Production of mycelial biomass by the Amazonian edible mushroom <i>Pleurotus albidus</i>

Kirsch, Larissa de Souza; Macedo, Ana Júlia Porto de; Teixeira, Maria Francisca Simas

doi:10.1016/j.bjm.2016.04.007

ABSTRACT

Edible mushroom species are considered as an adequate source of food in a healthy diet due to high content of protein, fiber, vitamins, and a variety of minerals. The representatives of Pleurotus genus are characterized by distinct gastronomic, nutritional, and medicinal properties among the edible mushrooms commercialized worldwide. In the present study, the growth of mycelial biomass of Pleurotus albidus cultivated in submerged fermentation was evaluated. Saccharose, fructose, and maltose were the three main carbon sources for mycelial biomass formation with corresponding yields of 7.28 g L⁻¹, 7.07 g L⁻¹, and 6.99 g L⁻¹. Inorganic nitrogen sources did not stimulate growth and the optimal yield was significantly higher with yeast extract (7.98 g L⁻¹). The factorial design used to evaluate the influence of saccharose and yeast extract concentration, agitation speed, and initial pH indicated that all variables significantly influenced the production of biomass, especially the concentration of saccharose. The greater amount of saccharose resulted in the production of significantly more biomass. The highest mycelial biomass production (9.81 g L⁻¹) was reached in the medium formulated with 30.0 g L⁻¹ saccharose, 2.5 g L⁻¹ yeast extract, pH 7.0, and a speed of agitation at 180 rpm. Furthermore, P. albidus manifested different aspects of morphology and physiology under the growth conditions employed. Media composition affected mycelial biomass production indicating that the diversification of carbon sources promoted its improvement and can be used as food or supplement.

Keywords:
Pleurotus albidus; Submerged fermentation; Mycelial biomass; Factorial design

Introduction

Pleurotus albidus (Berk.) is a species that occurs in Mexico, Argentina, and Brazil. It is glabrous, white to cream colored and presents infundibuliform and circular pileus, deeply decurrent lamella, stipe fluted upward through lamellar bases, tapering downward, usually curved-ascendant, dull white and occasionally with hairs at the base.¹1 Lechner BE, Wright JE, Albertó E. The genus Pleurotus in Argentina. Mycologia. 2004;96:845-858.

2 Moreno-Fuentes A, Bautista-Nava E. El “hongo blanco patón” Pleurotus albidus, en Hidalgo. Su primer registro em México. Rev Mex Micol. 2006;22:41-47.^-³3 Lechner BE, Albertó E. Search for new naturally occurring strains of Pleurotus to improve yields. Pleurotus albidus as a novel proposed species for mushroom production. Rev Iberoam Mycol. 2011;28:148-154. The Pleurotus species, commonly known as oyster mushrooms, have gastronomic, nutritional, and medicinal properties and are grown in the temperate and tropical rainforests. Nowadays, seventy species of this genus are reported, but only few of them are commercialized, including P. ostreatus, P. florida, P. sajor-caju, and P. eryngii.⁴4 Maftoun P, Johari H, Soltani M, Malik R, Othman NZ, El Enshasy HA. The edible mushroom Pleurotus spp.: I. Biodiversity and nutritional values. Int J Biotechnol Wellness Ind. 2015;4:67-83.

It has long been known that mushrooms develop biomass through degrading cellulose and lignin by the action of specific enzymes under optimal conditions.⁵5 Tang YJ, Zhu LW, Li HM, Li DS. Submerged culture of mushrooms in bioreactors - challenges, current state-of-the-art, and future prospects. Food Technol Biotechnol. 2007;45:221-229.^,⁶6 Heleno SA, Ferreira RC, Antonio AL, Queiroz MJRP, Barros L, Ferreira ICRF. Nutritional value, bioactive compounds and antioxidant properties of three edible mushrooms from Poland. Food Biosci. 2015;2:48-55. They can be cultivated at large scale using techniques of solid state and submerged cultures. Both methods use agroindustrial waste, although in submerged fermentation, the conditions are monitored with greater precision when compared to solid state fermentation.⁷7 Moonmoon M, Uddin MN, Ahmed S, Shelly NJ, Khan MA. Cultivation of different strains of king oyster mushroom (Pleurotus eryngii) on saw dust and rice straw in Bangladesh. Saudi J Biol Sci. 2010;17:341-345.^,⁸8 Alecrim MM, Palheta RA, Teixeira MFS, Oliveira IMA. Milk-clotting enzymes produced by Aspergillus flavo furcatis strains on Amazonic fruit waste. Int J Food Sci Technol. 2015;50:151-157.

Submerged fermentation is a viable alternative for efficient Pleurotus biomass production. This process has a number of advantages, such as a better control of physicochemical parameters, as well as the potential for high biomass production in a compact space, shorter growth time, and independent of seasonality.⁹9 Gregori A, Svagelj M, Pohleven J. Cultivation techniques and medicinal properties of Pleurotus spp. Food Technol Biotechnol. 2007;45:236-247.^,¹⁰10 Papaspyridi LM, Aligiannis N, Topakas E, Christakopoulos P, Skaltsounis AL, Fokialakis N. Submerged fermentation of the edible mushroom Pleurotus ostreatus in a batch stirred tank bioreactor as a promising alternative for the effective production of bioactive metabolites. Molecules. 2012;17:2714-2724.

In submerged fermentation of Pleurotus, no fruiting body production occurs, and the mycelial biomass develops in two forms: filamentous and pellet. Pellets are characterized by mycelia development into spherical aggregates, which are a branched and partially intertwined network of hyphae.¹¹11 Park JP, Kim YM, Kim SW, et al. Effect of agitation intensity on the exo-biopolymer production and micelial morphology in Cordyceps militaris. Lett Appl Microbiol. 2002;34:433-438.^,¹²12 Kim YM, Song HG. Effect of fungal pellet morphology and enzyme activities involved in phthalate degradation. J Microbiol. 2009;47:420-424. The filamentous form consists of hyphae homogenously spread in the culture medium which is more viscous than that of the pellet form. The mycelial biomass produced by submerged fermentation can be used as an inoculum source for mushroom production in semi-solid fermentations,¹1 Lechner BE, Wright JE, Albertó E. The genus Pleurotus in Argentina. Mycologia. 2004;96:845-858. in food additives, and for extraction of antimicrobial compounds, flavorings, polysaccharides, antioxidants, etc.¹⁰10 Papaspyridi LM, Aligiannis N, Topakas E, Christakopoulos P, Skaltsounis AL, Fokialakis N. Submerged fermentation of the edible mushroom Pleurotus ostreatus in a batch stirred tank bioreactor as a promising alternative for the effective production of bioactive metabolites. Molecules. 2012;17:2714-2724.

