The alteration of the expression level of neuropathy target esterase in human neuroblastoma SK-N-SH cells disrupts cellular phospholipids homeostasis

Neuropathy target esterase (NTE) has been proven to act as a lysophospholipase (LysoPLA) and phospholipase B (PLB) in mammalian cells. In this study, we took human neuroblastoma SK-N-SH cells as the research object and explored the effect of NTE on phospholipid homeostasis. The results showed that phosphatidylcholine (PC) and lysophosphatidylcholine (LPC) levels significantly increased (> 40%), while glycerophosphocholine (GPC) decreased (below 60%) after NTE gene was knockdown in the cells (NTE < 30% of control), which were prepared by gene silencing with dsRNA-NTE. However, in the NTE-overexpressed cells (NTE > 50% of control), which were prepared by expressing recombinant catalytic domain of NTE, LPC remarkably decreased (below 80%) and GPC enhanced (> 40%). Mipafox, a neuropathic organophosphorus compound (OP), significantly inhibited NTE-LysoPLA and NTE-PLB activities (> 95–99% inhibition at 50 μM), which was accompanied with a decreased GPC level (below 40%) although no change of the PC and LPC levels was observed; while paraoxon, a non-neuropathic OP, suppresses neither the activities of NTE-phospholipases nor the levels of PC, LPC, and GPC. Thus, we concluded that both the stable up- or down-regulated expression of NTE gene and the loss of NTE-LysoPLA/PLB activities disrupts phospholipid homeostasis in the cells although the inhibition of NTE activity only decreased GPC content without altering PC and LPC levels.     

Electrophysiologic changes following treatment with organophosphorus-induced delayed neuropathy-producing agents in the adult hen

Although clinical, pathological, and biochemical effects of organophosphorus-induced delayed neuropathy (OPIDN) have been intensively investigated in the adult hen, detailed electrophysiological studies are lacking. Adult white leghorn hens were treated with a single oral dose of either 30 mg/kg tri-2-cresyl phosphate (TOCP), 750 mg/kg TOCP, 4 mg/kg di-n-butyl-2,2-dichlorovinyl phosphate (DBCV), or 30 mg/kg di-n-butyl-2,2-dichlorovinyl phosphinate (DBCV-P). The 750 mg/kg TOCP and DBCV, but not the 30 mg/kg TOCP and DBCV-P, treatments resulted in clinical signs of OPIDN and mild to marked damage of the tibial nerve 21 days after dose. Twenty-four hr lymphocyte neurotoxic esterase (NTE) inhibition was used as an index of brain NTE inhibition for the various organophosphorus compound (OP) treatment. Twenty-four hr lymphocyte NTE inhibition for 30 mg/kg TOCP, 750 mg/kg TOCP, DBCV, and DBCV-P was 54.1, 87.1, 84.8, and 68.3%, respectively. Twenty-one days after dose, the TOCP-treated hens exhibited some abnormalities in conduction velocity and action potential duration in the tibial or sciatic nerves. No abnormalities were observed in action potential parameters of either the DBCV or DBCV-P treatments. Neurotoxic OP (TOCP and DBCV) treatment resulted in decreased refractoriness in the tibial nerve, increased refractoriness in the sciatic nerve, and elevated strength duration threshold for both nerves. These changes were not present in nerves from DBCV-P (a non-neurotoxic NTE inhibitor)-treated hens. These results suggest that refractory period and strength duration abnormalities in peripheral nerve correlate well with the production of OPIDN and are evident without coincident clinical signs or histopathology.     

Potentiation of organophosphorus-induced delayed neurotoxicity by phenylmethylsulfonyl fluoride

It is well known that pretreatment with the serine esterase inhibitor phenylmethylsulfonyl fluoride (PMSF) can protect experimental animals from organophosphorus-induced delayed neurotoxicity (OPIDN), presumably by blocking the active site of neurotoxic esterase (NTE) such that binding and "aging" of the neuropathic OP is thwarted. We report here that while PMSF (60 mg/kg, sc) given 4 h before the neuropathic organophosphate (OP) mipafox (50 mg/kg, im) completely prevented the clinical expression of OPIDN in hens, the identical PMSF treatment markedly amplified the delayed neurotoxicity (relative to hens treated with OP only) if administered 4 h after mipafox (5 or 50 mg/kg, im). Moreover, in a separate experiment using diisopropylphosphorofluoridate (DFP) as the neurotoxicant in place of mipafox, posttreatment with PMSF 4 h after DFP (0.5 mg/kg) also accentuated the severity of ataxia. These data indicate that PMSF only protects against OPIDN if given prior to exposure to the neurotoxicant; treatment with PMSF after OP exposure critically exacerbates the delayed neurotoxicity from exposure to organophosphorus compounds.     

