EC:3.1.1.7 - FACTA Search

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Query: EC:3.1.1.7 (acetylcholinesterase)
28,390 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have studied the effects of anaesthesia on the changes in central respiratory activity following the inhibition of acetylcholinesterase in chronically implanted cats. The organophosphate paraoxon was administered to the brainstem respiratory centres by intracerebroventricular (i.c.v.) injection (3 mg) into the IVth ventricle, thus avoiding peripheral effects such as paralysis of respiratory muscles. Paraoxon had opposite effects on respiratory activity depending on whether the cats were anaesthetized or not: it induced respiratory depression and sometimes respiratory arrest during pentobarbital (30 mg/kg i.v.) or halothane anaesthesia, but in the same animals in the waking state, the same dose of paraoxon always stimulated respiration. These results show a strong interaction between anaesthetics and the effects of acetylcholine (ACh) accumulation on central respiratory activity. This study extends previous results showing an interaction between ACh and pentobarbital on single respiratory neurons and stresses the importance of a 'wakefulness stimulus' for sustaining respiratory activity after organophosphate poisoning.
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PMID:Central respiratory depression induced by acetylcholinesterase inhibition: involvement of anaesthesia. 369 38

1. Oxygen consumption in vitro and persistence in the general circulation of rabbit erythrocytes treated with the cholinesterase inhibitor paraoxon were determined.2. Paraoxon in vitro reduced oxygen consumption below a measureable level within 2 hours. By contrast, the metabolic inhibitor N-ethylmaleimide (NEM) produced complete inhibition within 15 minutes.3. Erythrocytes from rabbits orally dosed with parathion also exhibited marked depression of oxygen consumption.4. Glutathione (GSH) restored oxygen uptake to pretreatment levels within 15 min in erythrocytes previously inhibited with NEM or paraoxon.5. Erythrocytes treated with NEM were rapidly removed from the general circulation while paraoxon treated cells were removed at a rate comparable to untreated cells.
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PMID:Effect of paraoxon on erythrocyte metabolism as measured by oxygen uptake in vitro. 509 Nov 62

The detoxication of organophosphorus compounds by phosphorylphosphatases was studied in primates. Taking into account the distribution of paraoxonase (EC 3.1.1.2) and DFPase (EC 3.8.2.1) in different tissues of the monkey (Macaca mulatta), the total detoxicating capacity for diethyl-p-nitrophenylphosphate (paraoxon, E 600) and diisopropylphosphorofluoridate (DFP) was determined. Acetylcholinesterase (AChE) (EC 3.1.1.7) of human brain was inhibited in vitro by paraoxon and DFP. Using the rate constants of AChE-inhibition and of AChE-synthesis those concentrations of organophosphorus inhibitors were calculated, which in vivo would reduce the steady-state AChE-activity to 20% of normal. This acute ineffective concentration is 7.6 X 10(-8) g/kg for DFP and 2.3 X 10(-8) g/kg for paraoxon. From substrate kinetics of the phosphorylphosphatases the time course of paraoxon and DFP detoxication in primates could be calculated. The time needed by phosphorylphosphatases to reduce a certain dose of an organophosphorus compound to the acute ineffective concentration is referred to as "effective detoxication time". The effective detoxication time (teff) was determined for different concentrations of paraoxon and DFP and was compared with the time needed by these organophosphate concentrations to inhibit AChE-activity to 12.5% of normal (t1/8). The significance of in vitro data for the evaluation of dose limits of organophosphate toxicity in vivo is discussed.
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PMID:[Enzymatic detoxication of organophosphorus insecticides and nerve gases in primates]. 629 13

The esterase activity of guinea-pig serum was investigated. A 3-fold purification was achieved by removing the serum albumin by Blue Sepharose CL-6B affinity chromatography. The partially purified enzyme preparation had carboxylesterase and cholinesterase activities of 1.0 and 0.22 mumol of substrate/min per mg of protein respectively. The esterases were labelled with [3H]di-isopropyl phosphorofluoridate (DiPF) and separated electrophoretically on sodium dodecyl sulphate/polyacrylamide gels. Two main labelled bands were detected: band I had Mr 80 000 and bound 18-19 pmol of [3H]DiPF/mg of protein, and band II had Mr 58 000 and bound 7 pmol of [3H]DiPF/mg of protein. Bis-p-nitrophenyl phosphate (a selective inhibitor of carboxylesterase) inhibited most of the labelling of bands I and II. The residual labelling (8%) of band I but not band II (4%) was removed by preincubation of partially purified enzyme preparation with neostigmine (a selective inhibitor of cholinesterase). Paraoxon totally prevented the [3H]DiPF labelling of the partially purified enzyme preparation. Isoelectrofocusing of [3H]DiPF-labelled and uninhibited partially purified enzyme preparation revealed that there were at least two separate carboxylesterases, which had pI3.9 and pI6.2, a cholinesterase enzyme (pI4.3) and an unidentified protein that reacts with [3H]DiPF and has a pI5.0. Sodium dodecyl sulphate/polyacrylamide-gel electrophoresis of these enzymes showed that the carboxylesterase enzymes at pI3.9 and pI6.2 corresponded to the 80 000-Mr subunit (band I) and 58 000-Mr subunit (band II). The cholinesterase enzyme was also composed of 80 000-Mr subunits (i.e. the residual labelling in band I after bis-p-nitrophenyl phosphate treatment). The unidentified protein at pI5.0 corresponded to the residual labelling in band II (Mr 58 000), which was insensitive to neostigmine and bis-p-nitrophenyl phosphate. These studies show that the carboxylesterase activity of guinea-pig serum is the result of at least two separate and distinct enzymes.
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PMID:The identification and characterization of two separate carboxylesterases in guinea-pig serum. 662 82

