Firefly luciferase inhibition by isopropyl-3-chlorocarbanilate and isopropyl-3-chloro-hydroxycarbanilate analogues

The firefly luciferase ATP assay was inhibited by the herbicide, isopropyl-3-chlorocarbanilate (I), and by two of its hydroxylated metabolites, isopropyl-5-chloro-2-hydroxycarbanilate (II) and isopropyl-3-chloro-4-hydroxycarbanilate (III). The β-O-glucosides of II and III reversed the inhibition of luciferase. Compounds I and II were linear noncompetitive inhibitors in respect to ATP (K_i ? 20 μM, each) and were linear competive inhibitors in respect to d-luciferin (K_i ? 6 μM, each). Compound III was a linear competitive inhibitor in respect to both ATP and d-luciferin (K_i ? 1 and 6 μM, respectively). The inhibition caused by III appeared to remain competitive for both substrates when AMP was added to the system, but the inhibition exhibited by III with respect to ATP and d-luciferin was more effective (K_i ? 0.5 μM, each). The effects of compounds I, II, and III upon the firefly luciferase ATP assay are discussed, and a relationship between the firefly system and plant susceptibility to compound I is proposed.     

S-cysteinyl-hydroxychlorpropham: Formation of the S-cysteinyl conjugate of isopropyl-3′-chloro-4′-hydroxycarbanilate in oat (Avena sativa L.)

Isopropyl-3′-chlorocarbanilate (chlorpropham) forms phenolic metabolites, isopropyl-3′-chloro-4′-hydroxycarbanilate (I), and isopropyl-5′-chloro-2′-hydroxycarbanilate (II), in several plant species. In oat, which is a chlorpropham-susceptible plant, I was converted to an S-cysteinyl-conjugate (III). The reaction in vitro was catalyzed by a partially purified, soluble enzyme. The formation of III by the enzyme preparation and by oat shoot sections was compared. Mass spectral data indicated the presence of an aryl-thioether bond, and chloro-, hydroxy-, and isopropylcarbanilate groups in III. The results of this investigation indicate that III was isopropyl-[(2-amino-2-carboxyethyl)thio]-chloro-hydroxycarbanilate (S-cysteinyl-hydroxychlorpropham).     

S-cysteinyl-hydroxychlorpropham transferase inhibition by chlorpropham analogs,sulfhydryl compounds,ortho- and/or para-substituted phenols,and firefly luciferin

Inhibition of S-cysteinyl-hydroxychlorpropham transferase from oat (Avena sativa L.) by various compounds was studied. The β-O-glucoside of the substrate, isopropyl-3′-chloro-4′-hydroxycarbanilate (4-hydroxychlorpropham), and isopropyl-3′-chlorocarbanilate (chlorpropham) did not inhibit the enzyme. Isopropyl-5′-chloro-2′-hydroxycarbanilate (2-hydroxy-5-chlorpropham), was a competitive inhibitor with respect to 4-hydroxychlorpropham, but 2-β-O-glucosyl-5-chlorpropham was not an inhibitor. The inhibition patterns exhibited by 2-hydroxy-5-chlorpropham and other aryl-hydroxylated analogs suggested that the site of aryl-cysteine thioether conjugation might be the ortho (2′) aromatic carbon. Inhibitions by 3-chloro-4-hydroxyaniline and ferulic acid suggest that related phenols and/or naturally occurring phenolic plant acids could serve as substrates for the enzyme system. Glutathione was a competitive inhibitor with respect to cysteine and could also form a conjugate with 4-hydroxychlorpropham. Atypical inhibitions of cysteine conjugation by cysteine ethyl ester or firefly d-luciferin were described. Similarities between S-cysteinyl-hydroxychlorpropham transferase and firefly luciferase were noted.     

