Original Article

Acanthophysium sp. KMF001, a New Strain with High Cellulase Activity

Sae-Min YOON2, So-Hyun PARK2, Tea-Jong KIM2, Young-Kyoon KIM2, Yeong-Suk KIM2,
Author Information & Copyright
2Department of Forest Products and Biotechnology, Kookmin University, Seoul 02707, Republic of Korea
Corresponding author: Yeong-Suk KIM (e-mail: yskim@kookmin.ac.kr, ORCID: 0000-0002-0221-5764)

© The Korean Society of Wood Science & Technology.

Received: Sep 16, 2019; Accepted: Oct 31, 2019

Published Online: Nov 25, 2019

Abstract

Cellulase is an eco-friendly biocatalyst, and its demand is growing in many industrial applications such as food, textile, paper, and bioenergy. Strains with a high cellulase activities are the starting point for the economic production of cellulase. In a previous study, Acanthophysium sp. KMF001 with high cellulase production ability was selected among 54 wood-rotting fungi. In this study, we evaluated the cellulase productivity of Acanthophysium sp. KMF001 quantitatively and analyzed its taxonomic location using a genetic method. Acanthophysium sp. KMF001 showed high cellulase productivity similar to that of Acanthophysium bisporum and was much better than A. bisporum in specific enzyme activity. The 28S rRNA sequence of Acanthophysium sp. KMF001 was similar to that of Acanthophysium lividocaeruleum MB1825, with 98.40% homology. Phylogenetic analysis suggested that Acanthophysium sp. KMF001 is a new strain. In this study, we propose a new strain with high cellulase productivity.

Keywords: cellulase; Acanthophysium; new strain; 28S rRNA; phylogenetic

1. INTRODUCTION

Cellulose is a biopolymer made of glucose, and it is used as a structural biopolymer that is difficult to break down in ecosystems. Cellulase is a collective enzyme that converts cellulose to glucose with three kinds of cellulase: endo-β-1,4-glucanase (EG; EC 3.2.1.4), cellobiohydrolase (CBH; EC 3.2.1.74), and β-glucosidase (BGL; EC 3.2.1.21) (Goyal et al., 1991; Hong et al., 2001; Li et al., 2006; Kim et al., 2015a). For efficient cellulose degradation, EG, CBH, and BGL degrade cellulose enzymatically in sequence (Ali et al., 2013; Biswas et al., 2011; Gao et al., 2014; Haigler and Weimer, 1991; Howard et al., 2002; Schülein, 1988; Zhu et al., 2009). EG randomly hydrolyzes the amorphous regions of cellulose to produce oligosaccharides of various lengths. CBH hydrolyzes the end of cellulose oligosaccharide chains produced by EG and produces cellobiose units. Cellobioses produced by CBH are converted into two glucoses by BGL. The enzymatic efficiency of cellulose is enhanced by the activity and complementary action of enzymes of each type. Many studies showed that wood-rotting fungi degrade cellulose efficiently by the complementary action of cellulase. Therefore, many commercial cellulases are produced from wood-rotting fungi such as Trichoderma viride, Trichoderma koningii, Penicillium pinophilum, Sporotrichum pulverulentum, Fusarium solani, Aspergillus niger, Trichoderma reesei, and Penicillium funiculosum (Castellanos et al., 1995; Fang et al., 2010; Gao et al., 2008; Howard et al., 2002; Jamshidian et al., 2016; Leathers et al., 2015; Lee et al., 2010; Pandey et al., 2006; Smits et al., 1996; Sutivisedsak et al., 2013; Zhang et al., 2012).

