Mechanism of inhibition reaction of acetylcholinesterase by phenyl N-methylcarbamates: Separation of hydrophobic,electronic, hydrogen bonding and proximity effects of aromatic substituents

The association equilibrium constant, $\text{1}\text{K}{}_{\mathrm{d}}$, and the carbamylation constant, k₂, of 53 o-, m-, and p-substituted phenyl N-methylcarbamates with bovine erythrocyte acetylcholinesterase were determined. The $\text{1}\text{K}{}_{\mathrm{d}}$ value varied 1000-fold, whereas the k₂ value did not depend upon the nature and position of substituents. The variation in $\text{log}\text{(}\text{1}\text{K}{}_{\mathrm{d}}\text{)}$ was analyzed using free energy related substituent parameters and regression analyses. The effect of substituents at o-, m-, and p-positions was nicely separated into hydrophobic, electronic, hydrogen bonding, and proximity (steric and field electronic for o-substituents) factors. The physicochemical significance of these factors was established by comparison with those for model organic reactivities. The mechanism of the whole reaction process was elucidated in terms of physical organic chemistry.     

Deuterium isotope effects on the formation of mercapturic acids from lindane in rats

Metabolism experiments with rats showed that significant isotope effects ($\text{k}{}_{\mathrm{<mtext>H</mtext>}}\text{k}{}_{\mathrm{<mtext>D</mtext>}}\text{= 2.4}\text{to}\text{3.5}$) were associated with the in vivo formation of dichloro and trichlorophenylmercapturic acids from a 1:1 mixture of normal and hexadeuterated lindane. This is evidence that rate-determining dehydrogenation and dehydrochlorination, both of which proceed with significant isotope effects, are essential in the pathway of dichloro- and trichlorophenylmercapturic acid formation from lindane. No significant primary isotope effects were associated ($\text{k}{}_{\mathrm{<mtext>H</mtext>}}\text{k}{}_{\mathrm{<mtext>D</mtext>}}\text{= 1.31 ± 0.17}$) with the formation of monochlorophenylmercapturic acid. This suggests that the 1,2-dechlorination to tetrachlorocyclohexene followed by glutathione conjugation is the probable pathway that produces this metabolite from lindane.     

Isomerization and Beckmann rearrangement reactions in the metabolism of methomyl in rats

Methomyl {S-methyl-N-[(methylcarbamoyl)oxy]thioacetimidate}, also known as Lannate, may exist in two geometric configurations but the more stable syn isomer is the form applied as an insecticide. In the rat, syn[¹⁴CN]methomyl [CH₃S(CH₃)CNOC(O)NHCH₃] was metabolized to respiratory ¹⁴CO₂ and $\text{CH}{}_3{}^{14}\text{CN}$ in a ratio of about 2 to 1. Studies with the anti isomer showed that it was metabolized predominately to $\text{CH}{}_3{}^{14}\text{CN}$. These and other data are presented supporting the contention that syn methomyl is partially isomerized to the anti isomer in the animal prior to the hydrolysis of the ester linkage. After hydrolysis, the syn oxime [CH₃S(CH₃)¹⁴CNOH] is further metabolized to ¹⁴CO₂ while the anti oxime is metabolized to $\text{CH}{}_3{}^{14}\text{CN}$. Proposed immediate precursors to the carbon dioxide and acetonitrile, formed by Beckmann rearrangement of the syn and anti oximes, are CH₃S¹⁴C(O)NHCH₃ and $\text{[}\text{CH}{}_3{}^{\mathrm{14\oplus }}\text{CNSCH}{}_3\text{]x}{}^{\mathrm{?}}$, respectively.     

Induction of glutathione S-transferase by phenobarbital and pesticides in various house fly strains and its effect on toxicity

The effect of phenobarbital and certain pesticides on glutathione S-transferase activity was investigated. The maximum amount of enzyme induction occurred 96 hr after phenobarbital treatment. Chlorinated hydrocarbons were more effective inducers than the other pesticides evaluated. Phenobarbital treatment did not alter the apparent K_m value but altered the $\text{V}{}_{\mathrm{<mtext>max</mtext>}}$ value of glutathione S-transferase to 3,4-dichloronitrobenzene. The amount of reduced glutathione was not increased by phenobarbital treatment. Pretreatment of house flies with phenobarbital provides some protection against methyl parathion, methyl paraoxon, azinphosmethyl, and methidathion toxicity.     

