Reactivation of phosphorylated cholinesterase immobilized in a gelatin membrane

The soluble and immobilized cholinesterases (acetyl cholinesterase of human blood erythrocytes (EC 3.1.1.7) and butyryl cholinesterase of equine blood serum, (EC 3.1.1.8] were inactivated by such irreversible inhibitors as diisopropyl fluorophosphate (DFP), O,O-dimethyl-O-(2,2)-dichlorovinyl) phosphate (DDVP), paraoxone, armine. The inactivated enzymes were reactivated under the effect of TMB-4 (1,1'-trimethylene-bis)-4-formyl-pyridine bromide (dioxime). The values of the reactivation rate constants proved to be equal both for the soluble and immobilized cholinesterases inactivated by the same irreversible inhibitor. The immobilized enzyme is simpler and more correct to study the reactivating action than the soluble one.     

Interaction between various cholinesterases and reversible inhibitors of polymethylene-bis-(trimethylammonium) diiodide series

It is established that derivatives of polymethylene bistrimethylammonium (CH3)3N+(CH2)nN+(CH3)3 (n = 4-10) are reversible competitive and mixed action inhibitors with respect to acetylcholinesterase of human erythrocytes, butyryl cholinesterase of horse blood serum, cholinesterase of frog brain and Todarodes pacificus optical ganglion. In case of mammals and frog cholinesterase the inhibitors efficiency rises with n, but the activity of the Todarodes pacificus cholinesterase less sensitive of the inhibitors is characterized by a "step" dependence on the length of the polymethylene chain of the inhibitor molecule. Studies in sensitivity of cholinesterases to this type of inhibitors revealed differences between enzymes of the same type in different animals.     

O,O-dialkyl-S-bromomethylthiophosphates--inhibitors of mammalian choline- and carboxyl esterases: structure-activity relationship

The interaction kinetics of potential pesticides, O,O-dialkyl S-bromomethylthiophosphates (RO)2P(O) SCH2Br (R = Et, i-Pr, n-Pr, n-Bu, or n-Am) with acetylcholinesterase, butyryl cholinesterase, and carboxyl esterase from warm-blooded animals was studied. All the compounds irreversibly inhibit these esterases, with k1 (M-1 min-1) being 1.8 x 10(4) - 1.9 x 10(6) for acetylcholinesterase, 2.0 x 10(6) - 4.1 x 10(7) for the more sensitive butyryl cholinesterase, and 2.3 x 10(7) - 2.3 x 10(8) and higher for the most sensitive carboxyl esterase. By using the Hansch and Kubinyi technique of multiple regression analysis, we quantitatively analyzed the relationship between the structure and inhibiting activity of these substances toward acetylcholinesterase and butyryl cholinesterase. Hydrophobic interactions were found to be important for the inhibition of both enzymes but are more pronounced in the case of butyryl cholinesterase. On the other hand, steric factors were much more significant in the inhibition of acetylcholinesterase. For both enzymes, the steric hindrances affect the phosphorylation stage of the enzyme.     

A study of the peripheral quaternary ligand binding site of cholinesterase with the use of ethidium bromide

The peripheral binding site of horse serum cholinesterase (EC 3.1.1.7) for quaternary ligands was investigated by fluorescent probing with the use of ethidium bromide. Spectral evidence for the participation of the tryptophan indole group of the peripheral site of horse serum cholinesterase in the formation of a cholinesterase complex with ethidium bromide is presented. The mechanism of cholinesterase effect on ethidium bromide fluorescence is proposed.     

A comparative study of the effect of vinyl phosphoric acid esters on cholinesterase and carboxylesterase activities in mammals and arthropods

Studies have been made of the effect of organophosphorus inhibitors on cholinesterase and carboxylesterase from various mammals (human erythrocytes, mouse brain, blood serum of mouse and rat, blood serum of horse) and arthropods (Calliphora vicina, Schizaphis graminum, Myzus persicae, Sitophilus oryzae, Pseudococcus maritimus, Tetranychus urticae). Organophosphorus inhibitors were presented by esters of vynylphosphoric acid containing normal and branched alkyls in the phosphoryl part of the molecule. The increase of the radical up to a propyl one increased the effect of organophosphorus inhibitors with respect to cholinesterase from the majority of the arthropods investigated. Organophosphorus compound with an isopropyl radical was found to be weaker for all the enzymes studied. Extremely high sensitivity of carboxylesterase from all arthropods to all organophosphorus inhibitors was noted; in some of the cases, anticarboxylesterase activity of all drugs was 2-3 orders higher than anticholinesterase one (P. maritimus, T. urticae). Regularities established for cholinesterase practically completely were confirmed on carboxylesterase. This finding evidently reveals similar structure of catalytic surface at the vicinity of esterase center in both enzymes.     

