Optimization of flask culture medium and conditions for hyaluronic acid production by a streptococcus equisimilis mutant nc2168

Chen, Yong-Hao; Li, Jun; Liu, Li; Liu, Hong-Zhi; Wang, Qiang

doi:10.1590/S1517-83822012000400040

Abstract

A mutant designated NC2168, which was selected from wild-type Streptococcus equisimilis CVCC55116by ultraviolet ray combined with60Co-γ ray treatment and does not produce streptolysin, was employed to produce hyaluronic acid (HA). In order to increase the output of HA in a flask, the culture medium and conditions for NC2168 were optimized in this study. The influence of culture medium ingredients including carbon sources, nitrogen sources and metal ions on HA production was evaluated using factional factorial design. The mathematical model, which represented the effect of each medium component and their interaction on the yield of HA, was established by the quadratic rotary combination design and response surface method. The model estimated that, a maximal yield of HA could be obtained when the concentrations of yeast extract, peptone, glucose, and MgSO4 were set at 3 g/100 mL, 2 g/100 mL, 0.5 g/100 mL and 0.15 g/100 mL, respectively. Compared with the values obtained by other runs in the experimental design, the optimized medium resulted in a remarkable increase in the output of HA and the maximum of the predicted HA production was 174.76 mg/L. The model developed was accurate and reliable for predicting the production of HA by NC2168.Cultivation conditions were optimized by an orthogonal experimental design and the optimal conditions were as follows: temperature 33ºC, pH 7.8, agitation speed 200 rpm, medium volume 20 mL.

Streptococcus equisimilis mutant; hyaluronic acid; optimization; culture medium; culture conditions

INDUSTRIAL MICROBIOLOGY

Optimization of flask culture medium and conditions for hyaluronic acid production by a streptococcus equisimilis mutant nc2168

Yong-Hao Chen^{I, II}; Jun Li^III; Li Liu^II; Hong-Zhi Liu^II; Qiang WangII, ^* * Corresponding Author. Mailing address: Institute of Agro-food Science and Technology, Chinese Academy of Agricultural Sciences, Yuanmingyuan West Road 2#, Beijing, P. R. China, 100193.; Tel/Fax: 86-010-62818455.; E-mail: caaswangqiang@hotmail.com

^IInstitute of Forestry and PomologyBeijing Academy of Agriculture and Forestry SciencesBeijing 100093, China

IIInstitute of Agro-food Science and Technology, Chinese Academy of Agricultural Sciences, Beijing 100193, China

^IIIBeijing Institute of landscape architecture, Beijing 100102, China

ABSTRACT

A mutant designated NC2168, which was selected from wild-type Streptococcus equisimilis CVCC55116by ultraviolet ray combined with⁶⁰C_o-γ ray treatment and does not produce streptolysin, was employed to produce hyaluronic acid (HA). In order to increase the output of HA in a flask, the culture medium and conditions for NC2168 were optimized in this study. The influence of culture medium ingredients including carbon sources, nitrogen sources and metal ions on HA production was evaluated using factional factorial design. The mathematical model, which represented the effect of each medium component and their interaction on the yield of HA, was established by the quadratic rotary combination design and response surface method. The model estimated that, a maximal yield of HA could be obtained when the concentrations of yeast extract, peptone, glucose, and MgSO₄ were set at 3 g/100 mL, 2 g/100 mL, 0.5 g/100 mL and 0.15 g/100 mL, respectively. Compared with the values obtained by other runs in the experimental design, the optimized medium resulted in a remarkable increase in the output of HA and the maximum of the predicted HA production was 174.76 mg/L. The model developed was accurate and reliable for predicting the production of HA by NC2168.Cultivation conditions were optimized by an orthogonal experimental design and the optimal conditions were as follows: temperature 33ºC, pH 7.8, agitation speed 200 rpm, medium volume 20 mL.