Aimed at the improvement of Pleurotus cultivation technology, the present study investigated the influence of physicochemical parameters of synthetic media on mycelial biomass production by P. albidus in submerged fermentation.

Material and methods

Fungus

P. albidus DPUA 1692 was obtained from Federal University of Amazonas DPUA Culture Collection, Brazil. All stock cultures were maintained on a potato dextrose agar (PDA) supplemented with 0.5% (w/v) yeast extract (YE) (HiMedia, Mumbai, India) slant, subcultured and incubated at 25 ºC for eight days in the dark and then stored at 4 ºC.¹³13 Kirsch LS, Pinto ACS, Porto TS, Porto ALF, Teixeira MFS. The influence of different submerged cultivation conditions on mycelial biomass and protease production by Lentinus citrinus Walleyn et Rammeloo DPUA 1535 (Agaricomycetidae). Int J Med Mushrooms. 2011;13:85-192.

Effect of inoculum volume on mycelial biomass production

An aqueous homogenate of mycelium, previously subcultured on PDA + YE, was prepared using 50 mL of sterilized distilled water (per dish) in a blender. Different volumes (0.5, 1.0, 2.0, 4.0, and 6.0 mL) of the mycelial homogenate were added into Erlenmeyer flasks (125 mL) containing 50 mL of standard medium (SM): KH₂PO₄ (1.0 g L⁻¹), MgSO₄·7H₂O (0.5 g L⁻¹), peptone (10.0 g L⁻¹), and glucose (20.0 g L⁻¹) at pH 6.0. The flasks were incubated for five days at 25 ºC, under aerobic conditions at 150 rpm, and tests were carried out in triplicate.¹⁴14 Wu JZ, Cheung PCK, Wong KH, Huang NL. Studies on submerged fermentation of Pleurotus tuber-regium (Fr.) Singer - Part 1: Physical and chemical factors affecting the rate of mycelial growth and bioconversion efficiency. Food Chem. 2003;81:389-393.

Effect of carbon and nitrogen sources on mycelial biomass production

Following nutrients were analyzed: glucose, fructose, maltose, saccharose, and lactose, as carbon sources; and peptone, yeast extract, tryptone, sodium nitrate and ammonium sulfate, as nitrogen sources. The glucose and peptone in the SM were replaced separately according to the carbon and nitrogen sources mentioned. The aqueous homogenate of mycelium (6.0 mL) was added to the flasks, and submerged fermentation was performed as mentioned above.

Determination of dry cell mass

At the end of fermentation, biomass was collected by vacuum filtration, washed three times with distilled water, and dried at 70 ºC for dry-weight quantification.¹⁵15 Dong CH, Yao YJ. Nutritional requirements of mycelial growth of Cordyceps sinensis in submerged culture. J Appl Microbiol. 2005;99:483-492.

Determination of total carbohydrates

The total carbohydrate concentration was determined colorimetrically by the phenol-sulfuric acid method according to the protocol described by Dubois et al.¹⁶16 Dubois M, Gilles KAL, Hamilton JK, Rebers PA, Smith F. Colorimetric method for determination of sugar and related substances. Anal Chem. 1956;28:350-356.

Conversion factor of substrate to biomass, yield and productivity

The conversion factor of substrate to biomass and the yield and productivity were calculated according to Confortin et al.¹⁷17 Confortin FG, Marchetto R, Bettin F, Camassola M, Salbador M, Dillon AJP. Production of Pleurotus sajor-caju strain PS-2001 biomass in submerged culture. J Ind Microbiol Biotechnol. 2008;35:1149-1155.

The conversion factor of substrate to biomass was expressed in grams of mycelial biomass produced per gram of substrate consumed (g g⁻¹):

(1)

where X_f and X_i are final and initial biomass concentration, respectively, and S_i and S_f are initial and final sugar concentration, respectively.

The yield was expressed in grams of mycelial biomass produced per gram of substrate initially present in the culture medium (g g⁻¹):

(2)

The productivity in biomass was expressed in grams of mycelial biomass produced per time (g L⁻¹ h⁻¹)¹⁷17 Confortin FG, Marchetto R, Bettin F, Camassola M, Salbador M, Dillon AJP. Production of Pleurotus sajor-caju strain PS-2001 biomass in submerged culture. J Ind Microbiol Biotechnol. 2008;35:1149-1155.:

(3)

where t is the incubation time.

Factorial design and statistical analysis

A 2⁴ factorial design was used to evaluate saccharose concentration, yeast extract concentration, agitation speed, and initial pH (independent variables) on mycelial biomass production (dependent variable).¹⁸18 Como variar tudo ao mesmo tempo.Neto BB, Scarminio IS, Bruns RE, eds. Como fazer experimentos: pesquisa e desenvolvimento na ciência e na industria. Campinas, Brasil: Unicamp; 2007:118–166. In previous experiments, saccharose and yeast extract were selected as the best carbon and nitrogen sources, respectively. SM was used with saccharose and yeast extract at different experimental concentrations. Submerged fermentation was conducted, and the biomass quantified as described previously. All statistical analyses were performed via Statistic 8.0 software.

All results of the submerged fermentation experiments were subjected to variance analysis (one-way ANOVA), and the values were compared by Tukey's test at p ≤ 0.05.

Morphology of the mycelial biomass

The morphology of the mycelial biomass produced under the factorial design was evaluated using the software Analysis FIVE Olympus and a stereomicroscope (Olympus SZ61, Ltd., Tokyo, Japan). The samples were fixed with a solution composed of 13 mL of 40% (v/v) formaldehyde, 5 mL of acetic acid, and 200 mL of 50% (v/v) ethanol.¹⁹19 Kim SW, Hwang HJ, Xu CP, Sung JM, Choi JW, Yun JW. Optimization of submerged culture process for the production of mycelial biomass and exo-polysaccharides by Cordyceps militaris C738. J Appl Microbiol. 2003;94:120-126.

Results and discussion

Effect of inoculum size

Mycelial biomass production varied significantly depending on the inoculum size (Fig. 1). The volume of 6.0 mL induced higher biomass production (5.00 g L⁻¹). Therefore, this volume was used for further experiments.

Fig. 1
Effect of different inoculum size on P. albidus mycelial biomass production. Means followed by the same letter(s) are not significantly different, as established by Tukey's test (p ≤ 0.05).

