Substrate Report for: Acetylthiocholine

As deduced from cDNA clones, the catalytic domain of Bungarus fasciatus venom acetylcholinesterase (AChE) is highly homologous to those of other AChEs. It is, however, associated with a short hydrophilic carboxyl-terminal region, containing no cysteine, that bears no resemblance to the alternative COOH-terminal peptides of the GPI-anchored molecules (H) or of other homomeric or heteromeric tailed molecules (T). Expression of complete and truncated AChE in COS cells showed that active hydrophilic monomers are produced and secreted in all cases, and that cleavage of a very basic 8-residue carboxyl-terminal fragment occurs upon secretion. The COS cells produced Bungarus AChE about 30 times more efficiently than an equivalent secreted monomeric rat AChE. The recombinant Bungarus AChE, like the natural venom enzyme, showed a distinctive ladder pattern in nondenaturing electrophoresis, probably reflecting a variation in the number of sialic acids. By mutagenesis, we showed that two differences (methionine instead of tyrosine at position 70; lysine instead of aspartate or glutamate at position 285) explain the low sensitivity of Bungarus AChE to peripheral site inhibitors, compared to the Torpedo or mammalian AChEs. These results illustrate the importance of both the aromatic and the charged residues, and the fact that peripheral site ligands (propidium, gallamine, D-tubocurarine, and fasciculin 2) interact with diverse subsets of residues.

Several of the residues constituting the peripheral anionic site (PAS) in human acetylcholinesterase (HuAChE) were identified by a combination of kinetic studies with 19 single and multiple HuAChE mutants, fluorescence binding studies with the Trp-286 mutant, and by molecular modeling. Mutants were analyzed with three structurally distinct positively charged PAS ligands, propidium, decamethonium, and di(p-allyl-N-dimethylaminophenyl)pentane-3-one (BW284C51), as well as with selective active center inhibitors, hexamethonium and edrophonium. Single mutations of residues Tyr-72, Tyr-124, Glu-285, Trp-286, and Tyr-341 resulted in up to 10-fold increase in inhibition constants for PAS ligands, whereas for multiple mutants up to 400-fold increase was observed. The 6th PAS element residue Asp-74 is unique in its ability to affect conformation of both the active site and the PAS (Shafferman, A., Velan, B., Ordentlich, A., Kronman, C., Grosfeld, H., Leitner, M., Flashner, Y., Cohen, S., Barak, D., and Ariel, N. (1992) EMBO J. 11, 3561-3568) as demonstrated by the several hundred-fold increase in Ki for D74N inhibition by the bisquaternary ligands decamethonium and BW284C51. Based on these studies, singular molecular models for the various HuAChE inhibitor complexes were defined. Yet, for the decamethonium complex two distinct conformations were generated, accommodating the quaternary ammonium group by interactions with either Trp-286 or with Tyr-341. We propose that the PAS consists of a number of binding sites, close to the entrance of the active site gorge, sharing residues Asp-74 and Trp-286 as a common core. Binding of ligands to these residues may be the key to the allosteric modulation of HuAChE catalytic activity. This functional degeneracy is a result of the ability of the Trp-286 indole moiety to interact either via stacking, aromatic-aromatic, or via pi-cation attractions and the involvement of the carboxylate of Asp-74 in charge-charge or H-bond interactions.