Key words:Streptococcus equisimilis mutant; hyaluronic acid; optimization; culture medium; culture conditions

INTRODUCTION

Hyaluronic acid (HA), a linear, unbranched polysaccharide consisted of alternating N-acetyl-D-glucosamine and D-glucuronic acid, exists in many mammalian connective tissues such as joints, vitreous bodies, umbilical cords, cartilages, skins, and combs of fowls as a constituent; it plays an important role in many biological processes such as in tissue hydration, proteoglycan organisation in the extracellular matrix, and tissue repair (14). HA is a valuable biopolymer in ophthalmics, orthopaedics, wound healing, tissue engineering, drug delivery, cosmetics, and as a vaccine aid (2, 6, 15).

In recent years, instead of extracting HA from rooster combs and umbilical cord, preparing HA through microbial fermentation is being used more, because the risk of cross-species viral infection can be avoided and the isolation process of high purity and high molecular weight HA can be simplified(5). This polymer is produced commercially by fermentation of the Lance field group C streptococci, Streptococcus equi subspeciesequsimilis and Streptococcus equi subspecieszooepidemicus which can produce a capsule that is composed of hyaluronic acid polymers identical to that found in mammalian connective tissues (10). However, Streptococcus spp. strain can produce streptolysin which causes hemolysis. Thus, it is very important that streptolysin is absent in the hyaluronic acid obtained by cultivation of the microorganism. According to the reports (8, 10, 12), NTG treatment was an effective induced measure to obtain a mutant which does not produce streptolysin. However, in this study, a mutant designated NC2168, which was selected from wild-type Streptococcus equisimilis CVCC55116 by ultraviolet ray combined with ⁶⁰C_o-γ ray treatment and does not produce streptolysin, was employed to produce HA.

Because no general medium works best for a new strain being tested, the optimization of the medium for the new mutant is necessary (9). Meanwhile, large numbers of experiments in stirred controlled vessels are not practical. However, the best medium chosen from shake flask data can build a foundation for the large scale stirred tank, thus it's essential to improve the HA production through the optimization of shake flask medium and cultivation conditions.

As a collection of statistical techniques for experiment designing, model developing and factors evaluating, response surface methodology (RSM) has been extensively applied in optimization of medium composition, conditions of enzymatic hydrolysis, fermentation and food manufacturing processes (3, 11, 13, 17,). In this study, to increase the yield of HA, the optimum medium composition was carried out by RSM and the optimum cultivation conditions including temperature, rotate speed, pH, and medium volume were investigated through orthogonal experimental design.

MATERIALS AND METHODS

Microorganism and Medium

The strain used in this study was Streptococcus equisimilis CVCC55116, from Chinese Veterinary Culture Collection. Microorganisms were grown in a solid culture medium consisting of 1 g glucose, 16 g ox-brain extract powder, 4 g ox-heart extract powder (Brain Heart Infusion, BHI), 10 g yeast extract and 20 g agar. The blood agar (Joint Logistics Department, Beijing Military Area Command) was used for the isolation of the mutant without hemolysin. The selected mutant was cultivated in the fermentation medium consisting of 20 g glucose, 16 g ox-brain extract powder, 4 g ox-heart extract powder (BHI), 10 g peptone, 2 g MgSO₄ and 2 g K₂HPO₄ per liter of distilled water. The cultivation conditions were: temperature 37ºC, pH 7.4, and agitation speed 180 rpm.

Mutagenesis

Streptococcus equisimilis CVCC55116 was incubated at 37°C for 24 h on the agar plate. A single colony was inoculated in a 250 mL flask containing 50 mL of fermentation medium; it was incubated at 37°C for 12h. The grown cells were collected by centrifugation at 3,000 g for 20 min and washed with distilled water. The collected cells were resuspended in distilled water and performed ultraviolet ray mutagenesis in a dark room. After ultraviolet ray treatment, the cells were incubated at 37°C for 12 h in the fermentation medium and plated on the blood agar plate for the selection of nonhemolytic mutants. The mutant treated by ultraviolet ray was irradiated by ⁶⁰C_O-γ ray with dose rate of 31.42 Gy/min. The irradiation doses of the two mutagenesis methods were based on irradiation time and corresponding the fatality rate. Through repeated screening, a high-producing hyaluronic acid mutant designated NC2168 was obtained.

