Abstract
Wheat straw and oak wood chips were incubated with Ceriporiopsis subvermispora and Lentinula edodes for 8 weeks. Samples from the fungal treated substrates were collected every week for chemical characterization. L. edodes continuously grew during the 8 weeks on both wheat straw and oak wood chips, as determined by the ergosterol mass fraction of the dry biomass. C. subvermispora colonized both substrates during the first week, stopped growing on oak wood chips, and resumed growth after 6 weeks on wheat straw. Detergent fiber analysis and pyrolysis coupled to gas chromatography/mass spectrometry showed a selective lignin degradation in wheat straw, although some carbohydrates were also degraded. L. edodes continuously degraded lignin and hemicelluloses in wheat straw while C. subvermispora degraded lignin and hemicelluloses only during the first 5 weeks of treatment after which cellulose degradation started. Both fungi selectively degraded lignin in wood chips. After 4 weeks of treatment, no significant changes in chemical composition were detected. In contrast to L. edodes, C. subvermispora produced alkylitaconic acids during fungal treatment, which paralleled the degradation and modification of lignin indicating the importance of these compounds in delignification. Light microscopy visualized a dense structure of wood chips which was difficult to penetrate by the fungi, explaining the relative lower lignin degradation compared to wheat straw measured by chemical analysis. All these changes resulted in an increased in in vitro rumen degradability of wheat straw and oak wood chips. In addition, more glucose and xylose were released after enzymatic saccharification of fungal treated wheat straw compared to untreated material.
Highlights
Cellulose in lignified plant cell walls can be a source of energy in applications such as animal nutrition and biofuel production
The ergosterol mass fraction in wheat straw and oak wood chips showed a steady increase during 8 weeks of L. edodes treatment indicating a continuous growth of this fungus during the whole incubation period
Ergosterol mass fraction of both wheat straw and oak wood chips increased in the first week of treatment
Summary
Cellulose in lignified plant cell walls can be a source of energy in applications such as animal nutrition and biofuel production. The utilization of cellulose in lignocellulosic biomass cannot directly be used for these purposes because of the presence of lignin. This recalcitrant polymer is difficult to degrade and several chemical and/or physical methods have been developed to selectively remove lignin [1]. Fungal treatment of lignocellulosic biomass can be a relatively inexpensive and environmental friendly technology to decrease lignin mass fraction of the dry biomass and to increase the accessibility of cellulose [2,3]. The fungal treated biomass showed increased in vitro rumen degradability, demonstrating that the cellulose becomes available for rumen microbes.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
