Anomalous biochemical responses in tests of the delayed neuropathic potential of methamidophos (O,S-dimethyl phosphorothioamidate), its resolved isomers and of some higher O-alkyl homologues

In vitro study of the neuropathic potential of the organophosphorus compounds fenamiphos and profenofos: Comparison with mipafox and paraoxon

Organophosphorus-induced delayed neuropathy (OPIDN) is a central-peripheral distal axonopathy that develops 8-14 days after poisoning by a neuropathic organophosphorus compound (OP). Several OPs that caused OPIDN were withdrawn from the agricultural market due to induction of serious delayed effects. Therefore, the development of in vitro screenings able to differentiate neuropathic from non-neuropathic OPs is of crucial importance. Thus, the aim of this study was to evaluate the differences in the neurotoxic effects of mipafox (neuropathic OP) and paraoxon (non-neuropathic OP) in SH-SY5Y human neuroblastoma cells, using the inhibition and aging of neuropathy target esterase (NTE), inhibition of acetylcholinesterase (AChE), activation of calpain, neurite outgrowth, cytotoxicity and intracellular calcium as indicators. Additionally, the potential of fenamiphos and profenofos to cause acute and/or delayed effects was also evaluated. Mipafox had the lowest IC50 and induced the highest percentage of aging of NTE among the OPs evaluated. Only mipafox was able to cause calpain activation after 24 h of incubation. Concentrations of mipafox and fenamiphos which inhibited at least 70% of NTE were also able to reduce neurite outgrowth. Cytotoxicity was higher in non-neuropathic than in neuropathic OPs while the intracellular calcium levels were higher in neuropathic than in non-neuropathic OPs. In conclusion, the SH-SY5Y cellular model was selective to differentiate neuropathic from non-neuropathic OPs; fenamiphos, but not profenofos presented results compatible with the induction of OPIDN.

Japanese quail acute exposure to methamidophos: experimental design, lethal, sub-lethal effects and cholinesterase biochemical and histochemical expression

We exposed the Japanese quail (Coturnix coturnix japonica) to the organophosphate methamidophos using acute oral test. Mortality and sub-lethal effects were recorded in accordance to internationally accepted protocols. In addition cholinesterases were biochemically estimated in tissues of the quail: brain, liver and plasma. Furthermore, brain, liver and duodenum cryostat sections were processed for cholinesterase histochemistry using various substrates and inhibitors. Mortalities occurred mainly in the first 1-2h following application. Sub-lethal effects, such as ataxia, ruffled feathers, tremor, salivation and reduced or no reaction to external stimuli were observed. Biochemical analysis in the brain, liver and plasma indicates a strong cholinesterase dependent inhibition with respect to mortality and sub-lethal effects of the quail. The histochemical staining also indicated a strong cholinesterase inhibition in the organs examined and the analysis of the stained sections allowed for an estimation and interpretation of the intoxication effects of methamidophos, in combination with tissue morphology visible by Haematoxylin and Eosin staining. We conclude that the use of biochemistry and histochemistry for the biomarker cholinesterase, may constitute a significantly novel approach for understanding the results obtained by the acute oral test employed in order to assess the effects of methamidophos and other chemicals known to inhibit this very important nervous system enzyme.

An alternative in vitro method for detecting neuropathic compounds based on acetylcholinesterase inhibition and on inhibition and aging of neuropathy target esterase (NTE)

Organophosphorus-induced delayed polyneuropathy (OPIDP) is a syndrome induced by certain organophosphorus compounds (OPs) through a mechanism based on the inhibition and further modification (aging) of neuropathy target esterase (NTE). OECD guidelines for testing the capability of OPs to trigger OPIDP include two in vivo tests with hens. Activities of acetylcholinesterase and NTE found in SH-SY5Y human neuroblastoma cells were inhibited by 10 different OPs with kinetics similar to those found with chicken brain enzymes (model system for in vivo and in vitro-ex vivo assays). NTE in SH-SY5Y cells inhibited by these OPs aged and reactivated similarly to that described for hen brain NTE ex vivo. In short, we have developed an alternative methodology for predicting the capability of OPs to induce OPIDP based on the inhibition kinetics of acetylcholinesterase and NTE and on the capability of OPs to age the inhibited NTE from SH-SY5Y cell line. The results obtained always agreed with the previously reported ex vivo results with hen brain. The developed methodology correctly predicted the neuropathic potential of the tested OPs in eight cases. The in vivo-in vitro discrepancies with two of the tested compounds can be explained on the basis of differences between in vivo and in vitro biotransformation.

Stereoisomeric separation and bioassay of a new organophosphorus compound, O,S-dimethyl-N-(2,2,2-trichloro-1-methoxyethyl)phosphoramidothioate: some implications for chiral switch