Triphenyl phosphite neurotoxicity in the hen: inhibition of neurotoxic esterase and of prophylaxis by phenylmethylsulfonyl fluoride

The neuropathic syndrome resulting in the cat and the rat from single or multiple doses of the phosphorous acid ester tiphenyl phosphite (TPP) has been reported to differ from the syndrome caused by numerous phosphoric acid esters, which is known as organophosphorous compound-induced delayed neurotoxicity (OPIDN). Since the hen is used to test compounds for OPIDN, we chose to study the neurotoxicity of single subcutaneous doses of TPP using this animal model. TPP (1000 mg/kg) produced progressive ataxia and paralysis which began to develop 5–10 days after dosing. Similar signs were observed when subcutaneous doses of the OPIDN-causing agents tri-o-cresyl phosphate (TOCP) or diisopropyl phosphorofluoridate (DFP) were administered. The minimum neurotoxic dose of TPP was 500 mg/kg. Prior administration of phenylmethylsulfonyl fluoride (PMSF) prevented the development of a neuropathy induced by DFP, but did not fully protect the hens from TPP or TOCP. PMSF slowed, but did not prevent, the neuropathy caused by TOCP. PMSF reduced the neurotoxicity of 500 mg/kg TPP, but increased the neurotoxicity of 1000 mg/kg TPP. TPP was found to be a very potent inhibitor of neurotoxic esterase (NTE), the putative target site for OPIDN, in vitro, with a k_i of about 2.1×10⁵ M^–1min^–1. Equimolar doses of either TPP (1000 mg/kg) and TOCP (1187 mg/kg) caused over 80% inhibition of neurotoxic esterase (NTE) in brain and sciatic nerve. This high level of NTE inhibition persisted for several weeks. This prolonged inhibition probably accounts for the inability of PMSF to block the neurotoxicity of TOCP. The dose-response curve for NTE inhibition 48 h after dosing indicated that a level of 70% inhibition correlated with the neurotoxicity of TPP.Subneurotoxic doses of TPP and DFP were found to have an additive effect which could be blocked by PMSF. These results indicate that TPP can cause OPIDN in the hen. The synergism between PMSF and the higher dose of TPP suggests the presence of a second neurotoxic effect as well.     

Lysophospholipase inhibition by organophosphorus toxicants

Lysophospholipases (LysoPLAs) are a large family of enzymes for removing lysophospholipids from cell membranes. Potent inhibitors are needed to define the importance of LysoPLAs as targets for toxicants and potential therapeutics. This study considers organophosphorus (OP) inhibitors with emphasis on mouse brain total LysoPLA activity relative to the mipafox-sensitive neuropathy target esterase (NTE)-LysoPLA recently established as 17% of the total activity and important in the action of OP delayed toxicants. The most potent inhibitors of total LysoPLA in mouse brain are isopropyl dodecylphosphonofluoridate (also for LysoPLA of Vibrio bacteria), ethyl octylphosphonofluoridate (EOPF), and two alkyl-benzodioxaphosphorin 2-oxides (BDPOs)[(S)-octyl and dodecyl] (IC50 2-8 nM). OP inhibitors acting in vitro and in vivo differentiate a more sensitive portion but not a distinct NTE-LysoPLA compared with total LysoPLA activity. For 10 active inhibitors, NTE-LysoPLA is 17-fold more sensitive than total LysoPLA, but structure-activity comparisons give a good correlation (r(2) = 0.94) of IC50 values, suggesting active site structural similarity or identity. In mice 4 h after intraperitoneal treatment with discriminating doses, EOPF, tribufos (a plant defoliant), and dodecanesulfonyl fluoride inhibit 41-57% of the total brain LysoPLA and 85-99% of the NTE-LysoPLA activity. Total LysoPLA as well as NTE-LysoPLA is decreased in activity in Nte(+/-)-haploinsufficient mice compared to their Nte(+/+) littermates. The lysolecithin level of spinal cord but not brain is elevated significantly following EOPF treatment (3 mg/kg), thereby focusing attention on localized rather than general alterations in lysophospholipid metabolism in OP-induced hyperactivity and toxicity.     