In investigations on P. tuber-regium¹⁴14 Wu JZ, Cheung PCK, Wong KH, Huang NL. Studies on submerged fermentation of Pleurotus tuber-regium (Fr.) Singer - Part 1: Physical and chemical factors affecting the rate of mycelial growth and bioconversion efficiency. Food Chem. 2003;81:389-393. and Grifola frondosa,²⁰20 Lee BC, Bae JR, Pyo HB, et al. Submerged culture conditions for the production of mycelial biomass and exopolysaccharides by the edible Basidiomycete Grifola frondosa. Enzyme Microb Technol. 2004;35:369-376. the inoculum size with a cell suspension volume ranging from 0.5 to 12.0 mL, or 2 to 6%, had a higher positive influence on mycelial growth in comparison to the medium volume in submerged fermentation.

Effect of carbon and nitrogen sources

All carbon sources tested promoted P. albidus growth (Table 1). However, saccharose (7.28 g L⁻¹), fructose (7.07 g L⁻¹), and maltose (6.99 g L⁻¹) were the carbon sources that promoted the most considerable growth. Although the mushroom manifested the highest mycelial biomass production in the treatment with saccharose, the consumption of this sugar during the fermentation process was twice lower than that of fructose. This result might have been caused by the nature of the carbon source, because saccharose is a disaccharide which is necessary for invertase excretion, and after decomposition into glucose and fructose, it can be absorbed by the fungus.²⁷27 Fungal nutrition.Deacon JW, ed. Fungal Biology. New York, USA: Blackwell Publishing Ltd.; 2006:110–121.

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Table 1
Mycelial biomass, conversion factor of substrate to biomass (Y _X/S), yield (Y _r/S ) and productivity (P _X ) of P. albidus under different carbon and nitrogen sources.

Monosaccharides, such as fructose and glucose, are carbon sources that stimulate Pleurotus growth in submerged fermentation.²¹21 Fasidi IO, Olorunmaiye KS. Studies on requirements for growth of Pleurotus tuber-regium (Fr.) Singer, a Nigerian edible mushroom. Food Chem. 1994;50:397-401.^,²²22 Gbolagade J, Sobowale A, Adejoye D. Optimization of submerged culture conditions for biomass production in Pleurotus florida (mont.) Singer, a Nigerian edible fungus. Afr J Biotechnol. 2006;5:1464-1469. However, the preference for saccharose as a carbon source has also been reported for Antrodia cinnamomea,²³23 Yang FC, Huang HC, Yang MJ. The influence of environmental conditions on the mycelial growth of Antrodia cinnamomea in submerged cultures. Enzyme Microb Technol. 2003;33:395-402.Cordyceps militaris,²⁴24 Park JP, Kim SW, Hwang HJ, Yun JW. Optimization of submerged culture conditions for the mycelial growth and exo-biopolymer production by Cordyceps militaris. Lett Appl Microbiol. 2001;33:76-81.C. sinensis,¹⁵15 Dong CH, Yao YJ. Nutritional requirements of mycelial growth of Cordyceps sinensis in submerged culture. J Appl Microbiol. 2005;99:483-492. and C. jiangxiensis.²⁵25 Xiao JH, Chen DX, Wan WH, Hu XJ, Qi Y, Liang ZQ. Enhanced simultaneous production of mycelia and intracellular polysaccharide in submerged cultivation of Cordyceps jiangxiensis using desirability functions. Process Biochem. 2005;41:1887-1893. Considering costs and ease of production, saccharose can be considered a more suitable substrate compared to other synthetic sources available on the market.

In our study, saccharose was more efficiently converted into biomass (1.15 g g⁻¹) with a higher productivity (0.061 g L⁻¹ h⁻¹), whereas biomass and productivity were 0.86 g g⁻¹ and 0.059 g L⁻¹ h⁻¹, respectively, for fructose. These values were higher than those reported for Pleurotus sajor-caju (0.82 g g⁻¹ and 0.085 g L⁻¹ h⁻¹) in a liquid medium containing an initial concentration of 10 g L⁻¹ glucose and 0.59 g g⁻¹ and 0.041 g L⁻¹ h⁻¹ for 10 g L⁻¹ saccharose.¹⁷17 Confortin FG, Marchetto R, Bettin F, Camassola M, Salbador M, Dillon AJP. Production of Pleurotus sajor-caju strain PS-2001 biomass in submerged culture. J Ind Microbiol Biotechnol. 2008;35:1149-1155.

The addition of sodium nitrate and ammonium sulfate in the culture media did not favor mycelial biomass production. The maximum values of biomass formation were 0.79 and 1.39 g L⁻¹, respectively (Table 1). These findings are in accordance with those obtained for C. militaris²⁴24 Park JP, Kim SW, Hwang HJ, Yun JW. Optimization of submerged culture conditions for the mycelial growth and exo-biopolymer production by Cordyceps militaris. Lett Appl Microbiol. 2001;33:76-81. and G. frondosa.²⁰20 Lee BC, Bae JR, Pyo HB, et al. Submerged culture conditions for the production of mycelial biomass and exopolysaccharides by the edible Basidiomycete Grifola frondosa. Enzyme Microb Technol. 2004;35:369-376. Overall, it seems that inorganic nitrogen does not promote growth of several fungi species, in contrast to organic sources.²⁴24 Park JP, Kim SW, Hwang HJ, Yun JW. Optimization of submerged culture conditions for the mycelial growth and exo-biopolymer production by Cordyceps militaris. Lett Appl Microbiol. 2001;33:76-81.^,²⁶26 Kim HO, Lim JM, Joo JH, et al. Optimization of submerged culture condition for the production of mycelial biomass and exopolysaccharides by Agrocybe cylindracea. Bioresour Technol. 2005;96:1175-1182.

Deacon²⁷27 Fungal nutrition.Deacon JW, ed. Fungal Biology. New York, USA: Blackwell Publishing Ltd.; 2006:110–121. describes that as a result of ammonia metabolism, H⁺ ions are released, and the pH of the medium is reduced, inhibiting the growth of some mushroom species. This was also observed when, at the end of fermentation process, the pH of culture media in which ammonium sulfate and sodium nitrate were utilized was below 4.6 (Table 1).

Our results indicated that YE (7.98 g L⁻¹) was the nitrogen source that stimulated most pronouncedly mycelial biomass production, which was due to presence of several other nutrients, including carbon sources, growth factors, and vitamins present in YE. The biomass of P. albidus was higher in the culture medium containing YE, and the values obtained for yield and productivity were 0.40 g g⁻¹ and 0.066 g L⁻¹ h⁻¹, respectively, which were significantly higher when compared with the other nitrogen sources evaluated. However, no statistical differences (p ≤ 0.05) were observed between the values for yeast extract and control concerning the values of the conversion factor of substrate to biomass.