The manufacture and use of single- or enriched-enantiomer pesticides are green-chemistry developments advocated in the 21st century, but predictive work for chiral switch of newly produced chiral active ingredients is limited. In the present study, the stereoselective separation, target activity, and nontarget toxicity of O,S-dimethyl-N-(2,2,2-trichloro-1-methoxyethyl)phosphoramidothioate (MCP), a new organophosphorus compound, were investigated. Because being highly active and safe is a prerequisite for marketing single-isomer products, the above studies were used to offer some implications for the chiral switch of racemic MCP. The results showed that all four stereoisomers of MCP were successfully separated with a Chiralpak AD column on HPLC. The resolved isomers and the pairs of enantiomers were further distinguished using a circular dichroism detector, designating the first and third eluted peaks as one pair of enantiomers and the second and fourth peaks as the other pair. Then, the insecticidal activities and acute and delayed toxicities of the resolved isomers of MCP were evaluated by their acute lethal efficacy against Daphina magna , their inhibitory potentials to acetylcholinesterase (AChE), and axon-like outgrowth of the SH-SY5Y cells, respectively. The inhibition potencies of the isomers against AChE in SH-SY5Y cells were low and slightly stereoselective. On the other hand, a significant difference was observed among the isomers in their activities and delayed neurotoxicities. The 48 h acute toxicities of isomers to D. magna followed the order peak 1 approximately pair 1 (i.e., equimolar mixture of peaks 1 and 3) > peak 4 approximately racemate > pair 2 (i.e., equimolar mixture of peaks 2 and 4) > peak 2 > peak 3, with 1.0-6.3-fold differences among them. In comparison, the inhibitory potentials of the isomers toward axon growth of SH-SY5Y cells decreased in the order peak 2 > pair 2 > peak 4 > racemate > peak 3 > pair 1 approximately peak 1, with at least a 60-fold difference between the strongest and weakest inhibitors. Those results imply that peak 1 has the optimal target selectivity and ecological profile among the four stereoisomers. It was calculated that two-thirds of the usual pesticide usage can be saved concomitantly with a substantial decrease in neuropathic risk if MCP is present only as peak 1 rather than the racemate. When considering the absence of the economically feasible synthetic methods and techniques to produce optically pure isomers of organophosphorus pesticides, pair 1 of MCP shows considerable worth for future applications on the basis of its biological predominance and cost effectiveness.

Stereospecific hydrolysis of a phosphoramidate as a model to understand the role of biotransformation in the neurotoxicity of chiral organophosphorus compounds

Calcium-dependent and EDTA-resistant hydrolyses of R and S isomers of O-hexyl O-2,5-dicholorophenyl phosphoramidate (HDCP) were observed in serum and subcellular fractions of liver, kidney and brain from hen, rat and rabbit. In serum, the Ca(2+)-dependent hydrolysis was much higher in rabbit than in other species. Liver showed a higher activity than kidney and brain. The S-HDCP isomer was hydrolysed to a higher extent than the other isomer. The fact that this stereospecificity favours the S-isomer is more clearly observed in rabbit serum, and in rat and rabbit liver particulate fractions. In such tissues and species, the EDTA-resistant hydrolysis was not stereospecific. Soluble fractions of rat brain and of hen liver, kidney and brain, showed a lower total activity but with a higher proportion of EDTA-resistant activity and a higher hydrolysis of the R-HDCP isomer. The Ca(2+)-dependent stereoselective biodegradation of S-HDCP is dominant in the most active tissues in rabbit and rat. It can therefore be concluded that S-HDCP would be biodegraded faster than R-HDCP. Furthermore, R-HDCP is the isomer that will remain at a higher proportion to be available for interaction with the target of neurotoxicity.

Adsorption characteristics of pesticides methamidophos and glyphosate by two soils

Contributions of organic matter and minerals in soil were evaluated by comparing changes in adsorption of methamidophos (MDP) and glyphosate (GPS) before and after removal of organic matter from argaltoll (mollisol) and typustalf (alfisol) soils. Adsorption isotherms of MDP and GPS by the two soils comforted to Freundlich equation, and the adsorption capacity of GPS by argaltoll soil was higher than that of MDP. Due to the removal of organic matter from soils, K(f) values of MDP and GPS adsorbed by argaltoll soil, which were calculated from Freundlich equations and the measure of adsorption capacity, decreased by 46.1% and 75.0%, and these by typustalf soil decreased by 34.9% and 52.5%, respectively. Results from this study suggested that soil organic matter made greater contributions to adsorption of GPS, but soil minerals could provide more available adsorption sites for MDP.

Organophosphate-Induced Delayed Polyneuropathy

Organophosphate-induced delayed polyneuropathy (OPIDP) is a rare toxicity resulting from exposure to certain organophosphorus (OP) esters. It is characterised by distal degeneration of some axons of both the peripheral and central nervous systems occurring 1-4 weeks after single or short-term exposures. Cramping muscle pain in the lower limbs, distal numbness and paraesthesiae occur, followed by progressive weakness, depression of deep tendon reflexes in the lower limbs and, in severe cases, in the upper limbs. Signs include high-stepping gait associated with bilateral foot drop and, in severe cases, quadriplegia with foot and wrist drop as well as pyramidal signs. In time, there might be significant recovery of the peripheral nerve function but, depending on the degree of pyramidal involvement, spastic ataxia may be a permanent outcome of severe OPIDP. Human and experimental data indicate that recovery is usually complete in the young. At onset, the electrophysiological changes include reduced amplitude of the compound muscle potential, increased distal latencies and normal or slightly reduced nerve conduction velocities. The progression of the disease, usually over a few days, may lead to non-excitability of the nerve with electromyographical signs of denervation. Nerve biopsies have been performed in a few cases and showed axonal degeneration with secondary demyelination. Neuropathy target esterase (NTE) is thought to be the target of OPIDP initiation. The ratio of inhibitory powers for acetylcholinesterase and NTE represents the crucial guideline for the aetiological attribution of OP-induced peripheral neuropathy. In fact, pre-marketing toxicity testing in animals selects OP insecticides with cholinergic toxicity potential much higher than that to result in OPIDP. Therefore, OPIDP may develop only after very large exposures to insecticides, causing severe cholinergic toxicity. However, this was not the case with certain triaryl phosphates that were not used as insecticides but as hydraulic fluids, lubricants and plasticisers and do not result in cholinergic toxicity. Several thousand cases of OPIDP as a result of exposure to tri-ortho-cresyl phosphate have been reported, whereas the number of cases of OPIDP as a result of OP insecticide poisoning is much lower. In this article, we mainly discuss OP pesticide poisoning, particularly when caused by chlorpyrifos, dichlorvos, isofenphos, methamidophos, mipafox, trichlorfon, trichlornat, phosphamidon/mevinphos and by certain carbamates. We also discuss case reports where neuropathies were not convincingly attributed to fenthion, malathion, omethoate/dimethoate, parathion and merphos. Finally, several observational studies on long-term, low-level exposures to OPs that sometimes reported mild, inconsistent and unexplained changes of unclear significance in peripheral nerves are briefly discussed.

