Activation of Immobilized Lipase in Non-Aqueous Systems by Hydrophobic Poly-DL-Tryptophan Tethers

Many industrially important reactions use immobilized enzymes in non-aqueous, organic systems, particularly for the production of chiral compounds such as pharmaceutical precursors. The addition of a spacer molecule (“tether”) between a supporting surface and enzyme often substantially improves the...

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Main Authors: Schilke, Karl F., Kelly, Christine
Format: Article in Journal/Newspaper
Language:English
unknown
Published: John Wiley & Sons Ltd.
Subjects:
Antarc*
Antarctica
Online Access:https://ir.library.oregonstate.edu/concern/articles/ht24wk059
id ftoregonstate:ir.library.oregonstate.edu:ht24wk059
record_format openpolar
spelling ftoregonstate:ir.library.oregonstate.edu:ht24wk059 2024-04-14T08:01:47+00:00 Activation of Immobilized Lipase in Non-Aqueous Systems by Hydrophobic Poly-DL-Tryptophan Tethers Schilke, Karl F. Kelly, Christine https://ir.library.oregonstate.edu/concern/articles/ht24wk059 English [eng] eng unknown John Wiley & Sons Ltd. https://ir.library.oregonstate.edu/concern/articles/ht24wk059 Copyright Not Evaluated Article ftoregonstate 2024-03-21T15:47:26Z Many industrially important reactions use immobilized enzymes in non-aqueous, organic systems, particularly for the production of chiral compounds such as pharmaceutical precursors. The addition of a spacer molecule (“tether”) between a supporting surface and enzyme often substantially improves the activity and stability of enzymes in aqueous solution. Most “long” linkers (e.g. polyethylene oxide derivatives) are relatively hydrophilic, improving the solubility of the linker-enzyme conjugate in polar environments, but this provides little benefit in non-polar environments such as organic solvents. We present a novel method for the covalent immobilization of enzymes on solid surfaces using a long, hydrophobic polytryptophan tether. Candida antarctica lipase B (CALB) was covalently immobilized on non-porous, functionalized 1-μm silica microspheres, with and without an intervening hydrophobic poly-DL-tryptophan tether (n ≈ 78). The polytryptophan-tethered enzyme exhibited 35 times greater esterification of n-propanol with lauric acid in the organic phase and five times the hydrolytic activity against p-nitrophenol palmitate, compared to the activity of the same enzyme immobilized without tethers. In addition, the hydrophobic tethers caused the silica microspheres to disperse more readily in the organic phase, while the surface-immobilized control treatment was less lipophilic and quickly settled out of the organic phase when the suspensions were not vigorously mixed. Keywords: Immobilization, Enzyme-catalyzed organic synthesis, Candida antarctica lipase B, Hydrophobic tethers, Silica microspheres, Poly-DL-tryptophan Article in Journal/Newspaper Antarc* Antarctica ScholarsArchive@OSU (Oregon State University)
institution Open Polar
collection ScholarsArchive@OSU (Oregon State University)
op_collection_id ftoregonstate
language English
unknown
description Many industrially important reactions use immobilized enzymes in non-aqueous, organic systems, particularly for the production of chiral compounds such as pharmaceutical precursors. The addition of a spacer molecule (“tether”) between a supporting surface and enzyme often substantially improves the activity and stability of enzymes in aqueous solution. Most “long” linkers (e.g. polyethylene oxide derivatives) are relatively hydrophilic, improving the solubility of the linker-enzyme conjugate in polar environments, but this provides little benefit in non-polar environments such as organic solvents. We present a novel method for the covalent immobilization of enzymes on solid surfaces using a long, hydrophobic polytryptophan tether. Candida antarctica lipase B (CALB) was covalently immobilized on non-porous, functionalized 1-μm silica microspheres, with and without an intervening hydrophobic poly-DL-tryptophan tether (n ≈ 78). The polytryptophan-tethered enzyme exhibited 35 times greater esterification of n-propanol with lauric acid in the organic phase and five times the hydrolytic activity against p-nitrophenol palmitate, compared to the activity of the same enzyme immobilized without tethers. In addition, the hydrophobic tethers caused the silica microspheres to disperse more readily in the organic phase, while the surface-immobilized control treatment was less lipophilic and quickly settled out of the organic phase when the suspensions were not vigorously mixed. Keywords: Immobilization, Enzyme-catalyzed organic synthesis, Candida antarctica lipase B, Hydrophobic tethers, Silica microspheres, Poly-DL-tryptophan
format Article in Journal/Newspaper
author Schilke, Karl F.
Kelly, Christine
spellingShingle Schilke, Karl F.
Kelly, Christine
Activation of Immobilized Lipase in Non-Aqueous Systems by Hydrophobic Poly-DL-Tryptophan Tethers
author_facet Schilke, Karl F.
Kelly, Christine
author_sort Schilke, Karl F.
title Activation of Immobilized Lipase in Non-Aqueous Systems by Hydrophobic Poly-DL-Tryptophan Tethers
title_short Activation of Immobilized Lipase in Non-Aqueous Systems by Hydrophobic Poly-DL-Tryptophan Tethers
title_full Activation of Immobilized Lipase in Non-Aqueous Systems by Hydrophobic Poly-DL-Tryptophan Tethers
title_fullStr Activation of Immobilized Lipase in Non-Aqueous Systems by Hydrophobic Poly-DL-Tryptophan Tethers
title_full_unstemmed Activation of Immobilized Lipase in Non-Aqueous Systems by Hydrophobic Poly-DL-Tryptophan Tethers
title_sort activation of immobilized lipase in non-aqueous systems by hydrophobic poly-dl-tryptophan tethers
publisher John Wiley & Sons Ltd.
url https://ir.library.oregonstate.edu/concern/articles/ht24wk059
genre Antarc*
Antarctica
genre_facet Antarc*
Antarctica
op_relation https://ir.library.oregonstate.edu/concern/articles/ht24wk059
op_rights Copyright Not Evaluated
_version_ 1796310752900939776

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