Enhancement of Laccase Activity by Marine-derived Deuteromycete Pestalotiopsis sp. J63 with Agricultural Residues and Inducers

doi:10.1016/S1004-9541(13)60567-4

Abstract

Abstract: Pestalotiopsis sp. J63, producing a high activity of laccase, is a new marine-derived fungus isolated from the oceanic sediment of the East China Sea. Since the marine environment is oligotrophic nutrient, marine derived fungi may use small amount of nutrients to grow and produce laccases. Agricultural residues that are mainly composed of lignin, cellulose and hemicellulose are difficult to be degraded and few microbes can take them as substrates, so they are considered as oligotrophic nutrient and have the potential to be used to produce value added products. In this study, the ability of Pestalotiopsis sp. J63 to use agricultural residues to produce laccases was tested in the submerged fermentation. The combination of 3 g·L^-1 maltose and 20 g·L^-1 rice straw was the best carbon sources and 8 g·L^-1 ammonium sulfate was the best nitrogen source under the condition without inducers. The effects of five inducers, the feeding time and concentration of inducer on laccase production were investigated. Adding 0.09 mmol·L^-1 phenol after 24 h of incubation led to high laccase activity (5089 U·L^-1), while with 0.09 mmol·L^-1 phenol in the medium and wheat bran as the nitrogen source, the laccase activity could reach 5791.7 U·L^-1. Native-PAGE results showed that two laccase isozymes were present in the cultures. One existed in both induced and non-induced culture filtrates, while the other was only found in the fermentation with the addition of phenol, guaiacol and veratryl alcohol.

Key words: laccase isozyme, Pestalotiopsis sp., marine microorganism, carbon and nitrogen source, inducer

摘要： Pestalotiopsis sp. J63, producing a high activity of laccase, is a new marine-derived fungus isolated from the oceanic sediment of the East China Sea. Since the marine environment is oligotrophic nutrient, marine derived fungi may use small amount of nutrients to grow and produce laccases. Agricultural residues that are mainly composed of lignin, cellulose and hemicellulose are difficult to be degraded and few microbes can take them as substrates, so they are considered as oligotrophic nutrient and have the potential to be used to produce value added products. In this study, the ability of Pestalotiopsis sp. J63 to use agricultural residues to produce laccases was tested in the submerged fermentation. The combination of 3 g·L^-1 maltose and 20 g·L^-1 rice straw was the best carbon sources and 8 g·L^-1 ammonium sulfate was the best nitrogen source under the condition without inducers. The effects of five inducers, the feeding time and concentration of inducer on laccase production were investigated. Adding 0.09 mmol·L^-1 phenol after 24 h of incubation led to high laccase activity (5089 U·L^-1), while with 0.09 mmol·L^-1 phenol in the medium and wheat bran as the nitrogen source, the laccase activity could reach 5791.7 U·L^-1. Native-PAGE results showed that two laccase isozymes were present in the cultures. One existed in both induced and non-induced culture filtrates, while the other was only found in the fermentation with the addition of phenol, guaiacol and veratryl alcohol.

关键词: laccase isozyme, Pestalotiopsis sp., marine microorganism, carbon and nitrogen source, inducer

FENG Xiaoyu, CHEN Huiying, XUE Dongsheng, YAO Shanjing. Enhancement of Laccase Activity by Marine-derived Deuteromycete Pestalotiopsis sp. J63 with Agricultural Residues and Inducers[J]. Chin.J.Chem.Eng., 2013, 21(10): 1182-1189.

冯晓雨, 陈慧英, 薛栋升, 姚善泾. Enhancement of Laccase Activity by Marine-derived Deuteromycete Pestalotiopsis sp. J63 with Agricultural Residues and Inducers[J]. Chinese Journal of Chemical Engineering, 2013, 21(10): 1182-1189.

References

1 Thurston, C.F., “The structure and function of fungal laccases”, Microbiol., 140, 19-26 (1994).

2 Kunamneni, A., Plou, F.J., Ballesteros, A., Alcalde, M., “Laccases and their applications: A patent review”, Recent Patents on Biotech., 2, 10-24 (2008).

3 Dwivedi, U.N., Singh, P., Pandey, V.P., Kumar, A., “Structure-function relationship among bacterial, fungal and plant laccases”, J. Mol. Catal. B: Enzym., 68, 117-128 (2011).

4 Harms, H., Schlosser, D., Wick, L.Y., “Untapped potential: Exploiting fungi in bioremediation of hazardous chemicals”, Nat. Rev. Microbiol., 9, 177-192 (2011).

5 Junghanns, C., Parra, R., Keshavarz, T., Schlosser, D., “Towards higher laccase activities produced by aquatic ascomycetous fungi through combination of elicitors and an alternative substrate”, Eng. Life Sci., 8, 277-285 (2008).

6 Gassara, F., Brar, S.K., Tyagi, R.D., Verma, M., Surampalli, R.Y., “Screening of agro-industrial wastes to produce ligninolytic enzymes by Phanerochaete chrysosporium”, Biochem. Eng. J., 49, 388-394 (2010).

