Applications of Plackett–Burman and Central Composite Design for the Optimization of Novel Brevundimonas diminuta KT277492 Chitinase Production, Investigation of its Antifungal Activity

Warda, E. Ashour; Abeer, A. Abd El Aty; Eman, R. Hamed; Mahmoud, A. Swelim; Ahmed, I. El-Diwany

doi:10.1590/1678-4324-2016160245

ABSTRACT

Biological control strategy which can damage chitin, a vital component of pathogenic fungi and arthropods promises a safe solution for many fungal problems. And it’s more favorable than chemicals which increase health risks and environmental problems. Thus, the chitinase producers appear potential candidates of biological control of pathogenic fungi. Brevundimonus diminuta KT277492 is a new isolate that has been isolated recently from Egyptian soil. Significant factors that affecting the chitinase enzyme production were studied and optimized using Plackett-Burman and Response Surface Methodology (RSM). As a result, maximum production of chitinase enzyme was 832.87 IUL^-1, this result presented about 8.767-fold increase in the enzyme production. In the last phase of the study, partially purified chitinase enzyme obtained from B. diminuta KT277492 was tested against two pathogenic fungi and the results showed good inhibitory activity against A. alternata and F. solani with IZD of 31±0.25 and 25±0.91 mm respectively. Finally, obtained results indicated the value of optimization process and the optimized chitinase enzyme could be an excellent choice in application of food and biotechnology as a biofungicide. This reflects the necessity of studying the characteristics and kinetics of the enzyme in the forthcoming study.

Key words:
chitinase; Brevundimonas diminuta KT277492; optimization; Plackett–Burman; central composite design; antifungal

INTRODUCTION

According to ¹1 Hao Z, Yujie C, Xiangru L, Xiaoli Z, Zhiyou F, Dabing, Z. Optimization of nutrition factors on chitinase production from a newly isolated Chitiolyticbacter meiyuanensis. ‎Braz. J. Microbiol. 2011; 3:177-186. Chitin is the second most abundant insoluble biodegradable polymer, which exists naturally in the biosphere as a structural polysaccharide of 1,4-N-acetyl-D-glucosamine. It is highly distributed in nature, as a constituent of insect exoskeleton, shells of crustaceans, fungal cell walls and algae components ²2 Chang SC, Wang JT, Vandamme P, Hwang JH, Chang PS. Adefensive roles for chitinases. In: Jolle’s, Muzzarelli, R.A.A. (Eds.). 2004; 72: 1057-1083.. Chitinases enzymes (E.C.3.2.1.14) capable of hydrolyzing chitin to its oligo and monomeric components. There are several sources for chitinases as, microorganisms ²2 Chang SC, Wang JT, Vandamme P, Hwang JH, Chang PS. Adefensive roles for chitinases. In: Jolle’s, Muzzarelli, R.A.A. (Eds.). 2004; 72: 1057-1083., higher plants ³3 Graham LS, Sticklen MB. Plant chitinases of , Serratia marcescensCan. J. Microbiol.1994; 15: 689–696., even lower animals and birds ⁴4 Boman HG. Peptide antibiotics and their role in innate immunity. Annu. Rev. lmmunol., (1995); 13: 61-92..

Bacterial chitinases are believed to be important in the hydrolysis process of chitin for utilization as an energy and carbon sources, therefore, they have been implicated in protection against parasites in fungi, protozoa, invertebrates and especially in breakdown of chitin in the cell wall of fungal pathogens. ⁵5 Patil RS, Ghormande V, Deshpande MV. Chitinolytic enzymes: an exploration. Enzyme Microb Technol. 2000; 26: 473-483.^,⁶6 Abdel-Aziz SM, Moharam ME, Hamed HA, Mouafi FE. Extracellular Metabolites Produced by a Novel Strain, NRC-14: 1. Some Properties of the Chitinolytic System. Bacillus alveiNew York Science Journal. 2012; 5(1): 53- 62.. One of such bacteria are Brevundimonus sp. that able to produce the lytic enzymes such as chitinase and has tremendous impact for an industrial scale production ⁷7 Sim T, Oh JCS. Spent brewery as substrate for the production of cellulase by QM 94114. Trichoderma reeseiJ Ind Microbiol. 1990; 5: 153–8.. Recently, Ashour et al ⁸8 Ashour WE, Hamed ER, El-Diwany AI, Swelim MA, Abd El Aty AA. Isolation and Characterization of Plant Growth-Promoting Rhizobacteria from Rhizosphere and Evaluation of their Potential Substances Produced. Trigonella foenum- graecum LRes. J. Pharm., Biol. Chem. Sci. 2016; 7(3):130-143. locally isolated the rhizobacterial strain Brevundimonus diminuta KT277492 from rhizosphere of Trigonella foenum- graecum L in Egypt. The qualitative colloidal chitin agar plate test suggested its ability for first time to produce chitinase enzyme better than other isolates.

