Acetylcholinesterase: inhibition by tetranitromethane and arsenite. Binding of arsenite by tyrosine residues

Tetranitromethane inhibits acetylcholinesterase with respect to the hydrolysis of both acetylthiocholine and indophenyl acetate. The loss of activity with indophenyl acetate, a poor substrate, is preceded by an increase in enzyme activity. Only 12 of the 21 tyrosine residues/monomer of enzyme are susceptible to nitration. Loss of activity with respect to indophenyl acetate occurs well after no further nitration of tyrosines occurs and must be due to the modification of other residues. Incubation of the enzyme with arsenite before nitration results in the nitration of only 10 tyrosines. This experiment reveals that the structural basis for the binding of arsenite is the formation of a diester with two tyrosine residues.     

Indophenyl acetate and acetylcholinesterase: binding of a non-specific substrate on the margin of the active center.

1. Indophenyl acetate is a very poor substrate of eel or bovine acetylcholinesterase (acetylcholine hydrolase, EC 3.1.1.7), with a V less than 5% of that of phenyl acetate, but it is a labile ester and in imidazole buffer is hydrolyzed, non-enzymically, even faster than phenyl acetate. 2. Indophenyl acetate completely protects the enzymes against inhibition by diisopropylphosphorofluoridate but promotes inhibition by methanesulfonyl fluoride. 3. With either of these inhibitors the measured rate of inactivation of eel acetylcholinesterase is the same whether activity is determined with this poor substrate or with a good substrate, acetylthiocholine. With bovine enzyme the inactivation rate is 25% lower when assayed with the former substrate. However this preparation contains a minor enzyme component which is involved in hydrolysis of indophenyl acetate but not good substrates, and which is not readily inhibited. When this is taken into account the inactivation rates for bovine acetylcholinesterase, too, are found to be the same in either assay. These and other observations in the literature can be explained if indophenyl acetate, because of its size, cannot fully penetrate into the active center and is bound in adjoining non-polar regions of the protein. From this external position it makes only intermittent contact with the esteratic site. Hence it is slowly hydrolyzed and fails to protect the enzyme against methanesulfonyl fluoride, though it does protect, possibly sterically, against the larger inhibitor diisopropylphosphorofluoridate.     

Binding sites of cholinesterases. Alkylation by an aziridinium derivative

1. Alkylation of acetylcholinesterase and butyrylcholinesterase by 2-chloro-N-(chloroethyl)-N-methyl-2-phenylethylamine was observed. This alkylating agent was more potent than related compounds previously described, and less stable (half-life 8.5min. at 23 degrees ). 2. Alkylation had effects on hydrolysis of substrates varying from activation for indophenyl acetate to inhibition for acetylcholine, and intermediate effects with five other substrates. The effects were on V(max.) and not K(m). 3. Alkylation caused a variety of changes in sensitivity to inhibition by five carbamates, five organophosphates and four other inhibitors, varying from total protection against tetraethylammonium to mildly enhanced sensitivity to urea. 4. The findings suggested the existence of three binding sites, one of which was anionic and another hydrophobic, in addition to the esteratic site.     

Steady-state kinetic analysis of human cholinesterases over wide concentration ranges of competing substrates

Substrate competition for human acetylcholinesterase (AChE) and human butyrylcholinesterase (BChE) was studies under steady-state conditions using wide range of substrate concentrations. Competing couples of substates were acetyl-(thio)esters. Phenyl acetate (PhA) was the reporter substrate and competitor were either acetylcholine (ACh) or acetylthiocholine (ATC). The common point between investigated substrates is that the acyl moiety is acetate, i.e. same deacylation rate constant for reporter and competitor substrate.Steady-state kinetics of cholinesterase-catalyzed hydrolysis of PhA in the presence of ACh or ATC revealed 3 phases of inhibition as concentration of competitor increased: a) competitive inhibition, b) partially mixed inhibition, c) partially uncompetitive inhibition for AChE and partially uncompetitive activation for BChE. This sequence reflects binding of competitor in the active centrer at low concentration and on the peripheral anionic site (PAS) at high concentration. In particular, it showed that binding of a competing ligand on PAS may affect the catalytic behavior of AChE and BChE in an opposite way, i.e. inhibition of AChE and activation of BChE, regardless the nature of the reporter substrate.For both enzymes, progress curves for hydrolysis of PhA at very low concentration (?K_m) in the presence of increasing concentration of ATC showed that: a) the competing substrate and the reporter substrate are hydrolyzed at the same time, b) complete hydrolysis of PhA cannot be reached above 1 mM competing substrate. This likely results from accumulation of hydrolysis products (P) of competing substrate and/or accumulation of acetylated enzyme·P complex that inhibit hydrolysis of the reporter substrate.     