The presence of tryptone (7.19 g L⁻¹) and peptone (6.56 g L ¹) in culture media also favored biomass production with values that were statistically different (p ≤ 0.05) from those of the inorganic sources of nitrogen. Various organic nitrogen sources have been reported as suitable for mushrooms growth, including meat peptone, polypeptone, yeast extract, and soybean concentrates.²⁰20 Lee BC, Bae JR, Pyo HB, et al. Submerged culture conditions for the production of mycelial biomass and exopolysaccharides by the edible Basidiomycete Grifola frondosa. Enzyme Microb Technol. 2004;35:369-376.^,²³23 Yang FC, Huang HC, Yang MJ. The influence of environmental conditions on the mycelial growth of Antrodia cinnamomea in submerged cultures. Enzyme Microb Technol. 2003;33:395-402.^,²⁸28 Pokhrel CP, Ohga S. Submerged culture conditions for mycelial yield and polysaccharides production by Lyophyllum decastes. Food Chem. 2007;105:641-646.

Factorial design

The variables and the results obtained from the runs of the 2⁴ full factorial design are listed in Table 2. The mycelial biomass production ranged from 3.92 g L⁻¹ to 9.81 g L⁻¹ represented by runs 3 and 12, respectively.

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Table 2
Results of the full factorial design 2⁴ for mycelial biomass production by P. albidus.

The contrast values were calculated for each of the variables and their interactions from the experiments of factorial design (Table 3). All variables had a substantial influence on mycelial biomass production, and, in terms of their impact, they can be classified in the following decreasing order of significance: saccharose concentration, agitation speed, yeast extract concentration, and pH. For the first three variables the effect was positive, which indicated that the increase of this lower level to the higher level favored biomass production of P. albidus in the fermentation process. The pH was also significant for this response; however, the negative effect showed that the reduction of the initial pH promoted more favorable conditions for production of mycelial biomass. The interactions of pH and agitation speed, and saccharose concentration and agitation speed on the higher level, also favored P. albidus growth.

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Table 3
Contrast values calculated according to factorial design of P. albidus mycelial biomass production.

The highest biomass production was 9.81 g L⁻¹, as determined in run number 12 with the culture medium formulated with saccharose (30.0 g L⁻¹), yeast extract (2.5 g L⁻¹), pH 7.0, and an agitation speed of 180 rpm. An R-square value of 0.9341 was obtained for the biomass, indicating that the model explained approximately 93% of the variability data.

Park et al.¹¹11 Park JP, Kim YM, Kim SW, et al. Effect of agitation intensity on the exo-biopolymer production and micelial morphology in Cordyceps militaris. Lett Appl Microbiol. 2002;34:433-438. evaluated the influence of different physicochemical parameters on the growth and production of polysaccharides by submerged fermentation in another mushroom species (C. militaris). Their results indicated that among the carbon sources tested, saccharose also exerted a favorable effect on mycelial growth. The growth was proportional to the increase of the initial concentration of this carbon source, ranging from 10 g L⁻¹ to 60 g L⁻¹ and expressing the maximum growth in the medium containing 60 g L⁻¹ of saccharose.

According to Tang et al.,⁵5 Tang YJ, Zhu LW, Li HM, Li DS. Submerged culture of mushrooms in bioreactors - challenges, current state-of-the-art, and future prospects. Food Technol Biotechnol. 2007;45:221-229. the agitated culture medium promoted proper homogenization of components, increased the oxygenation, and improved the mass and heat transfer. These conditions had a positive influence on mushroom mycelial growth by submerged fermentation. Nevertheless, extremely high agitation speeds may also cause shear forces that can damage the hyphae, causing changes in the mycelium, variations in growth rate, and interfere with product formation. The agitation speed of 180 rpm in P. albidus cultures was that the most suitable for the mycelial growth in comparison to the others speeds tested. These results differ from those obtained by Kim et al.²⁹29 Kim HM, Kim SW, Hwang HJ, et al. Influence of agitation intensity and aeration rate on production of antioxidative exopolysaccharides from submerged mycelial culture of Ganoderma resinaceum. J Microbiol Biotechnol. 2006;16:1240-1247. who evaluated the effect of agitation speed and aeration on the mycelial growth of Ganoderma resinarum. The authors reported that when agitation speed increased from 50 to 250 rpm, biomass production was reduced by approximately 30% (from 12.7 g L⁻¹ to 8.9 g L⁻¹).

The use of YE as a nitrogen source in the culture medium to evaluate biomass production by G. frondosa was reported.²⁰20 Lee BC, Bae JR, Pyo HB, et al. Submerged culture conditions for the production of mycelial biomass and exopolysaccharides by the edible Basidiomycete Grifola frondosa. Enzyme Microb Technol. 2004;35:369-376. The authors evidenced that the biomass increased as the concentration of the nitrogen source was elevated in the culture medium; and the yeast extract concentration of 6 g L⁻¹ was optimal for biomass production. A number of studies have indicated that mushrooms, when grown under the conditions of submerged fermentation, have preference for organic nitrogen sources, such as yeast extract and peptone rather than for the inorganic ones.³⁰30 Cho EJ, Oh JY, Chang HY, Yun JW. Production of exopolysaccharides by submerged mycelial culture of a mushroom Tremella fuciformis. J Biotechnol. 2006;127:129-140.^,³¹31 Das AR, Borthakur M, Saha AK, Joshi SR, Das P. Growth of mycelial biomass and fruit body cultivation of Lentinus squarrosulus collected from home garden of Tripura in Northeast India. J Appl Biol Biotechnol. 2015;3:17-19. Gbolagade et al.³²32 Gbolagade JS, Fasidi IO, Ajayi EJ, Sobowale AA. Effect of physico-chemical factors and semi-synthetic media on vegetative growth of Lentinus subnudus (Berk), an edible mushroom from Nigeria. Food Chem. 2006;99:742-747. reported that this preference may be explained by the complex combination of amino acids and carbohydrates present in these organic compounds, resulting in the enhanced fungal growth.