Chitinases are gaining much more attention worldwide because they have wide range of applications in the food, cosmetic industries, medical and fertilizer production areas ⁹9 Murao S, Kawada T, Itoh H, Oyama H, Shin T.Purification and characterization of a novel type of chitinase from . Vibrio alginolyticusBiosci Biotech Bioch. 1992; 56: 368 369.^,¹⁰10 Mathur A, Anita R, Gunjan B, Shikha B. Isolation of Bacillus producing chitinase from soil: production and purification of chito oligosaccharides from chitin extracted from fresh water crustaceans and antimicrobial activity of chitinase. Resent Res. Sci. Technol. 2011; 3: 1-6.. Also important in the biocontrol of fungal diseases in plants ¹¹11 Kamal K, Brian G. Biological control of plant pathogens. Plant Health Inst. Doi: 10. 1094/PHI. A. 1117.02. 2011.
https://doi.org/Doi: 10. 1094/PHI. A. 11... and as biobestsides ¹²12 Mendonsa ES, Vartak PH, Rao JU, Deshpande MV. An enzyme from that degrades insect cuticles for biocontrol of . Myrothecium verrucariaAedes aegypti mosquitoBiotechnol Lett.1996; 18: 373–376. doi: 10. 1007/BF00143454.
https://doi.org/doi: 10. 1007/BF00143454... .

In microorganisms, chitinase production is controlled by a receptor-inducer system; therefore, the composition of the culture medium can affect chitinase production ¹³13 Tasharrofi N, Sina A, Mehdi F, Hossein R, Mohammad RK, Mohammad AF. Optimization of Chitinase Production by Using Plackett-Burman Design and Response Surface Methodology. Bacillus pumilusIRAN J PHARM RES. 2011; 10(4): 759-768.. The conventional method for medium optimization involves changing one parameter at a time while keeping all others constant may be very expensive and time consuming. Furthermore, it is not effective to determine the combined effect of different factors. A number of statistical experimental designs have been used to overcome these problems ¹³13 Tasharrofi N, Sina A, Mehdi F, Hossein R, Mohammad RK, Mohammad AF. Optimization of Chitinase Production by Using Plackett-Burman Design and Response Surface Methodology. Bacillus pumilusIRAN J PHARM RES. 2011; 10(4): 759-768.^,¹⁴14 Lu Y, Mei L. Optimization of fermentation conditions for P450 BM-3monooxygenase production by hybrid design methodology. J. Zhejiang Univ. Sci. B.2007; 8: 27-32.. One of these methods are full factorial designs which provide more complete information.

The Plackett-Burman design ¹⁵15 Plackett RL, Burman JP. The design of optimum multifactorial experiments. Biometrica. 1944;33: 305-325., as a two level fractional factorial design, is especially useful in screening studies by estimating the main effects of variables. The variables screened by Plackett-Burman design can be optimized by using statistical and mathematical optimization tools such as response surface methodology (RSM) ¹⁶16 Myers RH, Montgomery D. Response Surface Methodology: Process and Product Optimization Using Designed Experiments. 2002. Wiley, New York.. Recent studies have indicated the use of RSM for analyzing effects of different factors on enzyme activity ¹⁷17 Nawani NN, Kapadnis BP. novel chitinolytic bacterium isolated from a freshwater pond for shrimp Optimization of chitinase production using statistics based experimental designs. Process biochem. 2005; 40: 651-660.and optimization of enzyme production ¹⁸18 Souza M, Roberto IC, Milagres AMF. Solid-State fermentation for xylanase production by using response surface methodology. Thermoascus aurantiacusAppl Microbiol Biotechnol. 1999;52: 768–772..

