Soluble and particulate organophosphorus neuropathy target esterase in brain and sciatic nerve of the hen, cat, rat, and chick

Properties of phenyl valerate esterase activities from chicken serum are comparable with soluble esterases of peripheral nerves in relation with organophosphorus compounds inhibition

Chicken serum, the usual in vivo animal for testing organophosphorus delayed neuropathy, has long been reported not to contain a homologous activity of the neuronal neuropathy target esterase (NTE) activity when it is assayed according to standard methods as the phenyl valerate esterase (PVase) activity, which is resistant to paraoxon and sensitive to mipafox. However, a PVase activity (1000-1500 nmol/min/ml) can be measured in serum that is extremely sensitive to both paraoxon, a non-neuropathic organophosphorus compound and mipafox, a model neuropathy inducer. The inhibition was time progressive in both cases, suggesting a covalent phosphorilating reaction. The fixed time inhibition curves suggest at least two sensitive components. The IC50 for 30 min, at 37 degrees C are 6 and 51 nM for paraoxon and 4 and 110 nM for mipafox, for every sensitive component. When paraoxon was removed from a serum sample pretreated with the inhibitor, the paraoxon sensitive PVase activity was recovered, in spite of showing a time progressive inhibition suggesting that hydrolytic dephosphorylating reaction recovered at a significant rate. The reactivation of the phosphorylated enzyme could explain that the time progressive inhibitions curves for long time with paraoxon tend to reach a plateau depending on the inhibition concentration. However, with mipafox, the curve approached the same maximal inhibitions at all concentrations as expected for a permanent covalent irreversible phosphorylation, which is coherent with the observations that the activity remained inhibited after removing the inhibitor. Data of serum esterases described in this paper showed similar properties to those previously reported for peripheral nerve soluble phenylvalerate esterase: (1) extremely high sensitivity to paraoxon and mipafox; (2) time progressive kinetic with two sensitive components; (3) recovery of activity after removal of paraoxon; and (4) permanent inhibition with mipafox. These properties of serum esterases are very similar to those of soluble fraction of peripheral nerves. So, serum PVases could be considered as appropriate biomarkers, as a mirror for the neural soluble paraoxon and mipafox sensitive soluble esterases that could be used for biomonitoring purpose.

Loss of neuropathy target esterase in mice links organophosphate exposure to hyperactivity

Neuropathy target esterase (NTE) is involved in neural development and is the target for neurodegeneration induced by selected organophosphorus pesticides and chemical warfare agents. We generated mice with disruptions in Nte, the gene encoding NTE. Nte(-/-) mice die after embryonic day 8, and Nte(+/-) mice have lower activity of Nte in the brain and higher mortality when exposed to the Nte-inhibiting compound ethyl octylphosphonofluoridate (EOPF) than do wild-type mice. Nte(+/-) and wild-type mice treated with 1 mg per kg of body weight of EOPF have elevated motor activity, showing that even minor reduction of Nte activity leads to hyperactivity. These studies show that genetic or chemical reduction of Nte activity results in a neurological phenotype of hyperactivity in mammals and indicate that EOPF toxicity occurs directly through inhibition of Nte without the requirement for Nte gain of function or aging.

NTE soluble isoforms: new perspectives for targets of neuropathy inducers and promoters

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.

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.

Delayed neuropathy and inhibition of soluble neuropathy target esterase following the administration of organophosphorus compounds to hens

Delayed neuropathy and inhibition of soluble neuropathy target esterase (NTE) and acetylcholinesterase (AChE) activities in different regions of brain and spinal cord of adult hens were studied after the intravenous administration of leptophos (30 mg/kg), tri-o-cresyl phosphate (TOCP 40 mg/kg) or dipterex (200 mg/kg). The level of NTE activity varied according to the regions of the central nervous system (CNS) of the control (normal) hen, being higher in the cerebrum (74.1 micromol of phenyl valerate hydrolyzed/10 minutes/mg protein) and in the cerebellum (68.7), and lower in the spinal cord (44.5 in cervical, 55.6 in thoracic and 50.0 in lumbar cord). Hens given leptophos and TOCP demonstrated delayed neuropathy with obvious inhibition of NTE, but the times of onset and the degrees of peak inhibition of NTE activity were different: 6-24 hours after dosing and 73-82% of normal activity for leptophos, and 24-48 hours and 45-80% for TOCP, respectively. Furthermore, the average inhibition of NTE during 6-48 hours after dosing, (called here 'period average inhibition') was also significantly different between the leptophos group (63-73%) and TOCP group (40-64%). Hens given dipterex did not demonstrate delayed neuropathy, and had the least peak inhibition and period average inhibition of NTE activity among the 3 groups. Ratios of NTE inhibition/AChE inhibition were higher in the leptophos group (0.91-1.24) and TOCP group (1.13-2.45) than in the dipterex group (0.25-0.79). These results indicate that the distribution of NTE in the soluble fraction of membrane proteins is different in different regions of the CNS, and that the degree of peak inhibition of NTE activity and the time of onset of peak inhibition induced by organophosphorus compounds (OPs) also differ for different OPs. Thus, practical and useful NTE measurements should identify the peak inhibition and period inhibition in several nervous tissue regions.

