Physiological mechanism of improved tolerance of Saccharomyces cerevisiae to lignin-derived phenolic acids in lignocellulosic ethanol fermentation by short-term adaptation

Gu, Hanqi; Zhu, Yuyong; Peng, Yanfang; Liang, Xiujun; Liu, Xiaoguang; Shao, Lingzhi; Xu, Yanyan; Xu, Zhaohe; Liu, Ran; Li, Jie

doi:10.1186/s13068-019-1610-9

Cited by 48 publications

(43 citation statements)

References 51 publications

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“…Combined, these results indicate that depletion of shikimate intermediates and/or build-up of VG pathway intermediate PAC impose a fitness burden to the cells, whereas the single loss-offunction of any other pathway gene results in growth disadvantage, corroborating earlier reports on vanillin toxicity and the response of S. cerevisiae to weak acids and lignin derivatives (Gu et al, 2019;Guo and Olsson, 2014;Hansen et al, 2009).…”

Section: Selection and Physiological Characterization Of Production Ssupporting

confidence: 88%

Regulatory control circuits for stabilizing long-term anabolic product formation in yeast

D’ambrosio

Dore

Blasi

et al. 2020

Preprint

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Engineering living cells for production of chemicals, enzymes and therapeutics can burden cells due to use of limited native co-factor availability and/or expression burdens, totalling a fitness deficit compared to parental cells encoded through long evolutionary trajectories to maximise fitness. Ultimately, this discrepancy puts a selective pressure against fitness-burdened engineered cells under prolonged bioprocesses, and potentially leads to complete eradication of highperforming engineered cells at the population level. Here we present the mutation landscapes of fitness-burdened yeast cells engineered for vanillin-β-glucoside production. Next, we design synthetic control circuits based on transcriptome analysis and biosensors responsive to vanillin-βglucoside pathway intermediates in order to stabilize vanillin-β-glucoside production over ~55 generations in sequential passage experiments. Furthermore, using biosensors with two different modes of action we identify control circuits linking vanillin-β-glucoside pathway flux to various essential cellular functions, and demonstrate control circuits robustness and 92% higher vanillin-βglucoside production, including 5-fold increase in total vanillin-β-glucoside pathway metabolite accumulation, in a fed-batch fermentation compared to vanillin-β-glucoside producing cells without control circuits.

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Section: Selection and Physiological Characterization Of Production Ssupporting

confidence: 88%

Regulatory control circuits for stabilizing long-term anabolic product formation in yeast

D’ambrosio

Dore

Blasi

et al. 2020

Preprint

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“…It is well known that cheap and sustainable lignocellulosic hydrolysates are rich in glucose and could be a promising carbon source for the ethanol fermentation industry (Gu et al . 2019; Park et al . 2020).…”

Section: Resultsmentioning

confidence: 99%

Improving the productivity of Candida glycerinogenes in the fermentation of ethanol from non‐detoxified sugarcane bagasse hydrolysate by a hexose transporter mutant

Qiao

Zhou

et al. 2021

J Appl Microbiol

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Aims In this study, we attempted to increase the productivity of Candida glycerinogenes yeast for ethanol production from non‐detoxified sugarcane bagasse hydrolysates (NDSBH) by identifying the hexose transporter in this yeast that makes a high contribution to glucose consumption, and by adding additional copies of this transporter and enhancing its membrane localisation stability (MLS). Methods and Results Based on the knockout and overexpression of key hexose transporter genes and the characterisation of their promoter properties, we found that Cghxt4 and Cghxt6 play major roles in the early and late stages of fermentation, respectively, with Cghxt4 contributing most to glucose consumption. Next, subcellular localisation analysis revealed that a common mutation of two ubiquitination sites (K9 and K538) in Cghxt4 improved its MLS. Finally, we overexpressed this Cghxt4 mutant (Cghxt4.2A) using a strong promoter, PCgGAP, which resulted in a significant increase in the ethanol productivity of C. glycerinogenes in the NDSBH medium. Specifically, the recombinant strain showed 18 and 25% higher ethanol productivity than the control in two kinds of YP‐NDSBH medium (YP‐NDSBH1G160 and YP‐NDSBH2G160), respectively. Conclusions The hexose transporter mutant Cghxt4.2A (Cghxt4K9A,K538A) with multiple copies and high MLS was able to significantly increase the ethanol productivity of C. glycerinogenes in NDSBH. Significance and Impact of the Study Our results provide a promising strategy for constructing efficient strains for ethanol production.

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“…Similarly, lignin and derivatives will be also present in superior amounts, with several consequences in the process. Phenolic compounds originated from lignin, such as ferulic and p-coumaric acid, have been reported to inhibit cell growth and fermentation [126,127]. Furthermore, lignin has been associated to a strong inhibition of cellulases action towards cellulose, either by forming a physical barrier to cellulose [122] or due to a non-productive binding of the enzymes to lignin [128], affecting their adsorption to cellulose.…”

Section: Vhg Fermentation For Cellulosic Ethanol Productionmentioning

confidence: 99%

Very High Gravity Bioethanol Revisited: Main Challenges and Advances

et al. 2021

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Over the last decades, the constant growth of the world-wide industry has been leading to more and more concerns with its direct impact on greenhouse gas (GHG) emissions. Resulting from that, rising efforts have been dedicated to a global transition from an oil-based industry to cleaner biotechnological processes. A specific example refers to the production of bioethanol to substitute the traditional transportation fuels. Bioethanol has been produced for decades now, mainly from energy crops, but more recently, also from lignocellulosic materials. Aiming to improve process economics, the fermentation of very high gravity (VHG) mediums has for long received considerable attention. Nowadays, with the growth of multi-waste valorization frameworks, VHG fermentation could be crucial for bioeconomy development. However, numerous obstacles remain. This work initially presents the main aspects of a VHG process, giving then special emphasis to some of the most important factors that traditionally affect the fermentation organism, such as nutrients depletion, osmotic stress, and ethanol toxicity. Afterwards, some factors that could possibly enable critical improvements in the future on VHG technologies are discussed. Special attention was given to the potential of the development of new fermentation organisms, nutritionally complete culture media, but also on alternative process conditions and configurations.

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Physiological mechanism of improved tolerance of Saccharomyces cerevisiae to lignin-derived phenolic acids in lignocellulosic ethanol fermentation by short-term adaptation

Cited by 48 publications

References 51 publications

Regulatory control circuits for stabilizing long-term anabolic product formation in yeast

Regulatory control circuits for stabilizing long-term anabolic product formation in yeast

Improving the productivity of Candida glycerinogenes in the fermentation of ethanol from non‐detoxified sugarcane bagasse hydrolysate by a hexose transporter mutant

Very High Gravity Bioethanol Revisited: Main Challenges and Advances

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