Title: Inhibition of Acetylcholinesterases by Stereoisomeric Organophosphorus Compounds Containing Both Thioester and p-Nitrophenyl Leaving Groups Talley TT, Chao CK, Berkman CE, Richardson RJ, Thompson CM Ref: Chemical Research in Toxicology, 33:2455, 2020 : PubMed
Studies with acetylcholinesterase (AChE) inhibited by organophosphorus (OP) compounds with two chiral centers can serve as models or surrogates for understanding the rate, orientation, and postinhibitory mechanisms by the nerve agent soman that possesses dual phosphorus and carbon chiral centers. In the current approach, stereoisomers of O-methyl, [S-(succinic acid, diethyl ester), O-(4-nitrophenyl) phosphorothiolate (MSNPs) were synthesized, and the inhibition, reactivation, and aging mechanisms were studied with electric eel AChE (eeAChE) and recombinant mouse brain AChE (rmAChE). The MSNP R(P)R(C) isomer was the strongest inhibitor of both eeAChE and rmAChE at 8- and 24-fold greater potency, respectively, than the weakest S(P)S(C) isomer. eeAChE inhibited by the R(P)R(C)- or R(P)S(C)-MSNP isomer underwent spontaneous reactivation -10- to 20-fold faster than the enzyme inhibited by S(P)R(C)- and S(P)S(C)-MSNP, and only 4% spontaneous reactivation was observed from the S(P)R(C)-eeAChE adduct. Using 2-pyridine aldoxime methiodide (2-PAM) or trimedoxime (TMB-4), eeAChE inhibited by R(P)R(C)- or S(P)R(C)-MSNP reactivated up to 90% and 3- to 4-fold faster than eeAChE inhibited by the R(P)S(C)- or S(P)S(C)-MSNP isomer. Spontaneous reactivation rates for rmAChE were 1.5- to 10-fold higher following inhibition by R(P)S(C)- and S(P)S(C)-MSNPs than inhibition by either R(C) isomer, a trend opposite to that found for eeAChE. Oxime reactivation of rmAChE following inhibition by R(P)R(C)- and S(P)R(C)-MSNPs was 2.5- to 5-fold faster than inhibition by R(P)S(C)- or S(P)S(C)-MSNPs. Due to structural similarities, MSNPs that phosphylate AChE with the loss of the p-nitrophenoxy (PNP) group form identical, nonreactivatable adducts to those formed from S(P)-isomalathion; however, all the MSNP isomers inhibited AChE to form adducts that reactivated. Thus, MSNPs inactivate AChE via the ejection of either PNP or thiosuccinyl groups to form a combination of reactivatable and nonreactivatable adducts, and this differs from the mechanism of AChE inhibition by isomalathion.
Title: Catalytic antibodies that hydrolyze (-)-cocaine obtained by a high-throughput procedure Cashman JR, Berkman CE, Underiner GE Ref: Journal of Pharmacology & Experimental Therapeutics, 293:952, 2000 : PubMed
Antibodies to a 2beta-carboxamido-2beta-phosphonate transition-state analog of (-)-cocaine benzoate ester hydrolysis were elicited in mice. A large number of hybridoma cell lines were propagated, and the catalytic activity of culture fluid was determined with a high-throughput photometric assay using cocaine benzoyl thioester as substrate. Binding avidity of the hybridoma supernatants to the phosphonate hapten was also determined. The initial rate constants for cocaine benzoyl thioester hydrolysis and binding avidity for a large number of hybridoma supernatants elicited to the phosphonate hapten did not always correlate. The lack of correlation of substrate hydrolysis with the binding affinity of 70 catalytic antibodies was also observed for (-)-cocaine hydrolysis using derivatization and HPLC analysis of methyl ecgonine as meta-nitrococaine. The k(cat) values for cocaine benzoyl thioester hydrolysis by monoclonal antibodies 3, 5, and 12 were 38, 4.2, and 0. 6 min(-1), respectively. For monoclonal antibody 5, the selectivity ratios (K(i) value divided by the K(m) value for the hydrolysis of cocaine benzoyl thioester) with ecgonine benzoyl ester, ecgonine methyl ester, norcocaine, and ecgonine were 101, 25, 9.4, and 4, respectively. Three active esterolytic monoclonal antibodies identified with the high-throughput assay procedure were examined in detail for their ability to hydrolyze (-)-cocaine. The k(cat) values for the hydrolysis of (-)-cocaine with monoclonal antibodies 3, 5, and 12 were 6.6, 0.4, and 0.1 min(-1), respectively. Hydrolysis of (-)-cocaine by monoclonal antibody 3 approached the k(cat) value for that of human butyrylcholinesterase. Cocaine esterolytic catalytic antibodies that approach or exceed the catalytic efficiency of human butyrylcholinesterase may represent a new pharmacological intervention approach to the treatment of cocaine abuse, and the high-throughput process described here represents an advance in the effort to develop clinically useful antibodies.
