Abstract
The fungus Phellinus is a mushroom that is widely used medicinally. The optimal conditions for mycelial growth of 13 strains of the fungus were investigated. Mycelial growth was optimal at 25℃ and was uniformly minimal at 15℃ and 35℃. Growth was optimal at pH 6~7. The mycelial phenotype was best promoted by growth using Potato Dextrose agar, Hamada, Glucose peptone, and Yeast-Malt media, whereas Czapek Dox, Hennerberg, and Lilly media were the most unfavorable for the mycelial growth of Phellinus spp. Glucose, sucrose, fructose, and dextrin were the most suitable carbon sources for mycelial growth, while lactose, maltose, and galactose were unsuitable. Among tested nitrogen sources, ammonium phosphate, potassium nitrate, and arginine best promoted mycelial growth, while alanine, urea, and histidine least promoted mycelial growth.
Keywords: Favourable condition, Filamentous growth, Phellinus spp., Supplemented nutrition
The genus Phellinus is a medicinal mushroom that is widely used in Korea, Japan and China. Typically, it grows naturally on dead mulberry trees. P. linteus, which is commonly known as song-gen in China, sang-hwang in Korea, and meshimakobu in Japan, exhibits anti-tumor properties on skin, lung, and prostate cells (Han et al., 1999; Park et al., 2003; Li et al., 2004). Phellinus is also used a traditional Kampo medicine for the treatment of diarrhea. The major compounds of the therapeutic preparations are polysaccharides, aminoacids, ã-aminobutyric acid, vitamins, and sugar. Polysaccharides and proteoglycan isolated from fruiting body of P. linteus are cytotoxic to tumor cells (Kim et al., 2004) and induce functional maturation of murine dendritic cells (Park et al., 2003). The aqueous extract of P. linteus inhibits immunoglobulin E-dependent mouse triphasic cutaneous reactions (Inagaki et al., 2005), and stimulates antibody production (Song et al., 1995) by an as yet unknown mechanism.
Immunodeficiency caused by anti-tumor drugs such as mitomycin C poses a serious problem for cancer patients. Mitomycin C has strong anti-tumor activity but also restricts bone marrow activity (Ohtake et al., 2000). In this case, the fungal water extract plays an important role in promoting immune activity (Edwards et al., 1984). Since Phellinus spp. are widely used medicinally, scaling-up of the commercial production of the fungus would be advantageous for its dessiminated use in cancer therapy. To this end, the present study sought to clarify cultural parameters that promote mycelial growth of Korean and foreign isolates of Phellinus spp.
Materials and Methods
Fungal strains
The mycelial cultures of 13 strains of Phellinus spp. were obtained from the Culture Collection and DNA Bank of Mushrooms (CCDBM) in the Department of Biology, University of Incheon, Korea (Table 1). The strains were transferred to Potato Dextrose agar (PDA) plates and incubated at 25℃ in the dark until they showed a full growth, after which they were maintained at 4℃. Unless otherwise stated, all experiments were done a minimum of four times.
Table 1.
Phellinus spp. used in this study
Effects of temperature and pH on vegetative growth
To ascertain the optimum temperature for mycelial growth, temperatures of 15℃, 20℃, 25℃, 30℃, and 35℃ were used. A 5 mm diameter agar plug removed from 10-day-old PDA cultures was placed in the centre of a Petri dish containing 20 ml of solidified PDA. The medium was adjusted to pH 6 and incubated for 10 days at the selected temperature. Radial growth of mycelia on each Petri dish was measured in three horizontal directions and the average value was calculated. To calculate the final mean value of mycelial growth of each strain, four replications were used. To assess the influence of pH, a plug similarly recovered from PDA was placed on fresh PDA. The medium was adjusted to pH 4, 5, 6, 7, 8, or 9 with the addition of 1 N NaOH or HCl, and incubated for 10 days at 25℃. The measurement of mycelial growth was ascertained as just described.
Effects of culture media on the vegetative growth
Nine different agar culture media (Czapek Dox, Hamada, Hennerberg, Glucose peptone, Glucose tryptone, Lilly, Mushroom complete, PDA, and Yeast Malt extract (YM)) were prepared (Table 2). The media were adjusted to pH 6 before autoclave sterilization. All media were similarly inoculated as described above. After 10 days of incubation at 25℃, measurement of mycelial growth was performed as described above.
Table 2.
Composition of growth media
Cza: Czapek Dox, Ham: Hamada, Hen: Hennerberg, GP: Glucose peptone, GT: Glucose tryptone, Lil: Lilly, MC: Mushroom complete, PDA: Potato dextrose agar and YM: Yeast-malt extract agar.
Effects of carbon and nitrogen sources on the vegetative growth
Basal medium (0.05 g MgSO4, 0.46 g KH2PO4, 1.0 g K2HPO4, 120 µg thiamine-HCl, and 20 g agar in 1 l of distilled water; Sung et al., 1993) was separately supplemented with 10 carbon sources (dextrin, fructose, galactose, glucose, lactose, maltose, mannose, sorbitol, sucrose, and xylose) or 10 nitrogen sources (alanine, ammonium acetate, ammonium phosphate, arginine, calcium nitrate, glycine, histidine, methionine, potassium nitrate, or urea). To screen for the carbon source most favorable for mycelial growth, each carbon source with 5 g of peptone was added to the basal medium separately at a concentration of 0.1M and mixed thoroughly (Shim et al., 1997). Each nitrogen source with 20 g of glucose was supplemented to the basal medium at a concentration of 0.02 M. In both cases, the basal medium was adjusted to pH 6 before autoclaving. To measure the colony diameter on the media, all plates were incubated for 10 days at 25℃. Radial growth of mycelia was measured as described above.