Toxicological assessment of isomeric pesticides: a strategy for testing of chiral organophosphorus (OP) compounds for delayed polyneuropathy in a regulatory setting

Many compounds, including some pesticides, contain structural centres of asymmetry, which convey the property of a type of stereoisomerism known as chirality. Such compounds can exist in two or more forms, depending on the number of chiral atoms and are termed stereoisomers or enantiomers. Stereoisomers of a particular compound can have different biological properties; one such of particular importance for toxicological evaluation, is the potential for differences in metabolic disposal of and binding of stereoisomers to molecular targets in the cell. The combination of differential metabolism of chiral organophosphorus (OP) pesticides and opposing stereoselectivity of inhibition of neuropathy target esterase (NTE) and acetylcholinesterase (AChE) can affect the value of the hen test, performed to OECD guidelines, in predicting the potential to cause organophosphate-induced delayed polyneuropathy (OPIDP) in humans. This is a mixed central and sensory and motor neuropathy. The experimental data on structural analogues of the pesticide methamidophos and the evidence for stereoselective OPIDP are reviewed and a model is given demonstrating how the properties of a chiral OP can result in the neuropathic potential not being detected by the standard hen test. A strategy for the assessment of a racemic mixture comprised of two OP enantiomers for the potential to induce OPIDP is outlined. The strategy uses information from structure activity relationships (SAR), in vitro tests and in vivo tests to allow risk assessment decisions to be made. It is suggested that the potential for stereoselective toxicity of pesticides should be routinely considered in regulatory assessments.

Enzymes involved in the detoxification of organophosphorus, carbamate and pyrethroid insecticides through hydrolysis

The most employed insecticides for indoor and agriculture purposes belong to carbamates, pyrethroid or organophosphates. The chemical structures of these three groups correspond to carbamic, carboxylic and triphosphoric esters. Technical monographs suggest that the hydrolysis of ester bonds of carbamates and pyrethroids plays an important role in the detoxification of these compounds. However, detailed studies about enzymes hydrolysing carbamates and pyrethroids in vertebrates are not available. Certain carbamate hydrolysing activities are associated to serum albumin. Phosphotriesterases, being of an unknown physiological role, hydrolyse (in some cases stereospecifically) organophosphorus insecticides (OP). Phosphotriesterases have been found in a multitude of species, from mammals to bacteria. A phosphotriesterase activity, EDTA-resistant, has been detected in serum albumin. Phosphotriesterases in serum of mammals display polymorphisms. Phosphotriesterases offer applications in therapy of organophosphorus poisonings, in biodegradation and bioremedation of organophosphates. Similar studies should be developed with enzymes hydrolysing pyrethroids and carbamate insecticides. Such studies will improve the knowledge of the detoxification routes in non-target species and will help to design specific and safer carbamate and pyrethroid insecticides.

Potential of the insecticides acephate and methamidophos to contaminate groundwater

The possible contamination of groundwater by the insecticides acephate and methamidophos was assessed using the behavior assessment model (BAM) and the groundwater pollution-potential model (GWP). The dissipation coefficients of the two insecticides in two soils (Annei silt loam and Pingchen silt clay loam) at different moisture contents (50 and 100% field capacity) and soil temperatures (20 and 30 degrees C) were studied by determining the degradation and adsorption of each insecticide in the soil. The movement of acephate and methamidophos was studied by leaching each insecticide in a soil column in the laboratory. The absorption coefficient of methamidophos was much higher than that of acephate in both types of soil. In the leaching test, methamidophos more easily leached out from the Pingchen soil column than from the Annei soil column. Methamidophos was rapidly degraded, with a half-life of 1.11 to 1.61 days in the Annei soil and 7.50 to 13.20 days in the Pingchen soil at different temperatures and soil water contents. Acephate was found to have a longer half-life than methamidophos in soil; however, the mobility of methamidophos in both soils was slower than that of acephate. The mobility of acephate in soil is somewhat faster than that of methamidophos, and thus acephate may lead to the contamination of groundwater much more easily than methamidophos under normal conditions.

