O,O,S-Trimethyl phosphorothioate effects on immunocompetence

O,O,S-Trimethyl phosphorothioate (OOS), a contaminant of technical formulations of some organophosphorus pesticides, was found to be immunotoxic at subtoxic doses in female C57Bl/6 mice. Mice treated orally with acute doses of 10 mg/kg OOS show no overt toxic signs such as weight loss or malaise. In addition, the levels of serum cholinesterase was not decreased. Histopathologic investigation demonstrated no alterations in liver, lung, kidney, heart, skin, brain, spleen, or gut. The LD₅₀ for delayed toxicity was approximately 35 mg/kg. Despite the lack of general toxic changes at doses of 5–10 mg/kg OOS, specific immunotoxic changes were found. The humoral or cell-mediated immune response of splenocytes from mice treated with 10 mg/kg OOS to in vivo immunization was diminished with respect to control animals. Responses were measured in ex vivo assays. Cytotoxic T-lymphocyte (CTL) responses were assessed by alloimmunization with the tumor P815 followed by a ⁵¹Cr release assay done ex vivo with splenic lymphocytes. Humoral responses were assessed by immunization with sheep red blood cells followed by a Jerne plaque assay to determine anti-sheep red blood cell antibody. Both cellular and humoral responses could be stimulated in vitro using cells from OOS-pretreated, primed animals, thus indicating that no permanent cellular elterations had occurred.     

Metabolism of O,O,S-trimethyl phosphorothioate in rats after oral administration of a toxic dose,and the effect of coadministration of its antagonistic thionate isomer

The in vivo metabolism of [¹⁴CH₃S]- and [¹⁴CH₃O]O,O,S-trimethyl phosphorothioate (OOS) was followed in rats after oral administration of threshold or LD₅₀ toxic doses of 20 or 60 mg/kg. Similar metabolic studies were conducted with coadministration of 1% O,O,O-trimethyl phosphorothionate (OOO), which prevented all signs of delayed toxicity, including weight loss. When administered alone, OOS was metabolized mainly (50–60%) via removal of the CH₃S moiety, which was largely converted to expired CO₂. Approximately 20% of the compound was O-demethylated, presumably by conjugation with glutathione, and then further metabolized to CO₂. Major urinary products were identified as O,O-dimethyl phosphoric acid (50–60%) and O,S-dimethyl phosphorothioic acid (～20%). Coadministration of OOO caused a slight decrease (～5%) in the cleavage of the CH₃S moiety, indicated by a reduction in ¹⁴CO₂ from [¹⁴CH₃S]OOS and a quantitatively similar increase in the formation of O,S-dimethyl phosphoric acid. Limited pharmacokinetic studies indicated that OOS was rapidly absorbed and distributed throughout the body. Coadministration of 1% OOO caused a slight increase in the blood half-life of parent OOS when administered at 60 mg/kg. It was concluded that a small proportion of the cleavage of the CH₃S moiety from OOS is involved in the intoxication process, and that this intoxication reaction is specifically inhibited by OOO.     

Physiological responses of corn (Zea mays) to AC 243,997 in combination with valine,leucine, and isoleucine

Various physiological processes were measured in corn after treatment with AC 243,997. Neutral sugar levels in leaves increased 39% over the control 24 hr after application of AC 243,997. Protein synthesis, measured by [¹⁴C]leucine and [¹⁴C]cystine incorporation, and lipid synthesis were not inhibited 24 hr after application of 150 μM of AC 243,997, while respiration and RNA synthesis were inhibited 32 and 15%, respectively. DNA synthesis was severely inhibited (70–90%) by 150 μM of the herbicide 24 hr after application. The inhibition of DNA synthesis by AC 243,997 did not begin until 5 to 7 hr after application. Although protein synthesis rates were apparently unaffected by AC 243,997, the level of the soluble proteins decreased 40% while free amino acid levels increased 32% 24 hr after application of the herbicide. An exogenous supply of valine, leucine, and isoleucine to corn prevented the inhibition of growth and reversed the inhibition of DNA synthesis caused by AC 243,997. All three amino acids at a concentration of 1 mM were needed to provide maximum protection. The results support the hypothesis that AC 243,997 kills plants by interfering with the biosynthesis of valine, leucine, and isoleucine.     