7 Hao, J., Song, F., Huang, F., Yang, C., Zhang, Z., Zheng, Y., Tian, X., “Production of laccase by a newly isolated deuteromycete fungus Pestalotiopsis sp. and its decolorization of azo dye”, J. Ind. Microbiol. Biotech., 34, 233-240 (2007).

8 Saparrat, M.C.N., Hammer, E., “Decolorization of synthetic dyes by the deuteromycete Pestalotiopsis guepinii CLPS no. 786 strain”, J. Basic Microbiol., 46, 28-33 (2006).

9 Clemente, A.R., Anazawa, T.A., Durrant, L.R., “Biodegradation of polycyclic aromatic hydrocarbons by soil fungi”, Braz. J. Microbiol., 32, 255-261 (2001).

10 Kluczek-Turpeinen, B., Tuomela, M., Hatakka, A., Hofrichter, M., “Lignin degradation in a compost environment by the deuteromycete Paecilomyces inflatus”, Appl. Microbiol. Biotech., 61, 374-379 (2003).

11 Kluczek-Turpeinen, B., Steffen, K.T., Tuomela, M., Hatakka, A., Hofrichter, M., “Modification of humic acids by the compost-dwelling deuteromycete Paecilomyces inflatus”, Appl. Microbiol. Biotech., 66, 443-449 (2005).

12 Chen, H.Y., Feng, X.Y., Xue, D.S., Yao, S.J., “Screening and production of ligninolytic enzyme by a marine-derived fungal Pestalotiopsis sp. J63”, Appl. Biochem. Biotech., 165, 1754-1769 (2011).

13 Elisashvili, V., Kachlishvili, E., Tsiklauri, N., Metreveli, E., Khardziani, T., Agathos, S., “Lignocellulose-degrading enzyme production by white-rot Basidiomycetes isolated from the forests of Georgia”, World J. Microbiol. Biotech., 25, 331-339 (2009).

14 Mishra, A., Kumar, S., “Kinetic studies of laccase enzyme of Coriolus versicolor MTCC 138 in an inexpensive culture medium”, Biochem. Eng. J., 46, 252-256 (2009).

15 Barreto Xavier, A.M.R., Mora Tavares, A.P., Ferreira, R., Amado, F., “Trametes versicolor growth and laccase induction with by-products of pulp and paper industry”, Electron. J. Biotech., 10, 444-451 (2007).

16 Thygesen, A., Thomsen, A.B., Schmidt, A.S., Jorgensen, H., Ahring, B.K., Olsson, L., “Production of cellulose and hemicellulose-degrading enzymes by filamentous fungi cultivated on wet-oxidised wheat straw”, Enzyme Microbol. Tech., 32, 606-615 (2003).

17 Froehner, S.C., Eriksson, K.L., “Induction of Neurospora crassa laccase with protein synthesis inhibitors”, J. Bacteriol., 120, 450-457 (1974).

18 Barbosa, A.M., Dekker, R.F.H., St. Hardy, G.E., “Veratryl alcohol as an inducer of laccase by an ascomycete, Botryosphaeria sp., when screened on the polymeric dye Poly R-478”, Lett. Appl. Microbiol., 23, 93-96 (1996).

19 Cambria, M.T., Ragusa, S., Calabrese, V., Cambria, A., “Enhanced laccase production in white-rot fungus Rigidoporus lignosus by the addition of selected phenolic and aromatic compounds”, Appl. Biochem. Biotech., 163, 415-422 (2011).

20 Hou, H., Zhou, J., Wang, J., Du, C., Yan, B., “Enhancement of laccase production by Pleurotus ostreatus and its use for the decolorization of anthraquinone dye”, Process Biochem., 39, 1415-1419 (2004).

21 Pandey, A., “Recent process developments in solid-state fermentation”, Process Biochem., 27, 109-117 (1992).

22 Hartke, A., Giard, J.C., Laplace, J.M., Auffray, Y., “Survival of Enterococcus faecalis in an oligotrophic microcosm: changes in morphology, development of general stress resistance, and analysis of protein synthesis”, Appl. Environ. Microbiol., 64, 4238-4245 (1998).

23 Hatakka, A., “Lignin-modifying enzymes from selected white-rot fungi: production and role from in lignin degradation”, FEMS Microbiol. Reviews, 13, 125-135 (1994).

24 Niladevi, K.N., Prema, P., “Effect of inducers and process parameters on laccase production by Streptomyces psammoticus and its application in dye decolourization”, Bioresource Technol., 99, 4583-4589 (2008).

25 Terrón, M.C., González, T., Carbajo, J.M., Yagüe, S., Arana-Cuenca, A., Téllez, A., Dobson, A.D.W., González, A.E., “Structural close-related aromatic compounds have different effects on laccase activity and on lcc gene expression in the ligninolytic fungus Trametes sp. I-62”, Fungal Genet. Biol., 41, 954-962 (2004).

26 De Souza, C.G.M., Tychanowicz, G.K., De Souza, D.F., Peralta, R.M., “Production of laccase isoforms by Pleurotus pulmonarius in response to presence of phenolic and aromatic compounds”, J. Basic Microbol., 44, 129-136 (2004).