Organophosphorus-induced delayed neuropathy: A simple and efficient therapeutic strategy

Organophosphorus (OP) used as pesticides and hydraulic fluids can produce acute poisoning known as OP-induced delayed neuropathy (OPIDN), whose effects take long time to recover. Thus a secure therapeutic strategy to prevent the most serious effects of this poisoning would be welcome. In this study, tri-o-cresyl phosphate (TOCP, 500 mg/kg p.o.) was given to hens, followed or not by nimodipine (1 mg/kg i.m.) and calcium gluconate (Ca-glu 5 mg/kg i.v.). Six hours after TOCP intoxication, neuropathy target esterase (NTE) activity inhibition was observed, peaking after 24 h exceeding 80% inhibition. A fall in the plasmatic calcium levels was noted 12 h after TOCP was given and, in the sciatic nerve, Ca²⁺ fell 56.4% 24 h later; at the same time calcium activated neutral protease (CANP) activity increased 308.7%, an effect that lasted 14 days. Any bird that received therapeutic treatment after TOCP intoxication presented significant signs of OPIDN. These results suggest that NTE may be implicated in the regulation of calcium entrance into cells being responsible for the maintenance of normal function of calcium channels, and that increasing CANP activity is responsible to triggering OPIDN. Thus, with one suitably adjusted dose of nimodipine as well as Ca-glu, we believe that this treatment strategy may be used in humans with acute poisoning by neuropathic OP.     

Phenylmethylsulfonyl fluoride protects against the degradation of neurofilaments in tri-ortho-cresyl phosphate (TOCP) induced delayed neuropathy

Tri-ortho-cresyl phosphate (TOCP) is an organophosphorus ester, which can cause a type of neurotoxicity known as organophosphate-induced delayed neuropathy (OPIDN). Our recent study has shown that the enhanced degradation of neurofilament (NF) in peripheral nerve of hens is an early event of TOCP-induced OPIDN (Song et al., 2009). The main objective of this investigation is to study the effect of TOCP administration on NF content and NF degradation when OPIDN is blocked by pretreatment with phenylmethylsulfonyl fluoride (PMSF). The hens were pretreated 24 h earlier with PMSF and subsequently treated with a single dosage of 750 mg/kg TOCP, then sacrificed on the corresponding time points of 0, 1, 5, 10, and 21 days after dosing TOCP, respectively. The tibial nerves were dissected, homogenized, and centrifuged at 100,000 × g. The level of NF triplet protein in both pellet and supernatant fractions of tibial nerves was determined. Western blotting analysis showed a significant increase of three NF subunits in hens treated with PMSF and TOCP compared with the control. These changes were observed within 24 h of PMSF administration and then followed by an obvious recovery. Furthermore, accompanied with the increase of NF content, a significant decline in NF-L degradation rate was observed in both fractions of tibial nerves. Taken together, these results demonstrated the pretreatment with PMSF could inhibit TOCP-induced NF degradation while it protected hens against the development of OPIDN, which suggested the inhibition of NF-associated protease in peripheral nerves might be an underlying protective mechanism of PMSF against OPIDN.     

The time course of protection from delayed neurotoxicity induced by tri-o-cresyl phosphate and O,O-diisopropyl phosphorofluoridate by phenyl methyl sulfonyl fluoride in chickens

The time dependence of the ability of phenyl methyl sulfonyl fluoride (PMSF) to protect adult hens from developing signs of paralysis following the administration of 750 mg/kg tri-ortho-cresyl phosphate (TOCP), p.o., of 1.7 mg/kg O,O-diisopropyl phosphorofluoridate (DFP), s.c., was investigated. PMSF was able to protect the hens from organophosphorus-induced delayed neurotoxicity (OPIDN) when given between 1 and 24 h before the administration of TOCP, or when given 4 h before DFP. However, PMSF was ineffective at preventing paralysis when given 24 h following dosing with TOCP or when given later than 4 h before DFP administration. These results support the notion that PMSF acts at the same site as the organophosphorus esters.     