Soybean shoot metabolism of isopropyl-3-chlorocarbanilate: Ortho and para aryl hydroxylation

This laboratory reported that isopropyl-3-chlorocarbanilate-phenyl-U-¹⁴C (chlorpropham-phenyl-¹⁴C) was absorbed, translocated, and metabolized by soybean plants. Both polar metabolites and insoluble residues were found in roots, whereas only polar metabolites were found in shoot tissues. In both roots and shoots the polar metabolites were shown to be the O-glucoside of isopropyl-2-hydroxy-5-chlorocarbanilate (2-hydroxy-chlorpropham). In shoot tissue there were other polar metabolites that were not identified. The experiments with soybeans have been repeated, but with new isolation and purification procedures. The plants were root treated with both chlorpropham-phenyl-¹⁴C and isopropyl-3-chlorocarbanilate-2-isopropyl-¹⁴C. The roots and shoots were extracted and separated into the polar, nonpolar, and insoluble metabolic components, using the Bligh-Dyer extraction method. The polar metabolites were separated by gel permeation chromatography. Further purification was accomplished on Amberlite XAD-2. The polar metabolites from the shoot and root tissues were hydrolyzed either by β-glucosidase or hesperidinase. The enzyme liberated aglycones were derivatized and separated by gas-liquid chromatography, and the components were characterized by mass spectrometry or NMR. The results of this study showed that the polar metabolites of soybean shoots were 2-hydroxy-chlorpropham and isopropyl-4-hydroxy-3-chlorocarbanilate (4-hydroxy-chlorpropham). These two hydroxy-chlorpropham metabolites were found in soybean shoots at a ratio of approximately 1:1. The only aglycone found in root tissue was 2-hydroxy-chlorpropham. Using the new procedures, no evidence was obtained for the presence of the unidentified polar metabolites that were previously observed in shoot tissues.     

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 isopropyl carbanilate (propham) in alfalfa grown in nutrient solution

Alfalfa plants, Moapa variety, were grown in nutrient solution containing isopropylring-[¹⁴C] carbanilate (43.8 μCi/liter propham). After 8 days, 41.2% of the radioactivity initially added to the nutrient culture was recovered; 10.9% of this was from shoots, 3.4% from roots and 26.9% from nutrient medium. Nonextracted residues accounted for 23% of the radioactivity in shoots and 62% of that in roots. The parent herbicide constituted 53 and 38% of the radioactivity extracted from shoots and roots, respectively. The balance of extracted ¹⁴C was polar metabolites which were purified and subjected to enzymatic and acid hydrolysis. Four aglycones were isolated, three of which were purified by thin-layer chromatography and characterized by mass spectrometry. The principal aglycones were: isopropyl-2-hydroxycarbanilate, isopropyl-4-hydroxycarbanilate, and 1-hydroxy-2-propylcarbanilate. The fourth aglycone was not identified.     

Comparative effects of dichlobenil and its phenolic alteration products on photo- and oxidative phosphorylation

Effects of dichlobenil (2,6-dichlorobenzonitrile) and its phenolic degradation products (2,6-dichloro-3-hydroxybenzonitrile and 2,6-dichloro-4-hydroxybenzonitrile) were compared on electron transport and phosphorylation in isolated spinach (Spinacia oleracea L.) chloroplasts and mung bean (Phaseolus aureus Roxb.) mitochondria. In chloroplasts, the hydroxylated derivatives inhibited both photoreduction and coupled photophosphorylation with water as the electron donor and with ferricyanide as oxidant, and cyclic photophosphorylation with phenazine methosulfate as the electron mediator under an argon gas phase. In mitochondria, the phenolic derivatives acted as uncouplers of oxidative phosphorylation as evidenced by the stimulation of ADP-limited respiration, circumvention of oligomycin-inhibited non-ADP-limited respiration, and the induction of ATPase activity. Treatment of excised mung bean hypocotyls by the phenolic derivatives also resulted in a very rapid and drastic lowering of ATP levels. In all assays, only limited, if any, interference was expressed by dichlobenil even at relatively high molar concentrations.Inhibition of oxidative and photophosphorylation by the phenolic degradation products, but not by dichlobenil, suggests that if there is a delay between the formation of the hydroxylated compounds and their conjugation, photosynthesis and respiration will be inhibited. Because biochemical and physiological processes depend on oxidative and photophosphorylation for the energy (ATP) needed to drive the reactions, interference with ATP production could be one of the major mechanisms through which phytotoxicity is expressed by the phenolic degradation compounds of the herbicide, if they should accumulate in the free from. Species selectivity may be related to the rate of formation of the phenolic products in different plants and the rapidity of conjugate formation.     

