Abstract
To enhance the competitiveness of industrial lignocellulose ethanol production, robust enzymes and cell factories are vital. Lignocellulose derived streams contain a cocktail of inhibitors that drain the cell of its redox power and ATP, leading to a decrease in overall ethanol productivity. Many studies have attempted to address this issue, and we have shown that increasing the glutathione (GSH) content in yeasts confers tolerance towards lignocellulose inhibitors, subsequently increasing the ethanol titres. However, GSH levels in yeast are limited by feedback inhibition of GSH biosynthesis. Multidomain and dual functional enzymes exist in several bacterial genera and they catalyse the GSH biosynthesis in a single step without the feedback inhibition. To test if even higher intracellular glutathione levels could be achieved and if this might lead to increased tolerance, we overexpressed the genes from two bacterial genera and assessed the recombinants in simultaneous saccharification and fermentation (SSF) with steam pretreated spruce hydrolysate containing 10% solids. Although overexpressing the heterologous genes led to a sixfold increase in maximum glutathione content (18 µmol gdrycellmass−1) compared to the control strain, this only led to a threefold increase in final ethanol titres (8.5 g L− 1). As our work does not conclusively indicate the cause-effect of increased GSH levels towards ethanol titres, we cautiously conclude that there is a limit to cellular fitness that could be accomplished via increased levels of glutathione.
Highlights
Targeting industrial chemicals with bio-based processes is an emerging market as it enables the production from non-petrochemical feedstock
We focused our approach on glutathione (GSH), the cellular protectant that plays a major role in detoxifying reactive oxygen species and free radicals (Grant 2001; Meister and Anderson 1983)
Recombinant strains have increased GSH levels without compromising growth Strains harbouring alternative enhanced pathways for glutathione were obtained in the S. cerevisiae CEN.PK background
Summary
Targeting industrial chemicals with bio-based processes is an emerging market as it enables the production from non-petrochemical feedstock. Pretreatment aids in reducing the crystallinity so that the carbohydrate degrading enzymes can access cellulose and hemicellulose and break them down into soluble sugars. Most of the pretreatment methods currently available (Kumar and Sharma 2017) produce inhibitors (e.g. aromatic aldehydes, organic acids) (Jönsson et al 2013; Taherzadeh 1999) that adversely affect the efficiency of microorganisms or the saccharifying enzymes both of which have implications on the final product cost. Numerous strategies have been reported for overcoming the challenges posed by lignocellulosic inhibitors to increase the yield and productivity of ethanol (Jönsson and Martín 2016; Kim 2018; Kumar et al 2020; Wang et al 2018). GSH is oxidised to Glutathione disulfide GSSG by reactions with free radicals.
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