三邻甲苯磷酸酯暴露鸡脊髓组织中Cofilin-1b的差异表达

目的从三邻甲苯磷酸酯(TOCP)暴露鸡的脊髓组织中筛选可能与调控微丝解聚作用相关的差异表达蛋白,为探讨有机磷化合物诱发的迟发性神经毒性(OPIDN)作用机制提供靶蛋白依据。方法 42只罗曼鹤母鸡随机分成1000 mg/kg TOCP组、预先给予40 mg/kg苯甲基磺酰氟(PMSF)后再投1000 mg/kg TOCP的干预组和生理盐水对照组,每组14只。染毒第5和20天,每组分别处死4只鸡,低温环境下分离脊髓,提取总蛋白。利用双向电泳结合质谱分析技术,筛选和鉴定可能与调控微丝解聚作用相关的差异表达蛋白。结果 TOCP组鸡于染毒第7日前后出现进行性共济失调和肌无力等OPIDN典型症状,起病从下肢远端部分开始且病变程度随时间逐渐加重直至全瘫,而其他组鸡在实验观察期间未见OPIDN症状。TOCP组鸡于暴露第5天,分别与对照组和PMSF前干预组比较,其脊髓组织肌动蛋白解聚因子Cofilin-1b分别下调3.4倍和2.8倍,且有统计学意义(差异表达<0.5或差异表达>2),而PMSF前干预组与对照组比较,鸡脊髓组织Cofilin-1b的表达差异无统计学意义。在TOCP暴露第20天,TOCP组鸡脊髓组织Cofilin-1b表达与其他两组比较尽管有下降趋势,但无显著性变化。结论 TOCP暴露能导致鸡脊髓神经组织Cofilin-1b表达在早期显著下调,且该蛋白表达下调可能与微丝骨架结构紊乱及其OPIDN诱发机制有关。     

Organophosphate induced delayed neuropathy in genetically dissimilar chickens: studies with tri-ortho-cresyl phosphate (TOCP) and trichlorfon

Measurements of plasma cholinesterase (pl.ChE), brain cholinesterase (Br.ChE) and brain Neuropathy Target Esterase (Br.NTE) were made in three different lineages of chickens. All birds received toxicants through gavage in a single oral dose between 08:00 and 09:00 h, after overnight fast. Babcock chickens were treated with 800 mg/kg tri-ortho-cresyl phosphate (TOCP) or 80 mg/kg trichlorfon. The TOCP group had 82% Br.NTE inhibition, when compared to the control group, and no birds displayed symptoms of clinical organophosphate-induced delayed neuropathy (OPIDN). Hy-line w36 lineage chickens were given 1600 mg/kg TOCP and despite this higher dose, Br.NTE inhibition was similar that presented by Babcock chickens. Isabrown chickens were given 1600 mg/kg TOCP or 80 mg/kg trichlorfon. At 36 h all trichlorfon treated birds had from 80 to 90% inhibition of Pl.ChE and Br.ChE, when compared to controls. However, Br.NTE was inhibited less than 20%, and there were no clinical signs of OPIDN. All TOCP treated isabrown chickens had more than 80% Br.NTE inhibition while one of them exhibited just light signs of OPIDN, two chickens became totally paralyzed. This finding suggested that chicken strain was important in the appearance of OPIDN. In addition, 70-80% of NTE inhibition was necessary but was not sufficient to produce OPIDN in chickens, since babcock and hy-line w36 chickens exhibited NTE inhibition in the range of 70-80% without clinical signs of OPIDN.     

Identification of differentially expressed proteins related to organophosphorus‐induced delayed neuropathy in the brains of hens

Some organophosphorus compounds can cause organophosphate‐induced delayed neuropathy (OPIDN). Incidents have been documented for decades, however, little is known about which proteins contribute to the initiation, progression and development of OPIDN. In this study, 51 hens were divided into three groups. The tri‐ortho‐cresyl‐phosphate (TOCP) group was treated with 1000 mg kg^–1 TOCP whereas the control group was treated with an equivalent volume of vehicle. The PMSF + TOCP group was treated subcutaneously with 40 mg kg^–1 phenylmethylsulfonyl fluoride (PMSF), followed by 1000 mg kg^–1 TOCP 24 h later. Proteins in the brains of hens were separated by two‐dimensional polyacrylamide gel electrophoresis on day 5 after TOCP administration. Mass spectrometry identified eight differentially expressed proteins. Among these proteins, downregulated expression of glutamine synthetase (GS) in the brains of hens after TOCP treatment was further confirmed by real time RT‐PCR and ELISA. Moreover, the brains of hens exposed to TOCP exhibited increased levels of glutamate (Glu) and cytosolic calcium concentration ([Ca²⁺]_i), and a decreased level of glutamine (Gln). However, there were no significant differences in GS expression or levels of Glu, Gln, and [Ca²⁺]_i in the brains of hens among the groups on day 21 after TOCP administration. These results indicate that TOCP exposure downregulates GS expression in the brains of hens, and that downregulation of GS is accompanied by increased levels of Glu and [Ca²⁺]_i in the early stage after TOCP administration. It is also suggested that the downregulated expression of GS might be associated with OPIDN through the disruption of homeostasis of the Glu–Gln cycle and [Ca²⁺]_i. Copyright © 2013 John Wiley & Sons, Ltd.     