Analytical Methods

CTAB Turbidimetric method was applied to determine the HA content (1). Ultraviolet and visible spectrophotometer (Rili, China) was used here.

Experiment design

Based on the single factor experiments, the carbon and nitrogen source and inorganic salt were determined, and the response surface methodology (RSM) was employed to optimize the medium for the mutant NC2168.Then, 23 runs were carried out using a factorial central composite design to study four independent variables each at five levels. The four independent variables X₁ (yeast extract), X₂ (peptone), X₃ (sucrose), and X₄(MgSO₄) at five levels and the experimental design were given in Table 1. A mathematical model, describing the relationships between the process indices (the output of HA) and the medium component contents in a quadratic equation, was developed. The accuracy and general ability of the above polynomial model could be evaluated by the coefficient of determination R². As for the optimization of the culture conditions, the experiment was arranged based on the 3 levels of orthogonal experimental design with 4 factors and 9 runs as shown in Table 3. Four independent variables representing temperature, rotate speed, initial pH and medium volume were employed respectively. In each case, the output of HA was monitored and all the experiments were carried out in triplicate for the average calculation.

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Statistical analysis

Statistical evaluations were performed using F-test. A value of p < 0.05 was considered significant. The quadratic model was obtained by a standard multinomial regression method for four factors using the software Statistica, version 6.0. The extremum was also acquired by differential coefficient calculation and canonical analysis which was used to predict the shape of the curve generated by the model. Variance analysis on the orthogonal experiment results was performed by SAS, version 8.0.

RESULTS AND DISCUSSION

Optimization of culture medium

Effect of nitrogen sources on the output of HA: The effect of organic and inorganic nitrogen sources on the yield of HA is shown in Figure 1a. It indicates that the output of HA based on inorganic source (NH₄)₂SO₄ was the lowest while those based on most of organic nitrogen sources were superior. The main reason might be that organic sources were more easily taken up, transported and absorbed while inorganic nitrogen could restrain the metabolism of the strain to some extent. It is easy to see that BHI was the best organic nitrogen source to cultivate the mutant NC2168 and the highest output of HA based on BHI touched 169.20 mg/L, even with the medium containing 1 g/100 mL BHI, the output was higher than that based on other nitrogen sources. However, the cost of BHI is several times higher than that of other nitrogen sources so that it is essential to find out a substitute to BHI. A composite medium containing multiple growth factors might meet the higher demand of Streptococcus on nutrition. As shown in Figure 1a, when the concentrations of yeast extract and peptone were 3 g/100 mL and 2 g/100 mL, the output of HA got 114.25 mg/L and 101.23 mg/L, respectively, which were the two better nitrogen sources besides BHI. The composite nitrogen source consisting of yeast extract and peptone might be a promising nitrogen source which could provide more necessary growth factors.

Based on the previous experiments, 3 g/100 mL yeast extract and 2 g/100 mL peptone were fixed respectively, and added 0.5, 1.0, 1.5, 2.0 and 2.5 g/100 mL peptone and yeast extract into the medium to constitute the composite nitrogen sources. The results in Figure 1b shows that 141.64 mg/L yield of HA was obtained using 3 g/100 mL yeast extract and 1.5 g/100 mL peptone, which was increased by 23.97% compared with 114.25 mg/L, using yeast extract only.