Interaction of perfluidone with mitochondrial,thylakoid, and liposome membranes

Perfluidone (1,1,1-trifluoro-N-[2-methyl-4-(phenylsulfonyl)phenyl]methanesulfonamide) was shown to interfere with phosphorylation and electron transport in isolated mung bean (Phaseolus aureus Roxb.) mitochondria. At low molar concentrations (<100 μM), perfluidone acted as an uncoupler of oxidative phosphorylation as evidenced by stimulation of state 4 respiration, induction of ATPase activity, and circumvention of oligomycin-inhibited state 3 respiration. At higher molar concentrations (>100 μM), perfluidone inhibited electron transport by acting on complexes I and II, and on the alternate (cyanide-insensitive) oxidase. In isolated spinach thylakoids (Spinacia oleracea L.), perfluidone also acted as an uncoupler, at low concentrations, as evidenced by stimulation of photoinduced electron transport with water as the reductant and methyl viologen and ferricyanide as oxidants, and from reduced dichlorophenolindophenol to methyl viologen. In addition, perfluidone inhibited the rate and magnitude of valinomycin-induced mitochondrial swelling in isotonic potassium chloride and potassium thiocyanate, and with thylakoids suspended in potassium thiocyanate at concentrations that inhibited ATP generation (<100 μM). Passive swelling in mitochondria was induced at higher concentrations. The permeability of lecithin liposomes to protons was also increased by perfluidone in a manner characteristic of uncouplers. The results obtained suggested that the partitioning of perfluidone perturbs the inner mitochondrial and thylakoid membranes. The perturbations increase the permeability of the membranes to protons and cations (at least potassium) and decrease membrane “fluidity.” As a consequence of the perturbations, the ATP-generating pathway in both mitochondria and chloroplasts is uncoupled and the structural organization of the electron transport components in mitochondria is disrupted, resulting in multisite inhibition of respiration. No evidence was obtained for a direct interaction between perfluidone and redox components of the electron transport pathways.     

The effect of phosphine on electron transport in mitochondria

The effects of phosphine on electron transport and on some partial reactions of oxidative phosphorylation of mitochondria from mouse liver, housefly flight muscles and granary weevils has been studied. Phosphine was a strong inhibitor of respiration of mitochondria in the “active” state (state 3), uncoupled state, and ion-pumping state on glutamate, pyruvate plus malate, succinate, α-glycerophosphate, and ascorbate-cytochrome c as substrates. Respiration of mitochondria in state 3 was completely inhibited by about 250 μM phosphine. By contrast, the respiration of mitochondria in state 4 was much less sensitive. This inhibition could not be released by uncouplers suggesting that it is due to a direct effect on electron transport. Only site III was inhibited to any significant extent. Kinetic studies show that the inhibition was noncompetitive with Ki ranging from 1.6×10^?5 to 7.2×10^?5 depending on the source and purity of cytochrome oxidase. The inhibition of site III was also more pronounced in sonicated particles than in intact mitochrondria. The significance of this is discussed in relation to membrane sideness and topology of the components of the respiratory chain.Phosphine was unable to activate the “latent” ATPase nor did it have any inhibition of the Mg²⁺-simulated ATPase and only high levels (1.1 mM) showed modest inhibition (41%) of uncoupler-stimulated ATPase. Phosphine had no effect on the ATP-Pi exchange and on the ATP-ADP exchange reaction at concentrations causing strong respiratory inhibition.     