Changes in beclin-1 and micro-calpain expression in tri-ortho-cresyl phosphate-induced delayed neuropathy

Tri-ortho-cresyl phosphate (TOCP) can cause toxic neuropathy known as organophosphate-induced delayed neuropathy (OPIDN), which is pathologically characterized by the swollen axon containing aggregations of neurofilaments, microtubules, and multivesicular vesicles. Autophagy is a self-degradative process which plays a housekeeping role in removing misfolded proteins and damaged organelles. The current study was designed to investigate the possible roles of autophagy in the pathogenesis of OPIDN. Adult hens were treated with a dose of 750mg/kg TOCP by gavage, or injected subcutaneously with 60mg/kg phenylmethanesulfonyl fluoride (PMSF) dissolved in DMSO 24h earlier and subsequently treated with TOCP, then sacrificed on the time-points of 0, 1, 5, 10, and 21 days after dosing of TOCP respectively. The levels of beclin-1 and μ-calpain in tibial nerves and spinal cords were determined by immunoblotting. The results showed that in both tissues TOCP increased the expression of μ-calpain while decreased that of beclin-1. When given before TOCP administration, PMSF pretreatment could protect hens against the delayed neuropathy. In the meantime, pretreatment with PMSF reduced calpain expression below basal and increased beclin-1 expression above basal in tibial nerve, whereas it simply returned calpain and beclin-1 expression to their basal levels in spinal cord. In conclusion, the intoxication of TOCP was associated with a significant change of beclin-1 in hen nervous tissues, which suggested that disruption of autophagy-regulated machinery in neurons might be involved in the pathogenesis of OPIDN.     

Biochemical, histopathological and clinical evaluation of delayed effects caused by methamidophos isoforms and TOCP in hens: Ameliorative effects using control of calcium homeostasis

This work evaluated the potential of the isoforms of methamidophos to cause organophosphorus-induced delayed neuropathy (OPIDN) in hens. In addition to inhibition of neuropathy target esterase (NTE) and acetylcholinesterase (AChE), calpain activation, spinal cord lesions and clinical signs were assessed. The isoforms (+)-, (±)- and (-)-methamidophos were administered at 50mg/kg orally; tri-ortho-cresyl phosphate (TOCP) was administered (500mg/kg, po) as positive control for delayed neuropathy. The TOCP hens showed greater than 80% and approximately 20% inhibition of NTE and AChE in hen brain, respectively. Among the isoforms of methamidophos, only the (+)-methamidophos was capable of inhibiting NTE activity (approximately 60%) with statistically significant difference compared to the control group. Calpain activity in brain increased by 40% in TOCP hens compared to the control group when measured 24h after dosing and remained high (18% over control) 21 days after dosing. Hens that received (+)-methamidophos had calpain activity 12% greater than controls. The histopathological findings and clinical signs corroborated the biochemical results that indicated the potential of the (+)-methamidophos to be the isoform responsible for OPIDN induction. Protection against OPIDN was examined using a treatment of 2 doses of nimodipine (1mg/kg, i.m.) and one dose of calcium gluconate (5mg/kg, i.v.). The treatment decreased the effect of OPIDN-inducing TOCP and (+)-methamidophos on calpain activity, spinal cord lesions and clinical signs.     

Effects of calcium gluconate and PMSF in the treatment of acute intoxication of chicken by TOCP

