Please use this identifier to cite or link to this item: https://doi.org/10.1186/s13068-017-0720-5
Title: Development of a genetically programed vanillin-sensing bacterium for high-throughput screening of lignin-degrading enzyme libraries
Authors: Sana, B
Chia, K.H.B
Raghavan, S.S
Ramalingam, B
Nagarajan, N 
Seayad, J
Ghadessy, F.J
Keywords: Biochemical engineering
Biomass
Biosensors
Cells
Cytology
Degradation
Enzymes
Escherichia coli
Flow cytometry
Fluorescence
Fluorescence microscopy
Lignin
Paper and pulp industry
Refining
Throughput
Biorefineries
Directed evolution
Enzyme engineering
Fluorescence activated cell sorting
High throughput screening
Inducible promoter
Microbial biosensor
Rna sequencing
Vanillin
Cell engineering
bacterium
catalysis
enzyme
fluorescence
lignin
microbial activity
phenol
RNA
Bacteria
Enzymes
Genetic Engineering
Lignins
Paper Industry
Screening
Bacteria (microorganisms)
Escherichia coli
Issue Date: 2017
Citation: Sana, B, Chia, K.H.B, Raghavan, S.S, Ramalingam, B, Nagarajan, N, Seayad, J, Ghadessy, F.J (2017). Development of a genetically programed vanillin-sensing bacterium for high-throughput screening of lignin-degrading enzyme libraries. Biotechnology for Biofuels 10 (1) : 32. ScholarBank@NUS Repository. https://doi.org/10.1186/s13068-017-0720-5
Rights: Attribution 4.0 International
Abstract: Background: Lignin is a potential biorefinery feedstock for the production of value-added chemicals including vanillin. A huge amount of lignin is produced as a by-product of the paper industry, while cellulosic components of plant biomass are utilized for the production of paper pulp. In spite of vast potential, lignin remains the least exploited component of plant biomass due to its extremely complex and heterogenous structure. Several enzymes have been reported to have lignin-degrading properties and could be potentially used in lignin biorefining if their catalytic properties could be improved by enzyme engineering. The much needed improvement of lignin-degrading enzymes by high-throughput selection techniques such as directed evolution is currently limited, as robust methods for detecting the conversion of lignin to desired small molecules are not available. Results: We identified a vanillin-inducible promoter by RNAseq analysis of Escherichia coli cells treated with a sublethal dose of vanillin and developed a genetically programmed vanillin-sensing cell by placing the 'very green fluorescent protein' gene under the control of this promoter. Fluorescence of the biosensing cell is enhanced significantly when grown in the presence of vanillin and is readily visualized by fluorescence microscopy. The use of fluorescence-activated cell sorting analysis further enhances the sensitivity, enabling dose-dependent detection of as low as 200 ?M vanillin. The biosensor is highly specific to vanillin and no major response is elicited by the presence of lignin, lignin model compound, DMSO, vanillin analogues or non-specific toxic chemicals. Conclusions: We developed an engineered E. coli cell that can detect vanillin at a concentration as low as 200 ?M. The vanillin-sensing cell did not show cross-reactivity towards lignin or major lignin degradation products including vanillin analogues. This engineered E. coli cell could potentially be used as a host cell for screening lignin-degrading enzymes that can convert lignin to vanillin. © 2017 The Author(s).
Source Title: Biotechnology for Biofuels
URI: https://scholarbank.nus.edu.sg/handle/10635/178130
ISSN: 17546834
DOI: 10.1186/s13068-017-0720-5
Rights: Attribution 4.0 International
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