Convenient and rapid detection of pesticides in extracts of sheep wool

A relatively simple, rapid extraction technique based on acetonitrile was combined with the use of screen-printed electrodes bearing cholinesterases to detect organo-phosphate pesticides from an otherwise intractable matrix, sheep wool. It proved possible to separate, for convenience, the exposure of the electrodes from measurement of their (inhibited) activity. The electrodes were used once and then discarded. Estimation of the extent of inhibition is dependent on reference to the activity of control electrodes. The presence of pesticides in the extracts could be detected with any of three commonly available cholinesterases but the most sensitive enzyme was butyryl cholinesterase from horse serum.     

Inhibition of cholinesterases by quaternary phosphonium compounds

Alkyl tributylphosphonium and triphenylphosphonium derivatives as well as tetraphenylphosphonium were first studied as inhibitors of acetylcholinesterase of human blood erythrocytes and butyrylcholinesterase of horse blood serum. The inhibition is reversible, of mixed type, with a different contribution of competitive and uncompetitive components. The value of the inhibitory effect is essentially dependent on the structure of phosphonium compounds, especially in experiments with butyrylcholinesterase: allyltriphenylphosphonium is 290 times as strong enzyme inhibitor as methyltributylphosphonium. Hexyltributylphosphonium is identical to hexyltributylammonium in both the pattern and efficiency of the inhibitory action on cholinesterases.     

Siliconorganic reversible inhibitors of cholinesterases of various animals

The review present data on cholinesterase effects of 28 specially synthesized siliconorganic compounds (monoonium, clementorganic, and bisonium derivatives) studied as reversible inhibitors of acetylcholinesterase (acetyl-ChE) of human erythrocytes, butyryl-ChE of horse blood serum, ChE of brain of common frog Rana temporaria, ChE of the optical ganglia tissue of Pacific squid Todarodes pacificus and of individuals of Commandor squid Berryteuthis magister from various habitats in the Northwestern aquatoria of the Pacific ocean. Among the tested compounds, there are revealed highly specific inhibitors of mammalian ChE as well as of ChE of the B. magister individuals from various habitats.     

Kinetic properties of butyrylcholinesterases immobilised on pH-sensitive field-effect transistor surface and inhibitory action of steroidal glycoalkaloids on these enzymes

The inhibitory action of steroid glycoalkaloids alpha-solanine, alpha-chaconine and tomatine on horse and human serum butyryl cholinesterases immobilized on the pH-sensitive field-effect transistors has been studied. Using acetyl- and butyryl choline as substrates, the optimal pH and the apparent kinetic parameters (< K(m) >, < V(max) >) of immobilized butyryl cholinesterases have been calculated in the absence of inhibitors. The affinity of each enzyme to glycoalkaloids has been estimated from calculation of apparent inhibition constants < K(i) > and inhibition coefficients i(0.5). Application of the studied cholinesterases for biosensoric determination of glycoalkaloids in the wide range of concentrations (10(-7)-10(-4) M) in different media has been discussed.     

Species-specific differences in the substrate-inhibitory specificity of cholinesterases from optical ganglia of squids of the Gonatidae family

A comparative study was carried out of the substrate and inhibitory specificity of cholinesterase preparations from squids, representatives of 3 genes and 5 species of the Gonatidae family:Berryteuthis (B. magister andB. anonichos),Gonatus (G. kamtschaticus andG. tinro), andGonatipsis (G. borealis), that have overlapping habitation areals in the Bering Sea. As substrates, there were used bromides of acetylthiocholine, propionylthiocholine, and butyrylthiocholine, as organophosphorus inhibitors, diisopropylfluorophosphate, a cation-containing inhibitor, and 4 hydrophobic compounds. The homogeneity of the cholinesterase activity in these preparations has been shown, the intergenus and interspecies differences in the enzyme properties are revealed, and also the peculiarity of properties of enzymes from Gonatidae squids is emphasized in comparison with cholinesterase from the Pacific squidTodarodes paciflcus and “standard” mammalian enzymes (from human erythrocytes and horse blood serum). The revealed interspecies differences are discussed in terms of evolutionary development of the Gonatidae family.     

How the various substrates activate the process of enzymatic hydrolysis by different cholinesterases

Kinetic analysis of the activating effect of substrate on the cholinesterase catalysis is performed. There are determined values of coefficient of activation A in the pH zone 5.0-7.5 for the process of hydrolysis of acetylcholine, indophenylacetate (IPA), and 2,6-dichlorophenolindophenylacetate (DIPA) by cholinesterase (ChE) of horse blood serum, as well as of IPA and DIPA by ChE of optical ganglia of the Pacific squid Todarodes pacificus. The phenomenon of activation has not been revealed at hydrolysis of phenylacetate by the horse blood serum ChE. The conclusion is made that the cause of the activating effect of substrate on the process of enzymatic hydrolysis by ChEs of different origin is the presence of the onium grouping in the structure of substrates.     