Two sites of ligand interaction in acetylcholinesterase (AChE) were first demonstrated in ligand binding studies and later confirmed by crystallography, site-specific mutagenesis, and molecular modeling: an acylation site at the base of the active site gorge and a peripheral site at its mouth. We recently introduced a steric blockade model which demonstrated how small peripheral site ligands such as propidium may inhibit substrate hydrolysis [Szegletes, T., Mallender, W. D., and Rosenberry, T. L. (1998) Biochemistry 37, 4206-4216]. In this model, the only effect of a bound peripheral site ligand is to decrease the association and dissociation rate constants for an acylation site ligand without altering the equilibrium constant for ligand binding to the acylation site. Here, we first provide evidence that not only rate constants for substrates but also dissociation rate constants for their hydrolysis products are decreased by bound peripheral site ligand. Previous reaction schemes for substrate hydrolysis by AChE were extended to include product dissociation steps, and acetylthiocholine hydrolysis rates in the presence of propidium under nonequilibrium conditions were simulated with assigned rate constants in the program SCoP. We next showed that cationic substrates such as acetylthiocholine and 7-acetoxy-N-methylquinolinium (M7A) bind to the peripheral site as well as to the acylation site. The neurotoxin fasciculin was used to report specifically on interactions at the peripheral site. Analysis of inhibition of fasciculin association rates by these substrates revealed KS values of about 1 mM for the peripheral site binding of acetylthiocholine and 0.2 mM for the binding of M7A. The AChE reaction scheme was further extended to include substrate binding to the peripheral site as the initial step in the catalytic pathway. Simulations of the steric blockade model with this scheme were in reasonable agreement with observed substrate inhibition for acetylthiocholine and M7A and with mutual competitive inhibition in mixtures of acetylthiocholine and M7A. Substrate inhibition was explained by blockade of product dissociation when substrate is bound to the peripheral site. However, our analyses indicate that the primary physiologic role of the AChE peripheral site is to accelerate the hydrolysis of acetylcholine at low substrate concentrations.

To explore the role that surface and active center charges play in electrostatic attraction of ligands to the active center gorge of acetylcholinesterase (AChE), and the influence of charge on the reactive orientation of the ligand, we have studied the kinetics of association of cationic and neutral ligands with the active center and peripheral site of AChE. Electrostatic influences were reduced by sequential mutations of six surface anionic residues outside of the active center gorge (Glu-84, Glu-91, Asp-280, Asp-283, Glu-292, and Asp-372) and three residues within the active center gorge (Asp-74 at the rim and Glu-202 and Glu-450 at the base). The peripheral site ligand, fasciculin 2 (FAS2), a peptide of 6.5 kDa with a net charge of +4, shows a marked enhancement of rate of association with reduction in ionic strength, and this ionic strength dependence can be markedly reduced by progressive neutralization of surface and active center gorge anionic residues. By contrast, neutralization of surface residues only has a modest influence on the rate of cationic m-trimethylammoniotrifluoroacetophenone (TFK+) association with the active serine, whereas neutralization of residues in the active center gorge has a marked influence on the rate but with little change in the ionic strength dependence. Brownian dynamics calculations for approach of a small cationic ligand to the entrance of the gorge show the influence of individual charges to be in quantitative accord with that found for the surface residues. Anionic residues in the gorge may help to orient the ligand for reaction or to trap the ligand. Bound FAS2 on AChE not only reduces the rate of TFK+ reaction with the active center but inverts the ionic strength dependence for the cationic TFK+ association with AChE. Hence it appears that TFK+ must traverse an electrostatic barrier at the gorge entry imparted by the bound FAS2 with its net charge of +4.

As deduced from cDNA clones, the catalytic domain of Bungarus fasciatus venom acetylcholinesterase (AChE) is highly homologous to those of other AChEs. It is, however, associated with a short hydrophilic carboxyl-terminal region, containing no cysteine, that bears no resemblance to the alternative COOH-terminal peptides of the GPI-anchored molecules (H) or of other homomeric or heteromeric tailed molecules (T). Expression of complete and truncated AChE in COS cells showed that active hydrophilic monomers are produced and secreted in all cases, and that cleavage of a very basic 8-residue carboxyl-terminal fragment occurs upon secretion. The COS cells produced Bungarus AChE about 30 times more efficiently than an equivalent secreted monomeric rat AChE. The recombinant Bungarus AChE, like the natural venom enzyme, showed a distinctive ladder pattern in nondenaturing electrophoresis, probably reflecting a variation in the number of sialic acids. By mutagenesis, we showed that two differences (methionine instead of tyrosine at position 70; lysine instead of aspartate or glutamate at position 285) explain the low sensitivity of Bungarus AChE to peripheral site inhibitors, compared to the Torpedo or mammalian AChEs. These results illustrate the importance of both the aromatic and the charged residues, and the fact that peripheral site ligands (propidium, gallamine, D-tubocurarine, and fasciculin 2) interact with diverse subsets of residues.