Effect of carbon sources on the output of HA: In this study, glucose, fructose, galactose, sucrose, maltose, xylose were used as the carbon sources respectively to enhance the yield of HA. Their influences at different concentrations are presented in Figure 2. It shows that the output of HA could be affected greatly by the kind and quantity of carbon sources. As shown in Figure 2, the highest output of HA was based on 0.5 g/100 mL glucose as the carbon source. Other carbon sources including maltose at 1.5 g/100 mL, fructose at 0.5 g/100 mL and sucrose at 0.5 g/100 mL could obtain a higher output of HA. However, the galactose and xylose could not be utilized well and the corresponding output of HA was relatively low. We speculate that both UDP glucuronic acid and N-acetamide uridine diphosphoglucose are the synthesize precursors of HA and thalli. Maltose and sucrose could be easily decompounded into glucose by the thalli and fructose could be easily transformed into glucose so that they could be utilized better.

Effect of metal ions on the output of HA: As for a cell, many metal ions are indispensable for active centers of an enzyme. During the process synthesizing HA, the HA synthetase is a key enzyme, which catalyzes the precursor of HA to synthesize HA (16). In this study, the effects of Mg²⁺ and K¹⁺ on the output of HA were explored considering their possible roles in the HA synthetase. As shown in Figure 3, the highest output of HA was achieved up to 198.86 mg/L at MgSO₄ concentration of 0.15 g/100 mL and the difference of output based on the different concentration of MgSO₄ was pronounced (p <0.05). However, as for KH₂PO₄, the output of HA based on the different concentration was almost the same, thus the effect of KH₂PO₄ concentrationwas negligible in the assigned range while Mg²⁺ was selected to be performed in the following experiment.

Orthogonal rotatable central composite design

In the previous experiments, the suitability of various nitrogen sources, carbon sources, and metallic ions for the superior production of HA was evaluated. After the influence factors were determined, response surface method was used to optimize the culture medium for enhancing the output of HA through the quadratic rotary combination design (4, 7). A set of 23 experiments were required with four variables, and each variable being at five levels (α = 1.682). The independent and dependent variables were analyzed to get regression equation, which was an empirical relationship between the HA output and the test variable in coded units. The regression equation obtained for the output of HA is as follows:

Y=174.76-3.39X₁+2.78X₂+6.09X₃+1.26X₄

-9.27X₁²-12.93X₂²-14.36X₃²-12.21X₄²

+1.03X₁X²-0.32X₁X₃+0.91X₁X₄+0.91X₂X₃-0.32X₂X₄-.03X₃X₄ (1)

Y represents the response, which is a dependent variable, the output of HA (mg/L), and X₁, X2, X₃, and X₄ represent values of the independent variables, yeast extract, peptone, glucose and MgSO₄, respectively.

Each of the observed value was compared with the predicted value which was calculated from the model, as depicted in Table 1. The statistical significance of the quadratic model equation was checked by analysis of variance (ANOVA), as shown in Table 2. The multiple coefficient of correlation R=0.9537 indicates a close agreement between experimental and predicted value of the HA output. The total determination coefficient, R²= 0.9095 implies that 90.95% of the variability in the response could be explained by the model.

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The significance of each coefficient was checked using the variance ratio test (F-test) and p- value in Table 2. On the one hand, the F-test result shows that F_0.05 (2, 6) = 5.14<F₁= 7.581<F_0.01 (2, 6) = 10.92, which implies that the Lack of Fit was significant wherein α= 0.05 level but not significant wherein α= 0.01 level. Based on the analysis of the culture medium composition, it manifests that the existence of the Lack of Fit factors were mainly due to the high order interaction. On the other hand, F₂ = 5.746> F_0.01 (14, 8) = 5.56 indicates that the regression equation was significant at α= 0.01 level.

The p- value less than 0.05 indicates that the model terms were significant. The corresponding variables will be more significant if the absolute F-value becomes larger and the p -value becomes smaller. In this case, it can be seen that the variables with the remarkable effects on the level of HA production were the quadratic term of glucose (X₃X₃), peptone (X₂X₂), MgSO₄ (X₄X₄), yeast extract (X₁X₁).Thep -value greater than 0.10 indicate that the model terms were not significant.