In vitro effects of malathion and O,O,S-trimethyl phosphorothioate on cytotoxic T-lymphocyte responses

Oral administration of O,O,S-trimethyl phosphorothioate (OOS), an impurity present in technical formulations of malathion, has been shown to be associated with a high incidence of pneumonia in rats and to be highly immunosuppressive in mice. Based on these findings, an in vitro model was established to study the effect of this and other organophosphorus compounds on murine cytotoxic T-lymphocyte (CTL) responses. The organophosphorus compounds were tested for their ability to block in vitro generation of CTL responses to alloantigen and/or the expression of these cytotoxic responses. Responses were generated in C57Bl/6 (H-2^b) spleen cells to mitomycin C-blocked P815 (H-2^d) tumor cells. The cytotoxicity of the cultured splenocytes to P815 target was measured using a 4-hr chromium release assay. These data demonstrated that malathion was able to block the ability of splenocytes to sensitize to P815 at concentrations as low as 25 μg/ml, but was not able to block the expression of cytotoxicity by mature killer T cells. The same was true for OOS which had been activated by preincubation with rat liver postmitochondrial supernatant (PMS). Activated OOS blocked the generation of CTL responses at concentrations as low as 75 μg/ml while having no effect on mature cytotoxic cells. In fact, both malathion and activated OOS were no longer able to suppress CTL responses if treatment was performed as early as 24 hr after exposure to antigen. Additionally, it was demonstrated that when malathion was preincubated with PMS it was no longer suppressive and that OOS without activation failed to suppress CTL responses.     

Herbicide perfluidone (1,1,1-trifluoro-N-[2-methyl-4-(phenylsulfonyl)phenyl]methanesulfonamide): Its metabolism in rats and chickens

Rats and chickens were each given a single oral dose (10 or 100 mg/kg body wt) of 1,1,1-trifluoro-N-[2-methyl-4-(phenylsulfonyl)phenyl-¹⁴C(U)]methanesulfonamide ([¹⁴C]perfluidone). Depending on the size of the dose, from 8.4 to 36.2% of the [¹⁴C] was eliminated in the urine and from 36.4 to 85.4% was eliminated in the feces within 48 hr after dosing. Less than 1% of the [¹⁴C] given to laying hens as [¹⁴C]perfluidone was present in the eggs produced during the first 96 hr after dosing. The percentage of the administered [¹⁴C] that remained in these animals (body with G.I. tract and contents removed) varied from 0.34 (96 hr after dosing) to 1.68% (48 hr after dosing). ¹⁴C-labeled compunds in the urine and feces from the rats and chickens were purified by solvent extraction, column chromatography, and gas-liquid chromatography, and then identified by infrared and mass spectrometry. The parent compound was the major ¹⁴C-labeled component in the urine and feces of both animals. 1,1,1-Trifluoro-N-[2-methyl-4-(3-hydroxyphenylsulfonyl)phenyl]methanesulfonamide was present in the feces of both animals. The proposed structures of other metabolites were 1,1,1-trifluoro-N-hydroxy-N-[2-methyl-4-(phenylsulfonyl)phenyl]methanesulfonamide (rat urine) and 1,1,1-trifluoro-N-{2-methyl-4-[(methylsulfonyl)-phenylsulfonyl]phenyl}methanesulfonamide (chicken urine).     

