Engineering Enzyme Stability and Resistance to an Organic Cosolvent by Modification of Residues in the Access Tunnel

Engineering Enzyme Stability and Resistance to an Organic Cosolvent by Modification of Residues in the Access Tunnel

Mutations targeting as few as four residues lining the access tunnel extended the half‐life of an enzyme in 40 % dimethyl sulfoxide from minutes to weeks and increased its melting temperature by 19 °C. Protein crystallography and molecular dynamics revealed that the tunnel residue packing is a key d...

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Veröffentlicht in:Angewandte Chemie International Edition 2013-02, Vol.52 (7), p.1959-1963
Hauptverfasser: Koudelakova, Tana, Chaloupkova, Radka, Brezovsky, Jan, Prokop, Zbynek, Sebestova, Eva, Hesseler, Martin, Khabiri, Morteza, Plevaka, Maryia, Kulik, Daryna, Kuta Smatanova, Ivana, Rezacova, Pavlina, Ettrich, Rudiger, Bornscheuer, Uwe T., Damborsky, Jiri
Format: Artikel
Sprache:eng
Schlagworte:
Accessibility
Biocatalysis
Dimethyl sulfoxide
Dimethyl Sulfoxide - chemistry
directed evolution
enzyme catalysis
Enzyme Stability
Enzymes
Enzymes - chemistry
Enzymes - metabolism
Evolution, Molecular
Kinetics
Melting
Molecular Dynamics Simulation
Protein Engineering
protein stability
Proteins
Residues
Solvents - chemistry
Stability
Tunnels (transportation)
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Beschreibung
Zusammenfassung:Mutations targeting as few as four residues lining the access tunnel extended the half‐life of an enzyme in 40 % dimethyl sulfoxide from minutes to weeks and increased its melting temperature by 19 °C. Protein crystallography and molecular dynamics revealed that the tunnel residue packing is a key determinant of protein stability and the active‐site accessibility for cosolvent molecules (red dots).
ISSN:1433-7851
1521-3773
DOI:10.1002/anie.201206708