The genetic control of arylesterase activity in the serum of Gotland Sheep

Esterase activity was determined in 955 serum samples of Gotland sheep. The activities showed a wide range and could be distinguished in six types. Family data were in agreement with the theory of three multiple alleles controlling the esterase activities (Lee, 1966). The following gene frequencies were estimated: Es ^a= 0.15, Es ^b= 0.75 and Es ^c= 0.10. The Es ^a allele controlled an enzym with high hydrolysis rate of α-naphthyl acetate, medium high of β-naphthyl acetate and low of indophenyl acetate. The enzym controlled by the Es ^b allele had medium high hydrolysis rate of α- and β-naphthyl acetate and relatively high of indophenyl acetate. The enzym of the Es ^c allele had low activities for all three substrates. The hydrolysis rate was increased by the addition of calcium. In starch-gel electrophoresis the esterase types could be divided in four groups due to the staining intensity of the arylesterase zone but no difference in migration rates was observed.     

Ligand exclusion on acetylcholinesterase

This paper examines covalent reactivity of AchE with respect to cationic and uncharged methylphosphonates and substrates in the absence and presence of cationic ligands selective for the active center and the peripheral anionic site. The organophosphorus inhibitors are enantiomeric alkyl methylphosphonothioates (1-5) containing cycloheptyl and isopropyl phosphono ester groups and S-methyl, S-n-pentyl, and S-[beta-(trimethylammonio)ethyl] leaving groups; these agents differ in their configuration about phosphorus and their steric, hydrophobic, and electrostatic characteristics. The synthetic substrates examined are acetylthiocholine, p-nitrophenyl acetate, and 7-acetoxy-4-methylcoumarin (7AMC). Antagonism of the methylphosphonothioate reaction by cationic ligands is strongly dependent on the nature of both the cation and the methylphosphonate but independent of the configuration about phosphorus. While all cations cause linear mixed inhibition of acetylthiocholine hydrolysis, there are observed a variety of inhibition patterns of 7AMC and p-nitrophenyl acetate hydrolysis that are distinctly nonlinear, as well as patterns in which the reciprocal plots intersect in the upper right quadrant. Strong antagonism of cationic (methylphosphonyl)thiocholines correlates very well with linear inhibition of acetylthiocholine. Ligands that cause only negligible antagonism of the uncharged methylphosphonates display nonlinear inhibition of uncharged substrates. These relationships, since they are most pronounced for peripheral site ligands and are strongly dependent on the charge carried by the reactant, suggest that the peripheral anionic site alters enzyme reactivity through an electrostatic interaction with the net negative active center. Such behavior indicates a potential role for the peripheral anionic site in conserving AchE catalytic efficiency within a narrow range of values.     

The monoclonal antibody AE-2 modulates fetal bovine serum acetylcholinesterase substrate hydrolysis

The monoclonal antibody (mAb) AE-2 decreases the rate of hydrolysis of acetylthiocholine (ATC) by fetal bovine serum acetylcholinesterase (acetylcholine acetylhydrolase EC 3.1.1.7) (FBS-AChE) (Doctor, B.P. et al. (1989) Proc. 32nd Oholo Conf., Eilat, Israel, in press), but increases the rate of hydrolysis (Vmax) of the nonpolar substrate, indophenyl acetate (IPA) approx. 15-fold. The affinity (Km) of FBS-AChE for IPA changes minimally in comparison with the increase in the rate of hydrolysis. The complex is dissociated, and the modulation of substrate hydrolysis is reversed by the active-center ligand, 1-methyl-2-hydroxyiminomethylpyridinium chloride (2-PAM).     