Peripheral nerve soluble esterases are spontaneously reactivated after inhibition by paraoxon: implications for a new definition of neuropathy target esterase

Soluble extracts of chicken peripheral nerve contain detectable amounts of phenyl valerate esterase (PVase) activity (about 2000 nmol/min per g of fresh tissue). More than 95% of this activity is inhibited in assays where substrate has been added to a preincubated mixture of tissue with the non-neuropathic organophosphorus compound (OP) paraoxon (O,O'-diethyl p-nitrophenyl phosphate): residual activity includes soluble neuropathy target esterase (S-NTE) which, by definition, is considered resistant to long-term progressive (covalent) inhibition by paraoxon. However we have previously shown that paraoxon strongly interacts with S-NTE so interfering with its sensitivity to other inhibitors. We now show that, surprisingly, removal of paraoxon by ultrafiltration ('P' tissue) in order to avoid such an interference results in the reappearance of about 65% of total original soluble PVase activity which is inhibited in the presence of this OP. Although a purely reversible non-progressive inhibition might be suspected, kinetic analysis data show a time-progressive inhibition which suggests that such PVase(s) covalently bind paraoxon. Also a time-dependent recovery due to spontaneous reactivation of the PVase activity was observed after dilution of the inhibitor. Gel filtration chromatography of 'P' tissue in Sephacryl S-300 shows that the reactivated activity is associated with proteins of about 100-kDa mass which include S-NTE and an, as yet, unknown number of other PVases. The implications of these findings in the definition of NTE in a target tissue for the so-called organophosphorus-induced delayed polyneuropathy (OPIDP) are discussed.

The role of phosphotriesterases in the detoxication of organophosphorus compounds

The enzymes that hydrolyze organophosphorus compounds are called phosphotriesterases. The presence of phosphotriesterases has been described in a variety of tissues. The physiological role of these enzymes is not known, although a clear correlation exists between the levels of phosphotriesterases and susceptibility of the species to the toxic effects of organophosphorus compounds. Thus, mammals that possess high levels of phosphotriesterases in serum and liver are more tolerant to the toxic effects of these compounds than birds and insects - these being species considered lacking of phosphotriesterases. Because most of these enzymes are not well characterized, they are usually differentiated according to their different patterns of response to activators and/ or inhibitors. Phosphotriesterases usually depend of divalent cations and therefore EDTA usually inhibits them. A peculiar EDTA-resistant phosphotriesterase has been described in serum albumin. The biotechnological and therapeutical applications of phosphotriesterases are currently subject to study.

Modification of the rate of aging of diisopropylfluorophosphate-inhibited neuropathy target esterase of hen brain

This study was aimed to investigate the possibility of modifying the rate of aging of diisopropylfluorophosphate-inhibited neuropathy target esterase (NTE) of hen brain. This reaction on NTE occurs with a half-time of 7.4 min. Atropine was effective in decreasing the rate of aging on DFP-inhibited NTE and this effect was time- and concentration-dependent. Atropine was also a weak but progressive inhibitor of NTE activity (I50 = 80 mM) and this reaction appears to be reversible at lower atropine concentrations. Among compounds containing oxime functional groups only OPAB, having longer methylene chain and being more lipophylic than other oximes usually used in acetylcholinesterase (AChE) reactivation studies, was effective in decreasing the rate of aging on DFP-inhibited NTE. However, when atropine and oximes were used together we have obtained a potentiating and/or synergistic effect which was most significant with combination of atropine and TMB-4 giving up to a 15-fold decrease in the rate of aging reaction. The efficacy of this particular combination was concentration-dependent. We have also discussed similarities and differences in aging reaction occurring on NTE and AChE.

Inhibition and aging of neuropathy target esterase by the stereoisomers of a phosphoramidate related to methamidophos

Discrepancies in the aging reaction between neuropathy target esterase (NTE) inhibited in vitro and in vivo by racemic mixtures of O-alkyl O-2,5-dichlorophenyl phosphoramidates have been observed. It suggested the existence of differences in the interactions (inhibition and aging) between NTE and each stereoisomers of the above mentioned compounds. In order to verify this hypothesis, stereoisomers of O-hexyl O-2,5-dichlorophenyl phosphoramidate (HDCP) were isolated by chiral column chromatography, followed by the evaluation of NTE inhibition and aging for each stereoisomers. The loss of reactivation capacity by KF was used as criterion of aging. The stereoisomer S-(-)-HDCP inhibited hen brain NTE with an I50 of 7.6 nM for 30 min of incubation, this being similar to the value obtained for the racemic mixture (I50 = 6.2 nM), and much lower than that recorded for R-(+)-HDCP (I50 = 191 nM). NTE inhibited by HDCP racemic mixture and the stereoisomer S-(-)-HDCP was reactivated by KF after 20 h of incubation at 37 degrees C. The NTE inhibited by R-(+)-HDCP could not be fully reactivated after inhibition.

Effects of organophosphorous compounds on fatty acid compositions and oxidative phosphorylation system in the brain of rats

Effects of organophosphorous compounds, O,O-dimethyl O-4-nitro-m-tolyl phosphorothioate (MEP), O-ethyl O-p-nitrophenyl phenylphosphonothioate (EPN) and O-(4-cyanophenyl) O-ethyl phenylphosphonothioate (CYP), on the fatty acid composition and the subsequent effects on the oxidative phosphorylation system in the brain of rats were studied. After 6 days exposure in pesticides, polyunsaturated fatty acids in brain free fatty acid fractions of CYP treated rats decreased, and the unsaturation index in them were lower than those in the control rats. The polyunsaturated/saturated ratio (P/S ratio) in brain total lipids of CYP treated rats was lower than that in the control. The fatty acid composition in the brain of EPN treated rats had the same inclination as that of CYP treated rats. In the P/S ratio and unsaturation index in serum no difference was observed between CYP treated rats and the control, therefore CYP could affect the fatty acid composition in the rat brain directly. Free fatty acid contents in the brain of EPN and CYP treated rats decreased after 6 days exposure. Activities of complex I of brains were significantly higher in the EPN and CYP exposed rats than in the control rats in spite of the fact that no difference of ATP productivity was observed between them. These results suggest that EPN and CYP may affect the free fatty acid content, especially the polyunsaturated fatty acid content and consequently the enzyme activities in the oxidative phosphorylation system in the brain. Those phenomena, however, were not observed after 28 days exposure in pesticide, therefore those effects may be a passing phenomenon in an acute stage.