To examine the efficacy of calcium gluconate (two doses of Ca-Glu 5 mg/kg i.v.) to alleviate the injurious effects of organophosphorus induced delayed neuropathy (OPIDN) in the presence or absence of phenylmethanesulfonyl fluoride (PMSF 90 mg/kg i.m.), 14 groups of four isabrown hens were used. To measure the lymphocyte neuropathy target esterase (LNTE)activity, groups receiving just distilled water (control), groups receiving just Tri-orto-cresyl phosphate (TOCP; 500 mg/kg p.o.) (Positive control), and other groups receiving TOCP and Ca-Glu or PMSF simultaneously or 12 hours later following intoxication by TOCP were used. They were sacrificed 12 and 24 hours after the administration of TOCP. To observe a 28-day time course of neurotoxicity scores and calcium plasma concentration, five groups were used. Regarding free Ca(2+)in the plasma, the positive control produced a characteristic profile time course up and down during 28 days, and some hens with maximum score of neurotoxicity in 28 days. The treatment, which prevented greater oscillation in free Ca(2+) in the plasma, presented a decrease in OPIDN in relation to the positive control. Twelve hours after the administration of TOCP, LNTE was 70-80% inhibited when compared with control, whereas the first decrease in the free Ca(2+) in the plasma was significantly different from the control only 24 hours after the administration of TOCP. In summary, the sooner the Ca-Glu is started, the less severe the neuropathy effects.     

Phenylmethylsulfonyl fluoride protects rats from Mipafox-induced delayed neuropathy

Initiation of organophosphorus-induced delayed neuropathy (OPIDN) is thought to consist of two molecular events involving the phosphorylation of the target enzyme, neurotoxic esterase, or neuropathy target enzyme (NTE), and a subsequent “aging” reaction which transforms the inhibited NTE into a charged moiety critical to the neuropathic process. Compounds that inhibit NTE but cannot age because of their chemical structure abort this two-stage initiation process, and when administered before a neurotoxic organophosphorus compound (OP), protect against the neuropathy by blocking NTE's active site (Johnson, 1970). In support of this, we report that prior exposure to a nonaging NTE inhibitor, phenylmethylsulfonyl fluoride (PMSF), protects rats from neurological damage after subsequent exposure to a neurotoxic OP, Mipafox. Adult, male, Long Evans rats were exposed to either PMSF (250 mg/kg, sc) or to Mipafox (15 mg/kg, ip) and a time course of brain NTE inhibition and recovery was defined. A separate group of PMSF-treated rats was exposed to Mipafox when brain NTE inhibition was 87.7 ± 2.3%. Conversely, another group of rats, pretreated with Mipafox, was dosed with PMSF when NTE inhibition was 90.2 ± 0.8%. A third group of animals, treated with PMSF, was exposed to Mipafox 14 days later, when NTE activity had recovered to within 10 ± 4.2% of control amounts. Histopathological survey (14 to 21 days post-exposure) indicated severe cervical cord damage (damage score ≥3) in the follwing frequencies: PMSF, 0%; Mipafox, 85%; PMSF-4 hr-Mipafox, 0%; Mipafox-4 hr-PMSF, 100%; PMSF-14 days-Mipafox, 75%; controls, 0%. These data indicate that PMSF pretreatment protects rats against Mipafox-induced neurological damage and that the timing of administration and order of presentation are critical to this protection. These results support the hypothesis that the initiation of OPIDN is a multistage event involving inhibition and aging, and that these stages are experimentally separable.     

Biosensor detection of neuropathy target esterase in whole blood as a biomarker of exposure to neuropathic organophosphorus compounds

Neuropathy target esterase (NTE) is the target protein for neuropathic organophosphorus (OP) compounds that produce OP compound-induced delayed neurotoxicity (OPIDN). Inhibition/aging of brain NTE within hours of exposure predicts the potential for development of OPIDN in susceptible animal models. Lymphocyte NTE has also found limited use as a biomarker of human exposure to neuropathic OP compounds. Recently, a highly sensitive biosensor was developed for NTE activity using a tyrosinase carbon-paste electrode for amperometric detection of phenol produced by hydrolysis of the substrate, phenyl valerate. The I50 (20 min at 37 degrees C) for N,N'-di-2-propylphosphorodiamidofluoridate (mipafox) against hen lymphocyte NTE was 6.94 +/- 0.28 microM amperometrically and 6.02 +/- 0.71 microM colorimetrically. For O,O-di1-propyl O-2,2-dichlorvinyl phosphate (PrDChVP), the I50 against hen brain NTE was 39 +/- 8 nM amperometrically and 42 +/- 2 nM colorimetrically. The biosensor enables NTE to be assayed in whole blood, whereas this cannot be done with the usual colorimetric method. Amperometrically, I50 values for PrDChVP against hen and human blood NTE were 66 +/- 3 and 70 +/- 14 nM, respectively. To study the possibility of using blood NTE inhibition as a biochemical marker of neuropathic OP compound exposure, NTE activities in brain and lymphocytes as well in brain and blood were measured 24 h after dosing hens with PrDChVP. Brain, lymphocyte, and blood NTE were inhibited in a dose-responsive manner, and NTE inhibition was highly correlated between brain and lymphocyte (r = .994) and between brain and blood (r = .997). The results suggest that the biosensor NTE assay for whole blood could serve as a biomarker of exposure to neuropathic OP compounds as well as a predictor of OPIDN and an adjunct to its early diagnosis.     

