as 0.5 sec were used. The phosphorus isomers of S_p configuration were more potent inhibitors than their R_p enantiomers by 1630-fold against the bovine enzyme, 9120-fold against the fly-head enzyme, and 40-fold against the horse serum enzyme. The differences in anticholinesterase activity were attributable to differences in the affinity constant, K_a, and the phosphonylation constant, k_p. Small but consistent inhibition rate differences were attributable to asymmetry at carbon. Against horse serum cholinesterase, the S_C isomers indicated the presence of three kinetic forms in this enzyme preparation.