Studies on the chiral isomers of fonofos and fonofos oxon: I. Toxicity and antiesterase activities

The toxicity of the (R)_P and (S)_P chiral isomers and racemates of fonofos and fonofos oxon to insects and white mice were determined. (R)_P-Fonofos and (S)_P-fonofos oxon were 2- to 12-fold more toxic to house flies, mosquito larvae, and mice than were the corresponding enantiomers. The racemates were intermediate in toxicity. Stereoselectivity also was observed in the in vitro inhibition of house fly-head and bovine erythrocyte acetylcholinesterase, horse serum cholinesterase, chymotrypsin, trypsin, and a variety of esterases. In all cases the (S)_P-oxon was a more potent inhibitor than the (R)_P-oxon with k₁ ratios of $\text{(S)}{}_{\mathrm{<mtext>P</mtext>}}\text{(R)}{}_{\mathrm{<mtext>P</mtext>}}$ ranging from 4- to 60-fold. Further, differences in levels of house fly-head, mouse brain, and blood cholinesterase obtained from house flies and mice treated with the enantiomers and racemates of fonofos and fonofos oxon were observed. Differences in toxicity of the enantiomers and racemates to house flies and mice were more closely related to in vivo than to in vitro cholinesterase inhibition.     

Inhibition of DNA polymerase β activity in isolated bovine liver nuclei by captan and related compounds

The effects on DNA synthesis of the fungicide captan and several structurally related compounds were investigated in isolated bovine liver nuclei. Captan, folpet, captafol, and trichloromethanesulfenyl chloride inhibited DNA synthesis to the same degree with ID₅₀ values of approximately 50 μM in a 40-min assay. The inhibition is concentration dependent and the degree of inhibition increases with time. Studies with structural analogs of captan indicated that inhibition of DNA synthesis by captan is mediated through the trichloromethylthio moiety of the captan molecule. In addition, the data indicate thiophosgene is probably not the toxic species involved in the inhibition of DNA synthesis. The isolated nuclei used in this study were shown to exhibit only a single DNA polymerase activity which was determined to be of the β or low-molecular-weight type. In addition to its inhibition in intact nuclei, captan inhibited the activity of the β polymerase in nuclear extracts as well as in partially purified enzyme preparations. These results indicate that captan inhibits DNA synthesis in our preparation of isolated nuclei by acting directly on the DNA polymerase-catalyzed reaction rather than by causing a nonspecific or indirect effect in the nuclear system such as alterations in the nuclear membrane or aggregation of the nuclei. The site of captan's inhibitory action is the DNA polymerase molecule. The interaction of captan with the polymerase results in irreversible inhibition of the enzyme. Interaction of captan with the template, if it occurs, does not appear to be involved in mediating the inhibition.     

Cytochrome P-450 content and aldrin epoxidation to dieldrin in isolated rat hepatocytes

A rat hepatocyte suspension effectively epoxidized aldrin to dieldrin with a V_max of 7.19 mol/mol P-450/min and a K_m of 9.27 μM. Viability and metabolic activity were stable for 6 hr after isolation when cells were maintained at room temperature (20°C) with the gentle introduction of $\text{O}{}_2\text{CO}{}_2$ onto the surface of the suspension. The cytochrome P-450 content of the suspension was 303 pmol/10⁶ cells. Primary maintenance culture of the cells also epoxidized aldrin. During culture for 3 days, metabolic activity decreased slowly day by day. Metabolic activity of microsomal fraction from rat liver was also examined. Microsomes epoxidized aldrin with a V_max of 5.11 mol/mol P-450/min and a K_m of 1.64 μM. Significant loss of some subspecies of cytochrome P-450 during fractionation of liver homogenate was indicated.     

The purification and characterization of esterases from insecticide-resistant and susceptible house flies

Four major esterases in one susceptible (CSMA) and two resistant (Hirokawa, E₁) house fly strains were separated by chromatofocusing. Of the four esterases, those with pI's of 5.1 and 5.3 accounted for 90% of the p-nitrophenyl butyrate hydrolyzing activity in the three house fly strains. They also accounted for 70% (Hirokawa, E₁) and 40% (CSMA) of the paraoxon-hydrolyzing activity as well as 87% (Hirokawa), 39% (E₁) and 66% (CSMA) of the malathion-hydrolyzing activity in microsomes as measured by esterase-antibody interaction. In the Hirokawa strain, the pI 5.1 esterase was the predominant esterase and was more active than that of the the CSMA strain. Different substrate specificities and a different K_m toward acetylthiocholine, as well as different rates of malathion and paraoxon hydrolysis between the Hirokawa and CSMA strains, suggest a qualitative difference in the pI 5.1 esterase. For the pI 5.1 esterase from the E₁ strain, a different substrate specificity, a different K_m for p-nitrophenyl butyrate, a different sensitivity to inhibitors, and a different rate of paraoxon hydrolysis suggest that it is a modified esterase. This esterase is not a phosphorotriester hydrolase, nor does it lack nonspecific esterase activity. It is a modified esterase which has a different substrate specificity when compared to the esterases from the other strains. The molecular weight of the esterases studied was approximately 220,000, with pH optima of about 7.0.The ratio of malathion α-monoacid to β-monoacid formation was about 9.0 for the pI 5.1 and 5.3 esterases and 1.5 for the pI 4.8 and 5.6 esterases. The existence of a higher $\text{α}\text{β}$ ratio for the pI 5.1 and 5.3 esterases and their significant rate of malathion hydrolysis in the Hirokawa strain indicate that an increase in the $\text{α}\text{β}$ ratio in house flies reported was due to the increase in the pI 5.1 esterase in the resistant strain.     

