Substrate-based differential expression analysis reveals control of biomass degrading enzymes in Pycnoporus cinnabarinus

•De novo transcriptome of P. cinnabarinus PB 94 contains 27,000 predicted genes.•Peroxidase gene expression increased up to 285-fold on plant material.•Alcohol oxidase gene expression increased up to 35-fold on plant material.•Laccases showed little regulation across substrates regardless of lignin...

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Bibliographic Details
Published in:Biochemical engineering journal 2018-02, Vol.130 (C), p.83-89
Main Authors: Henske, John K., Springer, Stephen D., O'Malley, Michelle A., Butler, Alison
Format: Article
Language:English
Subjects:
Biotechnology & Applied Microbiology
Cellulase
Engineering
Lignocellulose
Next generation sequencing
Peroxidase
Pynoporus
White rot fungi
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Summary:•De novo transcriptome of P. cinnabarinus PB 94 contains 27,000 predicted genes.•Peroxidase gene expression increased up to 285-fold on plant material.•Alcohol oxidase gene expression increased up to 35-fold on plant material.•Laccases showed little regulation across substrates regardless of lignin content.•A single laccase gene demonstrated strong regulation in presence of cellobiose. White rot fungi possess a powerful ability to degrade recalcitrant lignin within plant biomass. Pycnoporus cinnabarinus PB 94 accomplishes lignin degradation through the combined activity of laccases, peroxidases, and their supporting enzymes. Assembly of the de novo transcriptome for PB 94 resulted in identification of 45,286 transcripts, including isoforms, and a predicted 27,990 genes. Differential expression analysis revealed how the expression of these ligninolytic enzymes was dictated by the nature of the substrate. Growth on lignin containing poplar and switchgrass resulted in as much as a 285-fold increase in expression of peroxidases (auxiliary activity family AA2) and a 36-fold increase in expression of alcohol oxidases (auxiliary activity family AA3) compared to growth on soluble sugars. These findings suggest that expression of these enzyme classes was controlled by the presence of lignin, or triggered by an aromatic break out product of lignin degradation. Laccases showed little significant regulation under these growth conditions, but one laccase transcript (TR10024|c0_g1_i1), similar to laccase gene lcc2 in Pycnoporus sanguineus, was greatly upregulated during growth on cellobiose, suggesting that this sugar may be a mechanism for enhanced expression. The findings presented here reveal regulation patterns of enzymes critical for the lignin degrading activity of P. cinnabarinus PB 94 providing insight into how the white rot fungus controls lignocellulolytic activity.
ISSN:1369-703X
1873-295X
DOI:10.1016/j.bej.2017.11.015