Inhibitor Report for: MEPQ

We have successfully demonstrated that exogenously administered acetyl- or butyrylcholinesterase (AChE, BChE respectively) will sequester organophosphates (OPs) before they reach their physiological targets. In addition, a third enzyme, endogenous carboxylesterase is known to be capable of scavenging OPs. In these studies, we have administered AChE and BChE to three different species of animals (mice, marmosets and monkeys) which were challenged with three different OPs (VX, MEPQ and soman). Results obtained from these systematic studies demonstrate that: (a) a quantitative linear correlation exists between blood AChE levels and the protection afforded by exogenously administered ChEs in animals challenged with OP, (b) approximately one mole of either AChE or BChE sequesters one mole of OP, (c) such prophylactic measures are sufficient to protect animals against OPs without the administration of any supportive drugs. Thus the OP dose, the blood-level of esterase, the ratio of the circulating enzyme to OP challenge, and the rate of reaction between them determine the overall efficacy of an enzyme as a pretreatment drug. The biochemical mechanism underlying the sequestration of various OPs by the use of exogenously administered scavenging esterases is the same in all species of animals studied. Therefore, the extrapolation of the results obtained by the use of ChE prophylaxis in animals to humans should be more reliable and effective than extrapolating the results from currently used multidrug antidotal modalities.

7-(Methylethoxy phosphinyloxy)-1-methyl-quinolinium iodide (MEPQ), a powerful anti-cholinesterase methylphosphonate ester, was labeled with tritium (9 Ci/mmol) at the methylphosphonyl moiety (TCH2P(O)(OR)X) by an iodine-tritium replacement reaction. Kinetic measurements of the rate of inhibition of acetylcholinesterase (AChE) by [3H]MEPQ and its rate of hydrolysis in alkaline solution confirmed the identity of [3H]MEPQ with authentic MEPQ, which was prepared by the same reaction sequences. Gel-filtration experiments verified the radiospecificity of [3H]MEPQ. In vitro radiolabeling of both AChE and butyrylcholinesterase along with the whole-body autoradiography of [3H]MEPQ-treated mice suggests that [3H]MEPQ is a convenient marker for studying biological systems containing these esterases.

To substantiate reported data and improve the properties of anticholinesterase drugs in blood-brain barrier (B-BB) research, 7-(methylethoxyphosphinyloxy) 1-methyl-quinolinium iodide (MEPQ) was prepared and evaluated as an inhibitor of both acetyl- and butyrylcholinesterase (AChE and BuChE, respectively) from various sources. The second-order rate constants for the inhibition of cholinesterase from eel, mice brain and horse serum at 25 degrees were found to be 5.3 X 10(8), 1.3 X 10(8) and 5.4 X 10(7) M-1 min-1 respectively. The inhibited enzyme could be reactivated by 1-methyl-2-hydroxy iminomethylpyridinium iodide (2-PAM). The two enantiomers of the racemic mixture MEPQ inhibited AChE at similar rates. Low concentrations of AChE could be determined by the residual enzyme activity and by fluorescence measurements of the leaving group, thus suggesting the application of MEPQ as a sensitive titrant of cholinesterase, as well as a potential tool in studying B-BB permeability changes.

The kinetic behaviour of Drosophila melanogaster acetylcholinesterase toward its substrate shows, in comparison with classic Michaelis-Menten kinetics, an apparent homotropic cooperative double activation-inhibition pattern. In order to construct an appropriate kinetic model and obtain further information on the mechanism of the catalytic action of this enzyme, the hydrolysis of acetylthiocholine in the absence and presence of different concentrations of synthetic quaternary methylphosphonate, 7-(methylethoxyphosphinyloxy)1-methyl-quinolinium iodide (MEPQ), was followed on a stopped-flow apparatus. The reaction at low substrate concentrations was followed until the change of the absorbance became negligible and at high concentrations only initial parts were recorded. A simultaneous analysis of the progress curves using numerical integration showed that the powerful organophosphonate inhibitor binds and compete with the substrate for the same binding sites. The results are also in accordance with the hypothesis that virtually every substrate or quasi-substrate molecule that enters into the gorge of active site is hydrolysed.