The maximum of the model was obtained from the equation when the concentration of yeast extract, peptone, glucose and MgSO₄ were at 3.00 g/100 mL, 2.00 g/100 mL, 0.5 g/100 mL and 0.15 g/100 mL, respectively. The maximum of the predicted HA production was 174.76 mg/L. The triplicate experiments were also carried out to verify the accuracy of the result for HA production in a similar way as that of production model. Under the calculated optimal culture condition, the mean value of HA production was 178.53±3.50 mg/L, which was in agreement with the predicted value well. The average relative error between actual value and predicted value was 4.95%. Therefore, the model developed was considered to be accurate and reliable for predicting the production of HA by NC2168.

The 3-D response surface and the 2-D contour plots were the graphical representations of the regression equation (13) and showed the effect of each independent variable and also their mutual effects on the production of HA. The response surface curves and also contour plots for variations in HA production were depicted in Figure 4. The response surface representing HA yield was a function of the concentrations of the two medium components with other ingredients being at an optimal level. By using the response surface plot, the interaction between two variables and their optimum levels can be easily understood and located. The HA output was influenced by all the four independent variables. The maximum point was achieved when glucose, peptone, yeast extract and MgSO₄ concentrations were at their zero levels.

Optimization of culture condition

The effect of four factors: temperature, rotate speed, original pH and medium volume on the output of HA under the orthogonal experimental design are presented in Table 3. The intuitionistic analysis shows that the maximum HA production was 196.73 mg/L, which was got by the fifth run. The optimum culture condition was: initial pH=7.8; medium volume=20 mL; temperature=33ºC; rotate speed=150 rpm. The range analysis manifests that the factors order for the effect was: initial pH> medium volume > temperature > rotate speed.

The variance analysis (Table 4) showed that the effects of pH and medium volume were extremely significant (p <0.01) and the effect of temperature was significant (p <0.05). The result was in agreement with the range analysis. The validated experiment was run at the optimum condition mentioned above. HA output touched 224.52 mg/L, which was also in agreement with the orthogonal experiment result.

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CONCLUSION

As to the new mutant Streptococcus equisimilis NC2168 without producing streptomycin, of which the optimum culture medium for maximum HA production was carried out with orthogonal rotatable central composite design and RSM. The model developed was considerably accurate and reliable for predicting the production of HA by NC2168 and a maximum of 174.76 mg/L HA was obtained using the optimal culture medium as follows: yeast extract=3 g/100 mL, peptone=2 g/100 mL, glucose=0.5 g/100 mL, MgSO₄ =0.15 g/100 mL. The optimized culture condition was: temperature 32℃, rotate speed 200 rpm, initial pH 7.8, and medium volume 20 mL. The maximum HA production was 224.52 mg/L under the optimum condition. It is evident that the output of HA was affected significantly by culture medium and conditions optimization. The NC2168 showed 149.08% increase in HA production under the optimum culture medium and conditions. This design proved to be crucial in achieving increase in the production of HA.

ACKNOWLEDGEMENTS

This work was supported by Key Projects in the National Science and Technology Pillar Program (No.2010 BAD05A01-09) and by the Foundation of Chinese Academy of Agricultural Sciences for Outstanding Researchers.