Fermentation medium pH is an extremely important variable in the growth of fungi, as it affects the function of the cell membrane, the structure, and cellular morphology, as well as the processes of uptake of various nutrients and product biosynthesis.²⁷27 Fungal nutrition.Deacon JW, ed. Fungal Biology. New York, USA: Blackwell Publishing Ltd.; 2006:110–121.^,³³33 Papagianni M. Fungal morphology and metabolite production in submerged mycelial process. Biotechnol Adv. 2004;22:189-259. In this research, the results indicated that, in general, the use of lower initial pH in culture medium favored P. albidus growth. At the end of the fermentation process, the pH remained constant in the culture media where the initial pH was 5.0. However, when the fungus started its growth at initial pH 7.0, there was a reduction to pH 5.0. According to Papagianni,³³33 Papagianni M. Fungal morphology and metabolite production in submerged mycelial process. Biotechnol Adv. 2004;22:189-259. culture medium composition may affect the initial culture medium pH causing fluctuations in the pH range during fungal growth.

Morphological observations of mycelium in submerged fermentation

Znidarsic and Pavko³⁴34 Znidarsic P, Pavko A. Morphology of filamentous fungi. Food Technol Biotechnol. 2001;39:237-252. and Kim et al.²⁹29 Kim HM, Kim SW, Hwang HJ, et al. Influence of agitation intensity and aeration rate on production of antioxidative exopolysaccharides from submerged mycelial culture of Ganoderma resinaceum. J Microbiol Biotechnol. 2006;16:1240-1247. reported that the characteristics of the mycelium produced by submerged fermentation are influenced by culture conditions, such as the composition and initial pH of the fermentation medium, the age and size of inoculum, aeration rate, and agitation speed.

The formation of pellets with different sizes and morphology were observed in all fermentation conditions. These pellet characteristics were more evident after variation in the agitation speed, following the alterations in the initial pH of the culture medium. When the process was performed at 120 rpm, the pellets were large and few in numbers, whereas at 180 rpm, they became smaller in size and larger in quantity. The variation in the size of pellets under different agitation conditions was also reported by other authors.²⁹29 Kim HM, Kim SW, Hwang HJ, et al. Influence of agitation intensity and aeration rate on production of antioxidative exopolysaccharides from submerged mycelial culture of Ganoderma resinaceum. J Microbiol Biotechnol. 2006;16:1240-1247. They observed the presence of large pellets when Ganoderma resinaceum was subjected to an agitation speed of 50 rpm, whereas under more vigorous agitation (300 rpm), pellets became small at the end of the fermentation process.

At 120 rpm and pH 7.0, growth of elongated and protruding hyphae on the surface of the pellets was observed (Fig. 2a). Under fermentation conditions of pH 5.0, the extensions of these hyphae exhibited more reduced length or were absent (Fig. 2b and d). In a study performed by Hwang et al.,³⁵35 Hwang HJ, Kim SW, Xu CP, Choi JW, Yun JW. Morphological and rheological properties of the three different species of basidiomycetes Phellinus in submerged cultures. J Appl Microbiol. 2004;96:1296-1305. the authors verified that Phellinus baumii grown in a liquid medium produced pellets with a starfish-like appearance at a more acidic pH. However, when the pH of the culture medium ranged from neutral to alkaline, pellets became more compact, and no free mycelium was available.

Fig. 2
Pellet morphology under different culture conditions. (A) Run 11, (B) Run 5, (C) Run 8, (D) Run 9, (E) Run 12 and (F) Run 14 of the factorial design.

In cultures performed at a higher agitation speed (180 rpm), except for run no. 6, pellets were present, and, in general, elongated hyphae were observed on the surface. At pH 7.0 (Fig. 2c and e), hyphae around the pellets were more numerous than at pH 5.0 (Fig. 2f).

Similar results were also obtained by Park et al.,¹¹11 Park JP, Kim YM, Kim SW, et al. Effect of agitation intensity on the exo-biopolymer production and micelial morphology in Cordyceps militaris. Lett Appl Microbiol. 2002;34:433-438. who reported that the pellets of C. militaris formed during the fermentation period increased in size independently of the agitation speed. Nonetheless, when the fermentation was conducted under low agitation speed (50 rpm), the pellets became large and fluffy, whereas at a high agitation speed (300 rpm), the outer hairy regions of the pellets were removed and, consequently, became smaller and changed to a circular shape.

During the fermentation process, P. albidus biomass was observed to adhere strongly to the inside walls of the Erlenmeyer flasks in all growth conditions evaluated. This phenomenon was also observed in previous investigations on submerged fermentation of Ganoderma lucidum, in which the authors reported biomass adherence due to the polysaccharides production.³⁶36 Wagner R, Mitchell DA, Sassaki GL, Amazonas MALA. Link between morphology and physiology of Ganoderma lucidum in submerged culture for the production of exopolysaccharide. J Biotechnol. 2004;114:153-164.

When establishing a relationship between the production and biomass morphology of P. albidus, higher mycelial biomass production was found when the pellets were small in size with short hyphae.

Conclusion

The results obtained in this study elucidated some important aspects of the morphology and physiology of P. albidus. These findings can be considered pioneering for the production of mycelial biomass of this mushroom by submerged fermentation. The components of the culture media, including the concentration and type of carbon and nitrogen sources, initial pH, inoculum volume, and agitation speed are main factors that significantly affect biomass production. The experimental design was an effective tool for evaluating the culture factors that most influenced the growth and morphology of the mushroom biomass. This information may be useful for the production of P. albidus mycelial biomass for human consumption.

Acknowledgements

The authors acknowledge the technical and financial support granted by the Culture Collection DPUA and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Capes)/Brazil.