Non-Productive Binding of Substrates as One of Aspects of Substrate Specificity of Cholinesterases of Different Origin

Taking into account the phenomenon of non-productive binding of substrate, kinetic parameters of hydrolysis of acetylcholine (ACh) and its 13 derivatives with different structures of ammonium group by cholinesterase (ChE) of human erythrocytes, ChE of horse blood serum, and ChE of optic ganglia of the Pacific squid Todarodes pacificus are determined. A dependence is revealed of values of parameters of their enzymatic hydrolysis and parameters of the non-productive binding on the substrate structure and ChE nature. Effects of salts, LiCl, NaCl, KCl, MgCl₂, CaCl₂ and BaCl₂, on various kinetic parameters, including parameters of the non-productive binding of substrate, of enzymatic hydrolysis of iodides of ACh and N-acetoxyethylene-N-ethylpiperidinium under action of horse blood serum ChE are studied. Addition of the salts to the reaction mixture produced different effects on values of the catalytic center activity (a _c) and the Michaelis constant (K _M), depending on the cation nature and the substrate structure. At the same time, values of the a _c/K _M ratio that characterize to a degree the substrate affinity to the enzyme are equal to each other for two substrates differing in structure, regardless of the presence and nature of the studied cations. Parameters of the non-productive binding of N-acetoxyethylene-N-ethylpiperidinium iodide also depended on the salt nature; however, in that case, a question arises as to the correctness of the comparative analysis, when at determinations of the parameters the non-productive binding of ACh is ignored.     

The hydrolysis of rac-glycerol 1-monodecanoate by serum butyryl cholinesterase

Butyryl cholinesterase from horse and human sera catalyzed the hydrolysis of monoacylglycerols containing fatty acids varying in chain length from 8 to 12 carbons; maximum activity was obtained with rac-glycerol 1-monodecanoate as substrate. Neither the triacylglycerols of these fatty acids nor the monoacylglycerols of longer chain length fatty acids were hydrolyzed at measurable rates in the system used. The enzyme was eserine sensitive and indistinguishable from butyryl cholinesterase as judged by purification, response to the several inhibitors tested, and heat inactivation. Data from mixed substrate experiments suggest a possible effector role for butyryl choline in accelerating the rate of rac-glycerol 1-monodecanoate hydrolysis. Fatty acid released during the course of rac-glycerol 1-monodecanoate hydrolysis may irreversibly inactivate the enzyme.     

How various substrates activate the process of enzymatic hydrolysis by different cholinesterases

Kinetic analysis of the activating effect of substrate on the cholinesterase catalysis is performed. There are determined values of coefficient of activation A in the pH zone 5 for the process of hydrolysis of acetylcholine, indophenylacetate (IPhA), and 2,6-dichlorophenolindoph enylacetate (DIPhA) by cholinesterase (ChE) of horse blood serum, as well as of IPhA and DIPhA by ChE of optical ganglia of the Pacific squid Todarodes pacificus. The phenomenon of activation has not been revealed at hydrolysis of phenylacetate by the horse blood serum ChE. The conclusion is made that the cause of the activating effect of substrate on the process of enzymatic hydrolysis by ChEs of different origin is the presence of the onium grouping in the structure of substrates.     

Identification of isoenzymes in cholinesterase preparations using kinetic data of organophosphate inhibition

Commercial preparations of acetylcholinesterase (EC 3.1.1.7) and of cholinesterase (EC 3.1.1.8) were characterized by organophosphate inhibition. Cholinesterase activities were inhibited by varying organophosphate concentration and time of inhibition. Bimolecular rate constants were determined by plotting log activity vs inhibitor concentration or inhibition time. Inhibition of acetylcholinesterase from bovine erythrocytes by diethyl p-nitrophenyl phosphate (Paraoxon), diisopropylphosphorofluoridate (DFP), and N,N′-diisopropylphosphorodiamidic fluoride (Mipafox) in semilogarithmic plots showed a linear decay of activity. Inhibition of acetylcholinesterase from electric eel (Electrophorus electricus) and of cholinesterases from horse serum and from human serum did not show linear characteristics, indicating the presence of more than one single enzyme in these preparations. The corresponding inhibition curves were resolved by subtraction of exponential functions. In each case two different activity components were identified and characterized in respect to partial activity, substrate specificity, and reactivity with organophosphorous compounds. The suitability of the method for application on crude homogenates is discussed.     