In this study, we describe three different monoclonal antibodies (mAbs Elec-403, Elec-408, and Elec-410) directed against Electrophorus electricus acetylcholinesterase (AChE) which were selected as inhibitors for this enzyme. Two of these antibodies (Elec-403 and Elec-410), recognized overlapping but different epitopes, competed with snake venom toxin fasciculin for binding to the enzyme, and thus apparently recognized the peripheral site of AChE. In addition, the binding of Elec-403 was antagonized by 1,5-bis(4-allyldimethylammoniumphenyl)pentan-3-one dibromide (BW284C51) and propidium, indicating that the corresponding epitope encompassed the anionic site involved in the binding of these low-molecular-mass inhibitors. The third mAb (Elec-408), was clearly bound to another site on the AChE molecule, and its inhibitory effect was cumulative with those of Elec-403, Elec-410, and fasciculin. All mAbs bound AChE with high affinity and were as strong inhibitors with an apparent Ki values less than 0.1 nM. Elec-403 was particularly efficient with an inhibitory activity similar to that of fasciculin. Inhibition was observed with both charged (acetylthiocholine) and neutral substrates (o-nitrophenyl acetate) and had the characteristics of a non-competitive process. Elec-403 and Elec-410 probably exert their effect by triggering allosteric transitions from the peripheral site to the active site. The epitope recognized by mAb Elec-408 has not been localized, but it may correspond to a new regulatory site on AChE.

Several of the residues constituting the peripheral anionic site (PAS) in human acetylcholinesterase (HuAChE) were identified by a combination of kinetic studies with 19 single and multiple HuAChE mutants, fluorescence binding studies with the Trp-286 mutant, and by molecular modeling. Mutants were analyzed with three structurally distinct positively charged PAS ligands, propidium, decamethonium, and di(p-allyl-N-dimethylaminophenyl)pentane-3-one (BW284C51), as well as with selective active center inhibitors, hexamethonium and edrophonium. Single mutations of residues Tyr-72, Tyr-124, Glu-285, Trp-286, and Tyr-341 resulted in up to 10-fold increase in inhibition constants for PAS ligands, whereas for multiple mutants up to 400-fold increase was observed. The 6th PAS element residue Asp-74 is unique in its ability to affect conformation of both the active site and the PAS (Shafferman, A., Velan, B., Ordentlich, A., Kronman, C., Grosfeld, H., Leitner, M., Flashner, Y., Cohen, S., Barak, D., and Ariel, N. (1992) EMBO J. 11, 3561-3568) as demonstrated by the several hundred-fold increase in Ki for D74N inhibition by the bisquaternary ligands decamethonium and BW284C51. Based on these studies, singular molecular models for the various HuAChE inhibitor complexes were defined. Yet, for the decamethonium complex two distinct conformations were generated, accommodating the quaternary ammonium group by interactions with either Trp-286 or with Tyr-341. We propose that the PAS consists of a number of binding sites, close to the entrance of the active site gorge, sharing residues Asp-74 and Trp-286 as a common core. Binding of ligands to these residues may be the key to the allosteric modulation of HuAChE catalytic activity. This functional degeneracy is a result of the ability of the Trp-286 indole moiety to interact either via stacking, aromatic-aromatic, or via pi-cation attractions and the involvement of the carboxylate of Asp-74 in charge-charge or H-bond interactions.

The active site of acetylcholinesterase is near the bottom of a long and narrow gorge. The dimensions of the gorge and the strong electrostatic field generated by the enzyme appear inconsistent with the enzyme's high turnover rate. Consequently, a "back door" mechanism involving movement of the reaction products through a transient opening near the active center was recently suggested. We investigated this hypothesis in human acetylcholinesterase by testing mutants at key residues (Glu-84, Trp-86, Asp-131, and Val-132) located near or along the putative back door channel. The turnover rates of all mutants tested, and in particular of V132K, where the channel is expected to be sealed by salt bridge Lys-132-Glu-452, are similar to that of the wild type enzyme. This indicates that the proposed back door is not a route for product clearance from the active site gorge of acetylcholinesterase and is probably of no functional relevance to its catalytic activity.

