scholarly journals Ground-State Destabilization by Active-Site Hydrophobicity Controls the Selectivity of a Cofactor- Free Decarboxylase

2020 ◽  
Author(s):  
Michal Biler ◽  
Rory Crean ◽  
Anna K. Schweiger ◽  
Robert Kourist ◽  
Shina Caroline Lynn Kamerlin
Keyword(s):  
Ground State ◽  
Active Site ◽  
Valence Bond ◽  
Optical Purity ◽  
Interaction Network ◽  
Enzyme Engineering ◽  
Carboxylate Group ◽  
Solvent Exposure ◽  
Preferential Cleavage ◽  
High Optical Purity

<div> <div> <p> </p><div> <div> <div> <p>Bacterial arylmalonate decarboxylase (AMDase) and evolved variants have become a valuable tool with which to access both enantiomers of a broad range of chiral arylaliphatic acids with high optical purity. Yet, the molecular principles responsible for the substrate scope, activity and selectivity of this enzyme are only poorly understood to this day, greatly hampering the predictability and design of improved enzyme variants for specific applications. In this work, empirical valence bond and metadynamics simulations were performed on wild-type AMDase and variants thereof, to obtain a better understanding of the underlying molecular processes determining reaction outcome. Our results clearly reproduce the experimentally observed substrate scope, and support a mechanism driven by ground-state destabilization of the carboxylate group being cleaved by the enzyme. In addition, our results indicate that, in the case of the non-converted or poorly-converted substrates studied in this work, increased solvent exposure of the active site upon binding of these substrates can disturb the vulnerable network of interactions responsible for facilitating the AMDase-catalyzed cleavage of CO2. Finally, our results indicate a switch from preferential cleavage of the pro-(R) to the pro-(S) carboxylate group in the CLG-IPL variant of AMDase for all substrates studied. This appears to be due to the emergence of a new hydrophobic pocket generated by the insertion of the six amino acid substitutions, into which the pro-(S) carboxylate binds. Our results allow insight into the tight interaction network determining AMDase selectivity, which in turn provides guidance for the identification of target residues for future enzyme engineering. </p> </div> </div> </div> </div> </div>

scholarly journals Ground-State Destabilization by Active-Site Hydrophobicity Controls the Selectivity of a Cofactor- Free Decarboxylase

2020 ◽  
Author(s):  
Michal Biler ◽  
Rory Crean ◽  
Anna K. Schweiger ◽  
Robert Kourist ◽  
Shina Caroline Lynn Kamerlin
Keyword(s):  
Ground State ◽  
Active Site ◽  
Valence Bond ◽  
Optical Purity ◽  
Interaction Network ◽  
Enzyme Engineering ◽  
Carboxylate Group ◽  
Solvent Exposure ◽  
Preferential Cleavage ◽  
High Optical Purity

<div> <div> <p> </p><div> <div> <div> <p>Bacterial arylmalonate decarboxylase (AMDase) and evolved variants have become a valuable tool with which to access both enantiomers of a broad range of chiral arylaliphatic acids with high optical purity. Yet, the molecular principles responsible for the substrate scope, activity and selectivity of this enzyme are only poorly understood to this day, greatly hampering the predictability and design of improved enzyme variants for specific applications. In this work, empirical valence bond and metadynamics simulations were performed on wild-type AMDase and variants thereof, to obtain a better understanding of the underlying molecular processes determining reaction outcome. Our results clearly reproduce the experimentally observed substrate scope, and support a mechanism driven by ground-state destabilization of the carboxylate group being cleaved by the enzyme. In addition, our results indicate that, in the case of the non-converted or poorly-converted substrates studied in this work, increased solvent exposure of the active site upon binding of these substrates can disturb the vulnerable network of interactions responsible for facilitating the AMDase-catalyzed cleavage of CO2. Finally, our results indicate a switch from preferential cleavage of the pro-(R) to the pro-(S) carboxylate group in the CLG-IPL variant of AMDase for all substrates studied. This appears to be due to the emergence of a new hydrophobic pocket generated by the insertion of the six amino acid substitutions, into which the pro-(S) carboxylate binds. Our results allow insight into the tight interaction network determining AMDase selectivity, which in turn provides guidance for the identification of target residues for future enzyme engineering. </p> </div> </div> </div> </div> </div>

scholarly journals Ground-State Destabilization by Active-Site Hydrophobicity Controls the Selectivity of a Cofactor- Free Decarboxylase

