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

Ekramzadeh, Kimia; Brämer, Chantal; Frister, Thore; Fohrer, Jörg; Kirschning, Andreas; Scheper, Thomas; Beutel, Sascha

doi:10.1002/btpr.2935

Cited by 5 publications

(28 citation statements)

References 32 publications

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“… 46 The in vivo optimal pH (found here) is similar to that of the in vitro biotransformation reactions, determined between pH 6.4–6.6. 42 Accordingly, our results are similar to the E. coli strains used for the production of longifolene 47 and sclareol, 48 which used a pH of 7.0 during cultivation. Thereafter, the cultivation conditions of 20 °C and pH 6.75 were used for further evaluations.…”

Section: Resultssupporting

confidence: 79%

“…Nevertheless, the lowest temperature tests did not produce the highest (−)-patchoulol titers; possibly, due to the diminished enzyme activity of the (−)-patchoulol synthase. This could be supported because in previous in vitro biotransformation reactions, 42 (−)-patchoulol synthase showed higher activity at higher temperatures, reaching its maximum at 34 °C. Therefore, a balance is required among the production of soluble (−)-patchoulol synthase protein, enzyme activity, and cell growth, as observed in the tests grown at 20 °C, which achieved the highest (−)-patchoulol production.…”

Section: Resultssupporting

confidence: 56%

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Whole-Cell Production of Patchouli Oil Sesquiterpenes in Escherichia coli: Metabolic Engineering and Fermentation Optimization in Solid–Liquid Phase Partitioning Cultivation

et al. 2020

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Patchouli oil is a major ingredient in perfumery, granting a dark-woody scent due to its main constituent (−)-patchoulol. The growing demand for patchouli oil has raised interest in the development of a biotechnological process to assure a reliable supply. Herein, we report the production of patchouli oil sesquiterpenes by metabolically engineered Escherichia coli strains, using solid–liquid phase partitioning cultivation. The (−)-patchoulol production was possible using the endogenous methylerythritol phosphate pathway and overexpressing a (−)-patchoulol synthase isoform from Pogostemon cablin but at low titers. To improve the (−)-patchoulol production, the exogenous mevalonate pathway was overexpressed in the multi-plasmid PTS + Mev strain, which increased the (−)-patchoulol titer 5-fold. Fermentation was improved further by evaluating several defined media, and optimizing the pH and temperature of culture broth, enhancing the (−)-patchoulol titer 3-fold. To augment the (−)-patchoulol recovery from fermentation, the solid–liquid phase partitioning cultivation was analyzed by screening polymeric adsorbers, where the Diaion HP20 adsorber demonstrated the highest (−)-patchoulol recovery from all tests. Fermentation was scaled-up to fed-batch bioreactors, reaching a (−)-patchoulol titer of 40.2 mg L –1 and productivity of 20.1 mg L –1 d –1 . The terpene profile and aroma produced from the PTS + Mev strain were similar to the patchouli oil, comprising (−)-patchoulol as the main product, and α-bulnesene, trans-β-caryophyllene, β-patchoulene, and guaia-5,11-diene as side products. This investigation represents the first study of (−)-patchoulol production in E. coli by solid–liquid phase partitioning cultivation, which provides new insights for the development of sustainable bioprocesses for the microbial production of fragrant terpenes.

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Section: Resultssupporting

confidence: 79%

Section: Resultssupporting

confidence: 56%

Whole-Cell Production of Patchouli Oil Sesquiterpenes in Escherichia coli: Metabolic Engineering and Fermentation Optimization in Solid–Liquid Phase Partitioning Cultivation

et al. 2020

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“…atoms was reported that is explainable by the deprotonation step from E to 6 [10], but contradicts the retainment of this hydrogen as reported by Croteau [9]. Further support for Akhila's mechanism was provided by Ekramzadeh et al, who observed the uptake of two deuterium atoms at C3 and C12 in an incubation of FPP with PTS in deuterium oxide buffer that explain the reprotonations of the neutral intermediates 8 and 6 (Scheme 2C) [13].…”