Delayed acute toxicity of O,S,S-trimethyl phosphorodithioate and O,O,S-trimethyl phosphorothioate to the rat

The toxicity and LD₅₀ of O,S,S-trimethyl phosphorodithioate were reexamined in the rat. Animals treated orally (single dose) with this compound exhibited early cholinergic signs followed at approximately 5 hr by delayed toxic signs, with an LD₅₀ of 43 mg/kg. Contamination of O,S,S-trimethyl phosphorodithioate by as much as 5% (w/w) O,O,O-trimethyl phosphorothioate provided only limited antagonism to the dithioate's toxicity. In contrast, the addition of 5% O,O,S-trimethyl phosphorodithioate to O,O,S-trimethyl phosphorothioate gave protection against the toxic effects of the latter compound up to 80 mg/kg of toxicant. Pretreatment of rats with as little as 5% O,O,O-trimethyl phosphorothioate, 24 hr prior to treatment with 200 mg/kg O,O,S-trimethyl phosphorothioate, gave complete protection against the toxic effects of this compound. Conversely, administration of 10% (w/w) O,O,O-trimethyl phosphorothioate 4 or 24 hr after treatment with 60 or 80 mg/kg of O,O,S-trimethyl phosphorothioate provided only partial protection at 4 hr and no protection from the effects of the toxicant at 24 hr. The ability of O,O,O-trimethyl phosphorothioate to antagonize the toxicity of this compound depended markedly on the route of administration (oral, intravenous, or intraperitoneal). At 4 hr past treatment with toxicant, only oral administration of the antagonist provided full protection. Intraperitoneal and intravenous administration of antagonist 4 hr after treatment with toxicant were partially effective and completely ineffective, respectively, in halting the toxic effects of this compound.     

The effect of α-hexachlorocyclohexane on liver growth in intact and adrenalectomized rats

α-Hexachlorocyclohexane was administered as a single oral dose (100 mg/kg body wt) to both intact and adrenalectomized male Sprague-Dawley rats. In the intact rats there was a peak in [³H]thymidine incorporation into DNA at 30 hr and an increase in relative liver weight (liver weight/body wt × 100) which peaked at 60 hr post α-HCH dose. However, in α-HCH-dosed adrenalectomized rats [³H]thymidine incorporation into DNA remained elevated throughout the study period and relative liver weight was not significantly increased. In corticosterone-supplemented α-HCH-dosed Adx rats, [³H]thymidine incorporation into DNA was significantly reduced and RLW was increased comparable to that seen in intact animals. These results suggest that α-HCH-induced liver growth is mediated by corticosterone.     

Adrenalectomy and the adaptive liver response in mirex-treated rats

Mirex, an organochlorine compound, was administered as a single oral dose (100 mg/kg body wt) to both intact and adrenalectomized juvenile male Sprague-Dawley rats. Both mirex-treated intact and adrenalectomized animals (dosed 24 hr postsurgery) exhibited significant increases in liver weight to body weight ratios compared to controls. However, the liver weight to body weight ratios in mirex-treated intact animals were significantly greater than those observed in mirextreated adrenalectomized animals. Significant increases were observed in liver weight to body weight ratios in adrenalectomized animals treated with mirex 4 days after surgery. However, the 96-hr mortality in mirex-treated adrenalectomized animals increased from 20% (mirex dose given 1 day postadrenalectomy) to 56% (mirex dose given 4 days postadrenalectomy). Mirex treatment of intact and adrenalectomized animals had no significant effect upon either serum or hepatic activities of glutamic oxalacetic transminase, glutamic pyruvic transaminase, sorbitol dehydrogenase, or protein concentrations. Bromsulfophthalein clearance also was not affected by mirex treatment in adrenalectomized animals. Serum glucose concentrations were significantly decreased in both intact and adrenalectomized animals by mirex treatment. Daily corticosterone supplements to adrenalectomized animals restored liver hypertrophy and serum glucose concentrations to levels observed in mirex-treated intact animals. These results suggest that mirex-induced liver enlargement may be mediated by corticosterone.     

