Reactivation of human acetylcholinesterase and butyrylcholinesterase inhibited by leptophos-oxon with different oxime reactivators in vitro.

We have evaluated in vitro the potency of 23 oximes to reactivate human erythrocyte acetylcholinesterase (AChE) and plasma butyrylcholinesterase (BChE) inhibited by racemic leptophos-oxon (O-[4-bromo-2,5-dichlorophenyl]-O-methyl phenyl-phosphonate), a toxic metabolite of the pesticide leptophos. Compounds were assayed in concentrations of 10 and 100 µM. In case of leptophos-oxon inhibited AChE, the best reactivation potency was achieved with methoxime, trimedoxime, obidoxime and oxime K027. The most potent reactivators of inhibited BChE were K033, obidoxime, K117, bis-3-PA, K075, K074 and K127. The reactivation efficacy of tested oximes was lower in case of leptophos-oxon inhibited BChE.

Developmental toxicity of desbromoleptophos in chicks: enzyme inhibition, malformations and functional deficits.

The relationship among inhibition of acetylcholinesterase (AChE), inhibition of neuropathy target enzyme (NTE), and developmental toxicity of the organophosphorus ester desbromoleptophos (DBL) was evaluated in chicks exposed on day 3 or day 15 of incubation or 10 days posthatching. DBL induced prolonged inhibition of AChE and NTE when administered either early or late in incubation, structural malformations if administered before organogenesis, posthatching paresis if administered after organogenesis, and delayed deficits of gait if administered after hatching. The posthatching paresis and abnormal gait are not determined solely by either AChE inhibition of NTE inhibition, since they occur in the absence of the latter and are not invariably seen in the presence of the former (Toxicology 49: 253-261; 1988).

Effects of fenthion, fenitrothion and desbromoleptophos on gait, acetylcholinesterase, and neurotoxic esterase in young chicks after in ovo exposure.

Previous studies have demonstrated that gait is affected in chicks exposed to organophosphorus esters (OPs) that induce delayed neurotoxicity (OPIDN) in adult hens. To investigate the developmental relationship between such functional deficits and OPIDN, chicks were exposed to 3 OPs with different OPIDN potential. Desbromoleptophos (DBL) induces OPIDN in adult hens; fenthion (FEN) has uncertain OPIDN potential; fenitrothion (FTR) does not induce OPIDN. Chicks were treated by injection into the egg on day 15 of incubation, after the presumed period of OP-induced structural teratogenesis. AChE and neurotoxic esterase (NTE) were assayed during incubation and in parallel with post-hatching evaluations of gait. DBL, 125 mg/kg in ovo, caused paralysis in 70% of chicks after hatching. The gait of surviving chicks was affected for at least 6 weeks and marked by toes curling under. NTE was inhibited until 10 days post-hatching and AChE until hatching. FEN did not inhibit NTE significantly, but AChE was significantly inhibited until hatching. Chicks exposed as embryos to FEN were hyperactive and aggressive. Gait was still affected 6 weeks after treatment with 3 mg/kg FEN. FTR at 125 mg/kg inhibited AChE until day 10 post-hatching, but neither inhibited NTE nor affected gait. The growth of OP-exposed chicks was not significantly decreased, so the decreased length and increased width of the stride could not be ascribed to stunted growth. We conclude that OPs cause irreversible effects on gait that are not related to their defined neurotoxic effects, since altered gait (1) occurs below the age of sensitivity to OPIDN, (2) is seen in the absence of NTE inhibition and (3) does not invariably accompany AChE inhibition.

Effects of multiple dosing of fenthion, fenitrothion, and desbromoleptophos in young chicks.

The effects of multiple doses of desbromoleptophos, fenitrothion, and pure fenthion on brain acetylcholinesterase (AChE), brain neurotoxic esterase (NTE), and walking were investigated in immature chicks, below the age of sensitivity to organophosphorus ester-induced delayed neurotoxicity (OPIDN). Ten milligrams per kilogram per day of delayed neurotoxicant desbromoleptophos (DBL), 15 mg/kg.d of the non-neurotoxicant fenitrothion (FTR), and 3 mg/kg.d of the suspected neurotoxicant fenthion (FEN) were given orally for 7 d to 3-d-old chicks. Behavioral testing was performed for treated and control chicks on various days after treatment. Brain NTE and AChE assays were carried out for treated and control chicks on each day of behavioral testing. DBL altered gait and inhibited both NTE and AChE; FEN altered gait and inhibited AChE but not NTE; and FTR did not affect gait, while inhibiting AChE but not NTE. NTE and AChE inhibition were 70% and 55%, respectively, 24 h after the last treatment, for the chicks treated with DBL. NTE returned to normal levels by around d 25 and AChE by 20 d after the last treatment. FTR caused more than 50% AChE inhibition but no NTE inhibition, 24 h after last treatment. NTE inhibition for the FEN-treated chicks never exceeded 11% during the whole period of the experiment, whereas 54% inhibition of AChE was seen 1 d after last treatment. DBL and FEN significantly altered the gait of treated chicks, but the non-OPIDN-inducing FTR did not. This study confirms that alterations in the gait of young chicks are not direct consequences of either NTE or AChE inhibition, and that fenthion-induced functional deficits can be distinguished from classical OPIDN.