We have investigated the effect of electromechanical activity on the molecular forms of acetylcholinesterase (AChE) in cultured embryonic rat myotubes. Both globular and asymmetric forms of AChE are present on the 5th day of culture when myotubes are just beginning to fibrillate. Between days 5 and 8, the 4 S (G1), 10 S (G4), and 16 S (A12) forms increase dramatically, and appreciable 12.5 S (A8) AChE appears. When fibrillation is prevented by adding tetrodotoxin on day 4, the increases in the A12 and A8 forms are prevented, and the increases in the G4 and G1 forms are significantly impaired. At 8 days, fibrillating myotubes have 19 times more A12 AChE and over 4 times more G1 and G4 enzyme than do nonfibrillating myotubes. The effect of tetrodotoxin is reversible. When tetrodotoxin is removed at 7 days, fibrillation resumes promptly, and globular and asymmetric forms recover. Light microscopic examination of fibrillating and nonfibrillating myotubes showed that tetrodotoxin does not affect the gross morphological development of the myotubes. Titration of AChE-active sites with O-ethyl-S2-diisopropyl methyl-phosphonothionate demonstrated that the increase in AChE activity associated with fibrillation is due to an increase in the number of AChE molecules present and not to an increase in the rate at which individual AChE molecules turn over acetylcholine. To evaluate AChE metabolism in fibrillating and nonfibrillating myotubes, we examined the enzyme after inactivating it with paraoxon. Paraoxon readily penetrates cells and diethylphosphorylates a serine in the active site of AChE, thereby inactivating it. The diethylphosphorylated enzyme is stable, but it can be reactivated rapidly and quantitatively with pyridine-2-aldoxime methiodide (2-PAM). After inactivating AChE with paraoxon, we simultaneously evaluated synthesis (by following the newly synthesized active AChE) and turnover (by following the 2-PAM-reactivatable AChE). Our results show that globular and asymmetric forms of AChE are both synthesized more rapidly in fibrillating than in nonfibrillating myotubes.
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PMID:The effect of spontaneous electromechanical activity on the metabolism of acetylcholinesterase in cultured embryonic rat myotubes. 669 37

Carboxylesterases (EC 3.1.1.1) of chicken brain were investigated by applying kinetic analysis of organophosphorus inhibition. By iterative elimination of exponential inhibition curves and by sequential inhibition experiments using a combination of two organophosphorus inhibitors, 11 different carboxylesterases of chicken brain were characterized with respect to their phenyl valerate-hydrolyzing activity (milliunits per gram of brain) and their inhibition by O,O-diethyl O-4-nitrophenyl phosphate (Paraoxon), O,O-diisopropylphosphorofluoridate, and N,N'-diisopropylphosphorodiamidic fluoride (Mipafox). The bimolecular inhibition rate constants (liters . mole-1 . min-1) were calculated for the 11 enzymes and 3 organophosphorus compounds. The corresponding data for acetylcholinesterase (EC 3.1.1.7) in chicken brain were determined. The importance of inhibition rate constants for the development of acute cholinergic symptoms, delayed neurotoxicity, and atypical organophosphate effects is shown.
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PMID:Inhibition of brain carboxylesterases by neurotoxic and nonneurotoxic organophosphorus compounds. 686 14

Cholinesterases in hen brain were characterized with respect to inhibition kinetics and substrate specificity. Three organophosphorus inhibitors were used: diethyl p-nitrophenyl phosphate (Paraoxon, E 600), di-isopropylphosphorofluoridate (DFP), and N,N'-di-isopropylphosphorodiamidic fluoride (Mipafox). The kinetics of irreversible cholinesterase inhibition were studied using two substrates, acetylthiocholine and butyrylthiocholine. The inhibition curves were analysed by the method of iterative elimination of exponential functions. Final classification of the different enzymes was done by combining two inhibitors in sequential inhibition expts. Six cholinesterases were shown to hydrolyse choline esters in hen brain, one was identified as acetylcholinesterase (EC 3.1.1.7) and one as cholinesterase (EC 3.1.1.8). Four enzymes can be classified as intermediate type cholinesterases according to their substrate specificity and to their inhibition constants. The possible role of different brain cholinesterases for the development of atypical symptoms following organophosphate intoxication is discussed.
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PMID:Brain cholinesterases. Differentiation of target enzymes for toxic organophosphorus compounds. 687 Sep 9