The present study directed towards the improvement and optimization of the valuable newly isolated Brevundimonus diminuta KT277492 chitinase enzyme. Depending on the novel statistical designs and estimation of its antifungal activity important for biological control strategies of pathogenic fungi.

MATERIALS AND METHODS

Chemicals

Chitin was purchased from (Sigma-Aldrich-MO-USA). Other reagents were of analytical grade.

Microorganism and maintenance

The rhizobacterial strain Brevundimonus diminuta KT277492 used in this study, was locally isolated from rhizosphere of Trigonella foenum- graecum L. collected from the green house of Ministry of Agriculture, Giza, Egypt. [⁸8 Ashour WE, Hamed ER, El-Diwany AI, Swelim MA, Abd El Aty AA. Isolation and Characterization of Plant Growth-Promoting Rhizobacteria from Rhizosphere and Evaluation of their Potential Substances Produced. Trigonella foenum- graecum LRes. J. Pharm., Biol. Chem. Sci. 2016; 7(3):130-143.]. The stock culture was maintained on nutrient agar slants at 4 °C and periodically subcultured in the National Research Center, Chemistry of Natural and Microbial Products Dept. ¹1 Hao Z, Yujie C, Xiangru L, Xiaoli Z, Zhiyou F, Dabing, Z. Optimization of nutrition factors on chitinase production from a newly isolated Chitiolyticbacter meiyuanensis. ‎Braz. J. Microbiol. 2011; 3:177-186..

Culture conditions for chitinase enzymes production

Preparation of seed culture

The seed culture was prepared by inoculating single colony in a plate containing the medium composed of (gl^-1) glucose 2.0, peptone 4.0, KH₂PO₄ 0.7, MgSO₄.7H₂O 0.5, K₂HPO₄ 0.3, FeSO₄·7H₂O, 0.02 and agar 20.0. The plates incubated for 48h at 30°C, after that a loop full of the colony transferred to 50 mL seed liquid medium, initial pH 7 in 250 mL Erlenmeyer flasks and incubated under shaking (200 rpm) for 48 h at 30°C.

Chitinase production medium

Nutrient broth medium (NB) used as basal medium for chitinase production. The medium contained the following components (gl^-1): yeast extract 1.5, NaCl 5.0, beef extract 1.5, supplemented with 0.1% colloidal chitin ¹⁹19 Kuddus SM, Ahmad RIZ. Isolation of novel chitinolytic bacteria and production optimization of extracellular chitinase. J of genetic engen & biote. 2013; 11:39-46.. 250 mL Erlenmeyer flasks containing 50 mL of NB medium autoclaved at 121°C for 20 min. After cooling, each flask was inoculated with 1 mL containing (1×10⁸ spores^-ml) of the fresh seed culture and incubated under the same conditions mentioned above. All the experiments were carried out in duplicate and the average values are reported as mean ± SD calculated using MS Excel.

Effect of incubation period on the chitinase production

The time courses of the chitinase production by B.diminuta KT277492, using the basal production medium were monitored for 168 h after 24 h intervals, fermentation broth was centrifuged and chitinase activity was determined ¹1 Hao Z, Yujie C, Xiangru L, Xiaoli Z, Zhiyou F, Dabing, Z. Optimization of nutrition factors on chitinase production from a newly isolated Chitiolyticbacter meiyuanensis. ‎Braz. J. Microbiol. 2011; 3:177-186..