Metabolism of lindane in house flies: Metabolic desaturation,dehydrogenation and dehydrochlorination,and conjugation with glutathione

In lindane-treated house flies, a cis-dehydrogenated metabolite, $\text{(}\text{36}\text{45}\text{)-}\text{hexachlorocyclohexene}$, was identified by gas-liquid chromatography and mass spectrometry. The in vitro metabolism study showed that in the presence of NADPH the microsomal fraction of house flies converted lindane to three hexane-soluble metabolites. This conversion was inhibited by piperonyl butoxide, SKF-525A, and carbon monoxide. These metabolites were identified as $\text{(}\text{36}\text{45}\text{)-}\text{hexachlorocyclohexene}$, $\text{(}\text{36}\text{45}\text{)- and (}\text{346}\text{5}\text{)-pentachlorocyclohexene}$ (PCCHE) by gas-liquid chromatography. They, as well as lindane, were excellent substrates for the reaction with the postmicrosomal fraction in the presence of glutathione. While the reaction with lindane-d₆ showed a significant deuterium isotope effect (6.82), that of $\text{(}\text{36}\text{45}\text{)-}\text{PCCHE-d}{}_5$ did not (1.18). Enzymatic conjugation with glutathione probably occurs at the stage of PCCHE.     

The inhibition of nuclear DNA polymerizing activity by captan

A study was conducted concerning the inhibition of calf thymus nuclear DNA synthesis by captan. Captan was shown to be toxic to the in vitro incorporation of [³H]dTTP into calf thymus DNA, with an ID₅₀ value of 0.16 mM being measured. This inhibition was determined to be independent of Mg²⁺ concentration. Although intact nuclear activities were affected, the soluble DNA polymerizing activity isolated from calf thymus nuclei exhibited no inhibition when exposed to captan. Treatment of purified calf thymus DNA with 10^?5 and 10^?4M captan caused an elevation of the T_m by 2 and 6°C, respectively. The inhibitory characteristic of captan on DNA polymerizing activities and the influence of this compound on the thermostability of DNA indicate a mechanism of inhibition which is located in the nucleus and is possibly related to the template function of DNA and/or with the nuclear DNA polymerizing enzymes.     

Selective alterations of membrane properties of cultured human liver cells caused by the insecticide DDT

A variety of membrane-specific parameters was examined in both intact cells and isolated plasma membranes following exposure of cultured human liver cells to the insecticide 1,1-(2,2,2-trichloroethylidene)bis(4-chloro)benzene (DDT). Uptake of DDT was at equilibrium within 6 hr. In contrast, a decrease in the number of β-adrenergic hormone receptors first became significant after 48 hr of cell exposure. Whereas the uptake was largely reversible, the loss in the number of β receptors did not recover after DDT-exposed cells were cultured in fresh medium lacking the insecticide. Experiments in vitro substantiated the time lag of the biological effect. The decrease in receptor proteins was persistent in membranes with increased phospholipid unsaturation. Temperature-activity profiles (“Arrhenius plots”) of $\text{Na}{}^{\mathrm{+}}\text{K}{}^{\mathrm{+}}\text{-ATPase}$ and 5′-nucleotidase were unchanged. Endogenous tryptophan fluorescence of membrane proteins was lower in membranes from DDT-exposed cells. These selective alterations in membrane parameters suggest a specific interaction of DDT with membrane proteins; interference with cellular protein synthesis is possible. The results indicate that membrane lipid “fluidization” does not play a physiologically important role in the mechanism of DDT action in biomembranes.     