Chemical modification of electric eel acetylcholinesterase by tetranitromethane

The reaction of acetylcholinesterase (acetylcholinehydrolase, EC 3.1.1.7) with tetranitromethane has been studied. The reaction caused a decrease in enzyme activity as measured with the substrate acetylthiocholine under conditions where hydrolysis of the neutral substrate indophenyl acetate was unaltered. The inactivation of acetylcholinesterase by tetranitromethane was greatly accelerated by the quaternary oximes pyridine-2-aldoxime methyl nitrate or toxogonin, though not by other quaternary inhibitors tested and not by an aliphatic oxime. The enhanced inactivation by tetranitromethane in the presence of pyridine-2-aldoxime methyl nitrate was blocked by the enzyme inhibitor decamethonium.The oxime-induced inactivation of acetylcholinesterase by tetranitromethane was accompanied by significant changes in the immunological properties of the enzyme as demonstrated by complement fixation. The reaction also resulted in the disappearance of tyrosine and appearance of nitrotyrosine.     

Kinetic analysis of effector modulation of butyrylcholinesterase-catalysed hydrolysis of acetanilides and homologous esters

The effects of tyramine, serotonin and benzalkonium on the esterase and aryl acylamidase activities of wild-type human butyrylcholinesterase and its peripheral anionic site mutant, D70G, were investigated. The kinetic study was carried out under steady-state conditions with neutral and positively charged aryl acylamides [o-nitrophenylacetanilide, o-nitrotrifluorophenylacetanilide and m-(acetamido) N,N,N-trimethylanilinium] and homologous esters (o-nitrophenyl acetate and acetylthiocholine). Tyramine was an activator of hydrolysis for neutral substrates and an inhibitor of hydrolysis for positively charged substrates. The affinity of D70G for tyramine was lower than that of the wild-type enzyme. Tyramine activation of hydrolysis for neutral substrates by D70G was linear. Tyramine was found to be a pure competitive inhibitor of hydrolysis for positively charged substrates with both wild-type butyrylcholinesterase and D70G. Serotonin inhibited both esterase and aryl acylamidase activities for both positively charged and neutral substrates. Inhibition of wild-type butyrylcholinesterase was hyperbolic (i.e. partial) with neutral substrates and linear with positively charged substrates. Inhibition of D70G was linear with all substrates. A comparison of the effects of tyramine and serotonin on D70G versus the wild-type enzyme indicated that: (a) the peripheral anionic site is involved in the nonlinear activation and inhibition of the wild-type enzyme; and (b) in the presence of charged substrates, the ligand does not bind to the peripheral anionic site, so that ligand effects are linear, reflecting their sole interaction with the active site binding locus. Benzalkonium acted as an activator at low concentrations with neutral substrates. High concentrations of benzalkonium caused parabolic inhibition of the activity with neutral substrates for both wild-type butyrylcholinesterase and D70G, suggesting multiple binding sites. Benzalkonium caused linear, noncompetitive inhibition of the positively charged aryl acetanilide m-(acetamido) N,N,N-trimethylanilinium for D70G, and an unusual mixed-type inhibition/activation (alpha > beta > 1) for wild-type butyrylcholinesterase with this substrate. No fundamental difference was observed between the effects of ligands on the butyrylcholinesterase-catalysed hydrolysis of esters and amides. Thus, butyrylcholinesterase uses the same machinery, i.e. the catalytic triad S198/H448/E325, for the hydrolysis of both types of substrate. The differences in response to ligand binding depend on whether the substrates are neutral or positively charged, i.e. the differences depend on the function of the peripheral site in wild-type butyrylcholinesterase, or the absence of its function in the D70G mutant. The complex inhibition/activation effects of effectors, depending on the integrity of the peripheral anionic site, reflect the allosteric 'cross-talk' between the peripheral anionic site and the catalytic centre.     