Single and multiple site mutants of recombinant mouse acetylcholinesterase (rMoAChE) were inhibited with racemic 7-(methylethoxyphosphinyloxy)-1-methylquinolinium iodide (MEPQ) and the resulting mixture of two enantiomers, CH3PR,S(O)(OC2H5)-AChE(EMPR,S-AChE), were subjected to reactivation with 2-(hydroxyiminomethyl)-1-methylpyridinium methanesulfonate (P2S) and 1-(2'-hydroxyiminomethyl-1'-pyridinium)-3-(4"-carbamoyl-1"- pyridinium)-2-oxapropane dichloride (HI-6). Kinetic analysis of the reactivation profiles revealed biphasic behavior with an approximate 1:1 ratio of two presumed reactivatable enantiomeric components. Equilibrium dissociation and kinetic rate constants for reactivation of site-specific mutant enzymes were compared with those obtained for wild-type rMoAChE, tissue-derived Torpedo AChE and human plasma butyrylcholinesterase. Substitution of key amino acid residues at the entrance to the active-site gorge (Trp-286, Tyr-124, Tyr-72, and Asp-74) had a greater influence on the reactivation kinetics of the bisquaternary reactivator HI-6 compared with the monoquaternary reactivator P2S. Replacement of Phe-295 by Leu enhanced reactivation by HI-6 but not by P2S. Of residues forming the choline-binding subsite, the E202Q mutation had a dominant influence where reactivation by both oximes was decreased 16- to 33-fold. Residues Trp-86 and Tyr-337 in this subsite showed little involvement. These kinetic findings, together with energy minimization of the oxime complex with the phosphonylated enzyme, provide a model for differences in the reactivation potencies of P2S and HI-6. The two kinetic components of oxime reactivation of MEPQ-inhibited AChEs arise from the chirality of O-ethyl methylphosphonyl moieties conjugated with Ser-203 and may be attributable to the relative stability of the phosphonyl oxygen of the two enantiomers in the oxyanion hole.

Advances in the treatment of organophosphorus (OP) toxicity have focussed on the use of exogenous cholinesterases to act as scavengers for the OP agent. To further investigate the feasibility of the scavenger approach, we evaluated the effects of highly purified horse serum butyrylcholinesterase (HS-BChE) on performance in rats. HS-BChE (5000 U, IP) produced substantial increases in blood enzyme activity for up to 72 h after injection. HS-BChE (5000 U, IP) had no effect on acquisition or retention of a passive avoidance task. In contrast, atropine sulfate (10 mg/kg) impaired retention when tested 168 h after administration. When examined for 10 days following administration, HS-BChE (7500 U, IP) had no effect on either total daily motor activity or circadian pattern of activity. HS-BChE (5000 U, IM) also had no acute or prolonged effects on the rate of lever pressing maintained by a VI56 s schedule of food reinforcement. HS-BChE (7500 U, IM) was observed to confer significant, but partial, protection against response rate decreases produced by the OP, MEPQ, under the VI56 s schedule of reinforcement. These results suggest that, in rats, HS-BChE, at doses that attenuate OP toxicity, may be devoid of cognitive or motor effects.

Monoclonal antibodies (mAbs) were prepared against native or DFP-inhibited Torpedo californica acetylcholinesterase and native or DFP-, MEPQ-, and soman-inhibited fetal bovine serum acetylcholinesterase. The cross reactivity of these antibodies with acetylcholinesterases from various species and their ability to inhibit catalytic activity were determined. Eight antibodies were found to inhibit catalytic activity of either Torpedo or fetal bovine serum enzyme. In all cases the antibodies bound to the native form of the enzymes and in some cases even to the denatured form. None of the antibodies recognized human or horse serum butyrylcholinesterase. Sucrose density gradient centrifugation of enzyme-antibody complexes provided two types of profiles, one with multiple peaks, indicating numerous complexes between tetrameric forms of the enzyme, and the other with single peaks, demonstrating complex formation within the tetrameric form. Different antibodies appeared to interact with slightly different regions, but in all cases the binding encompassed the peripheral anionic site. Decrease in catalytic activity of the enzyme was most likely caused by conformational changes in the enzyme molecule resulting from interaction with these mAbs.

