Bio-inspired designer cellulosomes show strongest synergy on industrial substrates under natural-like conditions
- Author
- Babette Lamote (UGent) , Julie Vanderstraeten (UGent) , Nette De Ridder (UGent) , Kenan Meert (UGent) , Wout Boerjan (UGent) and Yves Briers (UGent)
- Organization
- Project
-
- Lignin engineering to improve lignocellulosic biomass processing efficiency
- Valorisation of industrial bio-based side streams with designer cellulosomics
- Designer cellulosomics for a customized conversion of lignocellulosic biomass to bioethanol
- Designer cellulosomics for customized solutions towards sustainable bioethanol production
- Abstract
- Designer cellulosomes are engineered multi-enzyme complexes inspired by natural cellulosomes, designed to improve lignocellulose breakdown. Their modular architecture enables the spatial colocalization of diverse catalytic activities, potentially enhancing depolymerization efficiency compared to free enzymes. Although conceptually promising, little is known about how they perform on complex lignocellulosic substrates. In this study, we developed a tetravalent designer cellulosome using a modular VersaTile assembly approach, incorporating endoglucanase, cellobiohydrolase, β-glucosidase, and endoxylanase activities. The process involved (i) delineating catalytic modules from Cellvibrio japonicus enzymes, (ii) generating docking enzyme variants via combinatorial cloning, and (iii) selecting optimal candidates based on expression, activity, and cohesin-dockerin binding before assembling them onto a scaffoldin with four cohesins and a cellulose-binding module. The resulting designer cellulosome was tested on two industrially relevant substrates: agro-industrial wheat fibers and genome-edited low-lignin poplar biomass under controlled laboratory conditions. It achieved cellulose-to-glucose conversion yields of 24.98% (150 pmol designer cellulosome/ml) and 0.82% (200 pmol designer cellulosome/ml), respectively, under the test conditions. By comparing the saccharification efficiencies of the enzymes in their free and complexed forms, we found that colocalization on a common scaffoldin significantly enhanced synergistic activity. This effect was most pronounced under low enzyme concentrations and when acting on complex lignocellulosic substrates, increasing glucose release compared to free enzymes. These observations highlight that the benefits of colocalization are substrate-dependent and occur under conditions that mimic the natural environment of biomass degradation, conditions that differ from typical industrial settings. This work advances our understanding of designer cellulosome behavior on real-world substrates, providing essential insights for evaluating their economic viability in industrial applications.
- Keywords
- Designer cellulosome, biocatalysis, enzyme synergy, industrial biotechnology, lignocellulosic biomass conversion, LIGNOCELLULOSIC BIOMASS, DEGRADATION, INTEGRATION, RECALCITRANCE, NANOMACHINES, BIOFUELS, PROMOTES, COMPLEX, ENZYMES
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Citation
Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01KGQAM7058CMTDB2TN4VW5MZ6
- MLA
- Lamote, Babette, et al. “Bio-Inspired Designer Cellulosomes Show Strongest Synergy on Industrial Substrates under Natural-like Conditions.” JOURNAL OF INDUSTRIAL MICROBIOLOGY & BIOTECHNOLOGY, vol. 53, 2026, doi:10.1093/jimb/kuag004.
- APA
- Lamote, B., Vanderstraeten, J., De Ridder, N., Meert, K., Boerjan, W., & Briers, Y. (2026). Bio-inspired designer cellulosomes show strongest synergy on industrial substrates under natural-like conditions. JOURNAL OF INDUSTRIAL MICROBIOLOGY & BIOTECHNOLOGY, 53. https://doi.org/10.1093/jimb/kuag004
- Chicago author-date
- Lamote, Babette, Julie Vanderstraeten, Nette De Ridder, Kenan Meert, Wout Boerjan, and Yves Briers. 2026. “Bio-Inspired Designer Cellulosomes Show Strongest Synergy on Industrial Substrates under Natural-like Conditions.” JOURNAL OF INDUSTRIAL MICROBIOLOGY & BIOTECHNOLOGY 53. https://doi.org/10.1093/jimb/kuag004.