Section: Introductionmentioning

confidence: 92%

“…For both experiments a full retainment of labelling was reported for all intermediates until 13, while a loss of tritium was observed for 14 with both substrates. From these experiments it was concluded that the hydrogen H6 must migrate into another position, as realised by the 1,4-hydride shift from C to D. The loss of 3 H in the experiment with [12,[13][14] C,1-3 H]FPP was expected for the aldol reaction of 13, but is more difficult to understand in the experiment with [12,13-14 C,6-3 H]FPP. In this case the loss of 3 H was explained by an exchange against 1 H during catalytic hydrogenation [9].…”

Section: Introductionmentioning

confidence: 94%

“…Notably, none of the proposed mechanisms in Schemes 1-3 can explain the reported results from all labelling experiments and some of the reported findings are even contradictory. For this reason, we have reinvestigated the enzyme mechanism of PTS in isotopic labelling experiments through methods recently developed in our laboratory that make use of 13 C and 2 H-substituted terpene precursors, and by DFT calculations. The general strategy in these experiments is to use substrates or substrate combinations so that deuterium migrations end at 13 C-labelled carbons, resulting in triplet signals in the 13 C NMR spectra [15,16].…”

Section: Introductionmentioning

confidence: 99%

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The enzyme mechanism of patchoulol synthase

Xu¹,

Goldfuß²,

Schnakenburg³

et al. 2022

Beilstein J. Org. Chem.

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Different mechanisms for the cyclisation of farnesyl pyrophosphate to patchoulol by the patchoulol synthase are discussed in the literature. They are based on isotopic labelling experiments, but the results from these experiments are contradictory. The present work reports on a reinvestigation of patchoulol biosynthesis by isotopic labelling experiments and computational chemistry. The results are in favour of a pathway through the neutral intermediates germacrene A and α-bulnesene that are both reactivated by protonation for further cyclisation steps, while previously discussed intra- and intermolecular hydrogen transfers are not supported. Furthermore, the isolation of the new natural product (2S,3S,7S,10R)-guaia-1,11-dien-10-ol from patchouli oil is reported.

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Enhancement of Patchoulol Production in Escherichia coli via Multiple Engineering Strategies

Zhou

Wang

Han

et al. 2021

J. Agric. Food Chem.

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As a natural sesquiterpene compound with numerous biological activities, patchoulol has extensive applications in the cosmetic industry and potential usage in pharmaceuticals. Although several patchoulol-producing microbial strains have been constructed, the low productivity still hampers large-scale fermentation. Escherichia coli possesses the ease of genetic manipulation and simple nutritional requirements and does not comprise competing pathways for the farnesyl diphosphate (FPP) precursor, showing its potential for patchoulol biosynthesis. Here, combinatorial strategies were applied to produce patchoulol in E. coli. The initial strain was constructed, and it produced 14 mg/L patchoulol after fermentation optimization. Patchoulol synthase (PTS) was engineered by semirational design, resulting in improved substrate binding affinity and a patchoulol titer of 40.3 mg/L; the patchoulol titer reached 66.2 mg/L after fusing of PTS with FPP synthase. To further improve the patchoulol production, the genome of an efficient chassis strain was engineered by deleting the competitive routes for acetate, lactate, ethanol, and succinate synthesis and cumulatively enhancing the expression of efflux transporters, which improved patchoulol production to 338.6 mg/L. When tested in a bioreactor, the patchoulol titer and productivity were further improved to 970.1 mg/L and 199 mg/L/d, respectively, and were among the highest levels reported using mineral salt medium.

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

Cited by 5 publications

References 32 publications

Whole-Cell Production of Patchouli Oil Sesquiterpenes in Escherichia coli: Metabolic Engineering and Fermentation Optimization in Solid–Liquid Phase Partitioning Cultivation

Whole-Cell Production of Patchouli Oil Sesquiterpenes in Escherichia coli: Metabolic Engineering and Fermentation Optimization in Solid–Liquid Phase Partitioning Cultivation

The enzyme mechanism of patchoulol synthase

Enhancement of Patchoulol Production in Escherichia coli via Multiple Engineering Strategies

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