Exploiting the Synthetic Potential of Sesquiterpene Cyclases for Generating Unnatural Terpenoids

Oberhauser, Clara; Harms, Vanessa; Seidel, Katja; Schröder, Benjamin; Ekramzadeh, Kimia; Beutel, Sascha; Winkler, Sven; Lauterbach, Lukas; Dickschat, Jeroen S.; Kirschning, Andreas

doi:10.1002/anie.201805526

Cited by 49 publications

(58 citation statements)

References 43 publications

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“…The elongation of GPP with 8a and 8b using FPPS also resulted in the two enantiomerso f4methyl-FPP (10)w ith high enantiomeric purity,a sd emonstrated by dephosphorylation with CIP followed by GC/MSa nd enantioselective GC analysis (Figures S10a nd S11). Ap reparative-scaler eaction with 8a and product isolation for structure elucidation by NMR (Table S2, Figures S12-S18) confirmed the structure of 4-methylfarnesol (12). Its optical rotation[ a] 20 d = À6.0 (CH 2 Cl 2 , c 0.25) allowed to assign the absolutec onfiguration of (S)-4-methylfarnesol (12 a)f or the product from 8a by comparison to literature data for the same enantiomer ([a] d = À10.7, hexane), [14] andc onsequently (R)-12 b was obtained from 8b.B ased on the same sign for the opticalr otation [a] 20 d = À5.5 (CH 2 Cl 2 , c 0.2) of 11 a formed from 8a,a nd on the same GC elution order on ac hiral stationary phase, analogous absolutec onfigurations werea ssignedf or (S)-11 a and (R)-11 b.…”

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confidence: 65%

“…[11] In addition to such natural enzymes ystemsf or the biosynthesis of homoterpenes, several canonical TSs exhibit ar emarkable plasticity that allows the conversion of non-natural substrate analoguesw ith additional Meg roupso rh eteroatoms. [12] This strategy can give a rapid and potentially enantioselective access towards methylated or functionalised terpene analogues, but previousw ork depended on the chemical synthesis of the oligoprenyl diphosphate analogues. Here we report on the stereoselective synthesis of homologated IPP derivatives, the enzymatic incorporation into methylated GPP and FPP analogues,a nd their TScatalysed conversion into non-naturalhomoterpenes.…”

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confidence: 99%

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Enzymatic Synthesis of Methylated Terpene Analogues Using the Plasticity of Bacterial Terpene Synthases

Hou

Lauterbach

Dickschat

2020

Chemistry A European J

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confidence: 65%

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confidence: 99%

Enzymatic Synthesis of Methylated Terpene Analogues Using the Plasticity of Bacterial Terpene Synthases

Hou

Lauterbach

Dickschat

2020

Chemistry A European J

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“…It is useful to evaluate the enzymatic conversion of other substrates, like monoterpene precursors or synthetic substrates as tested by Oberhauser et al by the PTS, with different buffers to test whether the formation of different products can be detected . To complete these NMR based studies, enzymatic experiments like homology modeling of PTS and further deuteration tests on reaction mechanisms of the other main products could be essential.…”

Section: Resultsmentioning

confidence: 99%

Optimization of factors influencing enzyme activity and product selectivity and the role of proton transfer in the catalytic mechanism of patchoulol synthase

Ekramzadeh¹,

Brämer²,

Frister³

et al. 2019

Biotechnology Progress

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The patchoulol synthase (PTS) from Pogostemon cablin is a versatile sesquiterpene synthase and produces more than 20 valuable sesquiterpenes by conversion of the natural substrate farnesyl pyrophosphate (FPP). PTS has the potential to be used as a biocatalyst for the production of valuable sesquiterpenes such as (−)‐patchoulol. The objective of the present study is to develop an efficient biotransformation and to characterize the biocatalytic mechanism of the PTS in detail. For this purpose, soluble PTS was prepared using an optimized cultivation protocol and continuous downstream process with a purity of 98%. The PTS biotransformation was then optimized regarding buffer composition, pH‐value, and temperature for biotransformation as well as functional and kinetic properties to improve productivity. For the bioconversion of FPP, the highest enzyme activity was reached with the 2‐(N‐morphlino)ethanesulfonic acid (MES) buffer containing 10% (v/v) glycerol and 10 mM MgCl2 at pH 6.4 and 34°C. The PTS showed an unusual substrate inhibition for sesquiterpene synthases indicating an intermediate sesquiterpene formed in the active center. Deuteration experiments were used to gain further insights into the biocatalytic mechanism described in literature. Thus it could be shown that a second substrate binding site must be responsible for substrate inhibition and that further protonation and deprotonation steps are involved in the reaction mechanism.

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“…GC-MS analyses of the pentane extractable products obtained from phosphorylation/cyclization reactions starting from 3 and 4 catalyzed by ScGDS, AaADS, 7epizingiberene synthase from Solanum habrochaites (ShEZS), and (À)-germacradiene-4-ol synthase from Streptomyces citricolor (ScGD4OL) showed that the respective natural products had been generated (20)(21)(22)(23) (Figure 2, S19-30). [30,32,44] Furthermore, using methylated prenol analogues 12 and 13 directly yielded the desirable unnatural semiochemicals (S)-14,15-dimethylgermacrene D (24), (S)-12-methylgermacrene D (25), and (S)-15-methylgermacrene D (26) (Figure 2). Similarly, using 4-hydroxyprenol (11) and 4 to form 15 followed by addition of AaADS yielded dihydroartemisinic aldehyde (27).…”

Section: Zuschriftenmentioning

confidence: 99%

Modular Chemoenzymatic Synthesis of Terpenes and their Analogues

et al. 2020

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Non-natural terpenoids offer potential as pharmaceuticals and agrochemicals. However, their chemical syntheses are often long, complex, and not easily amenable to large-scale production. Herein, we report a modular chemoenzymatic approach to synthesize terpene analogues from diphosphorylated precursors produced in quantitative yields. Through the addition of prenyl transferases, farnesyl diphosphates, (2E,6E)-FDP and (2Z,6Z)-FDP, were isolated in greater than 80 % yields. The synthesis of 14,15-dimethyl-FDP, 12methyl-FDP, 12-hydroxy-FDP, homo-FDP, and 15-methyl-FDP was also achieved. These modified diphosphates were used with terpene synthases to produce the unnatural sesquiterpenoid semiochemicals (S)-14,15-dimethylgermacrene D and (S)-12-methylgermacrene D as well as dihydroartemisinic aldehyde. This approach is applicable to the synthesis of many non-natural terpenoids, offering a scalable route free from repeated chain extensions and capricious chemical phosphorylation reactions.

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Exploiting the Synthetic Potential of Sesquiterpene Cyclases for Generating Unnatural Terpenoids

Cited by 49 publications

References 43 publications

Enzymatic Synthesis of Methylated Terpene Analogues Using the Plasticity of Bacterial Terpene Synthases

Enzymatic Synthesis of Methylated Terpene Analogues Using the Plasticity of Bacterial Terpene Synthases

Optimization of factors influencing enzyme activity and product selectivity and the role of proton transfer in the catalytic mechanism of patchoulol synthase

Modular Chemoenzymatic Synthesis of Terpenes and their Analogues

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