Steric,electronic, and polar parameters that affect the toxic actions of O-alkyl,O-phenyl phosphonothionate insecticides

The toxic action of a series of O-alkyl, O-substituted-phenyl alkyl- and aryl-phosphonates and phosphonothionates have been evaluated by correlating the linear free energy parameters for steric (E_s), electronic (σ), and polar ($\text{σ}{}^1$) effects with topical LD₅₀ to the house fly and oral LD₅₀ to the white mouse. In molecules free from major steric interactions with the reactive P atom, variations in these linear free energy parameters account for >90% of the variations in the LD₅₀ values, and the degree of correlation with LD₅₀ is at least as precise as that with the biomolecular rate constants for inhibition of the target-site enzyme acetylcholinesterase. The value of correlations of linear free energy parameters with LD₅₀ in understanding quantitative structure-activity relationships is illustrated.     

The metabolism of p,p′-DDT by the feral pigeon (Columba livia)

Male feral pigeons were dosed with ring-labeled $\text{[}{}^{14}\text{C}\text{]p,p′-}\text{DDT}$ and the tissues and droppings analyzed for total ¹⁴C, extractable ¹⁴C, and metabolites. Only 16% of an intraperitoneal dose of 1.5–2.2 mg kg^?1 was voided in the droppings over 28 days; the rate of loss reached a maximum on the 14th day and then fell quickly away. The rate of removal of ¹⁴C in droppings was low in comparison to that found in the rat and the Japanese quail. When pigeons were dosed with 32–38 mg kg^?1 DDT per bird, and killed after 77 days, 5.4% of the dose was eliminated in droppings and 87% was recovered in the body. The tissues and droppings from this experiment were analyzed for DDT and its metabolites. Of the ¹⁴C remaining in tissues 88% was accounted for as the apolar compounds DDE, DDT, and DDD. Approximately half of the ¹⁴C in droppings was present as DDE, DDT, and DDD, whereas 27–35% was apparently in conjugated form, extractable from aqueous solutions by ethyl acetate after prolonged acid hydrolysis. Two polar metabolites were isolated from the acid-released material. One was p,p′-DDA; the other was extractable from aqueous solution at pH 8 and was tentatively identified as a monohydroxy derivative of p,p′-DDT. DDE accounted for 93% of the ¹⁴C present as metabolites in tissues and droppings, clearly indicating the importance of this intermediate in this study. The metabolism of DDT in the feral pigeon is discussed in relation to its metabolism by other species.     

Interaction of insecticides with the Ca2+-pump activity of sarcoplasmic reticulum

The organophosphorus insecticides, parathion and azinphos (10^?5-10^?4M), significantly stimulate the Ca²⁺-pump activity of sarcoplasmic reticulum, while malathion has a limited effect. The rates of Ca²⁺ translocation and ATP hydrolysis are both stimulated and, apparently, the $\text{Ca}{}^{\mathrm{2+}}\text{ATP}$ ratio is improved. Parathion and azinphos maximally increase this ratio by 26 and 14%, respectively. The organochlorine compounds, DDT and aldrin, also stimulate the Ca²⁺ pump, and lindane has a reduced effect. These effects are smaller than those observed for parathion and azinphos. The order of effectiveness is similar to the toxicity of the compounds to mammals and can be described as follows: parathion > azinphos > DDT ≈ aldrin > malathion ≈ lindane.     

Fate of captan and folpet in rats and their effects on isolated liver nuclei

Excretion and distribution of single and multiple intraperitoneal doses of [³⁵S]captan and [¹⁴C]folpet were similar in normal and 70% hepatectomized male rats. After receiving the single dose of captan, the rats eliminate approximately 76% of the radioactivity in the urine after 72 hr. The elimination in the feces for the same time period was 13%. Normal rats administered single or multiple doses of [¹⁴C]folpet excreted nearly 100% of the total dose in the urine within the first 24 hr. Nuclei isolated from the liver of normal and 70% hepatectomized rats receiving multiple doses of [³⁵S]captan contained 0.008–0.009 μg ³⁵S/g of tissue. Appreciable amounts of the radioactivity from [³⁵S]captan were bound by isolated nuclei from the livers of normal and partially hepatectomized rats. After a 1-hr treatment with [³⁶S]captan, the nuclei were fractionated into nuclear sap protein, deoxyribonucleoprotein (including histones), acidic ribonucleoprotein, and “residual” protein fractions. These proteins in normal nuclei bound 10, 14, 39, and 16% of the total label, respectively, with essentially the same results obtained with nuclei from regenerating rat liver. When compared by polyacrylamide gel electrophoresis, acidic nuclear proteins from treated and nontreated normal nuclei were characterized by band diffusion and the presence or absence of Amido Schwartz-staining bands. None of the abovementioned effects on histones from treated nuclei were observed. Captan treatment of isolated nuclei also altered the extraction characteristics of the nuclear protein fractions, presumably because of extensive aggregation of thiol-containing nuclear proteins.     