Effect of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) on photosynthesis and respiration of Nitella dactyl cells

Long-term experiments with dactyl cells of Nitella flexilis showed that the herbicide 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) at a concentration of 1 × 10^?5M affected not only O₂ evolution in the light but also O₂ uptake in the dark. The inhibition of O₂ production was transitory, but dark respiration did not recover. DCMU induced the formation of giant mitochondria which disappeared before cell death. It was concluded that the algicidic effect of 1 × 10^?5M DCMU on N. flexilis, but not necessarily the elongation of mitochondria, was due to the inhibition of mitochondrial respiration and not of photosynthesis.     

Phytotoxicity and metabolism of chlortoluron in two wheat varieties

Varietal susceptibility of winter wheat to chlortoluron, 1-(3-chloro-4-methylphenyl)-3,3 dimethylurea, has been studied in two varieties, Corin (susceptible) and Clement (tolerant). After a 24-hr root absorption of the herbicide, phytotoxicity was estimated from growth measurements. When administered at 12 to 96 μM concentrations, the herbicide reduced the growth of both varieties. A significant selective effect was found at 96 μM. Measurements of chlorophyll fluorescence-induction kinetics allowed to discriminate between the two varieties treated with 12 to 48 μM chlortoluron. The metabolism of chlortoluron was studied following absorption of 24 μM solutions. Both varieties produced the same pattern of metabolites but the tolerant variety degraded the herbicide and the phytotoxic mono-N-demethylated metabolite at a slightly higher rate. An unexpected result was that the more susceptible variety possessed a very significant ability to metabolize chlortoluron. In conclusion, it appears that further studies are necessary before deciding whether the differences in susceptibility of the two varieties can be explained by the only metabolic factor.     

DDT inhibition of Ca-ATPase of the peripheral nerves of the American lobster

A Ca-ATPase highly sensitive to DDT has been found in peripheral nerves of lobster, Homarus americanus. The observed I₅₀ for this Ca-ATPase toward DDT is on the order of 10^?9M and has a low temperature quotien. The ATPase seems to work over a wide range of ATP concentrations. It is stimulated by Ca²⁺ (optimum 0.1 mM) and shows sensitivity to Na⁺ (optimum 20 mM) and K⁺ (optimum 20 mM) ions. The fact that it is highly sensitive to ruthenium red (I₅₀ = 10 μM) suggests that the enzyme is a Ca-ATPase and not a Mg-ATPase. Furthermore the enzyme is not a CaMg-ATPase, since the presence of Mg²⁺ along with Ca²⁺ ion is not required for its activity. DDT is found to inhibit the process of Ca²⁺ binding in the axonic membrane only in the presence of ATP. The evidence suggests the important role of the Ca-ATPase in regulating Ca²⁺ concentrations in the membrane. The possible significance of DDT inhibition of the ATPase is discussed.     

Effects of β-pinene,a nonsubstituted monoterpene,on rat liver mitochondria

β-Pinene uncouples oxidative phosphorylation and inhibits respiration in isolated rat liver mitochondria. The uncoupling effects are observed at lower concentrations (100 to 200 μM) than the inhibition of respiration (400 μM). At low concentrations, the effects observed could be explained by an increase of the passive permeability of the mitochondrial membrane produced by the terpene. Higher concentrations seemed to inhibit respiration through an effect on the electron transport chain. At the highest concentrations tested (600 to 1200 μM), β-pinene seemed to produce a partial resealing of the mitochondrial membrane. All effects can be explained by the interaction of β-pinene with the mitochondrial membrane. Other hydrophobic molecules tested do not show the effects of β-pinene or limonene on mitochondria.     

Effects of herbicidal carbamates on mitochondria and chloroplasts

At concentrations near 2 × 10^?4M, barban, chlorpropham, and phenmedipham are inhibitors of the electron transfer in potato and mung bean mitochondria. The inhibition seems to be localized in the flavoprotein region. It affects preferentially the exogenous NADH dehydrogenation, in potato mitochondria (I₅₀, 10^?4M). Succinate dehydrogenation is less inhibited. At noninhibiting concentrations, the studied carbamates cannot uncouple the oxidative phosphorylations. Photosynthesis is completely inhibited by 2.10^?7M phenmedipham, 5 × 10^?5M barban, and 2 × 10^?4M chlorpropham. The inhibition takes place at the PS II level. Moreover, barban and chlorpropham are uncouplers of the photophosphorylations for concentrations between 5 × 10^?5 and 5 × 10^?4M. The effects observed on mitochondrial respiration can also be found on respiration of Acer cultured cells. The effects on isolated chloroplast photosynthesis are also observed for slightly higher concentrations on cultured Chlorella and on pea and oat leaf fragments.     