Among fungi, T. reesei has already been studied and used extensively in the production of commercial enzymes (Goldbeck et al., 2013; Howard et al., 2002; Jørgensen et al., 2003; Kurabi et al., 2005). Trichoderma has been reported to be suitable for the production of industrial cellulase because its ability to produce extracellular enzymes is greater than that of bacteria (Rosgaard et al., 2006). T. reesei, however, cannot break down lignin (Howard et al., 2002) and the BGL of T. reesei is partially bound to the mycelium, so BGL is not efficiently recovered during enzyme production (Delabona et al., 2012). In the case of Schizophyllum, it was reported that the extracellular polysaccharide schizophyllan is produced during cellulase production (Esterbauer et al., 1991; Jamshidian et al., 2016; Leathers et al., 2015). Schizophyllan increased the viscosity of culture with cellulase production by forming a jelly-like structure. It is difficult to produce highly purified extracellular cellulase because of the high viscosity of enzyme solution by schizophyllan. In general, good microbial strains for economic enzyme production have a high enzymatic activity and a high specific activity without production of impurities in culture medium. In this study, we report Acanthophysium sp. KMF001, which produced cellulase with high activity and high specific activity.

Acanthophysium is a fungus in the Stereaceae family and Basidiomycota phylum and is known to be widespread in nature, but the ecological role of Acanthophysium is still unclear.

2. MATERIALS and METHODS

2.1. Strains used in this study

Acanthophysium sp. KMF001 (KCTC 18282P) was deposited at Korea Collection for Type Culture (Jeongeup-si, Korea). Acanthophysium bisporum (MUCL 32213), Acanthophysium cerussatum (MUCL 32645), and Acanthophysium lividocaeruleum (MUCL 33688) were purchased from the Belgian Co-ordinated Collections of Micro-organisms (Ottignies-Louvainla- Neuve, Belgium) as comparative strains for cellulase activity.

2.2. Culture conditions for the production of crude cellulase

Acanthophysium sp. KMF001 was activated on potato dextrose agar (catalog no. 7349834; BD Biosciences Korea, Seoul, Korea) plates at 30°C for 5 to 7 days. A. bisporum, A. cerussatum, and A. lividocaeruleum were activated on malt extract agar (20 g/L malt extract, 20 g/L glucose, 1 g/L peptone, and 20 g/L agar) plates at 25°C for 5 to 7 days.

The activated Acanthophysium sp. KMF001 was inoculated in 100 mL of potato dextrose broth (catalog no. 8129687; BD Biosciences Korea) and incubated at 30°C for 5 days under the shaking condition at 150 rpm to make a pre-culture. For A. bisporum, A. cerussatum, and A. lividocaeruleum, the activated cells were inoculated in 50 mL of malt extract broth (catalog no. 218630; BD Biosciences Korea) and incubated at 25°C for 5 days under the shaking condition at 150 rpm to make a pre-culture.

In the main culture, all four strains were inoculated with 5% (v/v) pre-culture in 200 mL modified TYE medium with cellulose [7 g/L tryptone, 3 g/L yeast extract, 5 g/L K2HPO4, 5 g/L KH2PO4, 3 g/L MgSO4·7H2O, and 20 g/L cellulose (20–100 mm; catalog no.25384405; Daejung, Seoul, Korea) at pH 6.0] in a 1 L baffled flask and incubated for 3 weeks under the shaking condition at 150 rpm at 30°C for Acanthophysium sp. KMF001 and at 25°C for A. bisporum, A. cerussatum, and A. lividocaeruleum.

2.3. Cellulase production

The crude supernatant from each culture was collected, cells were removed by filtration using Whatman filter paper No. 1 (catalog no. 1001-110; GE Healthcare Life Sciences, Seoul, Korea). The cell free supernatant of each was analyzed on the cellulase activity.

2.4. Measuring enzymatic activity of cellulase

For the EG activity assay, 5 μL of crude enzyme solution was mixed with 45 μL of substrate solution made with 2% (w/v) carboxylmethylcellulose sodium salt (catalog no. MKBW6753V; Sigma-Aldrich Korea LLC, Yongin, Korea) in 0.1 M sodium citrate buffer at pH 4.5. The mixture was incubated at 50°C for 30 minutes. The reaction was stopped by adding 50 μL of copper solution and heating at 100°C for 10 minutes. The amount of produced reducing end by EG was measured using the Somogyi–Nelson method (Nelson, 1944). One unit of EG was defined as the amount of enzyme producing 1 μmol glucose for 30 minutes under the described reaction condition.