Acute and delayed effects of fenthion in young chicks.

The effects of desbromoleptophos, fenitrothion, and fenthion on brain acetylcholinesterase (AChE), brain neurotoxic esterase (NTE), and walking were investigated in immature chicks, below the age of organophosphorus ester-induced delayed neurotoxicity (OPIDN). Seventy-five milligrams per kilogram of the delayed neurotoxicant desbromoleptophos (DBL) and 100 mg/kg of the nonneurotoxicant fenithrothion (FTR) were given orally to 8-d-old chicks. Five milligrams per kilogram of the suspected neurotoxicant fenthion (FEN) was administered topically for 7 d, in 4 different age groups. Behavioral testing was performed for treated and control chicks on various days after treatment. Brain NTE and AChE assays were carried out for treated and control chicks on each day of behavioral testing. NTE and AChE inhibition were around 80 and 50%, respectively, 24 h after treatment, for the chicks treated with DBL. NTE returned to normal levels by 20 d and AChE by 6 d after treatment. FTR caused 56% AChE inhibition but not NTE inhibition 24 h after treatment. NTE inhibition for the FEN-treated chicks never exceeded 25% during the whole period of the experiment, whereas 65 and 54% inhibition of AChE was seen in two age groups. DBL and FEN significantly altered the gait of treated chicks, but the non-OPIDN-inducing FTR did not. FEN-treated chicks developed an atypical ataxia at the normal age for onset of sensitivity to OPIDN. Minimal NTE inhibition, long latency for the development of ataxia, and immaturity of the chicks at treatment distinguish FEN-induced functional deficits from classical OPIDN.

The toxic and teratogenic effects of selected organophosphorus compounds on the embryos of three species of amphibians.

The toxic and teratogenic effects of 4 organophosphorus compounds (phenyl saliginen cyclic phosphate (PSCP), leptophos-oxon (LPTO), tri-o-tolyl phosphate (TOTP), and paraoxon (PXN] were investigated in the embryos of 3 species of frogs. Developmental abnormalities were observed in surviving embryos of each of the 3 species following exposure to PSCP at concentrations as low as 500 ppb for 24 h. LPTO, while being toxic to gray treefrog embryos at concentrations as low as 2.2 ppm, did not induce developmental abnormalities. TOTP and PXN were neither toxic nor teratogenic at concentrations of 10 ppm and 100 ppm respectively.

In vitro neurotoxic esterase assay using leptophos oxon analogs as inhibitors.

In comparing neurotoxic esterase (NTE) inhibition properties of a series of phenylphosphonates, it was discovered that certain compounds including leptophos inhibited mipafox-insensitive phenylvalerate hydrolases. This leads to erroneous values for NTE inhibition which can be corrected by a differential assay: the total amount of mipafox-insensitive activity is determined with O-(2,6-dichlorophenyl)O-methyl phenylphosphonate and subtracted from the apparent NTE determined with the test compound before calculating pI50's.

Assay of chicken brain neurotoxic esterase activity using leptophosoxon as the selective neurotoxic inhibitor.

Hen brain microsomal preparation has phenyl valerate-hydrolyzing activity associated with neurotoxic esterase activity. Part of that activity is due to paraoxon-insensitive esterases and a sub-part of this is sensitive to neurotoxic organophosphates, i.e., mipafox and leptophosoxon. This neurotoxic agent sensitive esterase activity is referred to as neurotoxic esterase (NTE). Because of the commercial unavailability and high toxicity of mipafox, which is usually used as the selective inhibitor for assaying NTE, leptophosoxon was used as an alternative to mipafox. Results indicated that the NTE fraction of hen brain microsomal PV-hydrolyzing activity is the same target for either mipafox or leptophosoxon. The inhibitory effect of leptophosoxon against that fraction was much higher than that of mipafox. The availability of leptophos/leptophosoxon makes this assay very useful for screening organophosphorus esters for neurotoxic effects.

The neuropathology of leptophos in the hen: a chronologic study.

Recent investigation into a possible association between exposure to Leptophos and neurological symptoms in insecticide factory workers makes study of the neurological effects of Leptophos in the experimental situation particularly important. The present study utilizes a single oral dose of 200 mg/kg of Leptophos in 20 chickens which are sacrificed in pairs to define the temporal sequence of changes in the sciatic nerve, its major branches, and the spinal cord and to correlate these findings with the clinical symptoms of the animals. At this dose Leptophos produces degeneration of the spinal cord in a pattern similar to that seen with tri-o-cresyl phosphate (TOCP). The ataxia seen in these birds is probably due to the posterior and lateral column involvement. At this dose onset of paralysis correlates roughly with both the degeneration of the anterior descending tract of the spinal cord and degeneration of the peripheral nerve. The minimal degree of nerve involvement suggests that the cord lesion is more significant at this dose in the hen. Using TOCP, spinal cord lesions predominate in the hen while the peripheral nervous system appears more sensitive in the human and non-human primate. Assuming that Leptophos resembles TOCP in this regard, peripheral nerve damage would be the expected earliest change, especially in the low-dose situation in the human.