Cholinesterase inhibition by methamidophos and its subsequent reactivation

Methamidophos (O,S-dimethylphosphoramidothioate, Monitor) is an organophosphorus, cholinesterase-inhibiting insecticide. The rate constant (k_i) for inhibiting rat plasma cholinesterase (ChE) was 1.57 ± 0.03 × 10³M^?1 min^?1, for rat erythrocyte ChE was 8.86 ± 1.10 × 10³M^?1 min^?1, and for rat brain ChE was 6.58 ± 0.42 M^?1 min^?1. Brain and plasma cholinesterases spontaneously recovered from over 90% inhibition at 30 min to 50% inhibition in 4 and 14 hr, respectively. Pralidoxime increased the rate of reactivation in vitro. In vivo, rats poisoned with methamidophos exhibited signs of cholinergic stimulation. The LD₅₀ of ip methamidophos in male rats was 15 ± 0.7 mg/kg. Pralidoxime (60 mg/kg) and atropine (10 mg/kg) given with the methamidophos increased the LD₅₀ to 52 ± 4.9 mg/kg and 60 ± 0.4 mg/kg, respectively. In rats given 12.5 mg methamidophos (an LD₂₀), ChE activity was depressed 95 ± 12.5% in plasma, 92 ± 0.6% in stomach, and 88 ± 1% in brain at 1 hr after injection. At 48 hr after injection ChE activity had returned to 60% or more of control values in each of the tissues. Administration of a single dose of 60 mg/kg of pralidoxime along with methamidophos did not increase ChE activities at the times and places it was measured.     

Phototoxicity of the allelochemical, α-terthienyl,to larvae of Manduca sexta (L.) (Sphingidae)

α-Terthienyl, a common chemical constituent in the Asteraceae, was administered to fifth-stadium larvae (Day 1) of the tobacco hornworm, Manduca sexta (L.) (Sphingidae), by incorporation into artificial diet and by topical application. Toxicity toward larvae was elicite by simultaneous exposure to this allelochemical and uv-A irradiation (320–400 nm). Larval treatment with either α-terthienyl or uv-A irradiation alone caused no apparent adverse effects. A single, ingested dose of α-terthienyl (50 μg g larval weight^?1), followed by irradiation for 4 hr, resulted in delayed and abnormal pupal formation with no subsequent adult emergence. Topical application of the plant compound (50 μg g^?1) and uv-A irradiation led to tissue necrosis that affected both sclerotization and melanization of the pupal case in later development.     

Non-target toxicology of a new mosquito larvicide, trypsin modulating oostatic factor

Trypsin modulating oostatic factor (TMOF), a peptide hormone originally isolated from the ovaries of adult Aedes aegypti, is currently under commercial development as a new pesticide chemistry with a novel mode of action for the control of larval mosquitoes. The objective of the current research is to evaluate potential risks of the use of TMOF as an insecticide on non-target organisms. TMOF (YDPAP₆) was degraded in vitro (as determined by HPLC and LC/MS) to DPAP₆, PAP₆, and then AP₆ by leucine aminopeptidase, a pancreatic enzyme found in the digestive system of vertebrates. The rate of degradation of TMOF and PAP₆ was significantly greater than that of DPAP₆, while no metabolism of AP₆ was found. TMOF technical insecticide was produced on a commercial scale by recombinant yeast (heat-killed before application). The technical TMOF when administered in a single dose by gavage to male and female mice at 2000 mg dry weight/kg body weight produced no negative effects as compared to controls up to 12 days after treatment. When male and female mallard ducks were treated by gavage with 1250 mg dry weight of technical TMOF/kg body weight each day for 5 days, again no toxic effects were noted through 35 days after the last treatment. TMOF technical insecticide was also applied to the shaved skin of male and female rabbits at the rate of 2000 mg/kg for 1-2 days, with no effect. The end point observations in these in vivo experiments were mortality; changes in growth rate, behavior, body structure, and color; and possible lesions observed during necropsy. Finally, Daphnia incubated with technical TMOF in rearing water at the level of 1.0 × 10⁶ yeast cells/ml (10 mg/ml) also demonstrated no negative effects on mortality, growth, molting, time to first brood, and production of viable neonates. It appears from these studies that TMOF can be degraded by vertebrate digestive proteases and technical TMOF is not toxic to the non-target organisms examined.     