For the CBH activity assay, 100 μL of crude enzyme solution was mixed with 100 μL of 10 mM p-nitrophenyl- β-D-cellobioside (catalog no. 077M4023V; Sigma-Aldrich Korea LLC) and 800 μL of 0.1 M sodium citrate buffer at pH 4.5. The mixture was incubated at 50°C for 15 minutes. The reaction was stopped by adding 100 μL of 2 M Na2CO3. The amount of produced p-nitrophenol by CBH was measured at 405 nm using a Opsys MR microplate reader (Hynex Technologies, Chantilly, VA, USA). One unit of CBH was defined as the amount of enzyme producing 1 μmol p-nitrophenol for 15 minutes under the described reaction condition.

For the BGL activity assay, all measuring procedure was similar with the above CBH activity assay with switching the substrate to 10 mM p-nitrophenyl-β-D-glycopyranoside (catalog no. BCBP2339V; Sigma-Aldrich Korea LLC). Enzymatic activity was defined as the enzyme activity of the crude solution based on the volume and expressed in U/mL.

2.5. Measuring specific activity of cellulase

To calculate a specific activity of each cellulase, the protein concentration was measured using the Bradford’s methods with bovine serum albumin as a standard (Bradford, 1976). Enzyme with 400 μL and protein assay reagent with 100 μL (Bio-Rad Laboratories, Inc., Hercules, CA, USA) were mixed violently in tubes for 10 seconds. The absorbance was measured at 595 nm after 5-minute incubation in room temperature. The specific activity of enzymes was defined as the cellulase activity per milligram of total protein and expressed in U/mg.

2.6. Genetic analysis of Acanthophysium sp. KMF001

Cells of Acanthophysium sp. KMF001 from the main culture were disrupted with TissueLyser LT (Qiagen Korea Ltd., Seoul, Korea), and the genomic DNA was purified using the DNeasy Plant Mini kit (Qiagen Korea Ltd.). The internal transcribed spacer region of 28S rRNA was amplified using polymerase chain reaction (PCR) with two primers: ITS4 (5′-TCCTCCGCTTATTGATATGC-3′) and ITS5 (5′-GGAAGTAAAAGTCGTAACAAGG-3′). The PCR condition with 35 cycles was 95°C for 20 seconds for denaturation, 55°C for 4 seconds for annealing, and 72°C for 60 seconds for extension. The amplified DNA was sequenced by Biofact Co., Ltd. (Daejeon, Korea). The analyzed sequence was registered at GenBank at the National Center for Biotechnology Information (NCBI; https://www.ncbi.nlm.nih.gov/) under MM680758.

The homologous sequences in the nucleotide database were identified using Nucleotide BLAST (https://blast.ncbi.nlm.nih.gov/Blast.cgi). They were aligned, and phylogenetic trees were analyzed using MEGA4 software (Tamura et al., 2007). The corresponding ribosomal DNA region of each strain was used for making phylogenetic trees with the distance methods based on the similarity.

3. RESULTS and DISCUSSION

3.1. Cellulase activity of Acanthophysium spp.

Acanthophysium sp. KMF001 was selected among 54 wood-rotting fungi based on the cellulase activity (Kim et al., 2015b). To evaluate the cellulase activity of Acanthophysium sp. KMF001, we purchased three Acanthophysium strains, namely, A. bisporum, A. cerussatum, and A. lividocaeruleum, and the cellulase activities of all four strains, including Acanthophysium sp. KMF001, were analyzed (Fig. 1). Cellulase production was analyzed on the basis of culture medium volume (Fig. 1A, 1C, and 1E) and protein weight for the specific activity (Fig 1B, 1D, and 1F). As shown in Fig. 1, A. cerussatum and A. lividocaeruleum showed low enzymatic and specific activity of cellulase, and Acanthophysium sp. KMF001 and A. bisporum showed strong cellulase activity among the four tested strains.