Degradation of acylanilide pesticides by Aspergillus niger

Aspergillus niger converts the herbicide 3′-chloro-2-methyl-p-valerotoluidide (solan) to 3′-chloro-4′-methylacetanilide and the fungicide 2,5-dimethylfuran-3-carboxanilide to acetanilide. The metabolites were formed by hydrolysis with an aryl acylamidase, followed by subsequent acetylation resulting in the corresponding acetanilides. Their structures were elucidated by mass spectrometric analysis and confirmed by comparison with synthetic compounds.     

Physiological actions of dinoterb,a phenol derivative: 2. Effects on isolated plant mitochondria and chloroplasts

Dinoterb, a contact herbicide, affects respiration and photosynthesis of mitochondria and chloroplasts. On mitochondria, at low concentrations, it acts as an uncoupler of oxidative phosphorylation; at higher concentrations, it inhibits the electron transport chains, probably before cytochrome c. On chloroplasts, dinoterb has a stimulatory effect on oxygen uptake in the reduced dichlorophenol-indophenol→methyl viologen couple; however, it is also an inhibitor of the Hill reaction and its site of inhibition is located before plastoquinone, near photosystem II.     

Metabolism of isopropyl carbanilate by soybean plants

Root-treated soybean plants absorb, translocate, and metabolize isopropyl carbanilatephenyl-¹⁴C (propham-¹⁴C). After a 3-day treatment period and removal of the exogenous ¹⁴C treating solution, only small concentrations of ¹⁴C-labeled materials were found in newly emerging tissues. A measurable concentration of radiocarbon was found in the seed pods, but the fruit tissues were shown to be free of any dectable ¹⁴C-labeling. Three days after removal of the exogenous propham-¹⁴C, the parent herbicide was completely metabolized by all tissues. Polar products and nonextractable residues were found in roots, stems, and leaves after a 3-day treatment period. The polar metabolites were not translocated once they were formed in either the roots or shoots.Conjugated polar metabolites were isolated, partially purified, and the prophamphenyl-¹⁴C moiety characterized. The aglycone moiety of the polar metabolites was liberated either by methanol-HCl solvolysis or by enzyme hydrolysis with β-glucosidase or hesperidinase. The aglycone from all three procedures was derivatized, purified and characterized by NMR, ir, and mass spectral analysis. The only aglycone was the derivative of isopropyl-2-hydroxycarbanilate which was at least in part conjugated as a glycoside.     

Potential involvement of alkoxyl and hydroxyl radicals in the peroxidative action of oxyfluorfen