Antifungal mode of action of imazalil

Imazalil had no effect on the initial growth of mycelia of Penicillium italicum (for 10 hr) or Aspergillus nidulans (for 2 hr). In P. italicum during this period neither respiration nor cell permeability was affected, but uptake of [³²P]phosphate, [¹⁴C]leucine, or [¹⁴C]uridine was partially inhibited. The initial (5 hr) inhibition of substrate uptake coincided with a 50% reduction in ergosterol content. Within 0.5 hr, incorporation of [¹⁴C]acetate into C-4-desmethyl sterols was strongly inhibited in mycelia of A. nidulans treated with 0.5 μg/ml of imazalil. However, radioactivity in C-4-methyl and dimethyl sterols exceeded that of control cultures. Concentrations of imazalil as low as 0.005 μg/ml caused short-term (1 hr) declines of incorporation into desmethyl sterols and increases into the C-4-methyl and dimethyl sterols. Incorporation into phospholipids, triglycerides, and free fatty acids was not affected. These data suggest that the primary antifungal action of imazalil is inhibition of demethylation in the biosynthesis of ergosterol.     

Effect of hepatic enzyme inducers on the in vivo and in vitro metabolism of dicrotophos,dimethoate, and phosphamidon in mice

Daily 75 mg/kg phenobarbital ip injections for 3 days or 25 ppm dieldrin in the diet of mice for 14 days caused an increase in liver cytochrome P-450 and blood B-esterase. Liver A-esterase was not significantly increased. Under in vitro conditions, phenobarbital and dieldrin induced the oxidative as well as hydrolytic metabolism of dicrotophos, dimethoate, and phosphamidon by liver homogenates or combined microsomes plus 105,000g supernatant fractions. The concentration of dimethoxon was increased more than fourfold by the pretreatments after incubation for 4 hr at 37.5°C with NADPH added. The organophosphorus insecticides used in this study were not metabolized as well by the liver microsomes alone or 105,000g supernatant alone, as by the combination of microsomes and 105,000g supernatant. Under in vivo conditions in mice, phenobarbital and dieldrin treatments increased the urinary recovery of metabolites in the initial 6 hr after [¹⁴C]carbonyl-dimethoate or [¹⁴C]N-ethyl-phosphamidon administration. Analysis of urine showed that the inducers caused a more than sixfold increase in dimethoxon recovered and twofold increase in water-soluble nontoxic metabolites within 6 hr after dimethoate administration. With phosphamidon both inducers increased the rate of metabolism, and the total recovery in aqueous and chloroform fractions was decreased. These results suggest that increased dimethoate toxicity after phenobarbital and dieldrin treatments in whole animals results from stimulation of the activation of dimethoate to dimethoxon, while the increase in hydrolytic products after both pretreatments results in decreased toxicity of the direct acetylcholinesterase inhibitors, dicrotophos and phosphamidon.     

Influence of methabenzthiazuron on ATP-level and protein synthesis in wheat

Spring wheat (Triticum aestivum L. “Kolibri”) was grown in vermiculite treated with the photosynthesis inhibiting herbicide methabenzthiazuron (1-(benzothiazol-2-yl)-1,3-dimethylurea) either before germination or when the plants were 13 days old. The plants were analyzed from 2 days before until 11 days after treatment or up to a plant age of 23 days.The results are interpreted to fit the concept of a “shade adaptation reaction” caused by a herbicidal photosynthesis inhibition. Soluble reducing sugars have been found to decrease 4 hr after treatment and to stay at a low level throught the experiment. The ATP level was decreased 1 day after treatment but increased above control values 4 days later. This increase was accompanied by a decrease of the chlorophyll $\text{a}\text{b}$ ratio. The explanation is given that the ATP level was first decreased because of a lowered carbohydrate supply for substrate and oxidative phosphorylation, and was afterwords increased as a result of an increased cyclic photophosphorylation activity.The soluble protein content and the incorporation of [¹⁴C]leucine into protein were increased 4 days after herbicidal treatment. The total protein was slightly decreased beginning 1 day after treatment. The nitrate concentration and the in vitro nitrate reductase activity were both increased 1 day after treatment. The increase of the nitrate concentration occurred in two phases: a first increase by 50% 1 and 2 days after treatment and a second, much stronger increase beginning on the third day. The first increase is interpreted as the result of a decreased in vivo nitrate reductase activity. The second increase possibly was the result of an increased rate of nitrate uptake.     