wood-47-6-751_F1
Fig. 1. Cellulase activity of four strains: Acanthophysium sp. KMF001 (■), A. bisporum (♦), A. cerussatum (▲), and A. lividocaeruleum (●). (A and B) EG activity, (C and D) CBH activity, and (E and F) BGL activity. (A, C, and E) Enzymatic activity in the crude solution based on the culture volume and (B, D, and F) specific activity of the enzyme based on the protein weight. The values are the average of three replicates. The standard deviations are shown.
Download Original Figure

The EG activity of Acanthophysium sp. KMF001 showed the highest enzymatic activity at 94.54 U/mL on 15 days of cultivation and similar enzyme activity until 21 day. On the other hand, EG enzyme activity of A. bisporum showed a similar level of EG activity to Acanthophysium sp. KMF001 at 15 days of cultivation, but the enzyme activity decreased with further incubation time after that (Fig. 1A). However, the specific activities of EG in Acanthophysium sp. KMF001 and A. bisporum showed 245 U/mg and 165 U/mg, respectively, at the 15 days of cultivation (Fig. 1B). These results indicated that the enzyme productivity per unit volume of the culture was similar in both strains, but the cellulase content based in the protein released to the outside of the cell in Acanthophysium sp. KMF001 was 1.5 times higher than that in A. bisporum. The other two cellulase enzyme activities, namely, CBH (Fig. 1D) and BGL (Fig. 1F), showed similar differences in specific enzyme activities. The production of such high-purity cellulase is advantageous for enzyme production and application.

The CBH activities on the 15th day of cultivation with Acanthophysium sp. KMF001 and A. bisporum showed 6.83 U/mL and 7.19 U/mL, respectively (Fig. 1C). The BGL activities on the 18th day of cultivation in Acanthophysium sp. KMF001 and A. bisporum showed 63.20 U/mL and 57.46 U/mL, respectively (Fig. 1E). The specific activity of CBH and BGL in Acanthophysium sp. KMF001 was higher, with 17% and 28% more, respectively, than those in A. bisporum (Fig. 1D and 1F, respectively). In particular, on the 15th day of cultivation, the specific CBH activity in Acanthophysium sp. KMF001 was about double of that in A. bisporum (Fig. 1D), and the specific BGL activity in Acanthophysium sp. KMF001 on the 12th day of cultivation was also about double of that in A. bisporum (Fig. 1F). In the case of Acanthophysium sp. KMF001, the decrease in CBH activity was moderate after the 15th day of cultivation, but the CBH activity of A. bisporum rapidly decreased during the same incubation time.

On the basis of the above results, all enzymatic cellulase activities of Acanthophysium sp. KMF001 were similar to that of A. bisporum, but the specific activity of Acanthophysium sp. KMF001 showed significantly higher levels of all tested enzyme activities than A. bisporum. This observation suggested that Acanthophysium sp. KMF001 was better than the others in Acanthophysium spp. tested in this study for high cellulase production. In a previous study, the CBH and BGL activities of Acanthophysium sp. KMF001 were higher than it of Trichoderma reesei, Fomitopsis palustris, and Aspergillus niger (Kim et al., 2015b). Considering the enzyme activities in the culture solution and specific activities in this study, the 15th day of cultivation is ideal for cellulase production of Acanthophysium sp. KMF001. In a previous study, the crude cellulase of Acanthophysium sp. KMF001 improved the quality of fabric effectively (Shin et al., 2016). In addition to effective cellulase production, Acanthophysium sp. KMF001 produced a novel endo-β -1,4-xylanase, which was an enzyme for hemicellulose degradation (Yoon et al., 2018). All studies suggested that Acanthophysium sp. KMF001 was a good enzyme-producing fungus for decaying wood.