Environmental pollutants alter taste responses in the gerbil

Taste and smell are chemical senses that play a crucial role in food selection. Damage to taste and smell receptors can impair food intake, nutritional status, and survival. The purpose of this study was to determine the effects of 11 environmental pollutants (nine insecticides and two herbicides) on electrophysiological taste responses in the gerbil. Integrated chorda tympani (CT) recordings were obtained from gerbils to a range of tastants before and after a 4-min application of 1 of 11 environmental pollutants. The taste stimuli were: sodium chloride (100 mM), calcium chloride (300 mM), magnesium chloride (100 mM), HCl (10 mM), potassium chloride (500 mM), monosodium glutamate (MSG) (50 mM), sucrose (100 mM), fructose (300 mM), sodium saccharin (10 mM), quinine HCl (30 mM), and urea (2 M). The nine insecticides included organophosphorous, carbamate, and pyrethroid insecticides. The seven organophosphorous insecticides tested were: acephate, carbofuran, chlorpyrifos, chlorpyrifos oxon, demeton, malathion, and methamidophos. The carbamate insecticide carbaryl and the pyrethroid insecticide fenvalerate were also tested. Two herbicides, paraquat and glyphosate, were tested, and dose-response curves for each of these two herbicides were also determined. All of the 11 insecticides and herbicides had an effect on some of the taste stimuli tested. Application of 10 mM methamidophos exhibited the greatest amount of suppression on the 11 taste solutions. Each taste stimulus was significantly suppressed with the exception of 2 M urea. Herbicides paraquat and glyphosate also reduced responses to several tastants. These data indicate that environmental pollutants can modify taste responses in the gerbil.

Mechanisms of toxicity and risk assessment

Incorporating mechanistic information into the risk assessment process is necessary because proliferation of in vitro and in vivo tests of uncertain significance has led to the realisation that the quantity of toxicological information may undermine its own value. Default options in risk assessment to be used in the absence of mechanistic data are mainly derived from extrapolations. Examples from mechanistic studies on organophosphate-induced delayed polyneuropathy (OPIDP) will illustrate 3 main areas of extrapolation where mechanistic data might allow meaningful conclusions for risk assessment: (i) from animal to humans; (ii) from high to low levels of exposure; (iii) from disaggregated systems to complex systems. The continuing effort to understand the mechanisms of toxicity will reduce uncertainty in these and other areas of the extrapolation processes. It could also lead to better appreciation of the significance of biomarkers (such as lymphocyte neuropathy target esterase (NTE) for OPIDP) to be used in biomonitoring programs.

Organophosphate polyneuropathy and neuropathy target esterase: studies with methamidophos and its resolved optical isomers

Methamidophos (O,S-dimethyl phosphorothioamidate) causes polyneuropathy in man and hens. However, experiments in the hen show that lower doses of methamidophos either protect from or promote the neuropathy caused by certain organophosphates. The initiation of neuropathy as well as protection from neuropathy are thought to be related to neuropathy target esterase (NTE), whereas promotion is likely to be due to interactions with another unknown target. Methamidophos is a racemate and we report studies with its resolved optical isomers, aimed at elucidating which isomer is responsible for the described effects. The time-course of acetylcholinesterase (AChE) and NTE activity in nervous tissues of hens after inhibition by single doses of either isomer showed that after D-(+) methamidophos (25 mg/kg PO) peak inhibition of both enzymes was achieved within 24 h (80-90%). However, after L-(-) methamidophos (15 mg/kg PO), peak inhibition (80-90%) was obtained within 24 h for AChE, whereas similar NTE inhibition (120 mg/kg PO) was observed only 4 days after dosing. The minimal neuropathic doses of D-(+) and L-(-) methamidophos were 60 and 120 mg/kg PO, respectively, and correlated with > 80% NTE inhibition in nervous tissues. OPIDP initiation by either isomer was slightly promoted by phenylmethanesulfonyl fluoride (120 mg/kg SC). D-(+) Methamidophos (25 mg/kg PO) partially protected from dibutyl dichlorovinyl-phosphate (DBDCVP) neuropathy (up to 0.8 mg/kg SC). This effect correlated with about 70% NTE inhibition. L-(-) Methamidophos (15 or 60 mg/kg PO) did not protect from DBDCVP neuropathy (0.2-0.8 mg/kg SC).

Mammalian toxicology of organophosphorus pesticides

Organophosphorus compounds have been utilized as pesticides for almost five decades. They continue to be used as insecticides, helminthicides, ascaricides, nematocides, and to a lesser degree as fungicides and herbicides. While they have been and continue to be extremely useful in agricultural pest control throughout the world, their extensive use has led to numerous poisonings of nontarget species, including many human fatalities. The primary acute mammalian toxicity associated with exposure to organophosphorus pesticides results from inhibition of the enzyme acetylcholinesterase. However, other toxicities, some of which are life-threatening but not related to acetylcholinesterase inhibition, have been observed following exposure to certain organophosphorus compounds. The focus of the current review is to summarize the known effects, both cholinergic and noncholinergic, of organophosphorus pesticides in mammals. Included in this summary is a discussion of the metabolic activation of organophosphorus pesticides, since this process plays a critical role in mediating the acute toxicities of many of these pesticides.