Bovine chromaffin cells in culture show carboxylesterase activities sensitive to organophosphorus compounds

Carboxylesterase activities are widely distributed in a great variety of tissues; however, the biological function of these enzymes remains unclear. Some organophosphorus compounds induce a neurodegenarative syndrome related to the covalent modification of a carboxylesterase known as neuropathy target esterase. We investigated the expression of neuropathy target esterase and related carboxylesterase in bovine chromaffin cells with the aim of developing a potential in vitro model for studying the cellular function of carboxylesterase enzymes and toxic effects of organophosphorus compounds. Total phenyl valerate esterase exhibited an activity of 1.27 +/- 0.19 mU/10(5) cells (SD, n = 15). From the phenyl valerate esterase paraoxon and mipafox inhibition curves the following activities have been determined: B-activity (resistant to 40 microM paraoxon), 1.05 +/- 0.08 mU/10(5) cells (n = 8); C-activity (resistant to 40 microM paraoxon plus 250 microM mipafox), 0.12 +/- 0.05 mU/10(5) cells (n = 8); and neuropathy target esterase, calculated by the difference between B- and C-activities, 0.93 +/- 0.08 mU/10(5) cells (n = 8). All of these activities increased linearly with the number of cells and time of incubation with the substrate. Most of the phenol product of the reaction was released and detected in the extracellular medium. None of the components of the reaction were shown to affect cell viability when assessed by trypan blue exclusion. The study shows that bovine chromaffin cells possess carboxylesterase activities and respond to inhibition by paraoxon and mipafox, thus facilitating the discrimination of neuropathy target esterase. In conclusion, bovine chromaffin cells are appropriate as an in vitro cell model for studying toxic effects of organophosphorus compounds.

Comparative studies of two organophosphorus compounds in the mouse

A rodent model, the albino mouse, was used to investigate the in vitro and in vivo capacity of 2 organophosphate (OP) compounds, mipafox and ecothiopate, to inhibit enzymes considered to be involved in the mechanisms of OP toxicity. Mipafox and ecothiopate were chosen as model compounds because the former can produce a delayed neuropathy whereas the latter does not. Mipafox (110 mumol/kg, s.c.) inhibited brain acetylcholinesterase (AChE), neuropathy target esterase (NTE) and phenylvalerate hydrolases by 58, 64 and 65%, while diaphragm AChE and phenylvalerate hydrolases were inhibited by 66 and 80%, respectively. In contrast, ecothiopate (0.5 mumol/kg) had no effect on brain NTE or on brain or diaphragm phenylvalerate hydrolases. At the same time, diaphragm AChE was inhibited by 60% while brain AChE activity had increased by 15% of control. Mipafox was a potent inhibitor of AChE and NTE in vitro. Although ecothiopate was a highly potent anti-ChE in vitro, it had no inhibitory effect on NTE.

Separation of two forms of neuropathy target esterase in the soluble fraction of the hen sciatic nerve

Neuropathy target esterase (NTE) activity is operatively defined in this paper as the phenyl valerate esterase activity resistant to 40 microM paraoxon but sensitive to 250 microM mipafox. Molecular exclusion column chromatography with Sephacryl S-300 of the soluble (S) fraction from chick sciatic nerve demonstrated two NTE activity peaks. The first eluted with the front, thus indicating a mol. wt. of over 700 kDa (peak Vo), while the second peak eluted with kd = 0.36, suggesting a mol. wt. of about 100 kDa. The curve of total phenyl valerate (PVase) activity inhibition with paraoxon (0.19-200 microM) shows that at a concentration of 40 microM the esterases highly sensitive to paraoxon are inhibited in the Vo and 100-kDa peaks. The NTE activity in these two peaks in turn represented 31% and 44% of the 40 microM paraoxon resistant activity, respectively. The mipafox inhibition curves (1.0-250 microM) revealed different sensitivities to mipafox, with I50 values (t = 30 min) of approximately 1.47 and 63 microM, for Vo and 100-kDa peaks respectively. Mipafox sensitivity of the Vo and 100-kDa peaks correlates with the two components, that had been deduced from the kinetic properties of the S-fraction.

Partial characterization of neuropathy target esterase and related phenyl valerate esterases from bovine adrenal medulla

The mechanism by which organophosphorus-induced delayed polyneuropathy is induced relates to the specific inhibition and subsequent modification ("aging") of a protein known as neuropathy target esterase (NTE), operatively defined as paraoxon-resistant and mipafox-sensitive phenyl valerate (PV) esterase activity. This protein has fundamentally been investigated in hen brain, the latter being the habitually employed OPIDP study model. In the present article, a partial characterization is made of the NTE and other related PV esterases in the bovine adrenal medulla and brain; NTE sensitivity to the neurotoxic organophosphorus compound mipafox is investigated, and its subcellular distribution is studied. The NTE activity of the adrenal medulla was found to be the highest of those among the tissues studied to date (5000 +/- 1400 mU/g tissue; +/- SD, n = 12). This activity represented 93% of the PV esterase activity resistant to 40 microM paraoxon in the particulate fraction of the adrenal medulla and approximately 50% of total PV esterase activity. In the bovine brain, these proportions were 72 and 26%, respectively, i.e., similar to those described in hen brain. The mipafox inhibition curve of PV esterase activity resistant to 40 microM paraoxon in the particulate fraction of the adrenal medulla suggests that NTE activity fundamentally comprises a mipafox-sensitive component with an I50 of 6.39 microM at 30 minutes, which is similar to the value reported in hen brain. NTE activity in the bovine adrenal medulla is almost exclusively limited to the particulate fraction, the microsomal fraction, plasma membrane, and chromaffin granule-enriched fractions being the highest in terms of specific activity.(ABSTRACT TRUNCATED AT 250 WORDS)