Inhibition of acetylcholinesterase (AChE) by isomalathion has been assumed to proceed by expulsion of diethyl thiosuccinyl to produce O, S-dimethyl phosphorylated AChE. If this assumption is correct, AChE inhibited by (1R)- or (1S)-isomalathions should reactivate at the same rate as AChE inhibited by configurationally equivalent (S)- or (R)-isoparathion methyl, respectively, which are expected to inhibit AChE by loss of 4-nitrophenoxyl to yield O,S-dimethyl phosphorylated AChEs. Previous work has shown that rat brain AChE inhibited by (1R)-isomalathions reactivates at the same rate as the enzyme inhibited by (S)-isoparathion methyl. However, although rat brain AChE inhibited by (R)-isoparathion methyl reactivates at a measurable rate, the enzyme inhibited by (1S)-isomalathions is intractable to reactivation. This surprising finding suggests the hypothesis that (1R)- and (1S)-stereoisomers of isomalathion inhibit AChE by different mechanisms, yielding enzymatic species distinguishable by their postinhibitory kinetics. The present study was carried out to test this hypothesis by comparing kinetic constants of reactivation (k+3) and aging (k+4) of hen brain AChE and bovine erythrocyte AChE inhibited by the four stereoisomers of isomalathion and the two stereoisomers of isoparathion methyl. Both AChEs inhibited by either (1R,3R)- or (1R,3S)-isomalathion had comparable corresponding k+3 values (spontaneous and oxime-mediated) to those of AChEs inhibited with (S)-isoparathion methyl. However, spontaneous and oxime-mediated k+3 values comparable to those of (R)-isoparathion methyl could not be obtained for AChEs inhibited by (1S,3R)- and (1S,3S)-isomalathion. Comparison of k+4 values for hen brain AChE inhibited by each stereoisomer of isomalathion and isoparathion methyl corroborated that only the (1S)-isomalathions failed to produce the expected O,S-dimethyl phosphoryl-conjugated enzymes. The results for (1R)-isomalathions suggest that the mechanism of inhibition of AChE by these isomers is the expected one involving diethyl thiosuccinyl as the primary leaving group. In contrast, the results for (1S)-isomalathions are consistent with an alternative mechanism of inhibition by these isomers implicating loss of thiomethyl as the primary leaving group.
Title: Cocaine benzoyl thioester: synthesis, kinetics of base hydrolysis, and application to the assay of cocaine esterases Cashman JR, Berkman CE, Underiner G, Kolly CA, Hunter AD Ref: Chemical Research in Toxicology, 11:895, 1998 : PubMed
The synthesis and characterization of diastereomers of cocaine benzoyl thioester is described. Allococaine benzoyl thioester and allopseudococaine benzoyl thioester were synthesized by the conjugate addition of p-methoxytolyl thiol to ecgonine methyl ester followed by debenzylation and benzoylation. The absolute structure of the hydrochloride salt of the major ecgonine p-methoxytolyl sulfide formed was determined by single-crystal diffraction analysis and used to establish the addition geometry. When placed in aqueous solution, the cocaine benzoyl thioester diastereomers hydrolyzed to give thioecgonine methyl ester. The rate of cocaine benzoyl thioester hydrolysis was carefully investigated spectrophotometrically by using the Ellman reagent. At neutral pH, the hydrolysis of the diastereomers was found to proceed at detectable rates. Upon increasing pH, the rate of hydrolysis of cocaine benzoyl thioester diastereomers was increased and the reaction was catalyzed by basic buffer species. In addition to defining the kinetics of hydrolysis in aqueous solution, cocaine benzoyl thioester was utilized as a highly efficient method to monitor the activity of cholinesterases and pig liver esterase. Use of cocaine benzoyl thioester represents a rapid and sensitive way to screen for cocaine esterase activity.
Title: Stereoselective inhibition of human butyrylcholinesterase by phosphonothiolate analogs of (+)- and (-)-cocaine Berkman CE, Underiner GE, Cashman JR Ref: Biochemical Pharmacology, 54:1261, 1997 : PubMed
The hydrolysis of cocaine (benzoylecgonine methyl ester) to ecgonine methyl ester by human butyrylcholinesterase (BCHE; EC 3.1.1.8) has been shown previously to constitute an important means to detoxicate this material to pharmacologically inactive metabolites. The naturally occurring (-)-cocaine is hydrolyzed to ecgonine methyl ester approximately 2000 times slower than the unnatural (+)-cocaine isomer. In good agreement with previous studies, (-)-cocaine bound to human BCHE with relatively good affinity and competitively inhibited the hydrolysis of the spectrophotometric substrate butyrylthiocholine with a Ki value of 8.0 microM. Similarly, (+)-cocaine also showed relatively high affinity for the human BCHE and competitively inhibited butyrylthiocholine hydrolysis with a Ki value of 5.4 microM. The phosphonothiolates corresponding to the transition state analogs for both (-)- and (+)-cocaine hydrolysis were synthesized and tested as inhibitors of human BCHE-catalyzed hydrolysis of butyrylthiocholine. The phosphonothiolate corresponding to the transition state for (-)-cocaine hydrolysis was a competitive inhibitor with a Ki value of 55.8 microM. The phosphonothiolate corresponding to the transition state for (+)-cocaine hydrolysis gave a Ki value of 25.9 microM, but, in addition, it also showed irreversible inhibition with a ki of inactivation of 68.8 min-1 M-1. It is likely that the mechanism-based inhibitor described herein may find use as a mechanistic probe of butyrylcholinesterase action and also possibly aid in the purification of this class of esterases.