REFERENCES

¹
Lechner BE, Wright JE, Albertó E. The genus Pleurotus in Argentina. Mycologia 2004;96:845-858.
²
Moreno-Fuentes A, Bautista-Nava E. El “hongo blanco patón” Pleurotus albidus, en Hidalgo. Su primer registro em México. Rev Mex Micol 2006;22:41-47.
³
Lechner BE, Albertó E. Search for new naturally occurring strains of Pleurotus to improve yields. Pleurotus albidus as a novel proposed species for mushroom production. Rev Iberoam Mycol 2011;28:148-154.
⁴
Maftoun P, Johari H, Soltani M, Malik R, Othman NZ, El Enshasy HA. The edible mushroom Pleurotus spp.: I. Biodiversity and nutritional values. Int J Biotechnol Wellness Ind 2015;4:67-83.
⁵
Tang YJ, Zhu LW, Li HM, Li DS. Submerged culture of mushrooms in bioreactors - challenges, current state-of-the-art, and future prospects. Food Technol Biotechnol 2007;45:221-229.
⁶
Heleno SA, Ferreira RC, Antonio AL, Queiroz MJRP, Barros L, Ferreira ICRF. Nutritional value, bioactive compounds and antioxidant properties of three edible mushrooms from Poland. Food Biosci 2015;2:48-55.
⁷
Moonmoon M, Uddin MN, Ahmed S, Shelly NJ, Khan MA. Cultivation of different strains of king oyster mushroom (Pleurotus eryngii) on saw dust and rice straw in Bangladesh. Saudi J Biol Sci 2010;17:341-345.
⁸
Alecrim MM, Palheta RA, Teixeira MFS, Oliveira IMA. Milk-clotting enzymes produced by Aspergillus flavo furcatis strains on Amazonic fruit waste. Int J Food Sci Technol. 2015;50:151-157.
⁹
Gregori A, Svagelj M, Pohleven J. Cultivation techniques and medicinal properties of Pleurotus spp. Food Technol Biotechnol 2007;45:236-247.
¹⁰
Papaspyridi LM, Aligiannis N, Topakas E, Christakopoulos P, Skaltsounis AL, Fokialakis N. Submerged fermentation of the edible mushroom Pleurotus ostreatus in a batch stirred tank bioreactor as a promising alternative for the effective production of bioactive metabolites. Molecules 2012;17:2714-2724.
¹¹
Park JP, Kim YM, Kim SW, et al. Effect of agitation intensity on the exo-biopolymer production and micelial morphology in Cordyceps militaris Lett Appl Microbiol 2002;34:433-438.
¹²
Kim YM, Song HG. Effect of fungal pellet morphology and enzyme activities involved in phthalate degradation. J Microbiol 2009;47:420-424.
¹³
Kirsch LS, Pinto ACS, Porto TS, Porto ALF, Teixeira MFS. The influence of different submerged cultivation conditions on mycelial biomass and protease production by Lentinus citrinus Walleyn et Rammeloo DPUA 1535 (Agaricomycetidae). Int J Med Mushrooms 2011;13:85-192.
¹⁴
Wu JZ, Cheung PCK, Wong KH, Huang NL. Studies on submerged fermentation of Pleurotus tuber-regium (Fr.) Singer - Part 1: Physical and chemical factors affecting the rate of mycelial growth and bioconversion efficiency. Food Chem 2003;81:389-393.
¹⁵
Dong CH, Yao YJ. Nutritional requirements of mycelial growth of Cordyceps sinensis in submerged culture. J Appl Microbiol 2005;99:483-492.
¹⁶
Dubois M, Gilles KAL, Hamilton JK, Rebers PA, Smith F. Colorimetric method for determination of sugar and related substances. Anal Chem 1956;28:350-356.
¹⁷
Confortin FG, Marchetto R, Bettin F, Camassola M, Salbador M, Dillon AJP. Production of Pleurotus sajor-caju strain PS-2001 biomass in submerged culture. J Ind Microbiol Biotechnol 2008;35:1149-1155.
¹⁸
Como variar tudo ao mesmo tempo.Neto BB, Scarminio IS, Bruns RE, eds. Como fazer experimentos: pesquisa e desenvolvimento na ciência e na industria Campinas, Brasil: Unicamp; 2007:118–166.
¹⁹
Kim SW, Hwang HJ, Xu CP, Sung JM, Choi JW, Yun JW. Optimization of submerged culture process for the production of mycelial biomass and exo-polysaccharides by Cordyceps militaris C738. J Appl Microbiol 2003;94:120-126.
²⁰
Lee BC, Bae JR, Pyo HB, et al. Submerged culture conditions for the production of mycelial biomass and exopolysaccharides by the edible Basidiomycete Grifola frondosa Enzyme Microb Technol 2004;35:369-376.
²¹
Fasidi IO, Olorunmaiye KS. Studies on requirements for growth of Pleurotus tuber-regium (Fr.) Singer, a Nigerian edible mushroom. Food Chem 1994;50:397-401.
²²
Gbolagade J, Sobowale A, Adejoye D. Optimization of submerged culture conditions for biomass production in Pleurotus florida (mont.) Singer, a Nigerian edible fungus. Afr J Biotechnol 2006;5:1464-1469.
²³
Yang FC, Huang HC, Yang MJ. The influence of environmental conditions on the mycelial growth of Antrodia cinnamomea in submerged cultures. Enzyme Microb Technol 2003;33:395-402.
²⁴
Park JP, Kim SW, Hwang HJ, Yun JW. Optimization of submerged culture conditions for the mycelial growth and exo-biopolymer production by Cordyceps militaris Lett Appl Microbiol 2001;33:76-81.
²⁵
Xiao JH, Chen DX, Wan WH, Hu XJ, Qi Y, Liang ZQ. Enhanced simultaneous production of mycelia and intracellular polysaccharide in submerged cultivation of Cordyceps jiangxiensis using desirability functions. Process Biochem 2005;41:1887-1893.
²⁶
Kim HO, Lim JM, Joo JH, et al. Optimization of submerged culture condition for the production of mycelial biomass and exopolysaccharides by Agrocybe cylindracea Bioresour Technol 2005;96:1175-1182.
²⁷
Fungal nutrition.Deacon JW, ed. Fungal Biology New York, USA: Blackwell Publishing Ltd.; 2006:110–121.
²⁸
Pokhrel CP, Ohga S. Submerged culture conditions for mycelial yield and polysaccharides production by Lyophyllum decastes Food Chem 2007;105:641-646.
²⁹
Kim HM, Kim SW, Hwang HJ, et al. Influence of agitation intensity and aeration rate on production of antioxidative exopolysaccharides from submerged mycelial culture of Ganoderma resinaceum J Microbiol Biotechnol 2006;16:1240-1247.
³⁰
Cho EJ, Oh JY, Chang HY, Yun JW. Production of exopolysaccharides by submerged mycelial culture of a mushroom Tremella fuciformis J Biotechnol 2006;127:129-140.
³¹
Das AR, Borthakur M, Saha AK, Joshi SR, Das P. Growth of mycelial biomass and fruit body cultivation of Lentinus squarrosulus collected from home garden of Tripura in Northeast India. J Appl Biol Biotechnol 2015;3:17-19.
³²
Gbolagade JS, Fasidi IO, Ajayi EJ, Sobowale AA. Effect of physico-chemical factors and semi-synthetic media on vegetative growth of Lentinus subnudus (Berk), an edible mushroom from Nigeria. Food Chem 2006;99:742-747.
³³
Papagianni M. Fungal morphology and metabolite production in submerged mycelial process. Biotechnol Adv 2004;22:189-259.
³⁴
Znidarsic P, Pavko A. Morphology of filamentous fungi. Food Technol Biotechnol 2001;39:237-252.
³⁵
Hwang HJ, Kim SW, Xu CP, Choi JW, Yun JW. Morphological and rheological properties of the three different species of basidiomycetes Phellinus in submerged cultures. J Appl Microbiol 2004;96:1296-1305.
³⁶
Wagner R, Mitchell DA, Sassaki GL, Amazonas MALA. Link between morphology and physiology of Ganoderma lucidum in submerged culture for the production of exopolysaccharide. J Biotechnol 2004;114:153-164.

