Engineering Saccharomyces cerevisiae for targeted hydrolysis and fermentation of glucuronoxylan through CRISPR/Cas9 genome editing
Journal article, 2024

Background
The abundance of glucuronoxylan (GX) in agricultural and forestry residual side streams positions it as a promising feedstock for microbial conversion into valuable compounds. By engineering strains of the widely employed cell factory Saccharomyces cerevisiae with the ability to directly hydrolyze and ferment GX polymers, we can avoid the need for harsh chemical pretreatments and costly enzymatic hydrolysis steps prior to fermentation. However, for an economically viable bioproduction process, the engineered strains must efficiently express and secrete enzymes that act in synergy to hydrolyze the targeted polymers.

Results
The aim of this study was to equip the xylose-fermenting S. cerevisiae strain CEN.PK XXX with xylanolytic enzymes targeting beechwood GX. Using a targeted enzyme approach, we matched hydrolytic enzyme activities to the chemical features of the GX substrate and determined that besides endo-1,4-β-xylanase and β-xylosidase activities, α-methyl-glucuronidase activity was of great importance for GX hydrolysis and yeast growth. We also created a library of strains expressing different combinations of enzymes, and screened for yeast strains that could express and secrete the enzymes and metabolize the GX hydrolysis products efficiently. While strains engineered with BmXyn11A xylanase and XylA β-xylosidase could grow relatively well in beechwood GX, strains further engineered with Agu115 α-methyl-glucuronidase did not display an additional growth benefit, likely due to inefficient expression and secretion of this enzyme. Co-cultures of strains expressing complementary enzymes as well as external enzyme supplementation boosted yeast growth and ethanol fermentation of GX, and ethanol titers reached a maximum of 1.33 g L− 1 after 48 h under oxygen limited condition in bioreactor fermentations.

Conclusion
This work underscored the importance of identifying an optimal enzyme combination for successful engineering of S. cerevisiae strains that can hydrolyze and assimilate GX. The enzymes must exhibit high and balanced activities, be compatible with the yeast’s expression and secretion system, and the nature of the hydrolysis products must be such that they can be taken up and metabolized by the yeast. The engineered strains, particularly when co-cultivated, display robust growth and fermentation of GX, and represent a significant step forward towards a sustainable and cost-effective bioprocessing of GX-rich biomass. They also provide valuable insights for future strain and process development targets.

Co-culture

Consolidated bioprocessing

Xylan

Yeast

α-glucuronidase

Xylanase

Microbial cell factories

Metabolic engineering

Author

Jonas Laukkonen Ravn

Chalmers, Life Sciences, Industrial Biotechnology

João Heitor Colombelli Manfrão Netto

Chalmers, Life Sciences, Industrial Biotechnology

Jana B. Schaubeder

Technische Universität Graz

Luca Torello Pianale

Chalmers, Life Sciences, Industrial Biotechnology

Stefan Spirk

Technische Universität Graz

Iván Francisco Ciklic

Chalmers, Life Sciences, Industrial Biotechnology

Cecilia Geijer

Chalmers, Life Sciences, Industrial Biotechnology

Microbial Cell Factories

14752859 (eISSN)

Vol. 23 85

Driving Forces

Sustainable development

Subject Categories

Biochemistry and Molecular Biology

Microbiology

Biocatalysis and Enzyme Technology

Areas of Advance

Life Science Engineering (2010-2018)

DOI

10.1186/s12934-024-02361-w

More information

Created

3/28/2024