2020 ◽  
Author(s):  
Michal Biler ◽  
Rory Crean ◽  
Anna K. Schweiger ◽  
Robert Kourist ◽  
Shina Caroline Lynn Kamerlin
Keyword(s):  
Ground State ◽  
Active Site ◽  
Valence Bond ◽  
Optical Purity ◽  
Interaction Network ◽  
Enzyme Engineering ◽  
Carboxylate Group ◽  
Solvent Exposure ◽  
Preferential Cleavage ◽  
High Optical Purity

<div> <div> <p> </p><div> <div> <div> <p>Bacterial arylmalonate decarboxylase (AMDase) and evolved variants have become a valuable tool with which to access both enantiomers of a broad range of chiral arylaliphatic acids with high optical purity. Yet, the molecular principles responsible for the substrate scope, activity and selectivity of this enzyme are only poorly understood to this day, greatly hampering the predictability and design of improved enzyme variants for specific applications. In this work, empirical valence bond and metadynamics simulations were performed on wild-type AMDase and variants thereof, to obtain a better understanding of the underlying molecular processes determining reaction outcome. Our results clearly reproduce the experimentally observed substrate scope, and support a mechanism driven by ground-state destabilization of the carboxylate group being cleaved by the enzyme. In addition, our results indicate that, in the case of the non-converted or poorly-converted substrates studied in this work, increased solvent exposure of the active site upon binding of these substrates can disturb the vulnerable network of interactions responsible for facilitating the AMDase-catalyzed cleavage of CO2. Finally, our results indicate a switch from preferential cleavage of the pro-(R) to the pro-(S) carboxylate group in the CLG-IPL variant of AMDase for all substrates studied. This appears to be due to the emergence of a new hydrophobic pocket generated by the insertion of the six amino acid substitutions, into which the pro-(S) carboxylate binds. Our results allow insight into the tight interaction network determining AMDase selectivity, which in turn provides guidance for the identification of target residues for future enzyme engineering. </p> </div> </div> </div> </div> </div>

scholarly journals Ground-State Destabilization Controls the Selectivity of a Cofactor-Free Decarboxylase

2020 ◽  
Author(s):  
Michal Biler ◽  
Anna K. Schweiger ◽  
Robert Kourist ◽  
Shina Caroline Lynn Kamerlin
Keyword(s):  
Ground State ◽  
Valence Bond ◽  
Optical Purity ◽  
Interaction Network ◽  
Enzyme Engineering ◽  
Molecular Processes ◽  
Solvent Exposure ◽  
Empirical Valence Bond ◽  
High Optical Purity ◽  
Insight Into

<div> <div> <div> <p>Bacterial arylmalonate decarboxylase (AMDase) and evolved variants have become a valuable tool with which to access both enantiomers of a broad range of chiral arylaliphatic acids with high optical purity. Yet, the molecular principles responsible for the substrate scope, activity and selectivity of this enzyme are only poorly understood to this day, greatly hampering the predictability and design of improved enzyme variants for specific applications. In this work, empirical valence bond simulations were performed on wild-type AMDase and variants thereof, to obtain a better understanding of the underlying molecular processes determining reaction outcome. Our results clearly reproduce the experimentally observed substrate scope, and support a mechanism driven by ground-state destabilization of the carboxylate group being cleaved by the enzyme. In addition, our results indicate that, in the case of the non-converted or poorly-converted substrates studied in this work, increased solvent exposure of the active site upon binding of these substrates can disturb the vulnerable network of interactions responsible for facilitating the AMDase-catalyzed cleavage of CO2. Our results thus allow insight into the tight interaction network determining AMDase selectivity, which in turn provides guidance for the identification of target residues for future enzyme engineering. </p> </div> </div> </div>