A steady-state kinetic model of butyrylcholinesterase from horse plasma

The steady-state kinetics of the butyrylcholinesterase-catalysed hydrolysis of butyrylthiocholine and thiophenyl acetate were shown to deviate from Michaelis–Menten kinetics. The `best' empirical rate law was selected by fitting different rate equations to the experimental data by non-linear regression methods. The results were analysed in view of two alternative interpretations: (1) the reaction is catalysed by a mixture of enzymes, or (2) the activity is due to a single enzyme displaying deviations from Michaelis–Menten kinetics. It was concluded that the second alternative applies, and this conclusion was further supported by experiments involving simultaneous hydrolysis of alternative thiol ester substrates (butyrylthiocholine/thiophenyl acetate) as well as alternative thiol ester and oxygen ester substrates (butyrylthiocholine/phenyl acetate; thiophenyl acetate/butyrylcholine; acetylthiocholine/phenyl acetate). On the basis of the conclusion that a single enzyme is responsible for the activity, a molecular model is proposed. This model involves an acylated enzyme, and implies binding to the enzyme of one acyl group and one ester molecule, but not two ester molecules at the same time. Thus butyrylcholinesterase, which is structurally a tetramer, behaves functionally as a co-operative dimer, an interpretation in accordance with available data from active-site titrations.     

Substrate specificity of enzymes from Bacillus mesentericus

The proteolytic enzymes of the sporogenous Bacillus mesentericus strains 64 and 8 were tested for their ability to hydrolyse different protein substrates. The enzymes were isolated using affinity chromatography on bacillichine-silochrome, and eluted with 25% isopropanol in 0.05 M Tris-HCl buffer, pH 8.0-8.4, containing 0.01 M CaCl2. Casein, hemoglobin, elastin, albumin and synthetic peptides, Z-L-Ala-Ala-Leu-pNa and Z-L-Ala-Gly-Leu-pNa, were used as substrates. The activity of esterase was assayed in terms of indophenyl acetate cleavage. The proteinases were compared with terrilytin, a commercial preparation. The proteinase of strain 64 was active in the hydrolysis of casein, hemoglobin and elastin; its specificity was close to that of terrilytin. The proteinase of strain 8 differed from them in a higher thrombolytic and fibrinolytic activity, and had a high esterase activity.     

Effect of cetyltrimethylammonium on the human blood cholinesterases activity

The influence of cationic detergent cetyltrimethylammonium on the human blood cholinesterases activity (erythrocyte acetylcholinesterase and plasma butyrylcholinesterase) in reactions of hydrolysis of alpha-thionaphthylacetat and acetylthiocholine is studied. It is shown, that cetyltrimethylammonium is reversible effector for both cholinesterases. This compound competitively inhibited enzymatic hydrolysis of acetylthiocholine by both cholinesterases, and in the reactions of enzymatic hydrolysis alpha-thionaphthylacetat display as the synergistic activator--in experiments with butyrylcholinesterase, and as the reversible inhibitor--in experiments with acetylcholinesterase. Kinetic constants in reaction of acetylcholinesterase inhibition by cetyltrimethylammonium defined by means of different substrates--alpha-thionaphthylacetat and acetylthiocholin. They are close among themselves and amount (2.5 +/- 0.3) x 10(-5) and (2.8 +/- 0.3) x 10(-5) M, accordingly. Butyrylcholinesterase was more sensitive to influence of cetyltrimethylammonium. The kinetic constants defined for this enzyme by the effect of inhibition of acetylthiocholin hydrolysis or activation of alpha-thionaphthylatcetat hydrolysis, are also close among themselves and amount (3.9 +/- 0.4) x 10(-6) and (4.4 +/- 0.4) x 10(-6) M, accordingly.     