1 Intravenous administration of paraoxon (150-825 mug/kg) to anaesthetized rats induced long-lasting, dose-dependent pressor effects. Only after injection of 825 mug/kg paraoxon was the pressor response followed by a depressor effect and a bradycardia that could be blocked by N-methylatropine. Intracerebroventricular injection of paraoxon into anaesthetized rats also induced pressor effects.2 In order to elucidate the mechanism of the pressor action rats were given dexetimide, N-methylatropine, mecamylamine, phentolamine, prazosin, yohimbine, atenolol and metoprolol. If treatment with these drugs resulted in a low initial blood pressure, vasopressin was infused to elevate blood pressure to normal levels. The influence of adrenalectomy, pretreatment with reserpine and midcollicular transection was also examined.3 The pressor effect of paraoxon was not influenced by N-methylatropine or mecamylamine. However, a combination of these drugs as well as dexetimide, phentolamine or prazosin combined with yohimbine, reduced or prevented the pressor effect.4 In conscious rats the effects of paraoxon and the action of antimuscarinic drugs upon the pressor response were similar to those observed in anaesthetized animals.5 Acetylcholinesterase activities were measured in various brain regions and in whole blood. Paraoxon concentrations within the CNS were also measured.6 It is concluded that the pressor effect of paraoxon in anaesthetized and conscious rats is mediated by a central mechanism, although a contribution of peripheral acetylcholinesterase inhibition in sympathetic ganglia to this pressor effect cannot be ruled out.
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PMID:The effects of paraoxon on blood pressure in the anaesthetized and in the conscious rat. 713 83

A light addressable potentiometric sensor was used to measure acetylcholinesterase (AChE) activity in order to evaluate the protective effects of quaternary compounds and NaF against enzyme phosphorylation and aging by two organophosphates. The use of the immobilized AChE made possible the quick removal of reagents (i.e., organophosphate, 2-pralidoxime, and protectant), thereby permitting accurate determination of AChE activity before and after phosphorylation and aging. Paraoxon was 15-fold more potent in inhibiting AChE than DFP, while the percent aging following phosphorylation by diisopropylfluorophosphate (DFP) was much higher. Sodium fluoride (NaF), the most effective protectant against phosphorylation and aging, and the quaternary ammonium compounds reduced significantly AChE inhibition by DFP and paraoxon, to similar degrees. Even though the percent AChE activity that was lost to aging was reduced by these agents, aging as a percent of phosphorylated AChE was not reduced. Thus, their major effect was in reducing the percent AChE phosphorylation, which consequently resulted in reduction of total aged AChE. The finding that quaternary ammonium compounds protect against phosphorylation is consonant with the proposed presence of the active site of AChE in an aromatic gorge.
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PMID:Choline derivatives and sodium fluoride protect acetylcholinesterase against irreversible inhibition and aging by DFP and paraoxon. 785 61

The effect of phosphotriesterase (PTE) on cholinesterase (ChE) activities was studied with exposures to different organophosphates in mice. Paraoxon (PO) (1.0 mg/kg, ip) almost totally inhibited serum ChE activity. This activity, however, recovered to the normal level within 24 hr. The PTE pretreatment (16.8 U/animal, 2.5 micrograms/10 g body wt, iv 10 min before the organophosphate) accelerated this reactivation. The same phenomenon was also seen in vitro. In vitro with human serum, there was only minimal reactivation of the inhibited ChE. PTE, however, reactivated it significantly. The PTE-pretreated mice (168 U/animal, 30 micrograms/10 g body wt, iv) tolerated even 50 mg/kg of PO without showing any remarkable signs of intoxication. In PTE-untreated animals, however, PO doses as low as 1.0 and 1.5 mg/kg caused severe signs of poisoning. PTE (16.8 U/animal, 4 micrograms/10 g body wt, iv) reduced the inhibition of brain and serum ChE activities after PO and diisopropyl fluorophosphate exposure. In sarin and soman intoxications, PTE decreased only slightly the inhibition of ChE activities. The results indicate that PTE pretreatment given iv prevents the inhibition of ChE activities after certain organophosphates and it also hastens the recovery of activities after PO poisoning.
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PMID:Phosphotriesterase--a promising candidate for use in detoxification of organophosphates. 786 9

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