3.2. Genetic identification of Acanthophysium sp. KMF001

To identify Acanthophysium sp. KMF001 genetically, the genetic information of its 28S rRNA was analyzed (Fig. 2). The results of the BLAST search with the 28S rRNA nucleotide sequence of Acanthophysium sp. KMF001 using the NCBI nucleotide database are shown in Table 1. The most homologous strain was A. lividocaeruleum MB1825, with 98.40% identity. The next most homologous strains were Acanthophysellum lividocoeruleum, with 98.24% identity, and additional six strains with 97.92% identity (Table 1). Using phylogenetic analysis with strains in Table 1, the taxonomic position of Acanthophysium sp. KMF001 was analyzed in Fig. 3. The phylogenetic tree analysis revealed that Acanthophysium sp. KMF001 separated into different phylogenetic branches from A. lividocaeruleum MB1825, the most similar strain with 99% identity by Nucleotide BLAST search. Although Acanthophysium sp. KMF001 was similar to the previously reported A. lividocaeruleum MB1825 with an identity of 98.40%, the phylogenetic analysis suggested that Acanthophysium sp. KMF001 might be a new strain.

wood-47-6-751_F2
Fig. 2. Base sequence of 28S rRNA in Acanthophysium sp. KMF001. This sequence was registered at GenBank at the NCBI under MM680758.
Download Original Figure
Table 1. Homology search by the NCBI, Acanthophysium sp. KMF001
Accession number Description Query coverage (%) Expect value Identity (%)
AY039314 A. lividocaeruleum MB1825 100 0.0 98.40
AF506400 A. lividocoeruleum 100 0.0 98.24
MH877876 Xylobolus subpileatus CBS 126032 100 0.0 97.92
MH866478 Xylobolus frustulatus CBS 271.28 100 0.0 97.92
KX066002 X. subpileatus FP102567 100 0.0 97.92
AF506491 X. frustulatus KGN980928 100 0.0 97.92
AY039319 A. lividocaeruleum FP100292 100 0.0 97.92
AY039307 X. frustulatus FP106073 100 0.0 97.92
MH867100 X. subpileatus CBS 415.34 100 0.0 97.76
AY039309 X. subpileatus FP106735 99 0.0 97.91
AB733325 Stereum hirsutum NBRC 6520 100 0.0 97.60
AY039310 A. cerussatum HHB11294 100 0.0 97.60
AF042563 Unidentified basidiomycete 100 0.0 97.60
AY293189 Hypsizygus tessulatus 100 0.0 97.60
Download Excel Table
wood-47-6-751_F3
Fig. 3. Phylogenetic trees of Acanthophysium sp. KMF001 with other related fungal species.
Download Original Figure

4. CONCLUSION

Comparison of the enzyme activity with other strains of Acanthophysium genus showed that Acanthophysium sp. KMF001 had similar levels of cellulase activity with A. bisporum in all three types, namely, EG, CBH, and BGL, but the specific enzyme activity of Acanthophysium sp. KMF001 was higher than cellulase from other tested Acanthophysium strains. Although Acanthophysium sp. KMF001 showed 98.40% nucleotide identity with the most homologous strain, the phylogenetic tree suggested that Acanthophysium sp. KMF001 is a new strain by separating into a different phylogenetic branch from the most homologous strain. This study suggested that Acanthophysium sp. KMF001 is a novel bacterium that produces an effective cellulase for the wood decay.

ACKNOWLEDGMENT

This study was carried out with the support of the “R&D Program for Forest Science Technology (Project No. 2013070E10-1819-AA03)” provided by the Korea Forest Service (Korea Forestry Promotion Institute).

References

1.

Ali S.R., Muthuvelayudham R., Viruthagiri T. Enhanced production of cellulase from tapioca stem using response surface methodology. Innovative Romanian Food Biotechnology. 2013; 12(March):40-51.

