Title: The 'aromatic patch' of three proximal residues in the human acetylcholinesterase active centre allows for versatile interaction modes with inhibitors Ariel N, Ordentlich A, Barak D, Bino T, Velan B, Shafferman A Ref: Biochemical Journal, 335:95, 1998 : PubMed
The role of the functional architecture of the human acetylcholinesterase (HuAChE) active centre in accommodating the non-covalent inhibitors tacrine and huperzine A, or the carbamates pyridostigmine and physostigmine, was analysed using 16 mutants of residues lining the active-centre gorge. Despite the structural diversity of the ligands, certain common properties of the complexes could be observed: (a) replacement of aromatic residues Tyr133, Tyr337 and especially Trp86, resulted in pronounced changes in stability of all the complexes examined; (b) effects due to replacements of the five other aromatic residues along the active-centre gorge, such as the acyl pocket (Phe295, Phe297) or at the peripheral anionic site (Tyr124, Trp286, Tyr341) were relatively small; (c) effects due to substitution of the carboxylic residues in the gorge (Glu202, Glu450) were moderate. These results and molecular modelling indicate that the aromatic side chains of residues Trp86, Tyr133 and Tyr337 form together a continuous 'aromatic patch' lining the wall of the active-centre gorge, allowing for the accommodation of the different ligands via multiple modes of interaction. Studies with HuAChE mutants carrying replacements at positions 86, 133 and 337 indicate that the orientations of huperzine A and tacrine in the HuAChE complexes in solution are significantly different from those observed in X-ray structures of the corresponding complexes with Torpedo californica AChE (TcAChE). These discrepancies may be explained in terms of structural differences between the complexes of HuAChE and TcAChE or, more likely, by the enhanced flexibility of the AChE active-centre gorge in solution as compared with the crystalline state.
Butyrylcholinesterase [BCHE (acylcholine acyl hydrolase); EC 3.1.1.8] limits the access of drugs, including tacrine, to other proteins. The "atypical" BCHE variant, in which Asp70 at the rim of the active site gorge is substituted by glycine, displayed a more drastically weakened interaction with tacrine than with cocaine, dibucaine, succinylcholine, BW284c51 [1,5-bis(4-allyldimethylammoniumphenyl)pentan-3-one dibromide], or alpha-solanine. To delineate the protein domains that are responsible for this phenomenon, we mutated residues within the rim of the active site gorge, the region parallel to the peripheral site in the homologous enzyme acetylcholinesterase [AChE (acetylcholine acetyl hydrolase); EC 3.1.1.7], the oxyanion hole, and the choline-binding site. When expressed in microinjected Xenopus laevis oocytes, all mutant DNAs yielded comparable amounts of immunoreactive protein products. Most mutants retained catalytic activity close to that of wild-type BCHE and were capable of binding ligands. However, certain modifications in and around the oxyanion hole caused a dramatic loss in activity. The affinities for tacrine were reduced more dramatically than for all other ligands, including cocaine, in both oxyanion hole and choline-binding site mutants. Modified ligand affinities further demonstrated a peripheral site in residues homologous with those of AChE. BCHE mutations that prevented tacrine interactions also hampered its ability to bind other drugs and inhibitors, which suggests a partial overlap of the binding sites. This predicts that in addition to their genetic predisposition to adverse responses to tacrine, homozygous carriers of "atypical" BCHE will be overly sensitive to additional anticholinesterases and especially so when exposed to several anticholinesterases in combination.
