Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.1.5 (neuropathy target esterase)
 1,070 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Considerable evidence exists suggesting that the so-called neuropathy target esterase (NTE) is involved in the mechanisms responsible for organophosphorus-induced delayed polyneuropathy (OPIDP). Earlier studies in the adult hen, the habitually employed experimental model in OPIDP, have shown that most NTE activity in the brain is centered in particulate fractions, whereas approximately 50% of this activity in the sciatic nerve is encountered in soluble form, with the rest being particulate NTE. In the present work, we have studied the particulate and soluble fractional distribution of paraoxon-resistant phenylvalerate esterase activity (B activity), paraoxon- and mipafox-resistant phenylvalerate esterase activity (C activity), and NTE activity (B-C) according to ultracentrifugation criteria (100,000 g for 1 h). To this effect, two sensitive (adult hen and cat) and two scarcely sensitive (rat and chick) models were used. In all four experimental models, the distribution pattern was qualitatively similar: B activity and total NTE were much greater in brain (900-2,300 nmol/min/g of tissue) than in sciatic nerve (50-100 nmol/min/g of tissue). The proportion of soluble NTE in brain was very low (< 2%), whereas its presence in sciatic nerve was substantial (30-50%). The NTE/B ratio in brain was high for the particulate fraction (> 60%) and low in the soluble fraction (7-30%); in sciatic nerve the ratio was about 50% in both fractions.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Soluble and particulate organophosphorus neuropathy target esterase in brain and sciatic nerve of the hen, cat, rat, and chick. 824 68

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.
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PMID:Biochemical properties and possible toxicological significance of various forms of NTE. 834 94

Single doses of triphenyl phosphite (TPP), a triester of trivalent phosphorus, cause ataxia and paralysis in hens. Characteristics of neurotoxicity were described as somewhat different from organophosphate induced delayed polyneuropathy (OPIDP), which is caused by triesters of pentavalent phosphorus. The onset of TPP neuropathy was reported to occur earlier than that of OPIDP (5-10 versus 7-14 days after dosing, respectively), and chromatolysis, neuronal necrosis and lesions in certain areas of the brain were found in TPP neuropathy only. Pretreatment with phenylmethanesulfonyl fluoride (PMSF) protects from OPIDP, but it either partially protected from effects of low doses or exacerbated those of higher doses of TPP. In order to account for these differences with OPIDP, it was suggested that TPP neuropathy results from the combination of two independent mechanisms of toxicity: typical OPIDP due to inhibition of neuropathy target esterase (NTE) plus a second neurotoxicity related with other target(s). We explored TPP neuropathy in the hen with attention to the phenomena of promotion and protection which are both caused by PMSF when given in combination with typical neuropathic OPs. When PMSF is given before neuropathic OPs it protects from OPIDP; when given afterwards it exaggerates OPIDP. The former effect is due to interactions with NTE, the latter to interactions with an unknown site. The time course of NTE reappearance after TPP (60 or 90 mg/kg i.v.) inhibition showed a longer half-life when compared to that after PMSF (30 mg/kg s.c.) (10-15 versus 4-6 days, respectively). The clinical signs of TPP neuropathy (60 or 90 mg/kg i.v.) were similar to those observed in OPIDP, appeared 7-12 days after treatment, correlated with more than 70% NTE inhibition/aging and were preceded by a reduction of retrograde axonal transport in sciatic nerve of hens. TPP (60 mg/kg i.v.) neuropathy was promoted by PMSF (120 mg/kg s.c.) given up to 12 days afterwards and was partially protected by PMSF (10-120 mg/kg s.c.) when given 24 h before TPP (60 or 90 mg/kg i.v.). The previously reported early onset of TPP neuropathy might be related to the higher dose used in those experiments and to the resulting more severe neuropathy. The lack of full protection might be explained by the slow kinetics of TPP, which would cause substantial NTE inhibition when PMSF effects on NTE had subsided. Since PMSF also affects the promotion site when given before initiation of neuropathy, the resulting neuropathy would then be due to both protection from and promotion of TPP effects by PMSF. No promotion by PMSF (120 mg/kg s.c.) was observed in TPP neuropathy (90 mg/kg i.v.) partially protected by PMSF (10-30 mg/kg s.c.). This might also be explained by the concurrent effects on NTE and on the promotion site obtained with PMSF pretreatment. We conclude that TPP neuropathy in the hen is likely to be the same as typical OPIDP. The unusual effects of combined treatment to hens with TPP and PMSF are explained by the prolonged pharmacokinetics of TPP and by the dual effect of PMSF i.e. protection from and promotion of OPIDP.
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PMID:Triphenylphosphite neuropathy in hens. 857 29