We have successfully demonstrated that exogenously administered acetyl- or butyrylcholinesterase (AChE, BChE respectively) will sequester organophosphates (OPs) before they reach their physiological targets. In addition, a third enzyme, endogenous carboxylesterase is known to be capable of scavenging OPs. In these studies, we have administered AChE and BChE to three different species of animals (mice, marmosets and monkeys) which were challenged with three different OPs (VX, MEPQ and soman). Results obtained from these systematic studies demonstrate that: (a) a quantitative linear correlation exists between blood AChE levels and the protection afforded by exogenously administered ChEs in animals challenged with OP, (b) approximately one mole of either AChE or BChE sequesters one mole of OP, (c) such prophylactic measures are sufficient to protect animals against OPs without the administration of any supportive drugs. Thus the OP dose, the blood-level of esterase, the ratio of the circulating enzyme to OP challenge, and the rate of reaction between them determine the overall efficacy of an enzyme as a pretreatment drug. The biochemical mechanism underlying the sequestration of various OPs by the use of exogenously administered scavenging esterases is the same in all species of animals studied. Therefore, the extrapolation of the results obtained by the use of ChE prophylaxis in animals to humans should be more reliable and effective than extrapolating the results from currently used multidrug antidotal modalities.

Fetal bovine serum acetylcholinesterase (FBS-AChE, EC 3.1.1.7) was titrated, both in vitro and in vivo, with a highly toxic anti-ChE organophosphate, 7-(methylethoxyphosphinyloxy)-1-methyl-quinolinium iodie (MEPQ). Approximately 1:1 stoichiometry was obtained for the sequestration of MEPQ by FBS-AChE in mice. A quantitative, linear correlation was demonstrated between blood-AChE levels and the protection afforded by exogenously administered AChE in mice when challenged with anti-ChE MEPQ. The results presented in this report demonstrate that such prophylactic measures are indeed sufficient to protect animals against poisoning by as high as an 8 x LD50 dose of organophosphate without the administration of any supportive drug. Despite the relatively large toxic dose, most of the mice that survived the challenge did not show any classical clinical signs of severe anti-ChE poisoning. MEPQ may be considered a suitable model compound for studying the quantitative aspects of the scavenger prophylactic approach described here.

7-(Methylethoxy phosphinyloxy)-1-methyl-quinolinium iodide (MEPQ), a powerful anti-cholinesterase methylphosphonate ester, was labeled with tritium (9 Ci/mmol) at the methylphosphonyl moiety (TCH2P(O)(OR)X) by an iodine-tritium replacement reaction. Kinetic measurements of the rate of inhibition of acetylcholinesterase (AChE) by [3H]MEPQ and its rate of hydrolysis in alkaline solution confirmed the identity of [3H]MEPQ with authentic MEPQ, which was prepared by the same reaction sequences. Gel-filtration experiments verified the radiospecificity of [3H]MEPQ. In vitro radiolabeling of both AChE and butyrylcholinesterase along with the whole-body autoradiography of [3H]MEPQ-treated mice suggests that [3H]MEPQ is a convenient marker for studying biological systems containing these esterases.

To substantiate reported data and improve the properties of anticholinesterase drugs in blood-brain barrier (B-BB) research, 7-(methylethoxyphosphinyloxy) 1-methyl-quinolinium iodide (MEPQ) was prepared and evaluated as an inhibitor of both acetyl- and butyrylcholinesterase (AChE and BuChE, respectively) from various sources. The second-order rate constants for the inhibition of cholinesterase from eel, mice brain and horse serum at 25 degrees were found to be 5.3 X 10(8), 1.3 X 10(8) and 5.4 X 10(7) M-1 min-1 respectively. The inhibited enzyme could be reactivated by 1-methyl-2-hydroxy iminomethylpyridinium iodide (2-PAM). The two enantiomers of the racemic mixture MEPQ inhibited AChE at similar rates. Low concentrations of AChE could be determined by the residual enzyme activity and by fluorescence measurements of the leaving group, thus suggesting the application of MEPQ as a sensitive titrant of cholinesterase, as well as a potential tool in studying B-BB permeability changes.