Heterologous expression of a glycosyl hydrolase and cellular reprogramming enable Zymomonas mobilis growth on cellobiose

Plant-derived fuels and chemicals from renewable biomass have significant potential to replace reliance on petroleum and improve global carbon balance. However, plant biomass contains significant fractions of oligosaccharides that are not usable natively by many industrial microorganisms, including...

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Bibliographic Details
Published in:PloS one 2020-08, Vol.15 (8), p.e0226235-e0226235
Main Authors: Kurumbang, Nagendra P, Vera, Jessica M, Hebert, Alexander S, Coon, Joshua J, Landick, Robert
Format: Article
Language:English
Subjects:
Adaptation
BASIC BIOLOGICAL SCIENCES
Biodiesel fuels
Biofuels
Biology and Life Sciences
Biomass
Carbohydrates
Carbon
Carbon sources
Cell growth
Cell metabolism
Cellobiase
Cellobiose
Cellulose
Conversion
E coli
Enzyme regulation
Enzymes
Ethanol
Fermentation
Gene expression
Genetic aspects
Genomes
Glucose
Glucosidase
Glycosidases
Glycosyl hydrolase
Gram-negative bacteria
Growth
Growth hormone
Hydrolase
Hydrolases
Lag phase
Lignocellulose
Methods
Microorganisms
Mutation
Observations
Oligomers
Oligosaccharides
Periplasm
Physical Sciences
Plant biomass
Plants
Plasmids
Properties
Protein synthesis
Proteins
Research and Analysis Methods
Science & Technology - Other Topics
Sucrose
Sugar
Synthetic biology
Zymomonas mobilis
β-Glucosidase
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Summary:Plant-derived fuels and chemicals from renewable biomass have significant potential to replace reliance on petroleum and improve global carbon balance. However, plant biomass contains significant fractions of oligosaccharides that are not usable natively by many industrial microorganisms, including Escherichia coli, Saccharomyces cerevisiae, and Zymomonas mobilis. Even after chemical or enzymatic hydrolysis, some carbohydrate remains as non-metabolizable oligosaccharides (e.g., cellobiose or longer cellulose-derived oligomers), thus reducing the efficiency of conversion to useful products. To begin to address this problem for Z. mobilis, we engineered a strain (Z. mobilis GH3) that expresses a glycosyl hydrolase (GH) with [beta]-glucosidase activity from a related [alpha]-proteobacterial species, Caulobacter crescentus, and subjected it to an adaptation in cellobiose medium. Growth on cellobiose was achieved after a prolonged lag phase in cellobiose medium that induced changes in gene expression and cell composition, including increased expression and extracellular release of GH. These changes were reversible upon growth in glucose-containing medium, meaning they did not result from genetic mutation but could be retained upon transfer of cells to fresh cellobiose medium. After adaptation to cellobiose, our GH-expressing strain was able to convert about 50% of cellobiose to glucose within 24 h and use it for growth and ethanol production. Alternatively, pre-growth of Z. mobilis GH3 in sucrose medium enabled immediate growth on cellobiose. Proteomic analysis of cellobiose- and sucrose-adapted strains revealed upregulation of secretion-, transport-, and outer membrane-related proteins, which may aid release or surface display of GHs, entry of cellobiose into the periplasm, or both. Our two key findings are that Z. mobilis can be reprogrammed to grow on cellobiose as a sole carbon source and that this reprogramming is related to a natural response of Z. mobilis to sucrose that promotes sucrase production.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0226235