27 Schneider-Poetsch, T., Ju, J., Eyler, D.E., Dang, Y., Bhat, S., Merrick, W.C., Green, R., Shen, B., Liu, J.O., “Inhibition of eukaryotic translation elongation by cycloheximide and lactimidomycin”, Nat. Chem. Biol., 6, 209-217 (2010).

28 Kimura, M., Nambara, E., “Stored and neo-synthesized mRNA in Arabidopsis seeds: effects of cycloheximide and controlled deterioration treatment on the resumption of transcription during imbibition”, Plant Mol. Biol., 73, 119-129 (2010).

29 Gnanamani, A., Jayaprakashvel, M., Arulmani, M., Sadulla, S., “Effect of inducers and culturing processes on laccase synthesis in Phanerochaete chrysosporium NCIM 1197 and the constitutive expression of laccase isozymes”, Enzyme Microbol. Tech., 38, 1017-1021 (2006).

30 Lai, C., Li, S., Peng, L., Wang, J., “Progress of applications of laccase in organic synthesis”, Chem. Ind. Eng. Progr., 29, 1300-1308 (2010). (in Chinese)

31 Pazarlio?lu, N.K., Sarii?ik, M., Telefoncu, A., “Laccase: Production by Trametes versicolor and application to denim washing”, Process Biochem., 40, 1673-1678 (2005).

32 Jhadav, A., Vamsi, K.K., Khairnar, Y., Boraste, A., Gupta, N., Trivedi, S., Patil, P., Gupta, G., Gupta, M., Mujapara, A.K., Joshi, B., Mishra, D., “Optimization of production and partial purification of laccase by Phanerochaete chrysosporium using submerged fermentation”, Int. J. Microbiol. Res., 1, 9-12 (2009).

33 Jang, M.Y., Ryu, W.Y., Cho, M.H., “Enhanced production of laccase from Trametes sp. by combination of various inducers”, Biotech. Bioproc. Eng., 11, 96-99 (2006).

34 Revankar, M.S., Lele, S.S., “Enhanced production of laccase using a new isolate of white rot fungus WR-1”, Process Biochem., 41, 581-588 (2006).

35 Xavier, A.M.R.B., Tavares, A.P.M., Ferreira, R., Amado, F., “Trametes versicolor growth and laccase induction with by-products of pulp and paper industry”, Electron. J. Biotech., 10, 445-451 (2007).

36 Thiruchelvam, A.T., Ramsay, J.A., “Growth and laccase production kinetics of Trametes versicolor in a stirred tank reactor”, Appl. Microbiol. Biotech., 74, 547-554 (2007).

37 Muñoz, C., Guillén, F., Martínez, A.T., Martínez, M.J., “Induction and characterization of laccase in the ligninolytic fungus Pleurotus eryngii”, Curr. Microbiol., 34, 1-5 (1997).

38 Pointing, S.B., Jones, E.B.G., Vrijmoed, L.L.P., “Optimization of laccase production by Pycnoporus sanguineus in submerged liquid culture”, Mycologia, 92, 139-144 (2000).

39 Liu, Z., Zhang, D., Hua, Z., Li, J., Du, G., Chen, J., “A newly isolated Paecilomyces sp. WSH-L07 for laccase production: Isolation, identification, and production enhancement by complex inducement”, J. Ind. Microbiol. Biotech., 36, 1315-1321 (2009).

40 Quaratino, D., Ciaffi, M., Federici, E., D'Annibale, A., “Response surface methodology study of laccase production in Panus tigrinus liquid cultures”, Biochem. Eng. J., 39, 236-245 (2008).

41 Sigoillot, J.C., Herpoël, I., Frasse, P., Moukha, S., Lesage-Mcessen, L., Marcel, A., “Laccase production by a monokaryotic strain of Pycnoporus cinnabarinus derived from a dikaryotic strain”, World J. Microbiol. Biotech., 15, 481-484 (1999).

42 Halaburgi, V.M., Sharma, S., Sinha, M., Singh, T.P., Karegoudar, T.B., “Purification and characterization of a thermostable laccase from the ascomycetes Cladosporium cladosporioides and its applications”, Process Biochem., 46, 1146-1152 (2011).

43 Tavares, A.P.M., Coelho, M.A.Z., Coutinho, J.A.P., Xavier, A.M.R.B., “Laccase improvement in submerged cultivation: Induced production and kinetic modelling”, J. Chem. Technol. Biotech., 80, 669-676 (2005).

[1]	Xiaomei Guo, Zuchao Zhu, Baoling Cui, Yi Li. Effects of the short blade locations on the anti-cavitation performance of the splitter-bladed inducer and the pump [J]. Chin.J.Chem.Eng., 2015, 23(7): 1095-1101.
[2]	CHEN Huiying, WANG Mingxia, SHEN Yubin, YAO Shan-jing. Optimization of Two-species Whole-cell Immobilization System Constructed with Marine-derived Fungi and Its Biological Degradation Ability [J]. Chin.J.Chem.Eng., 2014, 22(2): 187-192.