Butyrylcholinesterase in the visual ganglia of the squid todarodes sagittatus I. (cephalopoda). isolation,molecular forms,interaction with substrates and inhibitors

1. Soluble butyrylcholinesterase (BuChE) was isolated from the visual ganglia of the squid Todarodes sagittatus L. Gel-chromatography on Sephadex G-200 columns resulted in its separation into three molecular forms.2. The major component with a molecular mass of 180kDa was used for kinetic study.3. The substrate analysis revealed squid enzyme to be BuChE of unusual type.4. Unlike typical BuChE (EC 3.1.1.8), squid enzyme splits acetyl-β-methylcholine (AMCh) with a relatively high rate, alongside with common BuChE substrates—butyrylcholine (BCh), propionylcholine (PCh), acetylcholine (ACh), butyrylthiocholine (BTCh) and acetylthiocholine (ATCh), the enzymic hydrolysis being suppressed by excess of all these substrates.5. Among them, the highest values of k_{cat and}k_cat/K_m were found for BCh and BTCh. Maximal activity of the enzyme was noticed at low BCh and BTCh concentrations (1–2 mM).6. Tetraalkylammonium ions exhibit a mixed type of inhibition and suppress the substrate inhibition of squid BuChE.7. Among organophosphorus inhibitors (OPI), the methylthiophosphonates are most potent for squid BuChE, and for some phosphates, selective OPI of typical BuChE, are potent as well.8. By the pattern of selectivity to OPI, squid enzyme differs from both typical BuChE of horse serum and acetylcholinesterase (EC 3.1.1.7) from bovine erythrocytes.9. Some details of the active center structure of squid BuChE compared to that of typical enzymes are discussed.     

Hemolymph cholinesterase activity in the Mussel <Emphasis Type="Italic">Crenomytilus grayanus</Emphasis> (Dunker, 1853) that was exposed to adverse natural and anthropogenic conditions

The influence of habitat conditions on the activity, the structure of the substrate specificity (the ratio of the substrate hydrolysis rates), and the kinetic parameters of substrate hydrolysis due to the effect of hemolymph cholinesterase of the mussel Crenomytilus grayanus was studied. Mussels were collected from areas that are influenced by seasonal and stationary upwelling, as well as from a polluted area. Upwelling and anthropogenic pressure were shown to alter the structure of hemolymph cholinesterase substrate specificity in mussels, up to complete loss of the ability to catalyze the hydrolysis of propionyland butyrylthiocholine. It was established that during the seasonal upwelling the efficiency of the cholinergic process in mussels is provided by a wide range of effective concentrations of the substrates and by decreasing their affinity to the enzyme. Under the conditions of chronic anthropogenic pollution, the cholinesterase of the mussel hemolymph loses its ability to hydrolyze substrates other than acetylthiocholine.     

Use of 1- and 2-thionaphthylacetates as cholinesterase substrates

1- and 2-thionaphthylacetates were tested as cholinesterase substrates. It was shown that the butyrilcholinesterase from horse serum can hydrolize these compounds. The hydrolysis velocity of 1-thionaphthylacetate was comparable with hydrolysis velocity of acetylthiocholine (the well known cholinesterase substrate), but 2-thionaphthylacetate was hydrolysed more slowly. The values of the kinetic parameters V and K(m) for butyrylcholinesterase hydrolysis of 1- and 2-thionaphthylacetates were determined. It was offered to use 1-thionaphthylacetates as the substrate for cholinesterases.     

Comparative study of enzymatic activity of cholinesterases of different origin in thionaphthylacetate hydrolysis reactions

A comparative determination of kinetic parameters V and Km in the reaction of hydrolysis thionaphthylacetate and well known substrate acetylthiocholine by choline esterases from different sources was conducted. It is shown that butyrylcholine esterases hydrolyze thionaphthylacetate with velocity comparable with that of hydrolysis of acetylthiocholine, while acetylcholine esterases and propionylcholine esterases hydrolyze this substrate several times slower than acetylthiocholine. The values of Km in the reactions of hydrolysis of thionaphthylacetate for all studied cholinesterases is an order higher than for acetylthiocholine except cholinesterase of blood serum of fish. This value for the latter enzyme is practically equal.     

