| Title : Engineered Surface-Immobilized Enzyme that Retains High Levels of Catalytic Activity in Air - Badieyan_2017_J.Am.Chem.Soc_139_2872 |
| Author(s) : Badieyan S , Wang Q , Zou X , Li Y , Herron M , Abbott NL , Chen Z , Marsh EN |
| Ref : Journal of the American Chemical Society , 139 :2872 , 2017 |
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Abstract :
In the absence of aqueous buffer, most enzymes retain little or no activity; however, "water-free" enzymes would have many diverse applications. Here, we describe the chemically precise immobilization of an enzyme on an engineered surface designed to support catalytic activity in air at ambient humidity. Covalent immobilization of haloalkane dehalogenase on a surface support displaying poly(sorbitol methacrylate) chains resulted in approximately 40-fold increase in activity over lyophilized enzyme powders for the gas-phase dehalogenation of 1-bromopropane. The activity of the immobilized enzyme in air approaches 25% of the activity obtained in buffer for the immobilized enzyme. Poly(sorbitol methacrylate) appears to enhance activity by replacing protein-water interactions, thereby preserving the protein structure. |
| PubMedSearch : Badieyan_2017_J.Am.Chem.Soc_139_2872 |
| PubMedID: 28191945 |
Badieyan S, Wang Q, Zou X, Li Y, Herron M, Abbott NL, Chen Z, Marsh EN (2017)
Engineered Surface-Immobilized Enzyme that Retains High Levels of Catalytic Activity in Air
Journal of the American Chemical Society
139 :2872
Badieyan S, Wang Q, Zou X, Li Y, Herron M, Abbott NL, Chen Z, Marsh EN (2017)
Journal of the American Chemical Society
139 :2872