Promotion of peripheral axonopathies by certain esterase inhibitors

Certain esterase inhibitors were found to exacerbate the clinical signs of polyneuropathy caused by various neurotoxic compounds and to delay the recovery from nerve crush. This phenomenon is referred to as promotion of axonopathies. The molecular target of promotion has not yet been identified. However, all known promoters are also inhibitors of neuropathy target esterase (NTE), the putative target of organophosphate neuropathy, but it has been shown that the target of promotion is unlikely to be NTE. Available data suggest that promoters might affect a target and a mechanism present in the nervous system that is not activated by axonal lesions. Promotion may be important to understand the physiological mechanism of nerve damage and repair. This finding also implies a changing perspective for the risk assessment of exposures to esterase inhibitors, some of which are used as pesticides and might be promoters.

The search for the physiological functions of NTE; is NTE a receptor?

Neuropathy target esterase (NTE) was identified as the molecular target for organophosphate-induced delayed polyneuropathy several years ago but its physiological functions are still unknown. The mechanism which initiates neuropathy was thought to be a two step process: inhibition (phosphorylation) of NTE and aging of phosphorylated NTE. Depending on the occurrence of the second reaction (aging), inhibitors were ranked as neuropathic (forming an ageable NTE) and non-neuropathic (forming a non-ageable NTE). Non-neuropathic inhibitors protect from neuropathy if given before the neuropathic ones, because they occupy the catalytic centre of NTE. Thus the catalytic function of NTE seems irrelevant in maintaining the health of neurons. This paper reviews some new information concerning the interaction of NTE with its inhibitors as well as on a phenomenon called promotion of neuropathy. Some inhibitors which apparently form a non-ageable inhibited NTE were found to cause neuropathy, even though some of them must be given at very high doses. Moreover some 'non-neuropathic-protective' NTE inhibitors were found to exacerbate (promote) neuropathy when given after a neuropathic one. It is likely that the target for promotion is other than NTE. The hypothesis that NTE has some unknown receptorial functions where inhibitors act with different efficacy is discussed. NTE inhibitors have been ranked as full agonists (classic neuropathic inhibitors such as diisopropylfluorophosphate), partial agonists (protective or neuropathic, depending on the dose, such as methamidophos) and antagonists (protective, and neuropathic at the highest doses, such as phenylmethanesulfonyl fluoride). Age-related differences in the 'receptor' NTE might be responsible for the different sensitivities of juvenile and adult animals.

Stereo-specific degradation of the R-(+) isomer of O-n-hexyl-S-methylphosphorothioamidate catalysed by rabbit serum

Resolved isomers of O-n-hexyl-S-methylphosphorothioamidate (HXM) which had been synthesised by separate stereospecific routes were analysed by chiral glc: about 2-3% of R-(+) isomer was found in the S-(-) sample and accounted for nearly all the inhibitory power against neuropathy target esterase. Incubation of racemic HXM with rabbit serum led to slow but very specific disposal of R-(+) isomer to undetectable levels with very slight loss of S-(-): the rate of disposal was roughly estimated to be about 1% of the published rate of hydrolysis of paraoxon. Incubation with crystalline chymotrypsin caused a preferential but not totally selective disposal of S-(-) isomer.

Postscript to the symposium on organophosphorus compound induced delayed neuropathy

A short review is presented on the key points in the development of the hypothesis for the initiation of delayed neuropathy by reaction of organophosphorus compounds with neuropathy target esterase (NTE). It is now clear from information derived from experiments showing protection and promotion and from the action of some phosphorothioamidates (which cause delayed neuropathy without aging) that the original NTE hypothesis is not generally applicable and requires modification. A suggestion is made that aging of phosphorylated and phosphonylated NTE is facilitated perhaps by two linked esterases, one being NTE.

Symposium introduction: retrospect and prospects for neuropathy target esterase (NTE) and the delayed polyneuropathy (OPIDP) induced by some organophosphorus esters

This article introduces a Symposium devoted to Neuropathy Target Esterase (NTE). The characteristics of the disorder known as OPIDP are described and the steps by which NTE was identified as the target are summarised. Studies with many organophosphates, phosphinates and chiral phosphonates are entirely consistent with a 2-step process of initiation referred to as 'NTE (70-80%) aging': about 70-80% of available nervous system NTE is first covalently phosphylated causing inhibition of esterase activity, and then the molecules of inhibited NTE undergo a covalent bond-cleavage leaving a negative charge in the region of the still-bound phosphorus. This understanding has clarified structure/activity studies of neuropathic potential of OP esters and is now routinely applied in toxicological evaluations for regulatory purposes. However, the biological function of NTE has remained a mystery. Prospective views of the role of NTE are presented by different authors. Attempts to isolate catalytically active or radiolabelled inhibited NTE are near to success. Since the Symposium, complete isolation of NTE affinity-purified from hen brain has been reported (see M.K. Johnson & P. Glynn, Toxicologist, 13 (1993) 211, Abstr. 773). Some minor, but possibly significant, differences in properties of a soluble and a membrane-bound form of NTE in sciatic nerve has been identified. The nature of the disturbance brought about by covalent binding of organophosphoramidates at the active site of NTE and the discovery that 'non-aging' inhibitors of NTE can promote neuropathy in hens given a sub-neuropathic dose of neuropathic OPs has led to a concept of NTE inhibitors having a range of 'partial agonist' effects at the covalent binding site. Evidence is emerging that the promotion target may be 'cousin-of NTE' with very similar inhibition characteristics and a function in the processes of response to or repair of axonal damage.