2.

Biswas A.K., Umeki K., Yang W., Blasiak W. Change of pyrolysis characteristics and structure of woody biomass due to steam explosion pretreatment. Fuel Processing Technology. 2011; 92(10):1849-1854.

3.

Bradford M.M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry. 1976; 72(1-2):248-254.

4.

Castellanos O.F., Sinitsyn A.P., Vlasenko E.Y. Comparative evaluation of hydrolytic efficiency toward microcrystalline cellulose of Penicillium and Trichoderma cellulases. Bioresource Technology. 1995; 52(2):119-124.

5.

Delabona P.S., Farinas C.S., da Silva M.R., Azzoni S.F., Pradella J.G.d.C. Use of a new Trichoderma harzianum strain isolated from the Amazon rainforest with pretreated sugar cane bagasse for on-site cellulase production. Bioresource Technology. 2012; 107:517-521.

6.

Esterbauer H., Steiner W., Labudova I., Hermann A., Hayn M. Production of Trichoderma cellulase in laboratory and pilot scale. Bioresource Technology. 1991; 36(1):51-65.

7.

Fang H., Zhao C., Song X-Y. Optimization of enzymatic hydrolysis of steam-exploded corn stover by two approaches: Response surface methodology or using cellulase from mixed cultures of Trichoderma reeseiRUT-C30 and Aspergillus niger NL02. Bioresource Technology. 2010; 101(11):4111-4119.

8.

Gao D., Haarmeyer C., Balan V., Whitehead T.A., Dale B.E., Chundawat S.P.S. Lignin triggers irreversible cellulase loss during pretreated lignocellulosic biomass saccharification. Biotechnology for Biofuels. 2014; 7(1):175.

9.

Gao J., Weng H., Zhu D., Yuan M., Guan F., Xi Y. Production and characterization of cellulolytic enzymes from the thermoacidophilic fungal Aspergillus terreus M11 under solid-state cultivation of corn stover. Bioresource Technology. 2008; 99(16):7623-7629.

10.

Goldbeck R., Ramos M.M., Pereira G.A.G. Cellulase production from a new strain Acremonium strictumisolated from the Brazilian biome using different substrates. Bioresource Technology. 2013; 128:797-803.

11.

Goyal A., Ghosh B., Eveleigh D. Characteristics of fungal cellulases. Bioresource Technology. 1991; 36(1):37-50.

12.

Haigler C.H., Weimer P.J. Biosynthesis and biodegradation of cellulose. 1991 New York: Marcel Dekker. .

13.

Hong J., Tamaki H., Akiba S., Yamamoto K., Kumagai H. Cloning of a gene encoding a highly stable endo-â-1, 4-glucanase from Aspergillus nigerand its expression in yeast. Journal of Bioscience and Bioengineering. 2001; 92(5):434-441.

14.

Howard R., Abotsi E., Jansen van Rensburg E. Lignocellulose biotechnology: Issues of bioconversion and enzyme production. African Journal of Biotechnology. 2002; 2(12):602-619.

15.

Jørgensen H., Eriksson T., Börjesson J., Tjerneld F., Olsson L. Purification and characterization of five cellulases and one xylanase from Penicillium brasilianum IBT 20888. Enzyme and Microbial Technology. 2003; 32(7):851-861.

16.

Jamshidian H., Shojaosadati S.A., Vilaplana F., Mousavi S.M., Soudi M.R. Characterization and optimization of schizophyllan production from date syrup. International Journal of Biological Macromolecules. 2016; 92:484-493.

17.

Kim J.Y., Yoon S.M., Kim Y.S. Cellulase Activity of Symbiotic Bacteria from Snails, Achatina fulica. Journal of the Korean Wood Science and Technology. 2015a; 43(5):628-640.

18.

Kim Y.S., Kim T.J., Shin K., Yoon S.M. Novel Acanthophysiumsp. KMF001 having high cellulase activity. US patent Application number: 14/930585. 2015b.