The identification of neuropathy target esterase (NTE) as the site for initiation of organophosphorus-induced delayed polyneuropathy (OPIDP) has led to informative acute and chronic neurotoxicity tests (adopted by OECD and EPA), to structure/activity and in vitro/in vivo predictions, and to a sound basis for extrapolations to man. Purification of the sodium dodecyl sulphate (SDS)-denatured 155-kDa sub-unit of NTE has enabled partial sequencing and molecular biological studies. A MAb to the chicken brain sub-unit and PAbs to synthetic peptides have been raised: preliminary experiments suggest that one is effective for immunohistochemistry of frozen tissue. cDNA libraries are being screened with synthetic oligonucleotides, polymerase chain reaction (PCR)-developed primers, and with Ab in order to obtain cloned NTE. Previous studies of NTE in vivo have not revealed its normal physiological function or the route from inhibition to degeneration of axons, but the current progress in molecular biology of NTE is applicable to study of the function of normal and organophosphorus (OP)-modified NTE in cultured neural cells.
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PMID:Neuropathy target esterase (NTE) and organophosphorus-induced delayed polyneuropathy (OPIDP): recent advances. 859 94

Phenylmethanesulfonyl fluoride (PMSF) enhances the neuropathic response when given to hens after organophosphates causing delayed polyneuropathy. This study was undertaken to ascertain whether other sulfonyl fluorides promote diisopropyl fluorophosphate (DFP) neuropathy in hens and if they inhibit neuropathy target esterase (NTE), the target for organophosphate-induced delayed polyneuropathy. Among seven sulfonyl fluoride analogs of PMSF (alkyl-, and phenylsulfonyl fluorides), only n-butanesulfonyl fluoride was found to be an NTE inhibitor in vitro at a concentration (I50 = 60 microM) similar to that of PMSF, n-Butanesulfonyl fluoride (0.2 mmol.kg-1 sc to hens) caused both NTE inhibition in nervous tissues (> 80%) and promotion of neuropathy after DFP (0.003 mmol.kg-1 sc) similar to those observed after the same molar dose of PMSF. These results confirm that, so far, all known promoters of organophosphate polyneuropathy are also NTE inhibitors.
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PMID:Sulfonyl fluorides and the promotion of diisopropyl fluorophosphate neuropathy. 892 48

Certain esterase inhibitors (such as phenylmethanesulfonyl fluoride, PMSF) enhance the clinical and morphological signs of organophosphate-induced delayed polyneuropathy (OPIDP) in hens. This is called promotion of OPIDP. The target of promotion is unknown, but it is likely to be different from neuropathy target esterase (NTE), the target of OPIDP, NTE is a neural phenyl valerate (PV) esterase, operationally defined by selective inhibition with organophosphates. This study was aimed to ascertain whether the target for promotion is a PV esterase other than NTE. Brain and sciatic nerve PV esterases of hens were incubated with diisopropylphosphorofluoridate (DFP; 5 microM) or N,N-diisopropyl phosphorodiamidofluoridate (mipafox; 50 microM) to inhibit NTE and other esterases thought not to be relevant to promotion. Remaining activities, quantitatively similar after either inhibition, were titrated with PMSF (up to 500 microM) and analysis of time course of inhibition showed first-order kinetics. Mipafox (50 microM)-resistant PMSF (500 microM)-sensitive activity (about 80% of mipafox-resistant ones) was tested both in vitro and in vivo with several inhibitors. No correlation was found between inhibition of mipafox-resistant PMSF-sensitive activity and the capability of several inhibitors to promote OPIDP. We conclude that the target of promotion is unlikely to be a PV esterase resistant to mipafox (50 microM).
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PMID:Phenyl valerate esterases other than neuropathy target esterase and the promotion of organophosphate polyneuropathy. 930 88