The R-(+)isomer of O-n-hexyl S-methyl phosphorothioamidate causes delayed neuropathy in hens after generation of a form of inhibited neuropathy target esterase (NTE) which can be reactivated ex vivo

To initiate delayed neuropathy (DN) in adult hens organophosphates and phosphonates must inhibit most neural NTE and the inhibited NTE must undergo an 'aging' reaction. Phosphinates and those chiral isomers of phosphonates which produce non-aging NTE do not cause DN but act as prophylactic agents. Some racemic phosphoramidates cause DN although the inhibited NTE in autopsy samples can be reactivated in vitro (Johnson, Read and Vilanova, 1991, Arch. Toxicol., 65, 618-624). We now report that pure R(+)isomer of O-n-hexyl S-methyl phosphorothioamidate (5-20 mg/kg per os) caused slight acute effects but typical DN associated with high inhibition of NTE in brain, spinal cord and sciatic nerve (maximum by 6-24 h): the inhibited NTE was easily reactivated by KF (presumed not aged). For each dose the average residual NTE activity in the three tissues 24 h after dosing and the clinical ataxia severity on peak days 15-17 (score out of 4) was: 5 mg/kg: 13, 14, 27% (2,2,2,1); 10 mg/kg: 10, 14, 12%, (4,3,2); 15 mg/kg: 10,11,17%, (3,3,4); 20 mg/kg: 6, 10, 8% (3,3,3,2). The ability of this isomer and of other racemic phosphoramidates to initiate DN by covalent reaction at the active site of NTE (inhibition) without subsequent aging suggests that the chemistry (? charge distribution) in the region of the phosphorus atom determines that disturbance in the molecular environment of NTE which initiates DN.

The esterases: perspectives and problems

Many proteins capable of hydrolysing esters are present in biological material of all kinds (microorganisms, plants, invertebrates and vertebrates). Some serve, as indicated by their substrate specificity and distribution within organisms, a defined biological function. However for most esterases a rather general substrate specificity is found indicating that they may have a broad biological function. Their properties will be briefly reviewed with particular emphasis on inhibitors. The mechanism of hydrolysis of esters by many carboxylesterases (B-esterases) is well established largely due to the reaction of OP compounds with their catalytic centre. For others, such as enzymes hydrolysing (i) OP compounds and/or (ii) carboxyl esters which are not inhibited by a time and temperature dependent reaction by OP compounds, reaction mechanisms are still conjecture. The purpose of this presentation is to explore similarities and differences between the esterases and to discuss possible routes for progress in the A-esterase group.

Biochemical properties and possible toxicological significance of various forms of NTE

NTE (neuropathy target esterase) is considered to be the target for organophosphorus-induced delayed polyneuropathy and is operationally measured by radiolabelling or by determining its esteratic activity as the paraoxon-resistant mipafox-sensitive phosphorylable site(s). From electrophoresis and density gradient centrifugation using radiolabelling techniques, several phosphorylable sites have been described in hen brain that are paraoxon-resistant mipafox-sensitive; however, only the majority electrophoresis band (155 kDa) shows properties related with the aging reaction. Kinetic criteria have also suggested two components of brain NTE (NTEA and NTEB). Most brain NTE is recovered in the particulate microsomal fraction and only about 1% in soluble fraction. In sciatic nerve about 50%/50% activity is recovered as soluble (S-NTE) or particulate (P-NTE) forms. A similar distribution were observed in hen, cat, rat and young chick. The fixed time inhibition curves show that P-NTE is more sensitive to mipafox, DFP and hexyl-DCP than S-NTE, while the reverse is true for methamidophos. P-NTE fits properly to one sensitive component while S-NTE fits better to two sensitive component models, except in the case of methamidophos. In vivo, significant differences in the inhibition of P- and S-NTE by mipafox were found only when using low non-neuropathic dosing. The possible significance of different NTE forms are discussed.

Properties of partly preinhibited hen brain neuropathy target esterase

NTE inhibitors cause different toxicological consequences (protection, induction or potentiation/promotion of neuropathy) depending on the order of dosing. These effects might be explained in terms of several phosphorylable sites with 'allosteric irreversible' behaviour. Brain neuropathy target esterase (NTE) has been preinhibited with phenylmethylsulphonyl fluoride (PMSF) (0, 5, 10, 15, 30 and 60 microM) or with diisopropylphoshoro fluoridate (DFP) (0, 0.2, 0.5, and 1 microM) at 37 degrees C for 30 min. After washing by centrifugation, tissues were then reinhibited with a range of PMSF (0 to 80 microM) or DFP (0 to 1 microM) concentrations. The slopes of the inhibition curves (log % activity vs. concentration) of pretreated tissues were identical to those of the non-pretreated tissues, with non-distinguishable I50 values. It is concluded that allosteric effects are not likely to be involved in membrane-bound NTE of hen brain.

