Two Cascade Reactions with Oleate Hydratases for the Sustainable Biosynthesis of Fatty Acid-Derived Fine Chemicals

Prem, Sophia A.; Haack, Martina; Melcher, Felix; Ringel, Marion; Garbe, Daniel; Brück, Thomas

doi:10.3390/catal13091236

Catalysts

2023

DOI: 10.3390/catal13091236

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Two Cascade Reactions with Oleate Hydratases for the Sustainable Biosynthesis of Fatty Acid-Derived Fine Chemicals

Sophia A. Prem,

Martina Haack,

Felix Melcher

et al.

Abstract: Oleate hydratases (OHs) are of significant industrial interest for the sustainable generation of valuable fine chemicals. When combined with other enzymes in multi-step cascades, the direct formation of fatty acid congeners can be accomplished with minimal processing steps. In this study, two cascade reactions are presented, which can be applied in one-pot approaches. The first cascade was placed “upstream” of an OH derived from Rhodococcus erythropolis (OhyRe), where a lipase from Candida rugosa was applied t… Show more

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2024

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Cited by 2 publications

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Immobilization of Oleate Hydratase on Solid Supports

Oike,

Schoevaart,

Hollmann

et al. 2024

ChemCatChem

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Oleate hydratases open a biocatalytic access to hydroxy fatty acids by hydration of unsaturated fatty acids. Their practical applicability, however, is hampered by their low stability. In this study we report the immobilization of the oleate hydratase from Rhodococcus erythropolis PR4 on functionalized porous, spherical polymer beads. Different carrier materials promoting covalent, hydrophobic, ionic and his‐tag affinity were screened and immobilization yields typically >95% were observed. The highest activity recovery of 32% was achieved by immobilization via ionic interaction with quaternary ammonium functionalized beads. Biochemical properties of the enzyme immobilized via ionic interaction remain unchanged upon immobilization. The immobilized enzyme was applied for synthesis of 10‐hydroxystearic acid remaining stable under process conditions. Conversion of up to 100 mM oleic acid gave 10‐hydroxystearic acid achieving a TON of up to 19,000. Successful recycling of the biocatalyst for up to ten cycles further demonstrate its potential for the synthesis of 10‐hydroxystearic acid.

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Immobilization of Oleate Hydratase on Solid Supports

Oike,

Schoevaart,

Hollmann

et al. 2024

ChemCatChem

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Immobilization study of a monomeric oleate hydratase from Rhodococcus erythropolis

Bandookwala,

Prem,

Kollmannsberger

et al. 2024

Biotechnol Bioproc E

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The chemical, pharmaceutical, and cosmetic industries are currently confronted with the challenge of transitioning from traditional chemical processes to more sustainable biocatalytic methods. To support that aim, we developed various heterogeneous biocatalysts for an industrially relevant enzyme called oleate hydratase that converts oleic acid to 10-hydroxystearic acid, a fatty emollient substance useful for various technical applications. We used cheap support matrices such as silica, chitosan, cellulose, and agarose for further scale-up and economic feasibility at the industrial level alongside more sophisticated supports like metal–organic frameworks. Different physical and chemical binding approaches were employed. Particularly, by immobilizing oleate hydrates on a 3-aminopropyltriethoxysilane surface-functionalized cellulose matrix, we developed an enzyme immobilizate with almost 80% activity of the free enzyme. The long-term goal of this work was to be able to use the developed heterogeneous biocatalyst for multiple reuse cycles enabling profitable biocatalysis. Despite high initial conversion rate by the developed cellulose-based immobilizate, a depletion in enzyme activity of immobilized oleate hydratase was observed over time. Therefore, further enzyme modification is required to impart stability, the optimization of operational conditions, and the development of carrier materials that enable economical and sustainable enzymatic conversion of oleic acid to meet the commercial demand. Graphical abstract

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Two Cascade Reactions with Oleate Hydratases for the Sustainable Biosynthesis of Fatty Acid-Derived Fine Chemicals

Cited by 2 publications

References 57 publications

Immobilization of Oleate Hydratase on Solid Supports

Immobilization of Oleate Hydratase on Solid Supports

Immobilization study of a monomeric oleate hydratase from Rhodococcus erythropolis

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