The Synthesis of Optically Pure Epoxy-alkyl β-D-Glucosides and β-Cellobiosides as Active-Site Directed Inhibitors of Some β-Glucan Hydrolases

1990 ◽  
Vol 43 (8) ◽  
pp. 1391 ◽  
Author(s):  
EB Rodriguez ◽  
GD Scally ◽  
RV Stick
Keyword(s):  
Active Site ◽  
Optical Purity ◽  
Asymmetric Epoxidation ◽  
Chiral Alcohol ◽  
Pure Epoxy ◽  
Whole Process ◽  
High Optical Purity ◽  
The One ◽  
Sharpless Asymmetric Epoxidation ◽  
Optically Pure

(2R)- and (2S)-2,3-Epoxypropyl, (3R)- and (3S)-3,4-epoxybutyl and (4S)- 4,s-epoxypentyl B- Dglucopyranoside , together with the (3R)- and (3s)-3,4-epoxybutyl β- cellobiosides , have been prepared by condensation of a glycosyl bromide with the appropriate enantiomer of a chiral alcohol containing a diol protected as an isopropylidene acetal, and subsequent manipulation of the unmasked diol into the epoxide function. As well, in an improvement to the whole process, both diastereoisomers of the various epoxypropyl and epoxybutyl glycosides were available from just the one enantiomer of the alcohol by an alternative manipulation of the diol. Finally, precursors to 2,3-epoxy-4-hydroxybutyl β-D-glucosides and β- cellobiosides were prepared in high optical purity by Sharpless asymmetric epoxidation of the appropriate 4-hydroxybut-2-enyl glycosides.

scholarly journals Crystal structures of non-oxidative decarboxylases reveal a new mechanism of action with a catalytic dyad and structural twists

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Matthias Zeug ◽  
Nebojsa Markovic ◽  
Cristina V. Iancu ◽  
Joanna Tripp ◽  
Mislav Oreb ◽  
...  
Keyword(s):  
Crystal Structures ◽  
Active Site ◽  
Enzyme Engineering ◽  
Base Catalysis ◽  
Oxidative Decarboxylation ◽  
Transition State Stabilization ◽  
Major Bottleneck ◽  
Hydroxybenzoic Acids ◽  
Potassium Binding ◽  
Β Sheet

AbstractHydroxybenzoic acids, like gallic acid and protocatechuic acid, are highly abundant natural compounds. In biotechnology, they serve as critical precursors for various molecules in heterologous production pathways, but a major bottleneck is these acids’ non-oxidative decarboxylation to hydroxybenzenes. Optimizing this step by pathway and enzyme engineering is tedious, partly because of the complicating cofactor dependencies of the commonly used prFMN-dependent decarboxylases. Here, we report the crystal structures (1.5–1.9 Å) of two homologous fungal decarboxylases, AGDC1 from Arxula adenivorans, and PPP2 from Madurella mycetomatis. Remarkably, both decarboxylases are cofactor independent and are superior to prFMN-dependent decarboxylases when heterologously expressed in Saccharomyces cerevisiae. The organization of their active site, together with mutational studies, suggests a novel decarboxylation mechanism that combines acid–base catalysis and transition state stabilization. Both enzymes are trimers, with a central potassium binding site. In each monomer, potassium introduces a local twist in a β-sheet close to the active site, which primes the critical H86-D40 dyad for catalysis. A conserved pair of tryptophans, W35 and W61, acts like a clamp that destabilizes the substrate by twisting its carboxyl group relative to the phenol moiety. These findings reveal AGDC1 and PPP2 as founding members of a so far overlooked group of cofactor independent decarboxylases and suggest strategies to engineer their unique chemistry for a wide variety of biotechnological applications.

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