Structures of recombinant wild-type human acetylcholinesterase and of its E202Q mutant as complexes with fasciculin-II, a 'three-finger' polypeptide toxin purified from the venom of the eastern green mamba (Dendroaspis angusticeps), are reported. The structure of the complex of the wild-type enzyme was solved to 2.8 A resolution by molecular replacement starting from the structure of the complex of Torpedo californica acetylcholinesterase with fasciculin-II and verified by starting from a similar complex with mouse acetylcholinesterase. The overall structure is surprisingly similar to that of the T. californica enzyme with fasciculin-II and, as expected, to that of the mouse acetylcholinesterase complex. The structure of the E202Q mutant complex was refined starting from the corresponding wild-type human acetylcholinesterase structure, using the 2.7 A resolution data set collected. Comparison of the two structures shows that removal of the charged group from the protein core and its substitution by a neutral isosteric moiety does not disrupt the functional architecture of the active centre. One of the elements of this architecture is thought to be a hydrogen-bond network including residues Glu202, Glu450, Tyr133 and two bridging molecules of water, which is conserved in other vertebrate acetylcholinesterases as well as in the human enzyme. The present findings are consistent with the notion that the main role of this network is the proper positioning of the Glu202 carboxylate relative to the catalytic triad, thus defining its functional role in the interaction of acetylcholinesterase with substrates and inhibitors.
We have examined the effects of 11 substitutions of active centre gorge residues of human acetylcholinesterase (HuAChE) on the rates of phosphonylation by 1,2,2-trimethylpropyl methyl-phosphonofluoridate (soman) and the aging of the resulting conjugates. The rates of phosphonylation were reduced to as little as one-seventieth, mainly in mutants of the hydrogen-bond network (Glu-202, Glu-450, Tyr-133). These recombinant enzymes as well as the F338A, W86A, W86F and D74N mutant HuAChEs varied in their resistance to aging (15-3300-fold relative to the wild type). The most dramatic resistance to aging was observed for the phosphonyl conjugate of the mutant W86A enzyme (1850-3300-fold relative to the wild type). It is proposed that Trp-86 contributes to the aging process by stabilizing the evolving carbonium ion on the 1,2,2-trimethylpropyl moiety, via charge-pi interaction. The rate-enhancing effect of Trp-86 provides a rationale for the unique facility of aging in soman-inhibited cholinesterases, compared with the corresponding conjugates in other serine hydrolases. Replacements of Glu-202 by aspartic acid, glutamine or alanine residues resulted in a similar (1/130-1/300) decrease of the rates of aging. A comparable decrease was also observed for the conjugate of the F338A mutant. These results, and the similar pH dependence of aging rates for the wild-type and E202Q and F338A mutant HuAChEs, indicate that Glu-202 is not involved in proton transfer to the phosphonyl moiety. On the basis of these findings and of molecular modelling we suggest that Glu-202 and Phe-338 contribute to the aging process by stabilizing the imidazolium of the catalytic triad His-447 via charge-charge and charge-pi interactions respectively, thereby facilitating an oxonium formation on the phosphonyl moiety.
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.
The secretomes of a virulent Bacillus anthracis strain and of avirulent strains (cured of the virulence plasmids pXO1 and pXO2), cultured in rich and minimal media, were studied by a comparative proteomic approach. More than 400 protein spots, representing the products of 64 genes, were identified, and a unique pattern of protein relative abundance with respect to the presence of the virulence plasmids was revealed. In minimal medium under high CO 2 tension, conditions considered to simulate those encountered in the host, the presence of the plasmids leads to enhanced expression of 12 chromosome-carried genes (10 of which could not be detected in the absence of the plasmids) in addition to expression of 5 pXO1-encoded proteins. Furthermore, under these conditions, the presence of the pXO1 and pXO2 plasmids leads to the repression of 14 chromosomal genes. On the other hand, in minimal aerobic medium not supplemented with CO 2 , the virulent and avirulent B. anthracis strains manifest very similar protein signatures, and most strikingly, two proteins (the metalloproteases InhA1 and NprB, orthologs of gene products attributed to the Bacillus cereus group PlcR regulon) represent over 90% of the total secretome. Interestingly, of the 64 identified gene products, at least 31 harbor features characteristic of virulence determinants (such as toxins, proteases, nucleotidases, sulfatases, transporters, and detoxification factors), 22 of which are differentially regulated in a plasmid-dependent manner. The nature and the expression patterns of proteins in the various secretomes suggest that distinct CO 2 -responsive chromosome-and plasmid-encoded regulatory factors modulate the secretion of potential novel virulence factors, most of which are associated with extracellular proteolytic activities.Bacillus anthracis is a gram-positive spore-forming bacterium that is the etiological agent of anthrax, a lethal disease sporadically affecting humans and animals, in particular herbivores. In its most severe manifestation, B. anthracis infection is initiated by inhalation of spores, which are taken up by alveolar macrophages and germinate into fast-dividing vegetative cells which secrete toxins and virulence factors during growth (81,99). If untreated by prompt antibiotic administration, the bacteria invade the bloodstream, resulting in massive bacteremia and consequently generalized systemic failure and death. B. anthracis is considered to represent a potential biothreat agent, owing to the severity of the anthrax disease, the ease of respiratory contamination, and the perpetual environmental stability of the infective spores. The recent deliberate dissemination of B. anthracis (15) accelerated the efforts to identify new B. anthracis virulence-related determinants for the design of novel diagnostic, preventive, and/or therapeutic strategies.Fully virulent B. anthracis strains harbor two native plasmids, pXO1 and pXO2, which encode critical pathogenicity factors. The absence of either one of the two plasmids results in a pronounce...