Studies on hydrolases in various house fly strains and their role in malathion resistance

Aliesterase, carboxylesterase, and phosphorotriester hydrolase activities in six house fly strains were studied in relation to malathion resistance. Selection of two susceptible strains with malathion for three generations resulted in an increase in both carboxylesterase activity and LD₅₀ of malathion, indicating that the increased detoxication by the enzyme was the major mechanism selected for malathion resistance. With the highly resistant strains, however, the carboxylesterase activity alone was not sufficient to explain the resistance level, and the involvement of additional mechanisms, including phosphorotriester hydrolase activity, was suggested. The E₁ strain, which had high phosphorotriester hydrolase activity but normal or low carboxylesterase activity, showed a moderate level, i.e., sevenfold resistance. Upon DEAE-cellulose chromatography, two or three esterase peaks were resolved from susceptible, moderately resistant, and highly resistant strains. The substrate specificity, the sensitivity to paraoxon inhibition, and the $\text{α}\text{β}$ ratio of malathion hydrolysis were studied for each esterase peak from the different strains. The results suggested the existence of multiple forms of esterases with overlapping substrate specificity in the house fly.     

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.     

Volatile fungitoxicants from chemicals containing haloalkylthio groups

Addition of cysteine to the fungicides captan, folpet, dichlofluanid and captafol antagonizes the activity of these fungicides and results in the formation of volatile fungitoxicants. There is no relationship, however, between the vapour action upon reaction with cysteine and the fungitoxicity of these compounds.Samenvatting Cysteine heeft een antagonerend effect op de werking van captan, folpet, dichlofluanid en captafol (Tabel 1). Bij proeven in afgesloten ruimtes (twee petri schaaltjes, waarvan de één ongekeerd op de ander, Fig. 1) bleek vooral captan als gevolg van een reactie met cysteine een voorFusarium culmorum toxische damp af te geven, folpet deed dit daarentegen niet, en de twee andere fungiciden alleen in de hoogste concentratie (Tabel 1, Fig. 1). Er is dus weinig verband tussen de fungicide werking en de productie van fungicide dampen als gevolg van de reactie met thiolen.     

Picrotoxinin receptor in the central nervous system of the American cockroach: Its role in the action of cyclodiene-type insecticides

The nature of the picrotoxinin receptor was studied using the central nervous system (CNS) of the American cockroach. It first was confirmed by using an electrophysiological technique that the abdominal nerve cord of the American cockroach was sensitive to picrotoxinin. By using a $\text{[}{}^3\text{H]α-dihydropicrotoxinin}$ binding test it was determined that the picrotoxinin receptor in CNS of this insect had a higher affinity toward picrotoxinin and heptachlor epoxide than the corresponding receptor in the rat brain. Also, the cockroach brain preparation had a higher percentage of specific binding in the total binding, making this material suitable for receptor studies. By using a sucrose density centrifugation technique, it was determined that the fraction sedimented at the interphase of 1.0 to 1.2 M sucrose at 100,000g contained the highest level of specific binding site. The receptor showed a sensitivity to all insecticidal cyclodienes tested, namely photodieldrin, oxychlordane, endrin, heptachlor epoxide, γ-chlordane, dieldrin, aldrin, heptachlor, and isodrin (expressed in the order of potency). Among four BHC isomers, the γ-isomer showed the highest potency to bind with this receptor.     

Antifungal activities of mono- and di-SCCl3 substituted compounds: Structure-activity correlations

The mono- and di-N-SCCl₃ substituted derivatives of lactams, cyclic urea, 5,5-diphenylhydantoin and 5-ethyl-5-phenylbarbituric acid were synthesized. Many of these compounds have not been reported previously. The antifungal activities were determined by spore germination method using Stemphylium sarcinaeforme, Monilinia fructicola, Helminthosporium maydis and Alternaria solani. Among the lactam and cyclic urea derivatives studied 1,3-bis(trichloromethylthio)-2-imidazolidinone appears to be the most active compound against S. sarcinaeforme, and has activity slightly below those of the commercial products captan and folpet. Among the diphenylhydantoin and phenobarbital derivatives the mono-SCCl₃ compounds appear to be more potent than the disubstituted compounds in most of the cases examined, but they are not as active as the imidazolidinone derivative. The antifungal activity appears to be highly dependent on the lipophilic character as measured by the 1-octanol/water partition coefficient. Since the bis-SCCl₃ compounds are less potent than the mono-substituted compounds in both of the series of compounds studied, it is evident that the whole molecule rather than any decomposition products of the N-SCCl₃ moiety is responsible for the fungitoxicity.