Chitinase activity assay

According to ²⁰20 Sudhakar P, Nagarajan P. Production of chitinase by solid state fermentation from . Serratia marcescensInternational Journal of Chem.Tech. Research. 2011; 3(2): 590-598. chitinase activity was determined by a dinitrosalicylic acid (DNS) method ²¹21 Miller GL. Use of dinitrosalicylic acid reagent for determination of reducing sugars. Anal Chem. 1959; 31: 426–8. with some modification. This method works on the concentration of N-acetyl glucosamine (NAG), which is released as a result of enzymatic action ²²22 Ulhoa CJ, Peberdy JF. Regulation of chitinase synthesis in . Serratia marcescensJ Gen Microbiol. 1991; 14: 2163–9.. The 2mL reaction mixture contained 0.5 mL of 0.5% colloidal chitin in acetate buffer (pH 5.5), 0.5 mL crude enzyme extract and 1mL distilled water. The well vortexed mixture was incubated in a water bath shaker at 40°C for 2 h. The reaction was arrested by the addition of 3mL DNS reagent followed by heating at 100°C for 10 min with 40% Rochelle’s salt solution. The colored solution was centrifuged at 10,000 rotations per minute for 5 min and the absorption of the appropriately diluted test sample was measured at 530 nm using UV spectrophotometer (UV-160 A, Shimadzu, Japan) along with substrate and enzyme blanks. Colloidal chitin was prepared by the modified method of ²³23 Roberts A, Selitrenkoff N. Colloidal chitin preparations. J Gen Microbiol, 1985; 134: 169–76.. One unit (IU) of the chitinase activity is defined as the amount of enzyme that is required to release 1μmol of N-acetyl-d-glucosamine per minute from 0.5% of colloidal chitin solution under assay conditions.

Statistical optimization of B.diminuta KT277492 chitinase enzyme

Screening of critical media components using Plackett–Burman design

According to Shehata and Abd El Aty ²⁴24 Shehata AN, Abd El Aty AA. Optimization of process parameters by statistical experimental designs for the production of naringinase enzyme by marine fungi. Hindawi Publishing Corporation International J of Chem.Engineering, Article ID 273523, 10 pages. 2014 Plackett-Burman factorial design was used in our study to select significant medium components affecting the production of chitinase. Eleven medial components (chitin, glucose, starch, fructose, peptone, yeast extract, urea, potassium dihydrogen phosphate, dipotassium hydrogen phosphate, magnesium sulphate, sodium sulfate) were studied. Each variable was represented at 2-levels, upper (‘high, +’) and lower (‘low, -’) levels of the range covered by each variable and the response Table (1). Experimental responses were analyzed by first order model by the following equation Y=β_o+∑ 𝛽_𝑖𝑥_𝑖 , where Y is the response for chitinase production, B_o is the model intercept and β_i is the linear coefficient, and x_i is the level of the independent variable. According to the Stat-Ease analysis, a first-order model could be obtained from the regression results of fractional factorial experiment. This model describes the interaction among factors and it is used to screen and evaluate important factors that influence the response. The main effect of each variable was determined according to the following equation: 𝐸_𝑥𝑖= (Σ𝑀_𝑖+ −Σ𝑀_𝑖−)

𝑁

Where 𝐸𝑥𝑖 is the variable main effect, Σ𝑀𝑖+ is the summation of the response value at high level; Σ𝑀𝑖− is the summation of the response value at low level, and 𝑁 is the number of experiments. Statistical analysis of PBD is performed by using Design-Expert® 8 software from Stat-Ease, Inc. Table (2).

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Table (1)
Twelve trials Plackett-Burman experimental design with the response (chitinase activity).

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Table (2)
Statistical analysis of Plackett-Burman design.

Optimization of medium with the Response Surface Methodology

Chitin, yeast extract and potassium di-hydrogen phosphate were identified as the key factors that influenced chitinase production from the above experiment, and their suitable concentration ranges were also preliminarily determined. Consequently, response surface methodology of central composite design (CCD) used for statistical optimization of B.diminuta KT277492 chitinase enzyme. ²⁵25 Sandhya C, Adapa LK, Nampoothiri KM, Binod P, Szakacs G, Padney A. Extracellular chitinase production by in submerged fermentation. Trichoderma harzianumJ. Basic Microbiol. 2004; 44: 49-58.^,²⁶26 Vaidya RJ, Shah IM, Vyas PR, Chhatpar HS. Production of chitinase and its optimization isolate Alcaligenesxylosoxydans: Potential in antifungal biocontrol. from a novelW. J.Microbiol. Biotech. 2011; 17: 691-696.. The 3–factor–5–level central composite design (CCD) with twenty experiments were carried out to determine the optimal concentration of chitin (A), yeast extract (B) and potassium di-hydrogen phosphate (C) and to develop a mathematical correlation between the three important variables and chitinase activity (Y). All three variables were investigated at low level (-1), zero level (0) and high level (+1), respectively, with α = 1.682. Codes and actual values of variables and matrix of CCD along with chitinase activity of each trial are shown in Table (3). The behavior of the system was explained by the following quadratic model equation.

