Sustainable bioprocess evaluation for xylanase production by isolated Aspergillus terreus and Aspergillus fumigatus under solid - state fermentation using oil palm empty fruit bunch fiber

Current Trends in Biotechnology and Pharmacy

Volumn 5, Issue 4, 2011, Pages 1434-1444

  Suvarna Lakshmi, G ^a   Lakshmi Bhargavi, P ^a   Prakasham, R S ^a  

^a INDIAN INSTITUTE OF CHEMICAL TECHNOLOGY   (India)

Author keywords

Aspergillus; Bioprocess; Palm fiber; Solid state fermentation; Xylanase

Indexed keywords

AMMONIUM CHLORIDE; FRUCTOSE; SODIUM NITRATE; XYLAN ENDO 1,3 BETA XYLOSIDASE; XYLOSE;

ARTICLE; ASPERGILLUS FUMIGATUS; ASPERGILLUS TERREUS; BIOCATALYST; BIOPROCESS; CONTROLLED STUDY; ELAEIS; ENZYME SYNTHESIS; FUNGAL STRAIN; FUNGUS ISOLATION; MOISTURE; NONHUMAN; PARTICLE SIZE; PH; PROCESS OPTIMIZATION; SOLID STATE FERMENTATION;

ASPERGILLUS; ASPERGILLUS FUMIGATUS; ASPERGILLUS TERREUS; ELAEIS;

EID: 80054678471     PISSN: 09738916     EISSN: 22307303     Source Type: Journal    
DOI: None     Document Type: Article

References (30)