Rapid effects of a thiocarbamate herbicide and its dichloroacetamide protectant on macromolecular syntheses and glutathione levels in maize cell cultures

The rapid effects of the thiocarbamate herbicide S-ethyl dipropyl thiocarbamate (EPTC) and the herbicide protectant N,N-diallyl-2,2-dichloroacetamide (DDCA) on macromolecular syntheses and glutathione (GSH) levels in maize cell cultures were studied to determine whether stimulation of GSH could be the primary mechanism of action of DDCA. EPTC (0.5 and 1 mM) reduced incorporation of radioactive precursors within 1 hr after treatment, and affected incorporation of [³H]acetate into lipids more than incorporation of [³H]adenosine into acid-precipitable nucleic acids, or [¹⁴C]protein hydrolysate into protein. [¹⁴C]EPTC was rapidly biotransformed within 8 hr by maize cell suspensions. Measureable decreases in GSH levels following treatment with 1 mM EPTC occurred after 15 hr. DDCA stimulated incorporation of [³H]acetate into lipids within 4 hr but did not affect incorporation of [¹⁴C]protein hydrolysate into protein or [³H]adenosine incorporation into nucleic acids. Measureable increases in GSH following DDCA treatment began after 12 hr. Treatment with EPTC and DDCA in combination inhibited incorporation of [³H]acetate into lipids less than EPTC given alone. Increases in GSH levels could be observed following pretreatments with glutathione precursors, but no protectant activity could be detected, in contrast to treatments with DDCA. It is suggested that DDCA has an initial rapid effect on lipid metabolism followed by a slower effect involving increases in cellular GSH.     

Effects of herbicides and herbicide analogs on [14C]leucine incorporation by suspension-cultured Solanum nigrum cells

Assays of [¹⁴C]leucine incorporation were used to measure effects of herbicides on suspensioncultured heterotrophic Solanum nigrum cells. Most herbicidal vs. nonherbicidal chemicals in a set of 47 compounds could be distinguished from each other based on their extent of inhibition of leucine incorporation by S. nigrum cells. Herbicides which failed to inhibit leucine incorporation were photosynthetic inhibitors. Both phytotoxic and nonphytotoxic thiocarbamate analogs (as determined by whole-plant studies) tended to inhibit leucine incorporation. It was concluded that the leucine incorporation screen could detect a majority of compounds tested which are herbicidal, and that it may also be useful to detect compounds which have cellular toxicity which is not observed in the whole plant.     

Enhanced excretion of DDT and metabolites in rats treated with trans,trans-muconate

The interactions between trans,trans-muconate and p,p′-DDT were examined. Male Wistar rats were injected intraperitoneally with 6.67 mg kg^?1 [¹⁴C]p,p′-DDT. Two hours later the experimental animals received orally a solution of sodium muconate (75 mg kg^?1, 0.3 ml) in physiological saline, pH 7.2; control animals received an equal volume of physiological saline. Treatment was repeated every 12 hr for 10 days. Sodium muconate does not modify urinary excretion of labeled compounds, yet it reduces body burden by accelerating the excretion rate of these compounds in rat feces. This action was observed only during the first 24 hr after the animals were exposed to p,p′-DDT.     