Y (activity) = β0 + β1A + β2B + β3C + β11A2 + β22B2 + β33C2 + β12AB + β13AC + β23BC

where Y (activity) was the predicted production of chitinase (IUL^-1), β0 intercept, β1, β2 and β3 linear coefficients, β11, β22 and β33 quadratic coefficients and β12, β13 and β23 interactive coefficients. A, B and C were the independent variables corresponding to the concentration of chitin, yeast extract and potassium di-hydrogen phosphate, respectively. Statistical analysis of the model was performed to evaluate the analysis of variance (ANOVA) Table (4) and the quadratic models were represented as contour plots (3D) using Design-Expert® 8 software from Stat-Ease, Inc. ²⁷27 Adinarayana K, Ellaiah P, Srinivasulu B, Bhavani R, Adinarayana G. Response surface methodological approach to optimize the nutritional parameters for neomycin production by under solid-state fermentation. Streptomyces marinensisProcess Biochem. 2003; 38:1565-1572.. All experiments were carried out in duplicate and the averages of chitinase activity were taken as response.

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Table (3)
Chitinase activity from the expermental design for the Response Surface Quadratic Model (RSM).

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Table (4)
Analysis of variance (ANOVA) for response surface quadratic model.

Partial purification of chitinase enzyme

Fractional precipitation of chitinase with acetone take place. the precipitant was added to the cold culture filtrate in ice-salt bath until the required concentration was achieved. After isolating the precipitated fraction by centrifugation in a refrigerated centrifuge, the supernatant was subjected to further precipitation and the process was repeated. The enzyme fractions obtained (25, 50 and 75% acetone) were dried at room temperature and assayed for chitinase activity ²⁸28 Shehata AN, Abd El Aty AA. Improved production and partial characterization of chitosanase from a newly isolated KM651986 and its application for chitosan oligosaccharides. Chaetomium globosumJ of Chem.and Pharm. Research, 2015; 7: 727-740..

In-vitro estimation of B.diminuta KT277492 chitinase antifungal activities

B.diminuta KT277492 chitinase enzyme was screened in-vitro against two pathogenic fungi by the agar diffusion technique in Petri dishes according to ²⁸28 Shehata AN, Abd El Aty AA. Improved production and partial characterization of chitosanase from a newly isolated KM651986 and its application for chitosan oligosaccharides. Chaetomium globosumJ of Chem.and Pharm. Research, 2015; 7: 727-740.^,²⁹29 Mostafa FA, Abd El Aty AA, Hamed ER, Eid BM, Ibrahim NA. Enzymatic, kinetic and anti-microbial studies on culture filtrate and . Aspergillus terreusAllium cepa seeds extract and their potent applicationsBioca and Agricu Biotech.2016;5:116–122.. The root rot pathogenic fungal isolates (Fusarium solani NRC15 and Alternaria alternata NRC43) were obtained from the culture collection of the Department of Chemistry of Natural and Microbial Products, National Research Center, Cairo, Egypt. The microorganisms were passaged at least twice to ensure purity and viability. About 200 µl of the partial purified enzyme was applied on each well (10 mm in diameter) made in the solidified inoculated potato dextrose agar plates. The plates incubated for 72 h at 28 ºC. The antifungal effect was evaluated by measuring the inhibition zone diameter (IZD) around wells of the enzyme in (mm) at three different points and the average values are reported as Mean ± SD using MS Excel.

RESULTS

Chitinase enzyme production

Qualitative test of colloidal chitin agar plates showed the ability of B. diminuta KT277492 to produce chitinase enzyme, which hydrolyzed chitin forming clear zone around the bacterial colony as shown in Fig. (1). Results also demonstrated the ability of the novel isolate to produce chitinase enzyme (95 IUL^-1) in nutrient broth medium supplemented with 0.1% chitin better than the other bacterial isolates as mentioned in the previous study. Therefore, B. diminuta KT277492 was selected as the best bacterial isolate for further optimization and improvement for chitinase enzyme production ⁸8 Ashour WE, Hamed ER, El-Diwany AI, Swelim MA, Abd El Aty AA. Isolation and Characterization of Plant Growth-Promoting Rhizobacteria from Rhizosphere and Evaluation of their Potential Substances Produced. Trigonella foenum- graecum LRes. J. Pharm., Biol. Chem. Sci. 2016; 7(3):130-143..

