Comparison of Four Immobilization Methods for Different Transaminases
Heinks T, Montua N, Teune M, Liedtke J, Höhne M, Bornscheuer U, Fischer von Mollard G (2023)
Catalysts 13(2): 300.
Zeitschriftenaufsatz
| Veröffentlicht | Englisch
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Autor*in
Heinks, TobiasUniBi;
Montua, NicolaiUniBi ;
Teune, Michelle;
Liedtke, Jan;
Höhne, Matthias;
Bornscheuer, Uwe;
Fischer von Mollard, GabrieleUniBi
Einrichtung
Abstract / Bemerkung
Biocatalytic syntheses often require unfavorable conditions, which can adversely affect enzyme stability. Consequently, improving the stability of biocatalysts is needed, and this is often achieved by immobilization. In this study, we aimed to compare the stability of soluble and immobilized transaminases from different species. A cysteine in a consensus sequence was converted to a single aldehyde by the formylglycine-generating enzyme for directed single-point attachment to amine beads. This immobilization was compared to cross-linked enzyme aggregates (CLEAs) and multipoint attachments to glutaraldehyde-functionalized amine- and epoxy-beads. Subsequently, the reactivity and stability (i.e., thermal, storage, and solvent stability) of all soluble and immobilized transaminases were analyzed and compared under different conditions. The effect of immobilization was highly dependent on the type of enzyme, the immobilization strategy, and the application itself, with no superior immobilization technique identified. Immobilization of HAGA-beads often resulted in the highest activities of up to 62 U/g beads, and amine beads were best for the hexameric transaminase from Luminiphilus syltensis. Furthermore, the immobilization of transaminases enabled its reusability for at least 10 cycles, while maintaining full or high activity. Upscaled kinetic resolutions (partially performed in a SpinChemTM reactor) resulted in a high conversion, maintained enantioselectivity, and high product yields, demonstrating their applicability.
Stichworte
amine transaminase;
enzyme stability;
enzyme immobilization;
site-selective immobilization;
reusability;
storage stability;
thermostability;
operational stability;
solvent stability;
formylglycine-generating enzyme
Erscheinungsjahr
2023
Zeitschriftentitel
Catalysts
Band
13
Ausgabe
2
Art.-Nr.
300
Urheberrecht / Lizenzen
eISSN
2073-4344
Finanzierungs-Informationen
Open-Access-Publikationskosten wurden durch die Universität Bielefeld gefördert.
Page URI
https://pub.uni-bielefeld.de/record/2968690
Zitieren
Heinks T, Montua N, Teune M, et al. Comparison of Four Immobilization Methods for Different Transaminases. Catalysts. 2023;13(2): 300.
Heinks, T., Montua, N., Teune, M., Liedtke, J., Höhne, M., Bornscheuer, U., & Fischer von Mollard, G. (2023). Comparison of Four Immobilization Methods for Different Transaminases. Catalysts, 13(2), 300. https://doi.org/10.3390/catal13020300
Heinks, Tobias, Montua, Nicolai, Teune, Michelle, Liedtke, Jan, Höhne, Matthias, Bornscheuer, Uwe, and Fischer von Mollard, Gabriele. 2023. “Comparison of Four Immobilization Methods for Different Transaminases”. Catalysts 13 (2): 300.
Heinks, T., Montua, N., Teune, M., Liedtke, J., Höhne, M., Bornscheuer, U., and Fischer von Mollard, G. (2023). Comparison of Four Immobilization Methods for Different Transaminases. Catalysts 13:300.
Heinks, T., et al., 2023. Comparison of Four Immobilization Methods for Different Transaminases. Catalysts, 13(2): 300.
T. Heinks, et al., “Comparison of Four Immobilization Methods for Different Transaminases”, Catalysts, vol. 13, 2023, : 300.
Heinks, T., Montua, N., Teune, M., Liedtke, J., Höhne, M., Bornscheuer, U., Fischer von Mollard, G.: Comparison of Four Immobilization Methods for Different Transaminases. Catalysts. 13, : 300 (2023).
Heinks, Tobias, Montua, Nicolai, Teune, Michelle, Liedtke, Jan, Höhne, Matthias, Bornscheuer, Uwe, and Fischer von Mollard, Gabriele. “Comparison of Four Immobilization Methods for Different Transaminases”. Catalysts 13.2 (2023): 300.
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Material in PUB:
Dissertation, die diesen PUB Eintrag enthält
Cascading and Immobilization of Amine Transaminases for the Biosynthesis of Enantiomerically Pure Amines
Heinks T (2023)
Bielefeld: Universität Bielefeld.
Heinks T (2023)
Bielefeld: Universität Bielefeld.
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