Title: Contribution of aromatic moieties of tyrosine 133 and of the anionic subsite tryptophan 86 to catalytic efficiency and allosteric modulation of acetylcholinesterase Ordentlich A, Barak D, Kronman C, Ariel N, Segall Y, Velan B, Shafferman A Ref: Journal of Biological Chemistry, 270:2082, 1995 : PubMed
Substitution of Trp-86, in the active center of human acetylcholinesterase (HuAChE), by aliphatic but not by aromatic residues resulted in a several thousandfold decrease in reactivity toward charged substrate and inhibitors but only a severalfold decrease for noncharged substrate and inhibitors. The W86A and W86E HuAChE enzymes exhibit at least a 100-fold increase in the Michaelis-Menten constant or 100-10,000-fold increase in inhibition constants toward various charged inhibitors, as compared to W86F HuAChE or the wild type enzyme. On the other hand, replacement of Glu-202, the only acidic residue proximal to the catalytic site, by glutamine resulted in a nonselective decrease in reactivity toward charged and noncharged substrates or inhibitors. Thus, the quaternary nitrogen groups of substrates and other active center ligands, are stabilized by cation-aromatic interaction with Trp-86 rather than by ionic interactions, while noncharged ligands appear to bind to distinct site(s) in HuAChE. Analysis of the Y133F and Y133A HuAChE mutated enzymes suggests that the highly conserved Tyr-133 plays a dual role in the active center: (a) its hydroxyl appears to maintain the functional orientation of Glu-202 by hydrogen bonding and (b) its aromatic moiety maintains the functional orientation of the anionic subsite Trp-86. In the absence of aromatic interactions between Tyr-133 and Trp-86, the tryptophan acquires a conformation that obstructs the active site leading, in the Y133A enzyme, to several hundredfold decrease in rates of catalysis, phosphorylation, or in affinity to reversible active site inhibitors. It is proposed that allosteric modulation of acetylcholinesterase activity, induced by binding to the peripheral anionic sites, proceeds through such conformational change of Trp-86 from a functional anionic subsite state to one that restricts access of substrates to the active center.
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.
Amino acids located within and around the 'active site gorge' of human acetylcholinesterase (AChE) were substituted. Replacement of W86 yielded inactive enzyme molecules, consistent with its proposed involvement in binding of the choline moiety in the active center. A decrease in affinity to propidium and a concomitant loss of substrate inhibition was observed in D74G, D74N, D74K and W286A mutants, supporting the idea that the site for substrate inhibition and the peripheral anionic site overlap. Mutations of amino acids neighboring the active center (E202, Y337 and F338) resulted in a decrease in the catalytic and the apparent bimolecular rate constants. A decrease in affinity to edrophonium was observed in D74, E202, Y337 and to a lesser extent in F338 and Y341 mutants. E202, Y337 and Y341 mutants were not inhibited efficiently by high substrate concentrations. We propose that binding of acetylcholine, on the surface of AChE, may trigger sequence of conformational changes extending from the peripheral anionic site through W286 to D74, at the entrance of the 'gorge', and down to the catalytic center (through Y341 to F338 and Y337). These changes, especially in Y337, could block the entrance/exit of the catalytic center and reduce the catalytic efficiency of AChE.
Title: The effect of elimination of intersubunit disulfide bonds on the activity, assembly, and secretion of recombinant human acetylcholinesterase. Expression of acetylcholinesterase Cys-580----Ala mutant Velan B, Grosfeld H, Kronman C, Leitner M, Gozes Y, Lazar A, Flashner Y, Marcus D, Cohen S, Shafferman A Ref: Journal of Biological Chemistry, 266:23977, 1991 : PubMed
Site-directed mutagenesis was used to study the cysteine residue involved in the assembly of human acetylcholinesterase (HuAChE) catalytic subunits. Substitution of the cysteine at position 580 by alanine resulted in impairment of interchain disulfide bridge formation; the mutagenized enzyme (C580A) was secreted from recombinant cells in the monomeric form and failed to assemble into dimers. The mutant monomeric HuAChE did not differ from the native oligomeric enzyme neither in rate of catalysis nor in affinity to acetylthiocholine. Mutant monomers were also shown to retain the acetylcholinesterase characteristic sensitivity to high substrate concentrations. The mutation did not seem to affect the efficiencies of either synthesis or secretion of recombinant HuAChE polypeptides, as was demonstrated in cell lines derived from human embryonic kidney (293 cells) as well as from a human neuroblastoma (SK-N-SH). Furthermore, the mutation did not lead to an increase in accumulation of intracellular HuAChE polypeptides, suggesting that export of acetylcholinesterase from cells may not be coupled to subunit assembly.