Subchronic Delayed Neurotoxicity Evaluation of Jet Engine Lubricants Containing Phosphorus Additives

Synthetic polyol-based lubricating oils containing 3% of eithercommercial tricresyl phosphate (TCP), triphenylphosphorothionate(TPPT), or butylated triphenyl phosphate (BTP) additive wereevaluated for neurotoxicity in the adult hen using clinical,biochemical, and neuropathological endpoints. Groups of 17–20hens were administered the oils by oral gavage at a "limit dose"of 1 g/kg, 5 days a week for 13 weeks. A group of positive controlhens was included which received 7.5 mg/kg of one isomer ofTCP (tri-ortho-cresyl phosphate, TOCP) on the same regimen,with an additional oral dose of 500 mg/kg given 12 days beforethe end of the experiment. A negative control group receivedsaline. Neurotoxic esterase (NTE) activity in brain and spinalcord of hens dosed with the lubricating oils was not significantlydifferent from saline controls after 6 weeks of treatment. After13 weeks of dosing, NTE was inhibited 23 to 34% in brains oflubricant-treated hens. Clinical assessments of walking abilitydid not indicate any differences between the negative controlgroup and lubricant-treated hens. Moreover, neuropathologicalexamination revealed no alterations indicative of organophosphorus-induceddelayed neuropathy (OPIDN). in hens treated with the positivecontrol, significant inhibition of NTE was observed in brainand spinal cord at both 6 and 13 weeks of dosing; this groupalso demonstrated clinical impairment and pathological lesionsindicative of OPIDN. In conclusion, the results of the presentstudy indicated that synthetic polyol-based lubricating oilscontaining up to 3% TCP, TPPT, or BTP had low neurotoxic potentialand should not pose a hazard under realistic conditions of exposure.     

Potentiation of Organophosphorus-Induced Delayed Neurotoxicity Following Phenyl Saligenin Phosphate Exposures in 2-, 5-, and 8-Week-Old Chickens

Phenylmethylsulfonyl fluoride (PMSF), a nonneuropathic inhibitorof neurotoxk esterase (NTE), is a known potentiator of organophosphorus-induceddelayed neurotoxicity (OPIDN)- The ability of PMSF posttreatment(90 mg/kg, sc, 4 hr after the last PSP injection) to modifydevelopment of delayed neurotoxicity was examined in 2-, 5-,and 8-week-old White Leghorn chickens treated either one, two,or three times (doses separated by 24 hr) with the neuropathicOP compound phenyl saligenin phosphate (PSP, 5 mg/kg, sc). NTEactivity was measured in the cervical spinal cord 4 hr afterthe last PSP treatment. Development of delayed neurotoxicitywas measured over a 16-day postexposure period. All PSP-treatedgroups exhibited >97% NTE inhibition regardless of age ornumber of OP treatments. Two-week-old birds did not developclinical signs of neurotoxicity in response to either singleor repeated OP treatment regimens nor following subsequent treatmentwith PMSF. Five-week-old birds were resistant to the clinicaleffects of a single PSP exposure and were minimally affectedby repeated doses. PMSF posttreatment, however, significantlyamplified the clinical effects of one, two, or three doses ofPSP. A single exposure to PSP induced slight to moderate signsof delayed neurotoxicity in 8-week-old birds with more extensiveneurotoxicity being noted following repeated dosing. As with5-week-old birds, PMSF exacerbated the clinical signs of neurotoxicitywhen given after one, two, or three doses of PSP in 8-week-oldbirds. Axonal degeneration studies supported the clinical findings:PMSF posttreatment did not influence the degree of degenerationin 2-week-old chickens but resulted in more severe degeneration(relative to PSP only exposure) in cervical cords from both5- and 8-week-old birds. The results indicate that PMSF doesnot alter the progression of delayed neurotoxicity in very young(2 weeks of age) chickens but potentiates PSP-induced delayedneurotoxicity in the presence of 0–3% residual NTE activityin older animals. We conclude that posttreatment with neuropathicor nonneuropathic NTE inhibitors, following virtually completeNTE inhibition by either single or repeated doses of a neuropathicagent in sensitive age groups, can modify both the clinicaland morphological indices of delayed neurotoxicity. This studyfurther supports the hypothesis that potentiation of OPIDN occursthrough a mechanism unrelated to NTE.     