Title: Human liver carboxylesterase hCE-1: binding specificity for cocaine, heroin, and their metabolites and analogs Brzezinski MR, Spink BJ, Dean RA, Berkman CE, Cashman JR, Bosron WF Ref: Drug Metabolism & Disposition: The Biological Fate of Chemicals, 25:1089, 1997 : PubMed
Purified human liver carboxylesterase (hCE-1) catalyzes the hydrolysis of cocaine to form benzoylecgonine, the deacetylation of heroin to form 6-acetylmorphine, and the ethanol-dependent transesterification of cocaine to form cocaethylene. In this study, the binding affinities of cocaine, cocaine metabolites and analogs, heroin, morphine, and 6-acetylmorphine for hCE-1 were evaluated by measuring their kinetic inhibition constants with 4-methylumbelliferyl acetate in a rapid spectrophotometric assay. The naturally occurring (R)-(-)-cocaine isomer displayed the highest affinity of all cocaine and heroin analogs or metabolites. The pseudo- or allopseudococaine isomers of cocaine exhibited lower affinity indicating that binding to the enzyme is stereoselective. The methyl ester, benzoyl, and N-methyl groups of cocaine play important roles in binding because removal of these groups increased K(i) values substantially. Compounds containing a variety of hydrophobic substitutions at the benzoyl group of cocaine bound to the enzyme with high affinity. The high K(i) value obtained for cocaethylene relative to cocaine is consistent with weaker binding to the esterase and a longer elimination half-life reported for the metabolite. The spectrophotometric competitive inhibition assay used here represents an effective method to identify drug or environmental esters metabolized by carboxylesterases like hCE-1.
Title: Inhibition of various cholinesterases with the enantiomers of malaoxon Rodriguez OP, Muth GW, Berkman CE, Kim K, Thompson CM Ref: Bulletin of Environmental Contamination & Toxicology, 58:171, 1997 : PubMed
Title: Relative potencies of the four stereoisomers of isomalathion for inhibition of hen brain acetylcholinesterase and neurotoxic esterase in vitro Jianmongkol S, Berkman CE, Thompson CM, Richardson RJ Ref: Toxicology & Applied Pharmacology, 139:342, 1996 : PubMed
The cholinergic toxicity of malathion is exacerbated by its isomerization product, isomalathion, which inhibits detoxifying carboxylesterases as well as target acetylcholinesterase (AChE). Previous work has shown that the four stereoisomers of isomalathion, (1R, 3R), (1R, 3S), (1S, 3R), and (1S, 3S), differ in their inhibitory potencies against either rat brain or electric eel AChE. The present study examined the relative inhibitory potencies of these stereoisomers and the totally racemic mixture (1RS, 3RS) against hen brain AChE and neurotoxic esterase (NTE) to provide new data on stereoselective inhibition of neurotoxicologically significant esterases and to assess the potential of these compounds to cause organophosphorus (OP) compound-induced delayed neurotoxicity (OPIDN). The order of potencies against hen brain AChE was (1R, 3R) > (1R, 3S) > (1RS, 3RS) > (1S, 3R) > (1S, 3S), with a 15-fold difference between the strongest (ki = 388 mM-1 min-1; 20 min I50 = 89.3 nM) and weakest (ki = 25.6 mM-1 min-1; 20 min I50 = 1354 nM) inhibitors. Both asymmetric centers contributed substantially and interdependently to inhibitory potency, but the effect of changing the configuration at phosphorus alone was greater than changing the configuration at carbon alone. None of the isomalathions was an effective inhibitor of hen brain NTE (extrapolated 20 min I50 values were 1.2 to 29 mM), yielding NTE/ AChE I50 ratios (neuropathy target ratios, NTRs) of 1.5 x 10(3) to 1.5 x 10(5). NTRs of this magnitude indicate that none of the isomalathions should initiate OPIDN, even after doses greatly exceeding the LD50. Therefore, reports of OPIDN or other neuropathic sequelae associated with malathion exposures in humans cannot be explained on the basis of NTE inhibition by contaminating isomalathions.