Fig. (1)
Photo of colloidal chitin agar plate showing clear hydrolysis zone around the B.diminuta KT277492 indicting chitinase production.

Optimization of B.diminuta KT277492 chitinase production

Sequential optimization approaches were applied in the present part of the study. The first approach deals with the determination of the optimum incubation period, by one-variable-at-a-time method. The second approach deals with screening for nutritional factors affecting the selected bacterial isolate for chitinase production. The third approach is to optimize the factors that control the enzyme production process.

Determination of the optimum incubation period

One variable-at-a-time method is used to determine the optimum incubation period for chitinase production. Results indicated that at different incubation periods (48, 72, 96, 120, 144 and 168 h) the activity was (59.89, 102.7, 27, 22, 00.00 and 00.00 IUL^-1, resp.). The incubation period for 72 h was the most favorable for maximum chitinase production.

Evaluation of the factors affecting chitinase production

Eleven different medium constituents (variables) were chosen to perform the optimization process. The averages of chitinase activity of the different trials (experimental) together with the predicted activity are shown in Table (1). The data showed wide variation from 0 to 397±0.008 IUL^-1 of chitinase activity. This variation reflects the importance of medium optimization to attain c)higher productivity. The main effects of the examined variables on the enzyme activity were calculated and presented graphically in Fig. (2). Chitin, yeast extract, KH₂PO₄ showed the higher positive effect on chitinase activity followed by K₂HPO_4, urea and glucose, respectively. On the other hand, starch, fructose, peptone, MgSO₄and Na₂SO₄ were contributed negatively. Overall, the percentage contribution of the significant variables indicated that 50.90% was for initial chitin, 23.29% for yeast extract and 6.61% for KH₂PO₄, the remaining 19.2% for the other variables (Fig. 3).The first order model equation developed by PB design showed the dependence of B. diminuta chitinase production on the medium constituent: Y ( chitinase activity IUL^-1 )=+24.26157+ 34.61852* chitin +1.81944 *glucose -8.28611 * starch -2.17083* peptone +26.34583 * yeast extract +5.12917 * Urea +22.44667 * KH₂PO₄ +16.08667*K₂HPO₄ -9.06333* MgSO₄ -9.78333 * Na₂SO₄

Fig. (2)
Pareto chart of eleven-factor standard effects on chitinase production.

Fig. (3)
The percentage contribution of the nutrient components.

Statistical analysis of the responses is represented in Table (2) The Model 𝐹 value of 14010.39 implies that the model is significant. Values of “Prob > 𝐹” less than 0.0500 indicate that model terms are significant. In this case A, B, C, E, F, G, H, J, K, L are significant model terms. In addition, the predicted 𝑅²2 Chang SC, Wang JT, Vandamme P, Hwang JH, Chang PS. Adefensive roles for chitinases. In: Jolle’s, Muzzarelli, R.A.A. (Eds.). 2004; 72: 1057-1083. was found to be 0.9990, which is in reasonable agreement with the 𝑅²2 Chang SC, Wang JT, Vandamme P, Hwang JH, Chang PS. Adefensive roles for chitinases. In: Jolle’s, Muzzarelli, R.A.A. (Eds.). 2004; 72: 1057-1083. of 1.000 and adjusted 𝑅²2 Chang SC, Wang JT, Vandamme P, Hwang JH, Chang PS. Adefensive roles for chitinases. In: Jolle’s, Muzzarelli, R.A.A. (Eds.). 2004; 72: 1057-1083. of 0.9999. This revealed that there is good agreement between the experimental and the theoretical values predicted by the model. The obtained results showed that varying of the chitin of the medium between 0.5-5 gl^-1 had high effect on chitinase production by B. diminuta. Maximal enzyme activities were obtained only when the chitin contribution in the culture medium was 5 gl^-1. According to these results, a medium of the following composition is expected to be near optimum (gl^-1): chitin 5, yeast extract 5, K₂HPO₄ 3. The enzyme activity measurement on this medium was 397±0.008 IUL^-1. This result presented about 4.18-fold increase in the enzyme activity, when compared to the results obtained in basal production medium (95 IUL^-1). Variables with less significant effect were not included in the next optimization experiment but instead were used in all trials at their (−1) level and (+1) level, for the negatively contributing variables and the positively contributing variables, respectively.