19.

Kurabi A., Berlin A., Gilkes N., Kilburn D., Bura R., Robinson J., Markov A., Skomarovsky A., Gusakov A., Okunev O., Sinitsyn A., Gregg D., Xie D., Saddler J. Enzymatic hydrolysis of steam-exploded and ethanol organosolv-pretreated douglas-fir by novel and commercial fungal cellulases. Applied Biochemistry and Biotechnology. 2005; 121(1):219-230.

20.

Leathers T.D., Sutivisedsak N., Nunnally M.S., Price N.P.J., Stanley A.M. Enzymatic modification of schizophyllan. Biotechnology Letters. 2015; 37(3):673-678.

21.

Lee B-H., Kim B-K., Lee Y-J., Chung C-H., Lee J-W. Industrial scale of optimization for the production of carboxymethylcellulase from rice bran by a marine bacterium, Bacillus subtilis subsp. subtilis A-53. Enzyme and Microbial Technology. 2010; 46(1):38-42.

22.

Li Y-H., Ding M., Wang J., Xu G-j., Zhao F. A novel thermoacidophilic endoglucanase, Ba- EGA, from a new cellulose-degrading bacterium, Bacillus sp. AC-1. Applied Microbiology and Biotechnology. 2006; 70(4):430-436.

23.

Nelson N. A photometric adaptation of the Somogyi method for the determination of glucose. Journal of Biological Chemistry. 1944; 153(2):375-380.

24.

Pandey A., Webb C., FERNANDES M., Larroche C. Enzyme Technology. 2006 New York: Springer-Verlag New York Inc. .

25.

Rosgaard L., Pedersen S., Cherry J.R., Harris P., Meyer A.S. Efficiency of new fungal cellulase systems in boosting enzymatic degradation of barley straw lignocellulose. Biotechnology Progress. 2006; 22(2):493-498.

26.

Schülein M. Cellulases of Trichoderma reesei. Methods in Enzymology. 1988; 160Academic Press. p. 234-242.

27.

Shin K., Yoon S-M., Kim J.H., Kim Y-K., Kim T-J., Kim Y-S. Biopolishing of cotton fabric using crude cellulases from Acanthophysium sp. KMF001. Journal of the Korean Wood Science and Technology. 2016; 44(3):381-388.

28.

Smits J.P., Rinzema A., Tramper J., Sonsbeek H.M.V., Knol W. Solid-state fermentation of wheat bran by Trichoderma reesei QM9414: substrate composition changes, C balance, enzyme production, growth and kinetics. Applied Microbiology and Biotechnology. 1996; 46(5):489-496.

29.

Sutivisedsak N., Leathers T.D., Bischoff K.M., Nunnally M.S., Peterson S.W. Novel sources of â-glucanase for the enzymatic degradation of schizophyllan. Enzyme and Microbial Technology. 2013; 52(3):203-210.

30.

Tamura K., Dudley J., Nei M., Kumar S. MEGA4: molecular evolutionary genetics analysis (MEGA) software version 4.0. Molecular Biology and Evolution. 2007; 24(8):1596-1599.

31.

Yoon S-M., Kim Y-S., Kim Y-K., Kim T-J. A novel endo-â-1,4-xylanase from Acanthophysium sp. KMF001, a wood rotting fungus. Journal of the Korean Wood Science and Technology. 2018; 46(6):670-680.

32.

Zhang H., Sang Q., Zhang W. Statistical optimization of cellulases production by Aspergillus nigerHQ-1 in solid-state fermentation and partial enzymatic characterization of cellulases on hydrolyzing chitosan. Annals of Microbiology. 2012; 62(2):629-645.

33.

Zhu J.Y., Pan X.J., Wang G.S., Gleisner R. Sulfite pretreatment (SPORL) for robust enzymatic saccharification of spruce and red pine. Bioresource Technology. 2009; 100(8):2411-2418.