Interactions in vitro of some organophosphoramidates with neuropathy target esterase and acetylcholinesterase of hen brain

For organophosphates or phosphonates to initiate delayed neuropathy two steps are necessary: (1) progressive covalent reaction with neuropathy target esterase (NTE) to produce a form of inhibited NTE which can be reactivated by incubation with aqueous potassium fluoride (KF) and (2) progressive "aging" of inhibited NTE to a form which can no longer be reactivated by KF. However, it has been shown recently that certain N-unsubstituted organophosphoro-monoamidates (analogues of methamidophos) cause delayed neuropathy even though the inhibited NTE appeared not to have aged (Johnson et al. (1991). Arch. Toxicol., 65, 618-624). In order to study the generality of this phenomenon, we have examined some N-substituted compounds. We report in vitro studies of inhibition and reactivation and aging of both NTE and acetylcholinesterase (AChE) prior to toxicological tests. All the compounds studied were less inhibitory to both NTE and AChE in concentrated rather than in dilute suspensions of EDTA-washed brain particles without added cofactors. There was an apparent disposal of up to 100 mumoles of test compound by particles from 95 mg hen brain, which is far greater than can be explained by covalent binding. The activity is distinct from calcium-dependent "A" esterase. Several N-alkyl phosphoromonoamidates were found to be potent and selective inhibitors of NTE: second-order rate constant for O-n-pentyl N-benzylphosphoramido-fluoridate (Cmpd 6) = 5.6 x 10(7) M-1 min-1 at 37 degrees, which is about 100x higher than for acetylcholinesterase (AChE). Inhibited NTE and AChE from several chiral phosphoromono-amidates did not reactivate spontaneously (21 hours at 37 degrees). Virtually 100% reactivation by KF of AChE inhibited by phosphoromonoamidates was achieved at all times tested. Acetylcholinesterase inhibited by 2,5-dichlorophenyl N,N'-di-n-butylphosphorodiamidate was 42-56% reactivated by incubation with KF (192 mM in pH 5.2 buffer for 30 minutes at 37 degrees). We believe this is the first report of reactivation of any enzyme after inhibition by a phosphorodiamidate. For NTE inhibited by tabun (O-ethyl N-dimethylphosphoroamidocyanidate), virtually complete and rapid aging (t1/2 = 5.5-8.4 minutes) was observed. Consistent but only partial reactivation by KF was achieved 2 or more hours after inhibition of NTE by Cmpd 6 or by its 2,6-difluoro-analogue (Cmpd 7). However, a small but significant aging (approximately 15-20% loss of reactivatability) was measured soon after a 1 minute inhibition by Cmpd 7, but no further change occurred in 21 hours.(ABSTRACT TRUNCATED AT 400 WORDS)

Local application of neuropathic organophosphorus compounds to hen sciatic nerve: inhibition of neuropathy target esterase and peripheral neurological impairments

Diisopropyl phosphorofluoridate (DFP), mipafox, cresylsaligenyl phosphate, and phenylsaligenyl phosphate were applied to a 1.5-cm segment of the common trunk of the sciatic nerve in adult hens. At doses of 18-182 micrograms mipafox and 9-110 micrograms DFP, inhibition of neuropathy target esterase (NTE) for the treated segment was over 80%, whereas for the adjacent distal and proximal segments inhibition was under 40%, 15 min after application. NTE was not affected in the peripheral distal terminations arising from the common sciatic nerve (peroneal branches), contralateral sciatic nerve, brain, and spinal cord. A 24-hr study suggested a displacement of the activity-free region toward more distal segments of the nerve. All animals treated with 55 and 110 micrograms DFP or 110 micrograms mipafox lost a characteristic avian retraction reflex in the treated leg 9-15 days after dosing, suggesting peripheral neurological alterations. Only hens dosed at the maximum dose in both extremities presented alterations in motility (Grade 1 or 2 on a 0-8 scale), suggesting no significant central nervous system alterations. Electron microscopy of peroneal branches showed axon swelling and accumulation of smooth endoplasmic reticulum similar to animals dosed systemically (s.c.) with 1-2 mg/kg DFP. The branches also contained granular and electron-dense materials, as well as some intraaxonal and intramyelinic vacuolization. Clinical effects were not observed in animals protected with a 30 mg/kg (s.c.) dose of phenylmethanesulphonyl fluoride. It is concluded that the peripheral neurological effects of local dosing correlate with the specific modification of NTE in a segment of sciatic nerve and that the axon is a more likely target than the perikaryon or nerve terminal in the triggering mechanism of this axonopathy.

Phenylmethanesulfonyl fluoride elicits and intensifies the clinical expression of neuropathic insults

It has been recently reported that phenylmethanesulfonyl fluoride (PMSF) when given to hens after a neuropathic organophosphate (OP) promotes organophosphate-induced delayed polyneuropathy (OPIDP). Chicks are resistant to OPIDP despite high inhibition/aging of neuropathy target esterase (NTE), the putative target of OPIDP initiation. However, when PMSF (300 mg/kg s.c.) is given to chicks after di-butyl 2,2-dichlorovinyl phosphate (DBDCVP, 1 or 5 mg/kg s.c.), OPIDP is promoted. Inhibition/aging of at least 30% of NTE was thought to be an essential prerequisite for promotion to be elicited in adult hens. However, we observed in hens that when NTE is maximally affected (greater than 90%) by phenyl N-methyl N-benzyl carbamate (40 mg/kg i.v.), a non-ageable inhibitor of NTE, and then PMSF is given (120 mg/kg/day s.c. x 3 days) clinical signs of neuropathy become evident. Methamidophos (50 mg/kg p.o. to hens), which produces in vivo a reactivatable form of inhibited NTE, was shown either to protect from or promote OPIDP caused by DBDCVP (0.45 mg/kg s.c.), depending on the sequence of dosing. Because very high doses of methamidophos cause OPIDP, we considered this effect to be a "self-promoted" OPIDP. We concluded that NTE inhibitors might have different intrinsic activities for producing OPIDP once NTE is affected. Aging might differentiate highly neuropathic OPs, like DBDCVP, from less neuropathic OPs, like methamidophos, or from the least neuropathic carbamates, which require promotion in order for neuropathy to be expressed.(ABSTRACT TRUNCATED AT 250 WORDS)