- Chicago author-date (all authors)
- Lamote, Babette, Julie Vanderstraeten, Nette De Ridder, Kenan Meert, Wout Boerjan, and Yves Briers. 2026. “Bio-Inspired Designer Cellulosomes Show Strongest Synergy on Industrial Substrates under Natural-like Conditions.” JOURNAL OF INDUSTRIAL MICROBIOLOGY & BIOTECHNOLOGY 53. doi:10.1093/jimb/kuag004.
- Vancouver
- 1.Lamote B, Vanderstraeten J, De Ridder N, Meert K, Boerjan W, Briers Y. Bio-inspired designer cellulosomes show strongest synergy on industrial substrates under natural-like conditions. JOURNAL OF INDUSTRIAL MICROBIOLOGY & BIOTECHNOLOGY. 2026;53.
- IEEE
- [1]B. Lamote, J. Vanderstraeten, N. De Ridder, K. Meert, W. Boerjan, and Y. Briers, “Bio-inspired designer cellulosomes show strongest synergy on industrial substrates under natural-like conditions,” JOURNAL OF INDUSTRIAL MICROBIOLOGY & BIOTECHNOLOGY, vol. 53, 2026.
@article{01KGQAM7058CMTDB2TN4VW5MZ6,
abstract = {{Designer cellulosomes are engineered multi-enzyme complexes inspired by natural cellulosomes, designed to improve lignocellulose breakdown. Their modular architecture enables the spatial colocalization of diverse catalytic activities, potentially enhancing depolymerization efficiency compared to free enzymes. Although conceptually promising, little is known about how they perform on complex lignocellulosic substrates. In this study, we developed a tetravalent designer cellulosome using a modular VersaTile assembly approach, incorporating endoglucanase, cellobiohydrolase, β-glucosidase, and endoxylanase activities. The process involved (i) delineating catalytic modules from Cellvibrio japonicus enzymes, (ii) generating docking enzyme variants via combinatorial cloning, and (iii) selecting optimal candidates based on expression, activity, and cohesin-dockerin binding before assembling them onto a scaffoldin with four cohesins and a cellulose-binding module. The resulting designer cellulosome was tested on two industrially relevant substrates: agro-industrial wheat fibers and genome-edited low-lignin poplar biomass under controlled laboratory conditions. It achieved cellulose-to-glucose conversion yields of 24.98% (150 pmol designer cellulosome/ml) and 0.82% (200 pmol designer cellulosome/ml), respectively, under the test conditions. By comparing the saccharification efficiencies of the enzymes in their free and complexed forms, we found that colocalization on a common scaffoldin significantly enhanced synergistic activity. This effect was most pronounced under low enzyme concentrations and when acting on complex lignocellulosic substrates, increasing glucose release compared to free enzymes. These observations highlight that the benefits of colocalization are substrate-dependent and occur under conditions that mimic the natural environment of biomass degradation, conditions that differ from typical industrial settings. This work advances our understanding of designer cellulosome behavior on real-world substrates, providing essential insights for evaluating their economic viability in industrial applications.}},
articleno = {{kuag004}},
author = {{Lamote, Babette and Vanderstraeten, Julie and De Ridder, Nette and Meert, Kenan and Boerjan, Wout and Briers, Yves}},
issn = {{1367-5435}},
journal = {{JOURNAL OF INDUSTRIAL MICROBIOLOGY & BIOTECHNOLOGY}},
keywords = {{Designer cellulosome,biocatalysis,enzyme synergy,industrial biotechnology,lignocellulosic biomass conversion,LIGNOCELLULOSIC BIOMASS,DEGRADATION,INTEGRATION,RECALCITRANCE,NANOMACHINES,BIOFUELS,PROMOTES,COMPLEX,ENZYMES}},
language = {{eng}},
pages = {{16}},
title = {{Bio-inspired designer cellulosomes show strongest synergy on industrial substrates under natural-like conditions}},
url = {{http://doi.org/10.1093/jimb/kuag004}},
volume = {{53}},
year = {{2026}},
}
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