The potential involvement of hydroxyl and alkoxyl radicals in the peroxidative action of the p-nitro diphenyl ether herbicides acifluorfen (5-[2-chloro-4-(trifluoromethyl)phenoxyl]-2-nitrobenzoic acid), acifluorfen-methyl (methyl ester of acifluorfen), nitrofen [2,4-dichloro-1-(4-nitrophenoxy)benzene], nitrofluorfen [2-chloro-1-(4-nitrophenoxy)-4-(trifluoromethyl)benzene], and oxyfluorfen [2-chloro-1-(3-ethoxy-4-nitrophenoxy)-4-(trifluoromethyl)benzene] was evaluated under laboratory conditions. Methional was added to illuminated thylakoids from peas (Pisum sativum L., cv Little Marvel) and its oxidation to ethylene was used as an indicator of hydroxyl and alkoxyl radical production. Oxyfluorfen stimulated the rate of methional oxidation by 138% at 10 μM and 175% at 1 mM. This oxyfluorfen-induced stimulation of the rate of methional oxidation was dependent on light, photosynthetic electron transport, and hydrogen peroxide since it was not observed under dark conditions or in the presence of DCMU and catalase. Addition of Fe-EDTA, a catalyst of the Fenton reaction, stimulated the oxyfluorfen-induced enhancement of methional oxidation sixfold, suggesting that hydroxyl radicals are synthesized through a Fenton reaction. Acifluorfen, nitrofen, and nitrofluorfen inhibited the rate of methional oxidation whereas acifluorfen-methyl had no effect on the rate of methional oxidation, even at high concentrations (1 mM). Nitrofluorfen at 1 mM was the only p-nitro diphenyl ether herbicide tested to inhibit photosynthetic electron transport of pea thylakoids. In experiments with pea leaf disks, acifluorfen at low concentrations stimulated the rate of methional oxidation, whereas acifluorfen-methyl, nitrofen, and nitrofluorfen had no effect. These data indicate that hydroxyl and alkoxyl radicals could be involved in the mechanism of cellular damage caused by oxyfluorfen but they are not important for the activity of the diphenyl ether herbicides acifluorfen, acifluorfen-methyl, nitrofen, and nitrofluorfen.     

The metabolism of the herbicide flamprop-isopropyl in barley

The metabolism of the wild oat herbicide, flamprop-isopropyl, [Barnon, isopropyl (±) N-benzoyl-N-(3-chloro-4-fluorophenyl)-2-aminopropionate] in barley grown to maturity has been examined under glass-house and outdoor conditions. [¹⁴C]Flamprop-isopropyl labeled separately in two positions was used. The major metabolic route of the herbicide was by hydrolysis to the corresponding carboxylic acid, II, which occurred in free and conjugated forms. Flamprop-isopropyl also underwent hydroxylation in the 3 and 4 positions of the benzoyl group, and the 3-hydroxybenzoyl analogue of II was detected. The hydroxylated metabolites were also present in the plants as conjugates. Additional minor metabolites detected only in glass-house samples were N-benzoyl-3-chloro-4-fluoroaniline, 2-[3-chloro-4-fluorophenylamino]-propionic acid, and benzoic acid. The soil in which the plants were grown received part of the spray application of the herbicide. Residues in the 0–10-cm layer at barley harvest comprised the unchanged herbicide, the carboxylic acid II, and unidentified polar material.     

Differential response of plant cell membranes to some vinyl organophosphorus insecticides

The response of plant cell membranes to vinyl organophosphorus insecticides was studied by determining the release of intracellular materials as a measure of membrane permeability and the uptake of [1-¹⁴C]-α-aminoisobutyric acid as a measure of active transport. A pretreatment with chlorfenvinphos (2-chloro-1-(2,4-dichlorophenyl)-vinyl diethyl phosphate) at 0.4 mM or higher concentrations increased the leakage of cell contents from the tissues of pea, corn, and beet, but two other vinyl organophosphorus insecticides, tetrachlorvinphos (2-chloro-1-(2,4,5-trichlorophenyl)-vinyl diethyl phosphate) and phosphamidon (2-chloro-2-diethyl carbamoyl-1-methyl vinyl dimethyl phosphate), had no effect. Simultaneous addition of phospholipids, β-sitosterol, or Ca²⁺ inhibited in varying degrees the chlorfenvinphos-induced permeability, suggesting that the leakage of cell contents might be due to alteration in membrane structure.Chlorfenvinphos or tetrachlorvinphos at 0.1 mM or higher concentrations inhibited the uptake of α-aminoisobutyric acid. The degree of inhibition varied with different plant species. The inhibition was competitive and was not prevented by phospholipids. However, Ca²⁺ and other divalent cations were stimulatory to the uptake of α-aminoisobutyric acid, either in the presence or absence of chlorfenvinphos. Chlorfenvinphos also inhibited plant growth in tobacco callus and pea stem assays.From the differences in effective concentration, structural requirement, and interaction with phospholipids, it is suggested that chlorfenvinphos affected the membrane permeability and active transport by different mechanisms. These effects probably underlie its inhibitory action on plant growth.