How thione phosphonates inhibit activities of various cholinesterases

Analysis of mechanism of reversible inhibition of human erythrocyte acetylcholinesterase (AChE), of horse serum cholinesterase (ChE), and ChE of optical ganglia tissue of individuals of the Commander squid Berryleuthis magister from various habitat zones was studied under effect thionphosphonates (P=S), derivatives of piperidine, morpholine, perhydroazepine as well as several heterocyclic model compounds. Data of comparative inhibitory specificity have allowed us to suggest that thionphosphonates are sorbed in the area of cholinesterase esterase center at the expense of phosphoryl part of the inhibitor molecule, rather than of its heterocyclic grouping. An advantage in the antienzyme efficiency of thionphosphonates (P=S) over phosphonates (P=O) is revealed. The ion strength effect is used for analysis of contribution of the hydrophobichydrophilic interaction in the enzyme-inhibitor system.     

Effect of temperature and pH on carbamoylation and phosphorylation of serum cholinesterases. Theoretical interpretation of activation energies in complex reactions

1. The effect of temperature and pH was studied on the kinetics of inhibition of horse serum and human serum cholinesterase by four organophosphorus compounds and five carbamates. 2. For all compounds, and at each pH and temperature, the inhibition followed the kinetics of a bimolecular reaction with the inhibitor in excess, and with a negligible concentration of the Michaelis complex. 3. The second-order rate constants (k(a)) for inhibition of human serum cholinesterase by one organophosphate and one carbamate increased from 5 degrees to 40 degrees C with an apparent activation energy of 46kJ/mol (11kcal/mol). 4. The k(a) constant for inhibition of horse serum cholinesterase increased with temperature from 5 degrees to 30 degrees C, and then decreased from 30 degrees to 40 degrees C. The theoretical interpretation of such an unusual effect of temperature is derived. 5. The increase of k(a) with pH (human serum cholinesterase) followed the dissociation curve for a single group on the enzyme (pK7.5). 6. Rate constants for decarbamoylation (k(+3)) were determined, and the time-course of inhibition was calculated from the k(a) and k(+3) constants.     

Organosilicon reversible inhibitors of cholinesterases of different animals

The review presents data on cholinesterase effects of 28 specially synthesized organosilicon compounds (monoonium, organoelement, and bisonium derivatives) studied as reversible inhibitors of acetylcholinesterase (acetyl-ChE) of human erythrocytes, butyryl-ChE of horse blood serum, ChE of brain of common frog Rana temporaria, ChE of the optical ganglia tissue of Pacific squid Todarodes pacificus and of individuals of Commandor squid Berryteuthis magister from various habitats in the Northwestern aquatoria of the Pacific ocean. Among the tested compounds, there are revealed highly specific inhibitors of mammalian ChE as well as of ChE of the B. magister individuals from various habitats.     

Comparative-enzymological study of cholinesterases from optic ganglia of the Commander squid Berryteuthis magister individuals inhabiting different zones of the species areal

In this review a comparative analysis is performed of enzymological characteristics of cholinesterase (ChE) from optic ganglia of individuals of the Commander squid Berryteuthis magister caught in 8 zones of its habitation areal in the northern-western Pacific aquatorium, of ChE of the Pacific squid Todarodes pacificus as well as of the "standard" acetylcholinesterase from human erythrocytes and butyrylcholinesterase from horse blood serum. By the method of the substrate-inhibitor analysis there was shown heterogeneity of ChE preparations from the B. magister individuals from different habitation zones. Kinetic parameters of the enzymatic hydrolysis of 8 ester substrates are presented as well as the data on study of inhibitory specificity with use of 20 irreversible organophosphorus inhibitors, which show identity of ChE properties in the B. magister individuals from different habitation zones. Study of the process of the ChE reversible inhibition from the Commander squid individuals under action of 57 mono- and bisonium inhibitors has revealed differences in ChE properties of squid individuals from isolates in different zones of the habitation areal, which argues in favor of the existence of intraspecies groups of the Commander squid B. magister.     

Comparative Study of Reversible Organofluorine Ammonium Inhibitors of Cholinesterases of Different Animals

A group of organofluorine ammonium compounds, trimethyltrifluoromethylammonium, diethylmethyltrifluoromethylammonium, hexa(difluoromethylene)-bis(trimethylammonium), their non-substituted analogs as well as bis-onium organosilicone, phenyliodonium, and triphenylphosphonium derivatives were tested as reversible inhibitors of acetylcholinesterase of human erythrocytes, butyrylcholinesterase of horse blood serum, cholinesterase of brain of the frog Rana temporaria and cholinesterases of optic ganglion of the Pacific squid Todarodes pacificus. By the method of molecular mechanics, differences were revealed in conformational mobility of interonium chain and in geometric parameters of the studied compounds. It was shown that introduction of fluorine atoms into the inhibitor molecule affected only their interaction with the Pacific squid cholinesterase. It was possible to separate effects of the onium atom nature and of the interonium chain structure in the inhibitor molecule on the anticholinesterase potency.