Acetylcholinesterases (AChEs) are characterized by a high net negative charge and by an uneven surface charge distribution, giving rise to a negative electrostatic potential extending over most of the molecular surface. To evaluate the contribution of these electrostatic properties to the catalytic efficiency, 20 single- and multiple-site mutants of human AChE were generated by replacing up to seven acidic residues, vicinal to the rim of the active-center gorge (Glu84, Glu285, Glu292, Asp349, Glu358, Glu389 and Asp390), by neutral amino acids. Progressive simulated replacement of these charged residues results in a gradual decrease of the negative electrostatic potential which is essentially eliminated by neutralizing six or seven charges. In marked contrast to the shrinking of the electrostatic potential, the corresponding mutations had no significant effect on the apparent bimolecular rate constants of hydrolysis for charged and non-charged substrates, or on the Ki value for a charged active center inhibitor. Moreover, the kcat values for all 20 mutants are essentially identical to that of the wild type enzyme, and the apparent bimolecular rate constants show a moderate dependence on the ionic strength, which is invariant for all the enzymes examined. These findings suggest that the surface electrostatic properties of AChE do not contribute to the catalytic rate, that this rate is probably not diffusion-controlled and that long-range electrostatic interactions play no role in stabilization of the transition states of the catalytic process.

By examining inhibitor interactions with single and multiple site-specific mutants of mouse acetylcholinesterase, we have identified three distinct domains in the cholinesterase structure that are responsible for conferring selectivity for acetyl- and butyrylcholinesterase inhibitors. The first domain is the most obvious; it defines the constraints on the acyl pocket dimensions where the side chains of F295 and F297 primarily outline this region in acetylcholinesterase. Replacement of these phenylalanine side chains with the aliphatic residues found in butyrylcholinesterase allows for the catalysis of larger substrates and accommodates butyrylcholinesterase-selective alkyl phosphates such as isoOMPA. Also, elements of substrate activation characteristic of butyrylcholinesterase are evident in the F297I mutant. Substitution of tyrosines for F295 and F297 further alters the catalytic constants. The second domain is found near the lip of the active center gorge defined by two tyrosines, Y72 and Y124, and by W286; this region appears to be critical for the selectivity of bisquaternary inhibitors, such as BW284C51. The third domain defines the site of choline binding. Herein, in addition to conserved E202 and W86, a critical tyrosine, Y337, found only in the acetylcholinesterases is responsible for sterically occluding the binding site for substituted tricyclic inhibitors such as ethopropazine. Analysis of a series of substituted acridines and phenothiazines defines the groups on the ligand and amino acid side chains in this site governing binding selectivity. Each of the three domains is defined by a cluster of aromatic residues. The two domains stabilizing the quaternary ammonium moieties each contain a negative charge, which contributes to the stabilization energy of the respective complexes.

We report the existence, in Torpedo marmorata tissues, of a cholinesterase species (sensitive to 10(-5) M eserine) that differs from acetylcholinesterase (AChE, EC 3.1.1.7) in several respects: (a) The enzyme hydrolyzes butyrylthiocholine (BuSCh) at about 30% of the rate at which it hydrolyzes acetylthiocholine (AcSCh), whereas Torpedo AChE does not show any activity on BuSCh. (b) It is not inhibited by 10(-5) M BW 284C51, but rapidly inactivated by 10(-8) M diisopropylfluorophosphonate. (c) It does not exhibit inhibition by excess substrate up to 5 X 10(-3) M AcSCh. (d) It does not cross-react with anti-AChE antibodies raised against purified Torpedo AChE. This enzyme is obviously homologous to the "nonspecific" or pseudocholinesterase (pseudo-ChE, EC 3.1.1.8) that exists in other species, although it is closer to "true" AChE than classic pseudo-ChE in several respects. Thus, it shows the highest Vmax with acetyl-, and not propionyl- or butyrylthiocholine, and it is not specifically sensitive to ethopropazine. Pseudo-ChE is apparently absent from the electric organs, but represents the only cholinesterase species in the heart ventricle. Pseudo-ChE and AChE coexist in the spinal cord and in blood plasma, where they contribute to AcSCh hydrolysis in comparable proportions. Pseudo-ChE exists in several molecular forms, including collagen-tailed forms, which can be considered as homologous to those of AChE. In the heart the major component of pseudo-ChE appears to be a soluble monomeric form (G1). This form is inactivated by Triton X-100 within days.