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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 1010-1012Efficient Production of Laccase from Armillariella...

Efficient Production of Laccase from Armillariella tabescens by Solid State Fermentation

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Abstract:

The production of laccase by solid-state fermentation (SSF) using Armillariella tabescens was studied. Wheat bran was selected to be the most suitable solid substrate. Several operational variables including nitrogen source, moisture content, copper and aromatic inducers were investigated. The results showed that the complex nitrogen sources, NH₄NO₃coupled with peptone was shown to be the best nitrogen source. 75% of initial moisture content was proved to be appropriate. Copper significantly influenced the laccase production and the yield of laccase was improved by addition of 1.5 mM copper sulphate in the medium. Guaiacol efficiently induced the laccase production and the enzyme yield (24500U/g) was enhanced by 32% compared with he control without any aromatic inducers. Efficient production of laccase from A. tabescens can be achieved by solid-state fermentation.

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Periodical:

Advanced Materials Research (Volumes 1010-1012)

Pages:

42-47

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1010-1012.42

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Online since:

August 2014

Authors:

Jun Yao He*, Xuan Yi Ye, Qing Zhi Ling, Li Hui Dong

Keywords:

Armillariella tabescens, Inducer, Laccase, Optimization, Solid-State Fermentation

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[1] V. M. Halaburgi, S. Sharma, M. Sinha, T. P. Singh and T. B. Karegoudar: Process Biochem. Vol. 46 (2011), pp.1146-1152.

[2] S. Rodríguez Couto and J. L. Toca Herrera: Biotechnol. Adv. Vol. 24 (2006), pp.500-513.

[3] M. T. Cambria, S. Ragusa, V. Calabrese and A. Cambria: Appl. Biochem. Biotechnol. Vol. 163 (2011), pp.415-422.

DOI: 10.1007/s12010-010-9049-2

[4] J. Si, F. Peng and B. Cui: Bioresour. Technol. Vol. 128 (2013), pp.49-57.

[5] JSNMC (JiangSu Medical College): Dictionary of the Traditional Chinese Medicine. 1st ed. (1977), p.1716. Shanghai Science and Technology Press, Shanghai, China. (in Chinese).

[6] J. He, X. Ye, Q. Ling and L. Dong: J. Chem. Pharm. Res. Vol. 6 (2014), P. 240-245.

[7] M.A. Piccard, H. Vandertol, R. Roman and R. Vanquez-Duhalt: Can. J. Microbiol. Vol. 45(1999), pp.627-631.

[8] U. Chhaya and A. Gupte: Ann. Microbiol. Vol. 63 (2013), pp.215-223.

[9] T. Aydınoglu and S. Sargin: Bioprocess Biosyst. Eng. Vol. 36(2013), pp.215-222.

[10] M. S. Revankar, K. M. Desai and S. S. Lele: Appl. Biochem. Biotechnol. Vol. 143 (2007), pp.16-26.

[11] X. Peng, X. Yuan, G. Zeng, H. Huang, H. Zhong, Z. Liu, K. Cui, Y. Liang, Z. Peng, L. Guo, Y. Ma and W. Liu: Process Biochem. Vol. 47 (2012), pp.742-748.

DOI: 10.1016/j.procbio.2012.02.006

[12] D.F. Souza, G. K. Tychanowicz, C. G. M. Souza and R. M. Peralta: J. Basic Microbiol. Vol. 46 (2006), pp.126-134.

[13] P. Dwivedi, V. Vivekanand, N. Pareek, A. Sharma and R. P. Singh: New Biotechnol. Vol. 28 (2011), pp.616-626.

[14] R. R. Singhania, A. K. Patel, C. R. Soccol and A. Pandey: Biochem. Eng. J. Vol. 44 (2009), pp.13-18.

[15] S. Martins, S. I. Mussatto, G. Martinez-Avila, J. Montanez-Saenz, C. N. Aguilar and J. A. Teixeira: Biotechnol. Adv. Vol. 29 (2011), pp.365-373.

[16] D. Kalyani, S. S. Dhiman, H. Kim, M. Jeya, I. Kim and J. Lee: Process Biochem. Vol. 47 (2012), pp.671-678.

[17] G. Palmieri, P. Giardiana, C. Bianco, B. Fontanella and G. Sannia: Appl. Environ. Microbiol. Vol. 66 (2000), pp.920-924.

DOI: 10.1128/aem.66.3.920-924.2000

[18] M. Y. Jang, W. Y. Ryu and M. H. Cho: Biotchnol. Bioprocess Eng. Vol. 11(2006), pp.96-99.

[19] K.N. Niladevi and P. Prema: Bioresour. Technol. Vol. 99 (2008), pp.4583-4589.

[20] J. A. Saraiva, A. P. M. Tavares and A .M. R. B. Xavier: Appl. Biochem. Biotechnol. Vol. 167 (2012), pp.685-693.

[21] C. Eggert, U. Temp and K. E. Eriksson: Appl. Environ. Microbiol. Vol. 62 (1996), pp.1151-1158.

[22] K. Murugesan, M. Arulmani, I. H. Nam, Y. M. Kim, Y. S. Chang and P. T. Kalaichelvan: Appl. Microbiol. Biotechnol. Vol. 72 (2006), pp.939-946.