Submitted: August 04, 2011

Approved: June 07, 2012

1. Chen, Y. H.; Wang, Q. (2009). Establishment of CTAB Turbidimetric method to determine hyaluronic acid content in fermentation broth. Carbohyd. Polym. 78: 178-181.
2. Crescenzi, V. (1995). Microbial polysaccharides of applied interest: ongoing research activities in Europe. Biotechnol. Prog. 11: 251-259.
3. Cui, F. J.; Li, Y.; Xu, Z. H.; Xu, H. Y.; Sun, K.; Tao, W. Y. (2006). Optimization of the medium composition for production of mycelial biomass and exopolymer by Grifola frondosa GF9801 using response surface methodology. Bioresour. Technol. 97: 1209-1216.
4. Feng, Y. Y.; He, Z. M.; Ong, S. L.; Hu, J. Y.; Zhang, Z. G.; Ng, W. J. (2003). Optimization of agitation, aeration, and temperature conditions for maximum β-mannanase production. Enzyme. and Microbial. Techonol. 32: 282-289.
5. Fong Chong, B.; Blank, L. M.; Mclaughlin, R.; Nielsen, L. K. (2005). Microbial hyaluronic acid production. Appl. Microbiol. Biotechnol. 66: 341-351.
6. Fong Chong, B.; Nielsen, L. K. (2003). Amplifying the cellular reduction potential of Streptococcus zooepidemicus J. Biotechnol. 100: 33-41.
7. Hanan, M. I.; Wan, M.; Wan, Y.; Aidil, A. H. (2005). Optimization of medium for the production of β-cyclodextrin glucanotransferase using Central Composite Design (CCD). Process. Biochem. 40: 753-758.
8. Hosoya, H.; Kimura, M.; Endo, H. (1994). Novel production process of hyaluronic acid and bacterium strain therefore as well as cosmetic composition containing hyaluronic acid. Eur. Pat. 0, 244, 757.
9. Kennedy, M.; Krouse, D. (1999). Strategies for improving fermentation medium performance: a review. J. Ind. Microbiol. Biotechnol. 23: 456-475.
10. Kim, J. H.; Yoo,S. J.; Oh, d. k.; Kweon Y. G.; Park D. W.; Lee C. H., Gil G. H. (1996). Selection of a Streptococcus equi mutant and optimization of culture conditions for the production of high molecular weight hyaluronic acid.Enzyme. Microbial. Technol. 19: 440-445.
11. Mao, X. B.; Eksriwong, T.; Chauvatcharin, S.; Zhong, J. J. (2005). Optimization of carbon source and carbon/nitrogen ratio for cordycepin production by submerged cultivation of medicinal mushroom Cordyceps militaris. Process. Biochem. 40: 1667-1672.
12. Nimrod, A.; Greenman, B.; Kanner, D. (1988). High molecular weight sodium hyaluronate.U.S.A. Pat. 4, 784, 990.
13. Oh,B. R.;Seo,J. W.;Choi, M. H.;Kim, C. H. (2008). Optimization of Culture Conditions for 1,3-Propanediol Production from Crude Glycerol by Klebsiella pneumoniae Using Response Surface Methodology. Biotechnol. Bioprocess. Eng. 13:666-670.
14. Phrem, P. (1983). Synthesis of hyaluronate in differentiated teratocxcinoma cells: Characterization of the synthase. Biochem. J. 211: 181-189.
15. Radaeva, I. F.; Kostina, G. A.; Zmievskii, A.V. (1997). Hyaluronic acid: biological role, structure, synthesis, isolation, purification, and applications. Appl. Biochem. Microbiol. 33:111-115.
16. Stoolmiller, A. C.; Dorfman, A. (1969). The Biosynthesis of hyaluronic acid by Streptococcus J. Biol. Chem. 244(2): 236-246.
17. Wang, Y. X.; Lu, Z. X. (2005). Optimization of processing parameters for the mycelial growth and extracellular polysaccharide production by Boletus spp. ACCC50328. Process. Biochem. 40: 1043-1051.

*

Corresponding Author. Mailing address: Institute of Agro-food Science and Technology, Chinese Academy of Agricultural Sciences, Yuanmingyuan West Road 2#, Beijing, P. R. China, 100193.; Tel/Fax: 86-010-62818455.; E-mail:

caaswangqiang@hotmail.com

Publication Dates

Publication in this collection
19 Feb 2013
Date of issue
Dec 2012

History

Received
04 Aug 2011
Accepted
07 June 2012

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Chen, Y. H.; Wang, Q. (2009). Establishment of CTAB Turbidimetric method to determine hyaluronic acid content in fermentation broth. Carbohyd. Polym. 78: 178-181.

[2] 2. Crescenzi, V. (1995). Microbial polysaccharides of applied interest: ongoing research activities in Europe. Biotechnol. Prog. 11: 251-259.