Results and Discussion
Effects of temperature on the vegetative growth
Of the tested temperatures, 25℃ generally proved optimal for mycelial growth of the 13 isolates of Phellinus spp. Mycelial growth of isolates IUM3155 and IUM3169 was highest at 20℃, while 30℃ was best for isolate IUM3159. Mycelial growth was poorest at 15℃ or 35℃. In almost every case, mycelial growth was measured at 20℃ and 30℃ (Table 3). The optimal temperature of 25℃ differs from the 30℃ optimum previously reported for P. linteus (Hur, 2008). The dichotomy may be due to the different isolates used in the previous and present studies.
Table 3.
Effect of temperature on mycelial growth of tested Phellinus spp.
Temperature effect was assessed using PDA.
Effects of pH on vegetative growth
Among the 13 tested strains, the best mycelial growth was found at pH 7 for IUM 3153, IUM 3155, IUM 3156, IUM 3159, and IUM 3163; at pH 6 for IUM 3149, IUM 3150, IUM 3161, and IUM 3164; at pH 5 for IUM 3151 and IUM 3169; and at pH 4 for IUM 3157 and IUM 3158. A pH exceeding 7 did not support robust mycelial growth, with the poorest mycelial development being evident at pH 8 and 9 (Table 4). Other studies have reported that pH 6 is optimal for mycelial growth of P. linteus (Chi et al., 1996; Hur 2008). These and the present results indicate that Phellinus spp. including P. linteus optimally produce mycelia at neutral or acidic pHs.
Table 4.
Effect of pH on mycelial growth of tested Phellinus spp.
Effect of pH was assessed using PDA.
Effects of various media on the vegetative growth
Of the 13 tested strains, mycelial growth was greatest when cultivated on PDA (n = 6), Hamada (n = 4), and Glucose peptone (n = 2), with strain IUM3153 responding best to growth on YM (Table 5). For all strains, the lowest growth of the filamentous rim was measured following growth on Czapek Dox, Lilly, and Hennerberg (Table 5). These results differ from the previous finding that Mushroom Complete medium supports excellent mycelial growth of P. linteus (Hur, 2008). In case of Hericium erinaceus, the highest filamentous growth was observed in PDA, YM, Hamada, and Glucose peptone, with mycelial growth being poorest during growth on Czapek Dox, Hoppkins, Lilly, and Hennerberg (Imtiaj et al., 2008).
Table 5.
Effect of media on mycelial growth of tested Phellinus spp.
aCza: Czapek Dox, Ham: Hamada, Hen: Hennerberg, GP: Glucose peptone, GT: Glucose tryptone, Lil: Lilly, MC: Mushroom complete, PDA: Potato dextrose agar and YM: Yeast-malt extract agar.
Effects of carbon sources on the vegetative growth
While the results were varied for the tested strains, in general, glucose, fructose, sucrose, and dextrose were comparatively better than the other carbon sources used (Table 6). Lactose, maltose, and galactose were less effective in the enhancement of mycelial growth (Table 6). With exception of mannose, the present results agree with those of Hur (2008).
Table 6.
Effect of carbon sources on mycelial growth of tested Phellinus spp.
aDex: Dextrin, Fr: Fructose, Ga: Galactose, Gl: Glucose, Lac: Lactose, Mal: Maltose, Man: Mannose, Sor: Sorbitol, Suc: Sucrose and Xy: Xylose. Each carbon source was added to the basal medium at the concentration of 0.1M.
Effects of nitrogen sources on the vegetative growth
Ten of the 13 strains showed optimal mycelial growth when the nitrogen source was ammonium phosphate, potassium nitrate, or arginine. However, the other nitrogen sources also facilitated considerable mycelial growth of Phellinus spp. Comparatively, alanine, urea, and histidine produced the poorest mycelial growth (Table 7). Glycine is the most favorable and histidine, arginine and ammonium oxalate are the most unfavorable nitrogen sources for the mycelial growth of Macrolepiota procera (Shim et al., 2005), while potassium nitrate and sodium nitrate support the highest mycelial growth of P. linteus (Hur, 2008). Therefore, it is concluded that most of the nitrogen sources used in this experiment except alanine, urea, and histidine are suitable for the vegetative growth of the Phellinus spp.
Table 7.
Effect of nitrogen sources on mycelial growth of tested Phellinus spp.
aAla: Alanine, AA: Ammonium acetate, AP: Ammonium phosphate, Arg: Arginine, Gly: Glycine, His: Histidine, Met: Methionine, PN: Potassium nitrate and Ur: Urea. Each nitrogen source was added to the basal medium at the concentration of 0.02M.
Outlook
Future studies need to examine the dichotomies between the present and previous observations, with the aim of best characterizing the cultural conditions that will support the large-scale production of mycelia. Furthermore, the micro-scale procedures employed to date will need to be scaled up. For the present, however, this study advances our knowledge of the cultural conditions that promote growth and mycelium production by Phellinus spp.
Acknowledgement
This study was supported by an International Cooperative Research Grant (No. C00004) from Korean Research Foundation, Ministry of Education, Science and Technology.
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