Degradation of extractive-free lignocelluloses by Coriolus versicolor and Poria placenta
- 80 Downloads
- 5 Citations
Summary
The wood-decay fungi Coriolus versicolor, a white-rot fungus, and Poria placenta, a brown-rot fungus, were grown on an extractive-free lignocellulose prepared from quackgrass (Agropyron repens). Their abilities to decompose this lignocellulose were compared to their abilities to decompose softwood (Picea pungens) and hardwood (Acer rubrum) lignocelluloses. The two fungi were grown on malt-extract dampened lignocelluloses at 28°C for up to 12 weeks. Replicate cultures were periodically harvested and lignocellulose decomposition was followed by monitoring substrate weight loss, lignin loss, and carbohydrate loss. Coriolus versicolor decomposed the lignin and carbohydrate components of the grass lignocellulose as efficiently as the softwood and hardwood lignocelluloses. Poria placenta, however, was not an efficient degrader of either lignin or carbohydrate in the grass lignocellulose. Poria placenta readily decomposed carbohydrate components of the softwood lignocellulose but not the hardwood lignocellulose.
Keywords
Carbohydrate Lignin Substrate Weight Acer Rubrum Carbohydrate ComponentPreview
Unable to display preview. Download preview PDF.
References
- Adler E (1977) Lignin chemistry — Past, present and future. Wood Sci Technol 11:169–218Google Scholar
- Antai SP, Crawford DL (1981) Degradation of softwood, hardwood, and grass lignocelluloses by two Streptomyces strains. Appl Environ Microbiol 42:378–380Google Scholar
- Apenitis A, Erdtman H, Leopold B (1951) Studies on lignin. V. The decay of spruce wood by brown-rotting fungi. Sven Kem Tidskr 63:195–207Google Scholar
- Bray MW, Andrews TM (1924) Chemical changes of ground wood during decay. Ind Eng Chem 16:137–139Google Scholar
- Campbell WG (1952) The biological decomposition of wood. In: Wise, LE, Jahn, EC (eds) Wood chemistry. Reinhold, New York, pp 1061–1116Google Scholar
- Cowling EB (1961) Comparative biochemistry of decay of sweetgum sapwood by white-rot and brown-rot fungi. USDA Technical Bulletin 1258Google Scholar
- Crawford DL (1978) Lignocellulose decmposition by selected Streptomyces strains. Appl Environ Microbiol 35:1041–1045Google Scholar
- Crawford RL (1981) Lignin biodegradation and transformation. John Wiley & Sons Ltd, Chichester New York Brisband Toronto, p 192Google Scholar
- Higuchi T (1971) Formation and biological degradation of lignin. Adv Enzymol 34:207–283Google Scholar
- Higuchi T, Shimada M, Nakatsubo F, Tanahashi M (1977) Differences in biosynthesis of guaiacyl and syringyl lignins in woods. Wood Sci Technol 11:153–167Google Scholar
- Ishikawa H, Schuber WJ, Nord FF (1963) Investigations on lignins and lignification. XXVII. The degradation by Polyporus versicolor and Fomes fomentarius of aromatic compounds structurally related to softwood lignin. Arch Biochem Biophys 100:140–149Google Scholar
- Kaarik AA (1974) Decomposition of wood. In: Dickinson CH, Pugh AJF (eds) Biology of plant litter decomposition, vol I. Academic Press Inc., New York, pp 129–174Google Scholar
- Kawase K (1924) Chemical compounds of wood decayed under natural conditions and their properties. J Fac Agric Hokkaido Imp Univ 52:186–245Google Scholar
- Kirk TK (1973) The chemistry and biochemistry of decay. In: Nicholas D (ed) Wood deterioration and its prevention by preservative treatment, vol I. Syracuse Univ Press, Syracuse New York, pp 149–181Google Scholar
- Martin SB, Dale JL (1980) Biodegradation of turf thatch with wood decay fungi. Phytophatology 70:297–300Google Scholar
- Sarkanen KV, Ludwig CH (1971) Lignin, occurence, formation and reactions. Wiley-Interscience, New York, pp 165–240Google Scholar
- Zadražil F, Brunnert H (1981) Investigation of physical parameters important for the solid state fermentation of straw by white-rot fungi. Eur J Appl Microbiol Biotechnol 11:183–188Google Scholar