New insights into the binding and catalytic mechanisms of Bacillus thuringiensis lactonase: insights into B. thuringiensis AiiA mechanism

The lactonase enzyme (AiiA) produced by Bacillus thuringiensis serves to degrade autoinducer-1 (AI-1) signaling molecules in what is an evolved mechanism by which to compete with other bacteria. Bioassays have been previously performed to determine whether the AI-1 aliphatic tail lengths have any ef...

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Veröffentlicht in:	PloS one 2013-09, Vol.8 (9), p.e75395-e75395
Hauptverfasser:	Charendoff, Marc N, Shah, Halie P, Briggs, James M
Format:	Artikel
Sprache:	eng
Schlagworte:	Aliphatic compounds Analysis Antibiotics Bacillus thuringiensis Bacillus thuringiensis - enzymology Bacillus thuringiensis - genetics Bacteria Bacterial Proteins - chemistry Bacterial Proteins - genetics Bacterial Proteins - metabolism Bioassays Biochemistry Biofilms Biological activity Biology Carbonyls Catalysis Catalytic activity Catalytic Domain Enzymes Gene expression Gram-negative bacteria Homoserine lactones Ionization Lactones Metabolism Metalloendopeptidases - chemistry Metalloendopeptidases - genetics Metalloendopeptidases - metabolism Molecular dynamics Molecular Dynamics Simulation Protein Structure, Secondary Proteins Pseudomonas aeruginosa Reagents Signaling Simulation Studies Substrates Tails Zinc
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description	The lactonase enzyme (AiiA) produced by Bacillus thuringiensis serves to degrade autoinducer-1 (AI-1) signaling molecules in what is an evolved mechanism by which to compete with other bacteria. Bioassays have been previously performed to determine whether the AI-1 aliphatic tail lengths have any effect on AiiA's bioactivity, however, data to date are conflicting. Additionally, specific residue contributions to the catalytic activity of AiiA provide for some interesting questions. For example, it has been proposed that Y194 serves to provide an oxyanion hole to AI-1 which is curious given the fact the substrate spans two Zn(2+) ions. These ions might conceivably provide enough charge to promote both ligand stability and the carbonyl activation necessary to drive a nucleophilic attack. To investigate these questions, multiple molecular dynamics simulations were performed across a family of seven acylated homoserine lactones (AHL) along with their associated intermediate and product states. Distance analyses and interaction energy analyses were performed to investigate current bioassay data. Our simulations are consistent with experimental studies showing that AiiA degrades AHLs in a tail length independent manner. However, the presence of the tail is required for activity. Also, the putative oxyanion hole function of Y194 toward the substrate is not observed in any of the reactant or product state simulation trajectories, but does seem to show efficacy in stabilizing the intermediate state. Last, we argue through ionization state analyses, that the proton shuttling necessary for catalytic activity might be mediated by both water and substrate-based intra-molecular proton transfer. Based on this argument, an alternate catalytic mechanism is proposed.
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Our simulations are consistent with experimental studies showing that AiiA degrades AHLs in a tail length independent manner. However, the presence of the tail is required for activity. Also, the putative oxyanion hole function of Y194 toward the substrate is not observed in any of the reactant or product state simulation trajectories, but does seem to show efficacy in stabilizing the intermediate state. Last, we argue through ionization state analyses, that the proton shuttling necessary for catalytic activity might be mediated by both water and substrate-based intra-molecular proton transfer. 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Bioassays have been previously performed to determine whether the AI-1 aliphatic tail lengths have any effect on AiiA's bioactivity, however, data to date are conflicting. Additionally, specific residue contributions to the catalytic activity of AiiA provide for some interesting questions. For example, it has been proposed that Y194 serves to provide an oxyanion hole to AI-1 which is curious given the fact the substrate spans two Zn(2+) ions. These ions might conceivably provide enough charge to promote both ligand stability and the carbonyl activation necessary to drive a nucleophilic attack. To investigate these questions, multiple molecular dynamics simulations were performed across a family of seven acylated homoserine lactones (AHL) along with their associated intermediate and product states. Distance analyses and interaction energy analyses were performed to investigate current bioassay data. 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subjects	Aliphatic compounds Analysis Antibiotics Bacillus thuringiensis Bacillus thuringiensis - enzymology Bacillus thuringiensis - genetics Bacteria Bacterial Proteins - chemistry Bacterial Proteins - genetics Bacterial Proteins - metabolism Bioassays Biochemistry Biofilms Biological activity Biology Carbonyls Catalysis Catalytic activity Catalytic Domain Enzymes Gene expression Gram-negative bacteria Homoserine lactones Ionization Lactones Metabolism Metalloendopeptidases - chemistry Metalloendopeptidases - genetics Metalloendopeptidases - metabolism Molecular dynamics Molecular Dynamics Simulation Protein Structure, Secondary Proteins Pseudomonas aeruginosa Reagents Signaling Simulation Studies Substrates Tails Zinc
title	New insights into the binding and catalytic mechanisms of Bacillus thuringiensis lactonase: insights into B. thuringiensis AiiA mechanism
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