TOCP对鸡淋巴细胞神经病靶酯酶抑制的研究

对磷酸三邻甲苯酯(TOCP)染毒母鸡进行淋巴细胞神经病靶醋酶(NTE)活性测定,发现所有染毒组动物在染毒后24～48小时发生NTE活性抑制。其中NTE活性抑制≥69.5%的鸡,在染毒后8～17天全部出现迟发性神经病症状。提示淋巴细胞NTE活性测定对早期判断有机磷迟发性神经病的发生有参考价值。     

Inhibition of Hen Brain Acetylcholinesterase and Neurotoxic Esterase by Chlorpyrifos in Vivo and Kinetics of Inhibition by Chlorpyrifos Oxon in Vitro: Application to Assessment of Neuropathic Risk

Chlorpyrifos (CPS; O,O-diethyl 3,5,6-trichloro-2-pyridyl phosphorothionate;Dursban) is a widely used broad-spectrum organophosphorus (OP)insecticide. Because some OP compounds can cause a sensory-motordistal axonopathy called OP compound-induced delayed neurotoxicity(OPIDN), CPS has been evaluated for this paralytic effect. Earlystudies of the neurotoxicity of CPS in young and adult hensreported reversible leg weakness but failed to detect OPIDN.More recently, a human case of mild OPIDN was reported to resultfrom ingestion of a massive dose (about 300 mg/kg) in a suicideattempt. Subsequent experiments in adult hens (the currentlyaccepted animal model of choice for studies of OPIDN) showedthat doses of CPS in excess of the LD₅₀ in atropine-treatedanimals inhibited brain neurotoxic esterase (NTE) and producedmild to moderate ataxia. Considering the extensive use of CPSand its demonstrated potential for causing OPIDN at supralethaldoses, additional data are needed to enable quantitative estimatesto be made of the neuropathic risk of this compound. Previouswork has shown that the ability of OP insecticides to causeacute cholinergic toxicity versus OPIDN can be predicted fromtheir relative tendency to inhibit the intended target, acetylcholinesterase(AChE), versus the putative neuropathic target, NTE, in braintissue. The present study was designed to clarify the magnitudeof neuropathic risk associated with CPS exposures by measuringhen brain AChE and NTE inhibition following dosing in vivo anddetermining the bimolecular rate constant of inhibition (k₁)for each enzyme by the active metabolite, CPS oxon (CPO), invitro. CPS administered to atropine-treated adult hens at 0,75, 150, and 300 mg/kg po in corn oil produced mean values forbrain AChE inhibition 4 days after dosing of 0, 58, 75, and86%, respectively, and mean values for brain NTE inhibitionof 0, 21, 40, and 77%, respectively. Only the high dose (sixtimes the unprotected LD₅₀ in hens) produced NTE inhibitionabove the presumed threshold of 70%, and these animals werein extremis from cholinergic toxicity at the time of euthanizationdespite continual treatment with atropine. When 150 mg/kg CPSpo in corn oil was given to atropine-treated hens on Day 0,inhibition on Days 1, 2,4, 8, and 16 for brain AChE was 86,82, 72, 44, and 29%, respectively, and for brain NTE was 30,28, 38, 29, and 6%, respectively. No signs of OPIDN were observedin any of the animals during the 16-day study period. Kineticstudies of the inhibition of hen brain AChE and NTE by CPO invitro demonstrated that CPO exhibits high potency and extraordinaryselectivity for its intended target, AChE. The k₁, values were15.5 µM^–1 min^–1 for AChE and 0.145 µM^–1min^–1 for NTE. The calculated fixed-time (20-min) I₅₀values were 2.24 nM for AChE and 239 nM for NTE, yielding anI₅₀ ratio for NTE/AChE of 107. These results may be comparedwith data compiled for other OP compounds with respect to NTE/AChEI₅₀ ratios and the corresponding doses required to produce OPIDNrelative to the LD₅₀. In general, NTE/AChE I₅₀ ratios greaterthan 1 indicate that the dose required to produce OPIDN is greaterthan the LD₅₀. Taken together, the results of this study indicatethat acute exposures to CPS would not be expected to cause OPIDNexcept under extreme conditions such as attempted suicides involvingmedically assisted survival of doses considerably in excessof the LD₅₀.