Insights into the functionality and stability of designer cellulosomes at elevated temperatures

Enzymatic breakdown of lignocellulose is a major limiting step in second generation biorefineries. Assembly of the necessary activities into designer cellulosomes increases the productivity of this step by enhancing enzyme synergy through the proximity effect. However, most cellulosomal components a...

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Bibliographic Details
Published in:Applied microbiology and biotechnology 2016-10, Vol.100 (20), p.8731-8743
Main Authors: Galanopoulou, Anastasia P., Moraïs, Sarah, Georgoulis, Anastasios, Morag, Ely, Bayer, Edward A., Hatzinikolaou, Dimitris G.
Format: Article
Language:English
Subjects:
Analysis
Bacteria
Biomass
Biomedical and Life Sciences
Biorefineries
Biosynthesis
Biotechnologically Relevant Enzymes and Proteins
Biotechnology
Caldicellulosiruptor
Cell Cycle Proteins - genetics
Cell Cycle Proteins - metabolism
Cellulase
Cellulose
Cellulosomes - chemistry
Cellulosomes - genetics
Cellulosomes - metabolism
Cellulosomes - radiation effects
Chemical properties
Chromosomal Proteins, Non-Histone - genetics
Chromosomal Proteins, Non-Histone - metabolism
Cloning
Clostridium thermocellum
Cohesins
Enzyme kinetics
Enzyme Stability
Enzymes
Firmicutes - genetics
Geobacillus
High temperature
Hot Temperature
Hydrolysis
Life Sciences
Lignin - metabolism
Lignocellulose
Microbial Genetics and Genomics
Microbiology
Microorganisms
Observations
Plasmids
Proteins
Refineries
Stover
Studies
Temperature
Thermal properties
Zea mays - metabolism
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Summary:Enzymatic breakdown of lignocellulose is a major limiting step in second generation biorefineries. Assembly of the necessary activities into designer cellulosomes increases the productivity of this step by enhancing enzyme synergy through the proximity effect. However, most cellulosomal components are obtained from mesophilic microorganisms, limiting the applications to temperatures up to 50 °C. We hypothesized that a scaffoldin, comprising modular components of mainly mesophilic origin, can function at higher temperatures when combined with thermophilic enzymes, and the resulting designer cellulosomes could be employed in higher temperature reactions. For this purpose, we used a tetravalent scaffoldin constituted of three cohesins of mesophilic origin as well as a cohesin and cellulose-binding module derived from the thermophilic bacterium Clostridium thermocellum . The scaffoldin was combined with four thermophilic enzymes from Geobacillus and Caldicellulosiruptor species, each fused with a dockerin whose specificity matched one of the cohesins. We initially verified that the biochemical properties and thermal stability of the resulting chimeric enzymes were not affected by the presence of the mesophilic dockerins. Then we examined the stability of the individual single-enzyme-scaffoldin complexes and the full tetravalent cellulosome showing that all complexes are stable and functional for at least 6 h at 60 °C. Finally, within this time frame and conditions, the full complex appeared over 50 % more efficient in the hydrolysis of corn stover compared to the free enzymes. Overall, the results support the utilization of scaffoldin components of mesophilic origin at relatively high temperatures and provide a framework for the production of designer cellulosomes suitable for high temperature biorefinery applications.
ISSN:0175-7598
1432-0614
DOI:10.1007/s00253-016-7594-5