Publication Dates

Publication in this collection
Jul-Sep 2016

History

Received
10 Apr 2015
Accepted
9 Nov 2015

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] ¹
Lechner BE, Wright JE, Albertó E. The genus Pleurotus in Argentina. Mycologia 2004;96:845-858.

[2] ²
Moreno-Fuentes A, Bautista-Nava E. El “hongo blanco patón” Pleurotus albidus, en Hidalgo. Su primer registro em México. Rev Mex Micol 2006;22:41-47.

[3] ³
Lechner BE, Albertó E. Search for new naturally occurring strains of Pleurotus to improve yields. Pleurotus albidus as a novel proposed species for mushroom production. Rev Iberoam Mycol 2011;28:148-154.

[4] ⁴
Maftoun P, Johari H, Soltani M, Malik R, Othman NZ, El Enshasy HA. The edible mushroom Pleurotus spp.: I. Biodiversity and nutritional values. Int J Biotechnol Wellness Ind 2015;4:67-83.

[5] ⁵
Tang YJ, Zhu LW, Li HM, Li DS. Submerged culture of mushrooms in bioreactors - challenges, current state-of-the-art, and future prospects. Food Technol Biotechnol 2007;45:221-229.

[6] ⁶
Heleno SA, Ferreira RC, Antonio AL, Queiroz MJRP, Barros L, Ferreira ICRF. Nutritional value, bioactive compounds and antioxidant properties of three edible mushrooms from Poland. Food Biosci 2015;2:48-55.

[7] ⁷
Moonmoon M, Uddin MN, Ahmed S, Shelly NJ, Khan MA. Cultivation of different strains of king oyster mushroom (Pleurotus eryngii) on saw dust and rice straw in Bangladesh. Saudi J Biol Sci 2010;17:341-345.

[8] ⁸
Alecrim MM, Palheta RA, Teixeira MFS, Oliveira IMA. Milk-clotting enzymes produced by Aspergillus flavo furcatis strains on Amazonic fruit waste. Int J Food Sci Technol. 2015;50:151-157.

[9] ⁹
Gregori A, Svagelj M, Pohleven J. Cultivation techniques and medicinal properties of Pleurotus spp. Food Technol Biotechnol 2007;45:236-247.

[10] ¹⁰
Papaspyridi LM, Aligiannis N, Topakas E, Christakopoulos P, Skaltsounis AL, Fokialakis N. Submerged fermentation of the edible mushroom Pleurotus ostreatus in a batch stirred tank bioreactor as a promising alternative for the effective production of bioactive metabolites. Molecules 2012;17:2714-2724.

[11] ¹¹
Park JP, Kim YM, Kim SW, et al. Effect of agitation intensity on the exo-biopolymer production and micelial morphology in Cordyceps militaris Lett Appl Microbiol 2002;34:433-438.

[12] ¹²
Kim YM, Song HG. Effect of fungal pellet morphology and enzyme activities involved in phthalate degradation. J Microbiol 2009;47:420-424.

[13] ¹³
Kirsch LS, Pinto ACS, Porto TS, Porto ALF, Teixeira MFS. The influence of different submerged cultivation conditions on mycelial biomass and protease production by Lentinus citrinus Walleyn et Rammeloo DPUA 1535 (Agaricomycetidae). Int J Med Mushrooms 2011;13:85-192.

[14] ¹⁴
Wu JZ, Cheung PCK, Wong KH, Huang NL. Studies on submerged fermentation of Pleurotus tuber-regium (Fr.) Singer - Part 1: Physical and chemical factors affecting the rate of mycelial growth and bioconversion efficiency. Food Chem 2003;81:389-393.

[15] ¹⁵
Dong CH, Yao YJ. Nutritional requirements of mycelial growth of Cordyceps sinensis in submerged culture. J Appl Microbiol 2005;99:483-492.

[16] ¹⁶
Dubois M, Gilles KAL, Hamilton JK, Rebers PA, Smith F. Colorimetric method for determination of sugar and related substances. Anal Chem 1956;28:350-356.

[17] ¹⁷
Confortin FG, Marchetto R, Bettin F, Camassola M, Salbador M, Dillon AJP. Production of Pleurotus sajor-caju strain PS-2001 biomass in submerged culture. J Ind Microbiol Biotechnol 2008;35:1149-1155.

[18] ¹⁸
Como variar tudo ao mesmo tempo.Neto BB, Scarminio IS, Bruns RE, eds. Como fazer experimentos: pesquisa e desenvolvimento na ciência e na industria Campinas, Brasil: Unicamp; 2007:118–166.

[19] ¹⁹
Kim SW, Hwang HJ, Xu CP, Sung JM, Choi JW, Yun JW. Optimization of submerged culture process for the production of mycelial biomass and exo-polysaccharides by Cordyceps militaris C738. J Appl Microbiol 2003;94:120-126.

[20] ²⁰
Lee BC, Bae JR, Pyo HB, et al. Submerged culture conditions for the production of mycelial biomass and exopolysaccharides by the edible Basidiomycete Grifola frondosa Enzyme Microb Technol 2004;35:369-376.

[21] ²¹
Fasidi IO, Olorunmaiye KS. Studies on requirements for growth of Pleurotus tuber-regium (Fr.) Singer, a Nigerian edible mushroom. Food Chem 1994;50:397-401.

[22] ²²
Gbolagade J, Sobowale A, Adejoye D. Optimization of submerged culture conditions for biomass production in Pleurotus florida (mont.) Singer, a Nigerian edible fungus. Afr J Biotechnol 2006;5:1464-1469.

[23] ²³
Yang FC, Huang HC, Yang MJ. The influence of environmental conditions on the mycelial growth of Antrodia cinnamomea in submerged cultures. Enzyme Microb Technol 2003;33:395-402.

[24] ²⁴
Park JP, Kim SW, Hwang HJ, Yun JW. Optimization of submerged culture conditions for the mycelial growth and exo-biopolymer production by Cordyceps militaris Lett Appl Microbiol 2001;33:76-81.