1. Kachlishvili, E., Penninckx, M.J., Tsiklauri, N. and Elisashvili, V. (2005). Effect of nitrogen source on lignocellulolytic enzyme production by white-rot basidiomycetes under solid-state cultivation. World Journal of Microbiology and Biotechnology, 22(4): 391-397.
2. Haltrich, D., Nidetzky, B., Kulbe, K.D., Steiner, W. and Zupancic, S. (1996). Production of fungal xylanases. Bioresource Technology, 58: 137-161.
3. Betini, J.H.A., Michelin, M., Peixoto- Nogueira, S.C., Jorge, J.A., Terenzi, H.F. and Polizeli, M.L.T.M. (2009). Xylanases from Aspergillus niger, Aspergillus niveus and Aspergillus ochraceus produced under solid-state fermentation and their application in cellulose pulp bleaching. Bioprocess Biosyst Engineering, 32: 819-824.
4. Maciel, G.M., de Souza, L.P., Vandenberghe, Haminiuk, C.W.I., Fendrich, R.C., Bianca, B.E.D., Brandalize, T.Q.S., Pandey, A. and Soccol, C.R. (2008). Xylanase production by Aspergillus niger LPB 326 in solid-state fermentation using statistical experimental designs. Food Technology and Biotechnology, 46 (2): 181-187.
5. Botella, C., Diaz, A., Ory, I., Webb, C. and Blandino, A. (2007). Xylanase and pectinase production by Aspergillus awamori on grape pomace in solid state fermentation. Process Biochemistry, 42: 98-101.
6. Suvarna Laxmi, G., Sathish, T., Subba Rao, Ch., Brahmaiah, P., Hymavathi, M. and Prakasham, R.S. (2008). Palm fiber as novel substrate for enhanced xylanase production by isolated Aspergillus sp. RSP-6. Current Trends in Biotechnology and Pharmacy, 2(3): 447-455.
7. Miller, G.L. (1959). Modified DNS method for reducing sugars. Analytical Chemistry, 31: 426-428.
8. Lucia, M., Simoes, G., Torniseilo, S.M.T. and Tapia, D.M.T. (2009). Screening of culture condition for xylanase production by filamentous fungi. African Journal of Biotechnology, 8 (22): 6317-6326.
9. Antoine, A.A., Jacqueline, D. and Thonart, P. (2010). Xylanase production by Penicillium canescens on soya oil cake in solid-state fermentation. Applied Biochemistry and Biotechnology, 160: 50-62.
10. Yang, S.Q., Yan, Q.J., Jiang, Z.Q., Li, L.T., Tian, H.M. and Wang, Y.Z. (2006). Highlevel of xylanase production by the thermophilic Paecilomyces themophila J18 on wheat straw in solid-state fermentation. Bioresource Technology, 97: 1794-1800.
11. Ghanem, N.B., Yusef, H.H. and Mahrouse, H.K. (2000). Production of Aspergillus terreus xylanase in solid-state cultures: application of the Plackett - Burman experimental design to evaluate nutritional requirements. Bioresource Technology, 73: 113-121.
12. Nogueira, S.C.P., Michelin, M., Betini, J. H. A., Jorge, J.A., Terenzi, H.F. and Polizeli, M.L.T.M. (2009). Production of xylanase by Aspergilli using alternative carbon sources: application of the crude extract on cellulose pulp biobleaching. Journal of Industrial Microbiology and Biotechnology, 36:149-155.
13. Prakasham, R.S., Subba Rao, Ch. and Sarma, P. N. (2006). Green gram husk- an inexpensive substrate for alkaline protease production by Bacillus sp. in solidstate fermentation. Bioresource Technology, 97: 1449-1454.
14. Prakasham, R. S., Subba Rao, Ch., Sreenivasa Rao, R. and Sarma, P. N. (2007). Enhancement of acid amylase production by an isolated Aspergillus awamori. Journal of Applied Microbiology, 102: 204-211.
15. Xin, F. and Geng, A. (2010). Horticultural waste as the substrate for cellulase and hemicellulase production by Trichoderma reesei under solid-state fermentation. Applied Biochemistry and Biotechnology, 162: 295-306.
16. Mahalaxmi, Y., Sathish, T., Subba Rao, Ch. and Prakasham, R.S. (2010). Corn husk as a novel substrate for the production of rifamycin B by isolated Amycolatopsis sp. RSP-3 under solid state fermentation. Process biochemistry, 45:47-53.
17. Prakasham, R. S., Sreenivasa Rao, R., Subba Rao, Ch. and Sarma, P. N. (2005). cyclodextringlycosyl transferase production using isolated Bacillus sp and Bacillus circulance. Indian Journal of Biotechnology, 4: 347-352.
18. Prakasham, R. S., Subba Rao, Ch., Sreenivasa Rao, R. and Sarma, P. N. (2005). Alkaline protease production by an isolated Bacillus circulance under solid-state fermentation using agro-industry waste: Process parameters optimization. Biotechnology Progress, 21: 1380-138.
19. Panagiotou, G., Kekos, D., Macris, B.J. and Christakopoulos, P. (2003). Production of cellulolytic and xylanolytic enzymes by Fusarium oxysporum grown on corn stover in solid state fermentation. Industrial crops and products, 18: 37-45.
20. Smith, D. C. and Wood, T.M. (1991). Xylanase production by Aspergillus awamori. Development of a medium and optimization of the fermentation parameters for the production of extracellular xylanase and â-xylosidase while maintaining low protease production. Biotechnology and Bioengineering, 38: 883-890.
21. Gaffney, M., Doyle, S. and Murphy, R. (2009). Optimization of xylanase production by Thermomyces lanuginosus in solid-state fermentation. Bioscience, Biotechnology and Biochemistry, 73 (12): 2640-2644.
22. Pandey, A., Socool, C.R. and Mitichell, D. (2000). New developments in solid-state fermentation. I. Bioprocess and products. Process Biochemistry, 35: 1153-1169.
23. Shah, A.R. and Madamwar, D. (2005). Xylanase production by a newly isolated Aspergillus foetidus strain and its characterization. Process Biochemistry, 40: 1763-1771.
24. Christakopoulos, P., Kekos, D., Macris, B.J., Claeyssens, M. and Bhat, M.K. (1996). Purification and characterization of a major xylanase with cellulose and transferase activities from Fusarium oxysporum. Carbohydrate Research, 289: 91-104.
25. Kulkarni, N., Shendye, A. and Rao, M. (1999). Molecular and biotechnological aspects of xylanases. FEMS Microbiology Reviews, 23: 411-456.
26. Dubeau, H., Chahal, D.S. and Ishaque, M. (1987). Xylanase of Chaetomium Cellulolyticum: its nature of production and hydrolytic potential. Biotechnology letters 9 (4): 275-280.
27. Kanmani, P., Karuppasamy, P., Pothiraj, C. and Venkatesan, A. (2009). Studies on lignocellulose biodegradation of coir waste in solid state fermentation using Phanerocheate chrysosporium and Rhizopus stolonifer. African Journal of Biotechnology, 8 (24): 6880-6887.
28. Sater, M.A.A. and Said, A.H.M. (2001). Xylan-decomposing fungi and xylanolytic activity in agricultural and industrial wastes. International Biodeterioration and Biodegradation, 47: 15-21.
29. Seyis, I. and Aksoz, N. (2005). Effect of carbon and nitrogen sources on xylanase production by Trichoderma harzianum 1073 D3. International Biodeterioration and Biodegradation, 55(2): 115-119.
30. Haltrich, D., Preiss, M. and Steiner, W. (1993). Optimization of a culture medium for increased xylanase production by a wild strain of Schizophyllum commune. Enzyme and Microbial Technology, 15: 854-860.