Carboxylesterases are enzymes present in neural and other tissues that are sensitive to organophosphorus compounds. The esterase activity in particulate forms, resistant to paraoxon and sensitive to mipafox have been implicated in the initiation of organophosphorus-induced delayed polyneuropathy (OPIDP) and is called neuropathy target esterase (P-NTE). Certain esterases inhibitors such as phenylmethylsulfonyl fluoride (PMSF), can also irreversibly inhibit P-NTE and by this mechanism PMSF 'protects' from further effect of neuropathic OPs. However, if PMSF is dosed after a low non-neuropathic dose of a neuropathic OP, its neurotoxicity is 'promoted', causing severe neuropathy. The molecular target of promotion has not yet been identified and it has been shown that it is unlikely to be the P-NTE. In order to discriminate the different esterases, we used non-neuropathic (paraoxon), and neuropathic organophosphorus compounds (mipafox, DFP) and a neuropathy promoter (PMSF). They were used alone or in concurrent inhibition to study particulate and soluble fractions of brain, spinal cord and sciatic nerve of chicken. From the experimental data, a matrix was constructed and equations deduced to estimate the proportions of the different potential activity fractions that can be discriminated by their sensitivity to the tested inhibitors. It was deduced that only combinations of up to three inhibitors can be used for the analysis with consistent results. In all tissues, inside the paraoxon sensitive activity, most of the activity was sensitive either to mipafox, to PMSF or both. In all fractions, except brain soluble fractions, within the paraoxon resistant activity, a mipafox sensitive component was detected that is operationally considered NTE (P-NTE and S-NTE in particulate and soluble fractions, respectively). Most of this activity was also sensitive to PMSF, and this should be considered the target of organophosphorus inducing neuropathy and of PMSF protective effect. Either in brain and spinal cord, a significant amount of the activity resistant to 40 microM paraoxon and 250 microM mipafox (usually called 'C' activity) is sensitive to PMSF. It could be a good candidate to contain the target of the promotion effect of PMSF as well as the S-NTE activity that is also PMSF sensitive.
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PMID:Discrimination of carboxylesterases of chicken neural tissue by inhibition with a neuropathic, non-neuropathic organophosphorus compounds and neuropathy promoter. 941 46

Several organophosphorus compounds (OP) and carbamates (CA) are used as insecticides or warfare agents (OPs only). Their acute toxic effect in the central and peripheral nervous system is due to inhibition of acetylcholinesterase (AChE) at nerve endings which causes accumulation of acetylcholine and consequently overstimulation of the nicotinic and muscarinic receptors. The cholinergic syndrome appears at approximately 50% AChe inhibition whereas death is believed to occur at > 90%. Inhibition of AChE (phosphorylation) by most OPs is irreversible whereas CAs reversibly inhibit AChE (spontaneous reactivation with a t(1/2) of minutes); dimethylphosphorylated AChE partially and slowly (t(1/2) = 1-2 h) reactivates. Although long-term, mild neurobehavioural changes of questionable significance have been reported in some instances, recovery from the cholinergic syndrome appears to be complete, unless lesions develop in the central nervous system as a consequence of either convulsions or anoxia. Certain OPs and CAs have been reported to interact with cholinergic receptors in vitro. The toxicological relevance of these interactions is still not clear. Certain OPs cause OP-induced delayed polyneuropathy (OPIDP) which develops 2-5 weeks after an acute poisoning. The molecular target is believed to be neuropathy target esterase (NTE). OP insecticides are more potent AChE inhibitors rather than NTE inhibitors and therefore, the dose required to cause OPIDP is much higher than that causing the cholinergic syndrome. In the experimental animal, OPIDP is associated with > 70% NTE inhibition after single or repeated exposures. The threshold in man is not known, although there are indications that it is similar. Some non-neuropathic esterase inhibitors (OPs, CAs, sulfonyl fluorides) exacerbate the clinical outcome of OPIDP and other chemical axonopathies, and of nerve crush. The phenomenon has been called promotion and has so far been observed in experimental animals only.
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PMID:Experimental and clinical toxicology of anticholinesterase agents. 1002 4