[25] ²⁵
Xiao JH, Chen DX, Wan WH, Hu XJ, Qi Y, Liang ZQ. Enhanced simultaneous production of mycelia and intracellular polysaccharide in submerged cultivation of Cordyceps jiangxiensis using desirability functions. Process Biochem 2005;41:1887-1893.

[26] ²⁶
Kim HO, Lim JM, Joo JH, et al. Optimization of submerged culture condition for the production of mycelial biomass and exopolysaccharides by Agrocybe cylindracea Bioresour Technol 2005;96:1175-1182.

[27] ²⁷
Fungal nutrition.Deacon JW, ed. Fungal Biology New York, USA: Blackwell Publishing Ltd.; 2006:110–121.

[28] ²⁸
Pokhrel CP, Ohga S. Submerged culture conditions for mycelial yield and polysaccharides production by Lyophyllum decastes Food Chem 2007;105:641-646.

[29] ²⁹
Kim HM, Kim SW, Hwang HJ, et al. Influence of agitation intensity and aeration rate on production of antioxidative exopolysaccharides from submerged mycelial culture of Ganoderma resinaceum J Microbiol Biotechnol 2006;16:1240-1247.

[30] ³⁰
Cho EJ, Oh JY, Chang HY, Yun JW. Production of exopolysaccharides by submerged mycelial culture of a mushroom Tremella fuciformis J Biotechnol 2006;127:129-140.

[31] ³¹
Das AR, Borthakur M, Saha AK, Joshi SR, Das P. Growth of mycelial biomass and fruit body cultivation of Lentinus squarrosulus collected from home garden of Tripura in Northeast India. J Appl Biol Biotechnol 2015;3:17-19.

[32] ³²
Gbolagade JS, Fasidi IO, Ajayi EJ, Sobowale AA. Effect of physico-chemical factors and semi-synthetic media on vegetative growth of Lentinus subnudus (Berk), an edible mushroom from Nigeria. Food Chem 2006;99:742-747.

[33] ³³
Papagianni M. Fungal morphology and metabolite production in submerged mycelial process. Biotechnol Adv 2004;22:189-259.

[34] ³⁴
Znidarsic P, Pavko A. Morphology of filamentous fungi. Food Technol Biotechnol 2001;39:237-252.

[35] ³⁵
Hwang HJ, Kim SW, Xu CP, Choi JW, Yun JW. Morphological and rheological properties of the three different species of basidiomycetes Phellinus in submerged cultures. J Appl Microbiol 2004;96:1296-1305.

[36] ³⁶
Wagner R, Mitchell DA, Sassaki GL, Amazonas MALA. Link between morphology and physiology of Ganoderma lucidum in submerged culture for the production of exopolysaccharide. J Biotechnol 2004;114:153-164.

Sources	Mycelial biomass (g L⁻¹)	Y_X/S (g g⁻¹)	Y_r/S (g g⁻¹)	P_X (g L⁻¹ h⁻¹)	Final pH
Carbon
Saccharose	7.28^a	1.15^a	0.36^a	0.061^a	5.19^a
Fructose	7.07^a	0.86^b	0.35^a	0.059^a	5.05^b
Lactose	6.23^c	0.65^d	0.31^c	0.052^c	5.21^a
Maltose	6.99^a	0.79^c	0.35^a	0.058^a	5.00^b
Glucose (basal)	6.56^b	0.43^e	0.33^b	0.055^b	5.06^b

Nitrogen
Yeast extract	7.98^a	0.42^a	0.40^a	0.066^a	5.45^a
Tryptone	7.19^b	0.39^b	0.36^b	0.060^b	4.70^c
Ammonium sulfate	1.39^d	0.24^c	0.07^d	0.012^d	3.33^d
Sodium nitrate	0.79^e	0.11^d	0.04^e	0.007^e	4.62^c
Peptone (basal)	6.56^c	0.43^a	0.33^c	0.055^c	5.06^b

Variables	Contrasts
(1) Saccharose concentration	120.75 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
(2) Yeast extract concentration	49.90 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
(3) pH	−11.00 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
(4) Agitation speed	63.75 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
Interaction 1-2	6.64 ± 1.06
Interaction 1-3	24.03 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
Interaction 1-4	47.25 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
Interaction 2-3	−23.34 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
Interaction 2-4	−18.50 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
Interaction 3-4	47.26 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
Interaction 1-2-3	−5.90 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
Interaction 1-2-4	24.93 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
Interaction 1-3-4	30.14 ± 1.06⁺ + Statistically significant values at a 95% confidence level.
Interaction 2-3-4	−20.93 ± 1.06⁺ + Statistically significant values at a 95% confidence level.

Runs	Sc^a a Sc, saccharose concentration (g L−1).	YEc^b b YEc, yeast extract concentration (g L−1).	pH	As^c c As, agitation speed (rpm).	Mycelial biomass (g L⁻¹)
1	10.0	2.5	5.0	120	4.52
2	10.0	2.5	5.0	180	5.47
3	10.0	2.5	7.0	120	3.92
4	10.0	2.5	7.0	180	5.37
5	10.0	10.0	5.0	120	6.70
6	10.0	10.0	5.0	180	5.72
7	10.0	10.0	7.0	120	5.21
8	10.0	10.0	7.0	180	5.11
9	30.0	2.5	5.0	120	6.87
10	30.0	2.5	5.0	180	6.49
11	30.0	2.5	7.0	120	5.24
12	30.0	2.5	7.0	180	9.81
13	30.0	10.0	5.0	120	7.53
14	30.0	10.0	5.0	180	9.26
15	30.0	10.0	7.0	120	6.59
16	30.0	10.0	7.0	180	9.56
17^d d Central points.	20	5.0	6.0	150	7.47
18^d d Central points.	20	5.0	6.0	150	7.34
19^d d Central points.	20	5.0	6.0	150	7.41

Brasil

Brasil

Production of mycelial biomass by the Amazonian edible mushroom Pleurotus albidus

ABSTRACT

Introduction

Material and methods

Fungus

Effect of inoculum volume on mycelial biomass production

Effect of carbon and nitrogen sources on mycelial biomass production

Determination of dry cell mass

Determination of total carbohydrates

Conversion factor of substrate to biomass, yield and productivity

Factorial design and statistical analysis

Morphology of the mycelial biomass

Results and discussion

Effect of inoculum size

Effect of carbon and nitrogen sources

Factorial design

Morphological observations of mycelium in submerged fermentation

Conclusion

Acknowledgements

REFERENCES

Publication Dates

History