Title: Synthesis, absolute configuration, and analysis of malathion, malaoxon, and isomalathion enantiomers [published erratum appears in Chem Res Toxicol 1994 Mar-Apr;7(2):275] Berkman CE, Thompson CM, Perrin SR Ref: Chemical Research in Toxicology, 6:718, 1993 : PubMed
Syntheses of the enantiomers of malathion, malaoxon, and isomalathion are reported herein. Malathion enantiomers were prepared from (R)- or (S)-malic acid in three steps. Enantiomers of malathion were converted to the corresponding enantiomers of malaoxon in 52% yield by oxidation with monoperoxyphthalic acid, magnesium salt. The four isomalathion stereoisomers were prepared via two independent pathways using strychnine to resolve the asymmetric phosphorus moiety. The absolute configurations of the four stereoisomers of isomalathion were determined by X-ray crystallographic analysis of an alkaloid salt precursor. A high-performance liquid chromatography technique was developed to resolve the four stereoisomers of isomalathion, and to determine their stereoisomeric ratios.
Title: Interaction of acetylcholinesterase with the enantiomers of malaoxon and isomalathion Berkman CE, Quinn DA, Thompson CM Ref: Chemical Research in Toxicology, 6:724, 1993 : PubMed
The biomolecular reaction constants (ki), dissociation constants (Kd), and phosphorylation constants (kp) were determined for the enantiomers of malaoxon against rat brain acetylcholinesterase, and for the stereoisomers of isomalathion against rat brain acetylcholinesterase and electric eel acetylcholinesterase. (R)-Malaoxon was an 8.6-fold more potent anti-cholinesterase than (S)-malaoxon. Isomalathion stereoisomers with the R configuration at carbon were 3-13-fold stronger inhibitors than those with the S configuration. The isomalathion stereoisomers with the R configuration at phosphorus were 4.3-8.8-fold stronger inhibitors of rat brain acetylcholinesterase, yet 3.4-5.8-fold weaker inhibitors of electric eel acetylcholinesterase, than the isomalathion stereoisomers with the S configuration at phosphorus. The rat brain acetylcholinesterase spontaneous (k0 = approximately 13.0 x 10(-3) min-1) and oxime-mediated (koxime) = 51.0 x 10(-3) min-1) reactivation rate constants following inhibition by isomalathion stereoisomers with the R configuration at phosphorus were comparable to spontaneous (11.3 x 10(-3) min-1) and oxime-mediated (50.2 x 10(-3) min-1) reactivation rates obtained for (S)-isoparathion methyl. These data support a common phosphorylation mechanism, namely, the displacement of the thiosuccinyl moiety from isomalathion stereoisomers with the R configuration at phosphorus, and displacement of the p-nitrophenoxy ligand from (S)-isoparathion methyl to form the same O,S-dimethyl phosphorothiolated enzyme. Rat brain acetylcholinesterase inhibited by the isomalathion stereoisomers with the S configuration at phosphorus were refractory to reactivation, suggesting an alternate mechanism of inhibition, i.e., the loss of the methylthio ligand. Several mechanisms are proposed to account for the subsequent nonreactivation.(ABSTRACT TRUNCATED AT 250 WORDS)
Title: Kinetics of the postinhibitory reactions of acetylcholinesterase poisoned by chiral isomalathion: a surprising nonreactivation induced by the RP stereoisomers Berkman CE, Ryu S, Quinn DA, Thompson CM Ref: Chemical Research in Toxicology, 6:28, 1993 : PubMed
Inhibitory (ki), spontaneous (k0), and oxime-mediated reactivation (k(oxime)) reaction kinetics for the four stereoisomers of isomalathion (SPRC,SPSC,RPRC, and RPSC) were determined against rat brain acetylcholinesterase (AChE). (SPRC)-Isomalathion was the most potent anticholinesterase agent and RPSC-isomalathion the least potent with racemic material approximately midway in activity. Following inhibition of rat brain AChE by (SPRC)- or (SPSC)-isomalathion, k0 and k(oxime) values were obtained that were comparable to (SP)-isoparathion methyl, indicating that the same mechanism of inhibition was shared, namely, formation of an O,S-dimethyl phosphorothiolated enzyme. Conversely, no appreciable reactivation occurred with or without oxime following inhibition of rat brain AChE by (RPSC)- or (RPRC)-isomalathion. This observation was not consistent with (RP)-isoparathion methyl, and a switch in inhibition mechanism to the loss of the thiomethyl moiety is suggested. The nonreactivation of rat brain AChE following inhibition by the (RP)-isomalathion stereoisomers is postulated to result from a mechanism involving either a beta-elimination of diethyl fumarate or displacement of the thiosuccinate moiety from the phosphate moiety.