Substrate activation in acetylcholinesterase induced by low pH or mutation in the π-cation subsite

Substrate inhibition is considered a defining property of acetylcholinesterase (AChE), whereas substrate activation is characteristic of butyrylcholinesterase (BuChE). To understand the mechanism of substrate inhibition, the pH dependence of acetylthiocholine hydrolysis by AChE was studied between pH 5 and 8. Wild-type human AChE and its mutants Y337G and Y337W, as well as wild-type Bungarus fasciatus AChE and its mutants Y333G, Y333A and Y333W were studied. The pH profile results were unexpected. Instead of substrate inhibition, wild-type AChE and all mutants showed substrate activation at low pH. At high pH, there was substrate inhibition for wild-type AChE and for the mutant with tryptophan in the π-cation subsite, but substrate activation for mutants containing small residues, glycine or alanine. This is particularly apparent in the B. fasciatus AChE. Thus a single amino acid substitution in the π-cation site, from the aromatic tyrosine of B. fasciatus AChE to the alanine of BuChE, caused AChE to behave like BuChE. Excess substrate binds to the peripheral anionic site (PAS) of AChE. The finding that AChE is activated by excess substrate supports the idea that binding of a second substrate molecule to the PAS induces a conformational change that reorganizes the active site.     

Choliae esterases and choline acetyltransferase in the seeds ofAllium altaicum (Pall.) Reyse

In the seeds ofAllium altaicun (Pall.)Reyse a set of enzymes was found, metabolizing choline esters, composed of active choline esterases and choline acetyltransferase. Choline esterase cleaving acetylcholine occurs in five isoenzymes. The enzyme preparation hydrolyses strongly acetylthiocholine and sinapine, but weakly butyrylthiocholine (20%) in comparison with acetylthiocholine. The hydrolysis of the substrates mentioned is inhibited by physostigmine and neostigmine, but it is not inhibited by the specific inhibitor of acetylcholine esterase (BW 284 C51). In addition to hydrolytic activity a strong catalytic activity of choline acetyltransferase was also observed during the synthesis of sinapine from sinapic acid and choline. The detection of the mentioned enzymes in some representatives of theAllium genus indicates that choline esterases are more widely distributed in monocotyledons than previously assumed.     

THE EFFECT OF SPERMINE AND SPERMIDINE ON THE HYDROLYSIS OF ACETYLTHIOCHOLINE IN THE PRESENCE OF RAT CAUDATE NUCLEUS HOMOGENATE OR ACETYLCHOLINESTERASE FROM ELECTROPHORUS ELECTRICUS

Abstract— The effects of spermine and spermidine tetrahydrochloride on female Agus rat brain caudate nucleus homogenates, soluble acetylcholinesterase from the electric organ of Electrophorus electricus and acetylthiocholine iodide were studied. Measurements were made using an autoanalytical spectrophotometric method which measured the initial rate of reaction rapidly and accurately. Both polyamines interacted with the substrate, acetylthiocholine, causing an increase in the rate of its non-enzymatic hydrolysis. Slight inhibitory effects on acetylcholinesterase were also observed. Combined effect of the polyamine on the substrate and the enzyme showed an inhibition at low and activation at high (above 1 m m ) substrate concentrations.     

Effect of salt composition of the medium and ethanol on cholinesterase hydrolysis of various substrates

Sodium chloride, phosphate buffer and ethanol were studied for their effect on butyryl cholinesterase hydrolysis rate of acetylcholine, acetylthiocholine, butyrylthiocholine and nonion substrate of indophenylacetate. The concentrations of 1.10(-2) = 1.10(-1) M of sodium chloride activated enzymatic hydrolysis of ion substrates at the concentrations lower than 1.10(-4) M but sodium chloride is a competitive inhibitor at higher concentrations. Phosphate buffer also activates substrates enzyme hydrolysis at the concentrations of 2.10(-4) M and lower, but it inhibits incompetitively the nonion substrate indophenylacetate hydrolysis. Ethanol activates butyrylthiocholine hydrolysis and is a competitive inhibitor in acetylthiocholine and indophenylacetate hydrolysis. The observed effects are discussed on the assumption of two forms of butyrylcholinesterase E' and E" existence. These two forms are determined by different kinetic parameters and are in equilibrium.