Regio‐ and Enantio‐selective Chemo‐enzymatic C−H‐Lactonization of Decanoic Acid to (<i>S</i>)‐δ‐Decalactone

Manning, Jack; Tavanti, Michele; Porter, Joanne L.; Kreß, Nico; Visser, Sam P. de; Turner, Nicholas J.; Flitsch, Sabine L.

doi:10.1002/anie.201901242

Cited by 56 publications

(60 citation statements)

References 37 publications

(64 reference statements)

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“…The GC‐FID analysis of the extracted norcamphor lactone showed that the enzyme was able to convert 100% of the substrate norcamphor in 24 h at this reaction scale (Figure S1). Biocatalytic routes to the other lactone comonomer (ε‐CL) in this study ( vide infra ) and δ‐DL have recently been reported …”

Section: Resultsmentioning

confidence: 68%

Lactone monomers obtained by enzyme catalysis and their use in reversible thermoresponsive networks

Farhat

Biundo

Stamm

et al. 2020

J of Applied Polymer Sci

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The cover image by Per-Olof Syrén and colleagues shows a green route to new star-shaped polymeric materials that can reconstruct themselves by means of Diels-Alder chemistry when stimulated by heat. The image shows how enzyme catalysis successfully afforded two key reaction steps. In addition, the image reveals the conversion of bulky bicyclic ketone to its corresponding activated lactone monomer, as well as end-capping of the chemically synthesized polymer with the renewable building block furoic acid.Volume 137, Number 18 was mailed the week of February 3, 2020.ARTICLES 48608 Hydrophobic-associated polymer-based laponite nanolayered silicate composite as filtrate reducer for water-based drilling fluid at high temperature

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Section: Resultsmentioning

confidence: 68%

Lactone monomers obtained by enzyme catalysis and their use in reversible thermoresponsive networks

Farhat

Biundo

Stamm

et al. 2020

J of Applied Polymer Sci

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“…[24] Additionally, CYP505E3 could be employed for the synthesis of valuable diols and lactones. Alternative biocatalytic processes for the synthesis of C10 and C12 d-lactones are highly sought after [4,22] given that expensive natural substrates, variable supply, and environmental concerns [25] present challenges to processes currently used for the industrial production of "natural" lactones from unsaturated massoia d-lactones. [26]…”

Section: Zuschriftenmentioning

confidence: 99%

“…[1][2][3] However, there are several P450s that show in-chain hydroxylation of medium-chain fatty acids such as decanoic acid and dodecanoic acid, although hydroxylation is rarely more in-chain than the w-6 position. [3] One exception in this regard is CYP116B46 from Tepidiphilus thermophiles [4] which gives C5 hydroxylation of decanoic and dodecanoic acid. In the case of decanoic acid, it displays exquisite regioselectivity (99 %) and enantioselectivity to produce the "non-natural" (S)-d-decalactone with greater than 90 % ee.…”

mentioning

confidence: 99%

CYP505E3: A Novel Self‐Sufficient ω‐7 In‐Chain Hydroxylase

et al. 2020

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The self‐sufficient cytochrome P450 monooxygenase CYP505E3 from Aspergillus terreus catalyzes the regioselective in‐chain hydroxylation of alkanes, fatty alcohols, and fatty acids at the ω‐7 position. It is the first reported P450 to give regioselective in‐chain ω‐7 hydroxylation of C10–C16 n‐alkanes, thereby enabling the one step biocatalytic synthesis of rare alcohols such as 5‐dodecanol and 7‐tetradecanol. It shows more than 70 % regioselectivity for the eighth carbon from one methyl terminus, and displays remarkably high activity towards decane (TTN≈8000) and dodecane (TTN≈2000). CYP505E3 can be used to synthesize the high‐value flavour compound δ‐dodecalactone via two routes: 1) conversion of dodecanoic acid into 5‐hydroxydodecanoic acid (24 % regioselectivity), which at low pH lactonises to δ‐dodecalactone, and 2) conversion of 1‐dodecanol into 1,5‐dodecanediol (55 % regioselectivity), which can be converted into δ‐dodecalactone by horse liver alcohol dehydrogenase.

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“…Enzymes are potent biocatalysts that are able to carry out numerous chemical transformations with remarkable chemo‐, regio‐ and stereo‐selectivity . The intrinsic sustainability of enzymatic processes along with the use of green reaction conditions such as absence of potentially toxic solvents, and activation with non‐conventional sources of energy has expanded the use of biocatalysis in both chemical industries and in academic institutions, focusing in drug discovery and in the synthesis of molecules with relevant biological activity .…”

Section: Introductionmentioning

confidence: 99%

“…Enzymes are potent biocatalysts that are able to carry out numerous chemical transformations with remarkable chemo-, regio-and stereo-selectivity. [1][2][3][4][5] The intrinsic sustainability of enzymatic processes along with the use of green reaction conditions such as absence of potentially toxic solvents, and activation with non-conventional sources of energy has expanded the use of biocatalysis in both chemical industries and in academic institutions, focusing in drug discovery and in the synthesis of molecules with relevant biological activity. [6][7][8] Recent developments in protein engineering and enzyme directed evolution, [9,10] together with the availability of efficient methods for the production of recombinant molecules, have led to rapidly expanding new fields in biocatalysis.…”

Section: Introductionmentioning

confidence: 99%

Thermal and Mechanical Stability of Immobilized Candida antarctica Lipase B: an Approximation to Mechanochemical Energetics in Enzyme Catalysis.

Pérez‐Venegas¹,

Tellez-Cruz²,

Solorza‐Feria³

et al. 2019

ChemCatChem

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Very recently, several successful enzymatic processes performed with mechanical activation have been disclosed; that is, despite the mechanical stress caused by High-Speed Ball-Milling, immobilized enzymes can retain activity. In the present study, the effect of thermal and mechanical stress was examined as potential inducers of enzymatic denaturation, when using either free, immobilized, or ground immobilized enzyme. The recorded observations show a remarkable stability of ground immobilized enzyme. Moreover, ground biocatalyst turns out to exhibit an increase of one order of magnitude in the efficiency of the catalytic process, maintaining excellent enantiodiscrimination, without significant activity loss even after four milling cycles. These observations rule out enzyme inactivation as direct consequence of the milling process. Additionally, boosted enzyme efficiency was used to optimize a relatively inefficient chiral amine resolution reaction, achieving a 25 % faster biotransformation (in 45 min) and yielding essentially enantiopure products (ee > 99%, E > 500). E N435 = 595 and E 80°C = 317), leading to highly enantiopure compounds, higher than 99 % for both (S)-3 and (R)-4), and corroborating the aforementioned increase in ΔΔG � when ground N435 is used (Figure 9). 4 5 6 7 8

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Regio‐ and Enantio‐selective Chemo‐enzymatic C−H‐Lactonization of Decanoic Acid to (S)‐δ‐Decalactone

Cited by 56 publications

References 37 publications

Lactone monomers obtained by enzyme catalysis and their use in reversible thermoresponsive networks

Lactone monomers obtained by enzyme catalysis and their use in reversible thermoresponsive networks

CYP505E3: A Novel Self‐Sufficient ω‐7 In‐Chain Hydroxylase

Thermal and Mechanical Stability of Immobilized Candida antarctica Lipase B: an Approximation to Mechanochemical Energetics in Enzyme Catalysis.

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