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.
The role of the functional architecture of human acetylcholinesterase (HuAChE) active center in facilitating reactions with organophosphorus inhibitors was examined by a combination of site-directed mutagenesis and kinetic studies of phosphorylation with organophosphates differing in size of their alkoxy substituents and in the nature of the leaving group. Replacements of residues Phe-295 and Phe-297, constituting the HuAChE acyl pocket, increase up to 80-fold the reactivity of the enzymes toward diisopropyl phosphorofluoridate, diethyl phosphorofluoridate, and p-nitrophenyl diethyl phosphate (paraoxon), indicating the role of this subsite in accommodating the phosphate alkoxy substituent. On the other hand, a decrease of up to 160-fold in reactivity was observed for enzymes carrying replacements of residues Tyr-133, Glu-202, and Glu-450, which are constituents of the hydrogen bond network in the HuAChE active center, which maintains its unique functional architecture. Replacement of residues Trp-86, Tyr-337, and Phe-338 in the alkoxy pocket affected reactivity toward diisopropyl phosphorofluoridate and paraoxon, but to a lesser extent that toward diethyl phosphorofluoridate, indicating that both the alkoxy substituent and the p-nitrophenoxy leaving group interact with this subsite. In all cases the effects on reactivity toward organophosphates, demonstrated in up to 10,000-fold differences in the values of bimolecular rate constants, were mainly a result of altered affinity of the HuAChE mutants, while the apparent first order rate constants of phosphorylation varied within a narrow range. This finding indicates that the main role of the functional architecture of HuAChE active center in phosphorylation is to facilitate the formation of enzyme-inhibitor Michaelis complexes and that this affinity, rather than the nucleophilic activity of the enzyme catalytic machinery, is a major determinant of HuAChE reactivity toward organophosphates.Acetylcholinesterase (AChE, 1 EC 3.1.1.7) is among the most efficient enzymes, with a turnover number of over 10 4 s Ϫ1 (Quinn, 1987). Its catalytic power and the high reactivity toward organophosphorus inhibitors are believed to be determined by the unique architecture of the AChE active center, consisting of several subsites. Resolution of the three-dimensional structure of Torpedo AChE (Sussman et al., 1991), sitedirected mutagenesis, and molecular modeling together with kinetic studies of the AChE muteins with substrates and reversible inhibitors (Gibney et al., 1990;Velan et al., 1991aVelan et al., , 1991bShafferman et al., 1992aShafferman et al., , 1992bShafferman et al., , 1992cShafferman et al., , 1993 Ordentlich et al., 1993aOrdentlich et al., , 1993bOrdentlich et al., , 1995Radic et al., 1992Radic et al., , 1993Barak et al., 1994;Kronman et al., 1994;Gnatt et al., 1994) (for a recent review see also Taylor and Radic (1994)) are beginning to unveil the functional role of the various active center subsites in the reactivity characteristics of the enzyme: (a) the esteratic ...
Recombinant human acetylcholinesterase (HuAChE) and selected mutants (E202Q, Y337A, F,450A) were studied with respect to catalytic activity towards charged and noncharged substrates, phosphylation with organophosphorus (OP) inhibitors and subsequent aging of the OP-conjugates. Amino acid E450, unlike residues E202 and Y337, is not within interaction distance from the active center. Yet, the bimolecular rates of catalysis and phosphylation are 30~100 fold lower for both FA50A and E202Q compared to Y337A or the wild type and in both mutants the resulting OP-conjugates show striking resistance to aging. It is proposed that a hydrogen bond network, that maintains the functional architecture of the active center, involving water molecules and residues E202 and E450, is responsible for the observed behaviour.
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