Your search keyword '"VICKERS, CLAUDIA E."' showing total 3 results

1. Metabolic flux enhancement from the translational fusion of terpene synthases is linked to terpene synthase accumulation.

Author

Cheah, Li Chen, Liu, Lian, Stark, Terra, Plan, Manuel R., Peng, Bingyin, Lu, Zeyu, Schenk, Gerhard, Sainsbury, Frank, and Vickers, Claudia E.

Subjects

*TERPENES, *SYNTHASES, *PROTEIN stability, *TITERS, *PROTEOMICS

Abstract

The end-to-end fusion of enzymes that catalyse successive steps in a reaction pathway is a metabolic engineering strategy that has been successfully applied in a variety of pathways and is particularly common in terpene bioproduction. Despite its popularity, limited work has been done to interrogate the mechanism of metabolic enhancement from enzyme fusion. We observed a remarkable >110-fold improvement in nerolidol production upon translational fusion of nerolidol synthase (a sesquiterpene synthase) to farnesyl diphosphate synthase. This delivered a titre increase from 29.6 mg/L up to 4.2 g/L nerolidol in a single engineering step. Whole-cell proteomic analysis revealed that nerolidol synthase levels in the fusion strains were greatly elevated compared to the non-fusion control. Similarly, the fusion of nerolidol synthase to non-catalytic domains also produced comparable increases in titre, which coincided with improved enzyme expression. When farnesyl diphosphate synthase was fused to other terpene synthases, we observed more modest improvements in terpene titre (1.9- and 3.8-fold), corresponding with increases of a similar magnitude in terpene synthase levels. Our data demonstrate that increased in vivo enzyme levels – resulting from improved expression and/or improved protein stability – is a major driver of catalytic enhancement from enzyme fusion. • Fusion of farnesyl diphosphate synthase (FPPS) to nerolidol synthase increased nerolidol production by >110-fold. • Fusion of nerolidol synthase to metabolically inactive proteins also increased titres. • Fusion of FPPS to other terpene synthases produced smaller increases in titre. • Increases in titre coincided with elevated levels of terpene synthase. [ABSTRACT FROM AUTHOR]

Published

2023

2. Engineered protein degradation of farnesyl pyrophosphate synthase is an effective regulatory mechanism to increase monoterpene production in Saccharomyces cerevisiae.

Author

Peng, Bingyin, Nielsen, Lars K., Kampranis, Sotirios C., and Vickers, Claudia E.

Subjects

*SACCHAROMYCES cerevisiae, *PROTEIN engineering, *FARNESYL compounds, *PYROPHOSPHATES, *MONOTERPENES

Abstract

Monoterpene production in Saccharomyces cerevisae requires the introduction of heterologous monoterpene synthases (MTSs). The endogenous farnesyl pyrosphosphate synthase (FPPS; Erg20p) competes with MTSs for the precursor geranyl pyrophosphate (GPP), which limits the production of monoterpenes. ERG20 is an essential gene that cannot be deleted and transcriptional down-regulation of ERG20 has failed to improve monoterpene production. Here, we investigated an N-degron-dependent protein degradation strategy to down-regulate Erg20p activity. Degron tagging decreased GFP protein half-life drastically to 1 h (degron K3K15) or 15 min (degrons KN113 and KN119). Degron tagging of ERG20 was therefore paired with a sterol responsive promoter to ensure sufficient metabolic flux to essential downstream sterols despite the severe destabilisation effect of degron tagging. A dual monoterpene/sesquiterpene (linalool/nerolidol) synthase, AcNES1 , was used as a reporter of intracellular GPP and FPP production. Transcription of the synthetic pathway was controlled by either constitutive or diauxie-inducible promoters. A combination of degron K3K15 and the ERG1 promoter increased linalool titre by 27-fold to 11 mg L −1 in the strain with constitutive promoter constructs, and by 17-fold to 18 mg L −1 in the strain with diauxie-inducible promoter constructs. The sesquiterpene nerolidol remained the major product in both strains. The same strategies were applied to construct a limonene-producing strain, which produced 76 mg L −1 in batch cultivation. The FPPS regulation method developed here successfully redirected metabolic flux toward monoterpene production. Examination of growth defects in various strains suggested that the intracellular FPP concentration had a significant effect on growth rate. Further strategies are required to balance intracellular production of FPP and GPP so as to maximise monoterpene production without impacting on cellular growth. [ABSTRACT FROM AUTHOR]

Published

2018

3. A squalene synthase protein degradation method for improved sesquiterpene production in Saccharomyces cerevisiae.

Author

Peng, Bingyin, Plan, Manuel R., Chrysanthopoulos, Panagiotis, Hodson, Mark P., Nielsen, Lars K., and Vickers, Claudia E.

Subjects

*SACCHAROMYCES cerevisiae, *SESQUITERPENES, *CHEMICAL synthesis, *PROTEOLYSIS, *FUNGAL proteins, *SQUALENE, *CELL growth, *FERMENTATION

Abstract

Sesquiterpenes are C15 isoprenoids with utility as fragrances, flavours, pharmaceuticals, and potential biofuels. Microbial fermentation is being examined as a competitive approach for bulk production of these compounds. Competition for carbon allocation between synthesis of endogenous sterols and production of the introduced sesquiterpene limits yields. Achieving balance between endogenous sterols and heterologous sesquiterpenes is therefore required to achieve economical yields. In the current study, the yeast Saccharomyces cerevisiae was used to produce the acyclic sesquiterpene alcohol, trans-nerolidol. Nerolidol production was first improved by enhancing the upstream mevalonate pathway for the synthesis of the precursor farnesyl pyrophosphate (FPP). However, excess FPP was partially directed towards squalene by squalene synthase (Erg9p), resulting in squalene accumulation to 1% biomass; moreover, the specific growth rate declined. In order to re-direct carbon away from sterol production and towards the desired heterologous sesquiterpene, a novel protein destabilisation approach was developed for Erg9p. It was shown that Erg9p is located on endoplasmic reticulum and lipid droplets through a C-terminal ER-targeted transmembrane peptide. A PEST (rich in Pro, Glu/Asp, Ser, and Thr) sequence-dependent endoplasmic reticulum-associated protein degradation (ERAD) mechanism was established to decrease cellular levels of Erg9p without relying on inducers, repressors or specific repressing conditions. This improved nerolidol titre by 86% to ~100 mg L −1 . In this strain, squalene levels were similar to the wild-type control strain, and downstream ergosterol levels were slightly decreased relative to the control, indicating redirection of carbon away from sterols and towards sesquiterpene production. There was no negative effect on cell growth under these conditions. Protein degradation is an efficient mechanism to control carbon allocation at flux-competing nodes in metabolic engineering applications. This study demonstrates that an engineered ERAD mechanism can be used to balance flux competition between the endogenous sterol pathway and an introduced bio-product pathways at the FPP node. The approach of protein degradation in general might be more widely applied to improve metabolic engineering outcomes. [ABSTRACT FROM AUTHOR]

Published

2017