Impaired protein conformational landscapes as revealed in anomalous Arrhenius prefactors

Abstract: A growing body of data supports a role for protein motion in enzyme catalysis. In particular, the ability of enzymes to sample catalytically relevant conformational substates has been invoked to model kinetic and spectroscopic data. However, direct experimental links between rapidly interconverting conformations and the chemical steps of catalysis remain rare. We report here on the kinetic analysis and characterization of the hydride transfer step catalyzed by a series of mutant thermophilic alcohol dehydrogen… Show more

“…This indicates the much larger effect of an active site mutant on oligomeric protein stability than the subunit interface mutant Y25A. (31). A detailed characterization of these enzymes has led to the conclusion that the unusual Arrhenius curves observed for ht-ADH variants reflect a reversible distribution of the protein conformational landscape into inactive, low energy states at low temperature.…”

“…It is, thus, possible to identify an approximately 20-Å pathway of dynamical communication between the two targeted residues (Tyr-25 and Trp-87), comprised of the very same peptides that were previously demonstrated to rigidify below 30°C in ht-ADH (21). We conclude that intersubunit contacts in the family of tetrameric prokaryotic alcohol dehydrogenases can alter the protein conformational landscape (31), thereby controlling the active site configurations that are directly linked to Arrhenius behavior and the properties of hydride tunneling between substrate and cofactor.…”

“…It has been shown previously that both the Arrhenius behavior and KIEs for ht-ADH are sensitive to amino acid substitutions for conserved bulky hydrophobic residues in the NAD ϩ cofactor binding pocket (31,32). We have now analyzed a variant at a conserved residue in the substrate-binding pocket of ht-ADH (ht-W87A) that is shown to abrogate the Arrhenius break in the experimental temperature range.…”

Identification of a Long-range Protein Network That Modulates Active Site Dynamics in Extremophilic Alcohol Dehydrogenases

“…This indicates the much larger effect of an active site mutant on oligomeric protein stability than the subunit interface mutant Y25A. (31). A detailed characterization of these enzymes has led to the conclusion that the unusual Arrhenius curves observed for ht-ADH variants reflect a reversible distribution of the protein conformational landscape into inactive, low energy states at low temperature.…”

“…It is, thus, possible to identify an approximately 20-Å pathway of dynamical communication between the two targeted residues (Tyr-25 and Trp-87), comprised of the very same peptides that were previously demonstrated to rigidify below 30°C in ht-ADH (21). We conclude that intersubunit contacts in the family of tetrameric prokaryotic alcohol dehydrogenases can alter the protein conformational landscape (31), thereby controlling the active site configurations that are directly linked to Arrhenius behavior and the properties of hydride tunneling between substrate and cofactor.…”

“…It has been shown previously that both the Arrhenius behavior and KIEs for ht-ADH are sensitive to amino acid substitutions for conserved bulky hydrophobic residues in the NAD ϩ cofactor binding pocket (31,32). We have now analyzed a variant at a conserved residue in the substrate-binding pocket of ht-ADH (ht-W87A) that is shown to abrogate the Arrhenius break in the experimental temperature range.…”

Identification of a Long-range Protein Network That Modulates Active Site Dynamics in Extremophilic Alcohol Dehydrogenases

“…Results in the kinetics of catalytic reactions of the dehydrogenase and oxidase enzymes have shown an undoubted super-Arrhenius behaviour [25,53,54,68].…”

“…It often manifests because of collective phenomena, such as those amenable to treatment by the non-extensive thermodynamics of Tsallis, and covers an ample set of phenomena: rates of enzymatic catalysis-promoted processes [53][54][55], food preservation processes [56,57] and basic features of the dynamics of complex or glass-forming liquids and solids [58][59][60][61][62][63].…”

Kinetics of low-temperature transitions and a reaction rate theory from non-equilibrium distributions

Hydrostatic Pressure Studies Distinguish Global from Local Protein Motions in C−H Activation by Soybean Lipoxygenase‐1