Three in One: Temperature,Solvent and Catalytic Stability by Engineering the Cofactor‐Binding Element of Amine Transaminase |
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| Authors: | Dr. Tim Börner Dr. Sebastian Rämisch Dr. Sebastian Bartsch Dr. Andreas Vogel Prof. Patrick Adlercreutz Assoc. Prof. Carl Grey |
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| Affiliation: | 1. Department of Chemistry and Biotechnology, Institute of Materials Science, Nestlé Research Center, Lausanne 26, Switzerland;2. Schief Lab, Department of Immunology and Microbial Science, The Scripps Research Institute, La Jolla, CA, USA;3. c-LEcta GmbH, Leipzig, Germany;4. Division of Biotechnology, Department of Chemistry, Lund University, Lund, Sweden |
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| Abstract: | Amine transaminase (ATA) catalyse enantioselectively the direct amination of ketones, but insufficient stability during catalysis limits their industrial applicability. Recently, we revealed that ATAs suffer from substrate‐induced inactivation mechanism involving dissociation of the enzyme–cofactor intermediate. Here, we report on engineering the cofactor‐ring‐binding element, which also shapes the active‐site entrance. Only two point mutations in this motif improved temperature and catalytic stability in both biphasic media and organic solvent. Thermodynamic analysis revealed a higher melting point for the enzyme–cofactor intermediate. The high cofactor affinity eliminates the need for pyridoxal 5′‐phosphate supply, thus making large‐scale reactions more cost effective. This is the first report on stabilising a tetrameric ATA by mutating a single structural element. As this structural “hotspot” is a common feature of other transaminases it could serve as a general engineering target. |
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| Keywords: | amines enzyme catalysis operational stability pyridoxamine 5′ -phosphate transaminase |
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