Certain esterase inhibitors elicit or intensify the clinical expression of various insults to axons. This phenomenon was called promotion of axonopathies because these chemicals are not additive neurotoxicants nor do they interfere with the pharmacokinetics. Characterization of promotion was carried out by using organophosphate induced delayed polyneuropathy (OPIDP) as a model. The search for a physiological explanation of promotion has the following background: (1) Promotion expresses clinically the biochemical lesions which are otherwise well compensated (such as 30/40% neuropathy target esterase (NTE) inhibition by neuropathic organophosphates). (2) Promotion is not specific because axonopathies of different origin are affected. (3) Promoters are effective when given several days before the neuropathic insult. (4) Promotion is less effective in young animals as compared with adults. (5) Promotion occurs when axons, but not necessarily the cell body, are targeted by promoters. (6) Repeated dosing with a promoter failed to produce axonopathy. Based on this evidence it is suggested that promotion might interfere with a mechanism(s) of compensation and/or repair of long axons. The target of promotion of axonopathies is thought to be similar or linked to NTE which is defined as the phenyl valerate esterase activity (PVE) in nervous tissues resistant to paraoxon and sensitive to mipafox (40 and 50 microM, pH 8.0, 20 min, respectively). Mipafox (50 microM) resistant PVEs include some activity sensitive to the promoter phenylmethane sulfonylfluoride (PMSF) but no correlation was found between its inhibition and promotion. A complete titration curve of paraoxon-resistant PVEs by mipafox (0-1 mM) dissected, besides NTE (I50 about 10 microM), another PVE with an I50 of approximately 200 microM. This enzyme was present in hen brain, spinal cord and peripheral nerve, corresponding to about 10, 20 and 30% of NTE activity, respectively, and was sensitive both in vitro and in vivo to promoters and much less so to neuropathic NTE inhibitors. By means of chromatography, other workers have identified in soluble extracts of peripheral nerves two forms of mipafox-sensitive PVEs with different molecular weights and different sensitivity to mipafox. These might correspond to NTE and to the other enzyme. Inhibition in vivo of the latter also correlated with promotion.
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PMID:Promotion of organophosphate induced delayed polyneuropathy by certain esterase inhibitors. 1042 91

Neural carboxylesterases can be discriminated by differential inhibition assays with organophosphorus compounds (OPs), paraoxon (O,O'-diethyl p-nitrophenyl phosphate) and mipafox (N,N'-diisopropyl phosphorodiamidofluoridate) being the ones used to discriminate esterases that should be either irrelevant or candidates as targets of the mechanism of induction of the organophosphorus-induced delayed polyneuropathy (OPIDP). The brain membrane-bound phenyl valerate esterase (PVase) defined by Dr Johnson in 1969 as neuropathy target esterase (NTE) and recently cloned by Dr Glynn and coworkers is termed here as particulate NTE due to its association to the membrane particulate fraction. It is considered as the target of OPIDP and is the activity measured in standard NTE assays and toxicity tests. Following the same operational criteria in the soluble fraction of sciatic nerve a paraoxon-resistant but mipafox-sensitive PVase activity was described and termed as S-NTE, with an apparent lower sensitivity to some inhibitors than particulate NTE. Two isoforms (S-NTE1 and S-NTE2) were subsequently separated by gel filtration chromatography. In a partly purified S-NTE2 preparation polypeptides were identified in western blots by labelling with S9B [1-(saligenin cyclic phospho)-9-biotinyldiaminononane], the same biotinylated OP used to label and isolate particulate NTE, but not with anti-particulate NTE antibodies. From sequential inhibition protocols, inhibitor washing-out and time course inhibition studies it is deduced that reversibility of inhibition is a new factor introducing a higher complexity in the identification of the esterases that could be candidates as targets of the mechanisms of induction and/or promotion of neuropathy. We have evidences that in sciatic nerve soluble fraction a high proportion (about 70%) of the activity that is inhibited by paraoxon in the usual concurrent assay is quickly reactivated after removing paraoxon and it is permanently inhibited by mipafox. Under this improved sequential paraoxon/mipafox inhibition procedure S-NTE represents about 50% of total PVases while in the usual concurrent assay it was only apparently about 1-2%. Moreover with such criteria, S-NTE2 isoform(s) represents about 97-99% of total S-NTE, and S-NTE1 is only a marginal amount probably resulting of a partial solubilization from particulate NTE. Fixed time inhibiton curves with variable mipafox concentration failed to discriminate more than one component. However kinetic behaviour of the time progressive inhibition cannot be explained by a simple model with a single exponential mathematical component, indicating that either the possibility of more than one component or a more complex mechanistic model should be considered. Consequently both particulate NTE and S-NTE assay protocols and their role in induction and promotion of neuropathies will need to be reviewed. Data published by Drs Lotti, Moretto and coworkers suggest that particulate NTE cannot be the target of promotion of axonopathies. The proposal that S-NTE2 could be such a target is suggestive and under collaborative biochemical and toxicological studies.
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PMID:NTE soluble isoforms: new perspectives for targets of neuropathy inducers and promoters. 1042 92


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