Alkylation of guanine in mice in vivo by organophosphorus insecticides. I. Trichlorphone and butonate

Following intraperitoneal administration to male mice of trichlorphone, 4 mg/animal = 160 mg/kg and butonate, 5 and 10 mg/animal = 200 and 400 mg/kg, labeled by ¹⁴C in the OCH₃-groups, nucleic acids taken from different organs and urine were analyzed for [7-¹⁴C]methylguanine. The limit of detection was 2 × 10^?8, calculated as ¹⁴C relative to the total dose. The maximum of ¹⁴C in 7-methylguanine was 2 × 10^?7 in lung, kidney, and testicles and 3 × 10^?6 in liver. The excretion rate of 7-MeG from nucleic acids is very rapid, a halflife of 2.0 hr was measured in liver from butonate and of < 24 hr was calculated in the whole body from trichlorphone, contrary to the excretion rate of 3.0–3.5 days following administration of strongly genotoxic agents. The relative amounts of [7-¹⁴C]methylguanine excreted in the urine were determined and compared with data for dichlorvos, dimethyl sulfate, and methyl methanesulfonate from the literature. Following intraperiotoneal administration, the methylating capability towards N-7 of guanine in nucleic acids is given by the ratio of about 100:10:25 for dichlorvos, butonate, and trichlorphone, respectively.     

Mercapturic acid formation in the metabolism of propachlor,CDAA, and fluorodifen in the rat

When [¹⁴C]F₃-fluorodifen (2,4′-dinitro-4-trifluoromethyl diphenylether), carbonyl-[¹⁴C]CDAA (N,N-diallyl-2-chloroacetamide), and carbonyl-¹⁴C-propachlor (2-chloro-N-isopropylacetanilide) were fed to rats, 57 to 86% of the ¹⁴C was excreted via the urine within 48 hr. Although very little radioactivity was excreted in the feces of CDAA-treated rats, 15–22% of the ¹⁴C was excreted in the feces of propachlor- of fluorodifentreated rats and an average of 8% of the ¹⁴C remained in these rats 48 hr after treatment. Oxidation of the ¹⁴C label to [¹⁴C]O₂ was not a major process in the metabolism of these herbicides. The only major radioactive metabolite present in the 24-h urine of fluorodifen-treated rats, 2-nitro-4-trifluoromethylphenyl mercapturic acid, accounted for 41% of the administered dose of ¹⁴C. In the metabolism of CDAA, the corresponding mercapturic acid accounted for 76% of the dose; it was the only major metabolite present in the 24-h urine. In contrast, three major metabolites were detected in the 24-h urine of propachlortreated rats, and the mercapturic acid accounted for only 20% of the dose. The mercapturic acid of each herbicide was identified by mass spectrometry.     

Residues in blackcurrants,fodder peas,spinach and potatoes treated with sublethal doses of 2,4,5-T to simulate wind drift damage

Blackcurrants, treated with 0.1 kg of 2,4,5-T ha^?1 (as esters of mixed C₄–C₆ alcohols; ‘Tormona 80’), contained 0.1 mg of 2,4,5-T residues kg^?1 in the berries at ripeness 29 days after treatment. Total residues in the berries were not reduced during growth and ripening, although the residue concentrations declined in the same period due to growth dilution. In spinach leaves from old plants, treated with 0.1 kg ha^?1, 0.05 mg of 2,4,5-T kg^?1 was found 14 days after treatment. Fodder peas showed no residues (< 0.002 mg kg^?1) at harvest 62 days after treatment with 2,4,5-T esters. After application of 0.1 kg ha^?1 on potato plants, the disappearance of 2,4,5-T was rapid during the first month, but residues were translocated into the tubers and reached a constant level of 0.02 mg kg^?1 after 1 month until harvest at 108 days after treatment. In all crops, visible effects were observed after treatment with 0.1 kg ha^?1. After the application at 0.01 kg ha^?1, phytotoxic effects were observed only in blackcurrants, but negligible residues were found in all the test crops.