[3] 3. Cui, F. J.; Li, Y.; Xu, Z. H.; Xu, H. Y.; Sun, K.; Tao, W. Y. (2006). Optimization of the medium composition for production of mycelial biomass and exopolymer by Grifola frondosa GF9801 using response surface methodology. Bioresour. Technol. 97: 1209-1216.

[4] 4. Feng, Y. Y.; He, Z. M.; Ong, S. L.; Hu, J. Y.; Zhang, Z. G.; Ng, W. J. (2003). Optimization of agitation, aeration, and temperature conditions for maximum β-mannanase production. Enzyme. and Microbial. Techonol. 32: 282-289.

[5] 5. Fong Chong, B.; Blank, L. M.; Mclaughlin, R.; Nielsen, L. K. (2005). Microbial hyaluronic acid production. Appl. Microbiol. Biotechnol. 66: 341-351.

[6] 6. Fong Chong, B.; Nielsen, L. K. (2003). Amplifying the cellular reduction potential of Streptococcus zooepidemicus J. Biotechnol. 100: 33-41.

[7] 7. Hanan, M. I.; Wan, M.; Wan, Y.; Aidil, A. H. (2005). Optimization of medium for the production of β-cyclodextrin glucanotransferase using Central Composite Design (CCD). Process. Biochem. 40: 753-758.

[8] 8. Hosoya, H.; Kimura, M.; Endo, H. (1994). Novel production process of hyaluronic acid and bacterium strain therefore as well as cosmetic composition containing hyaluronic acid. Eur. Pat. 0, 244, 757.

[9] 9. Kennedy, M.; Krouse, D. (1999). Strategies for improving fermentation medium performance: a review. J. Ind. Microbiol. Biotechnol. 23: 456-475.

[10] 10. Kim, J. H.; Yoo,S. J.; Oh, d. k.; Kweon Y. G.; Park D. W.; Lee C. H., Gil G. H. (1996). Selection of a Streptococcus equi mutant and optimization of culture conditions for the production of high molecular weight hyaluronic acid.Enzyme. Microbial. Technol. 19: 440-445.

[11] 11. Mao, X. B.; Eksriwong, T.; Chauvatcharin, S.; Zhong, J. J. (2005). Optimization of carbon source and carbon/nitrogen ratio for cordycepin production by submerged cultivation of medicinal mushroom Cordyceps militaris. Process. Biochem. 40: 1667-1672.

[12] 12. Nimrod, A.; Greenman, B.; Kanner, D. (1988). High molecular weight sodium hyaluronate.U.S.A. Pat. 4, 784, 990.

[13] 13. Oh,B. R.;Seo,J. W.;Choi, M. H.;Kim, C. H. (2008). Optimization of Culture Conditions for 1,3-Propanediol Production from Crude Glycerol by Klebsiella pneumoniae Using Response Surface Methodology. Biotechnol. Bioprocess. Eng. 13:666-670.

[14] 14. Phrem, P. (1983). Synthesis of hyaluronate in differentiated teratocxcinoma cells: Characterization of the synthase. Biochem. J. 211: 181-189.

[15] 15. Radaeva, I. F.; Kostina, G. A.; Zmievskii, A.V. (1997). Hyaluronic acid: biological role, structure, synthesis, isolation, purification, and applications. Appl. Biochem. Microbiol. 33:111-115.

[16] 16. Stoolmiller, A. C.; Dorfman, A. (1969). The Biosynthesis of hyaluronic acid by Streptococcus J. Biol. Chem. 244(2): 236-246.

[17] 17. Wang, Y. X.; Lu, Z. X. (2005). Optimization of processing parameters for the mycelial growth and extracellular polysaccharide production by Boletus spp. ACCC50328. Process. Biochem. 40: 1043-1051.

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Optimization of flask culture medium and conditions for hyaluronic acid production by a streptococcus equisimilis mutant nc2168

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