Homology Built Model of Acetylcholinesterase from<i>Drosophila Melanogaster</i>

Stojan, Jure

doi:10.3109/14756369909030316

Journal of Enzyme Inhibition

1999

DOI: 10.3109/14756369909030316

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Homology Built Model of Acetylcholinesterase fromDrosophila Melanogaster

Jure Stojan

Abstract: Acetylcholinesterases from Drosophila melanogaster and Torpedo marmorata possess 35% identical residues. We built a homology model of the Drosophila enzyme on the basis of the known three-dimensional structure of Torpedo acetylcholinesterase, which revealed an oval rim of the active site gorge with an additional hollow which could accept small charged ligands more firmly than the corresponding surface in the Torpedo enzyme. This difference at the peripheral site, together with the kinetics of W121A and W359L m… Show more

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Cited by 3 publications

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“…The main objection to the first explanation is based on known three-dimensional structures of vertebrate AChE's complexes with inhibitors showing no significant intramolecular movements (18). However, our three-dimensional homology-built model (19) suggested and newly resolved crystal structure of the native DmAChE (20) reveals such movements and therefore supports the first hypothesis.…”

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confidence: 56%

Interaction of Drosophila Acetylcholinesterases with d-Tubocurarine: An Explanation of the Activation by an Inhibitor

2000

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Homotropic cooperativity in Drosophila melanogaster acetylcholinesterase seems to be a consequence of an initial substrate binding to a high-affinity peripheral substrate binding site situated around the negative charge of D413 (G335, Torpedo numbering). An appropriate mutation which turns the peripheral binding site to a low-affinity spot abolishes apparent activation but improves the overall enzyme effectiveness. This contradiction can be explained as less effective inhibition due to a shorter occupation of such a peripheral site. A similar effect can be achieved by an appropriate peripheral inhibitor such as TC, which can in special cases, when less effective heterotropic inhibition prevails over homotropic, acts as an activator. At the highest substrate concentrations, however, these enzymes are always inhibited, although steric components may influence the strength of inhibition like in the F368G mutant (F290, Torpedo numbering). Cooperative effects thus may include a steric component, but covering of the entrance must affect influx and efflux to different extents.

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supporting

confidence: 56%

Interaction of Drosophila Acetylcholinesterases with d-Tubocurarine: An Explanation of the Activation by an Inhibitor

2000

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Distinctive Structural and Kinetic Properties of an Unusual Juvenile Hormone-Hydrolyzing Esterase

Kadono-Okuda

Ridley

Jones

et al. 2000

Biochemical and Biophysical Research Communications

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Exploration of the Drosophila Acetylcholinesterase Substrate Activation Site Using a Reversible Inhibitor (Triton X-100) and Mutated Enzymes

Marcel

Estrada‐Mondaca

Magné

et al. 2000

Journal of Biological Chemistry

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Cholinesterases are activated at low substrate concentration, and this is followed by inhibition as the level of substrate increases. However, one of these two components is sometimes lacking. In Drosophila acetylcholinesterase, the two phases are present, allowing both phenomena to be studied. Several kinetic schemes can explain this complex kinetic behavior. Among them, one model assumes that activation results from the binding of a substrate molecule to a non-productive site affecting the entrance of a substrate molecule into the active site. To test this hypothesis, we looked for an inhibitor competitive for activation and we found Triton X-100. Using organophosphates or carbamates as hemisubstrates, we showed that Triton X-100 inhibits or increases phosphorylation or carbamoylation of the enzyme. In vitro mutagenesis of the residues lining the active site gorge allowed us to locate the Triton X-100 binding site at the rim of the gorge with glutamate 107 playing the major role. These results led to the hypothesis that substrate binding at this site affects the entrance of another substrate molecule into the active site cleft.

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Homology Built Model of Acetylcholinesterase fromDrosophila Melanogaster

Cited by 3 publications

References 14 publications

Interaction of Drosophila Acetylcholinesterases with d-Tubocurarine: An Explanation of the Activation by an Inhibitor

Interaction of Drosophila Acetylcholinesterases with d-Tubocurarine: An Explanation of the Activation by an Inhibitor

Distinctive Structural and Kinetic Properties of an Unusual Juvenile Hormone-Hydrolyzing Esterase

Exploration of the Drosophila Acetylcholinesterase Substrate Activation Site Using a Reversible Inhibitor (Triton X-100) and Mutated Enzymes

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