Optimization of the culture conditions by response surface design

Effect of chitin, yeast extract and KH₂PO₄ concentrations on chitinase production were studied by response surface design. The individual and interactive effects of these media components were studied by carrying out the chitinase assay run at different randomly selected level as shown in Table (3). The results of experiments performed in this section showed that the maximum average yield of chitinase was 832.87 ±0.282 IUL^-1, which obtained under the following optimum conditions of the media (gl^-1): chitin 8, yeast extract 6, KH₂PO₄ 3, glucose 8, urea 1 and K₂HPO₄3. This result presented about 8.767-fold increase in the enzyme activity, when compared to (95 IUL^-1), the results obtained in the first basal production medium, without any optimization. And about 2.0979-fold increase when compared with the maximum production yield from plackette-Burman. This reflects the necessity and value of optimization process. The second-order regression equation provided the levels of chitinase activity can be presented in terms of Actual Factors: (Chitinase activity) = -190.18212+139.66876* Chitin +213.58995* yeast extract-58.60884* KH2PO4 +4.47329* Chitin * yeast extract +1.74450* Chitin * KH2PO4 +11.61675* yeast extract * KH2PO4 -10.92271* Chitin²2 Chang SC, Wang JT, Vandamme P, Hwang JH, Chang PS. Adefensive roles for chitinases. In: Jolle’s, Muzzarelli, R.A.A. (Eds.). 2004; 72: 1057-1083. -28.87481* yeast extract²2 Chang SC, Wang JT, Vandamme P, Hwang JH, Chang PS. Adefensive roles for chitinases. In: Jolle’s, Muzzarelli, R.A.A. (Eds.). 2004; 72: 1057-1083. ++8.08712* KH2PO4²2 Chang SC, Wang JT, Vandamme P, Hwang JH, Chang PS. Adefensive roles for chitinases. In: Jolle’s, Muzzarelli, R.A.A. (Eds.). 2004; 72: 1057-1083..

Analysis of variance (ANOVA) for the Quadratic model was shown in Table (4). Value of ‘‘Model Prob >F’’ less than 0.0050 implied that the model was high significant. In this case A, B, C, AB, AC, BC, A², B², C² are significant model terms. The R² coefficient obtained, of 1.0000, suggests that it is a reliable model and the "Pred R-Squared" of 1.0000 is in reasonable agreement with the "Adj R-Squared" of 1.0000. Three dimensional (3D) response surface plots of chitinase production based on the final model are depicted in Fig. (4) which were generated in pair-wise combination of the three factors while keeping the other one at its optimum level.

Fig. (4)
Three dimensional response surface plot for the effect of (a) chitin and yeast extract, (b) chitin and KH2PO4, (c) yeast extract and KH2PO4

The validation was carried out under the optimum conditions of the media and the experimental chitinase production of 832.87 ±0.282 IUL^-1 was obtained which is closer to the predicted chitinase production of 832.821 IUL^-1; this result indicated the validity and the effectiveness of the proposed model.

In-vitro antifungal activity of B. diminuta KT277492 chitinase enzyme

The antifungal properties of the chitinase enzyme partially purified from B. diminuta KT277492 in a petri medium against pathogenic fungi F. solani, and A. alternata are shown in Fig. (5). Results indicated that the enzyme has good antifungal effect against all pathogenic tested fungi causes rot to roots of plants but with different degrees. The tested pathogenic fungi can be arranged according to their degree of susceptibility for B. diminuta KT277492 chitinase enzyme as the following order A. alternata ˃ F. solani, with zones of inhibition 31±0.25 and 25±0.91 mm, respectively.

Fig. (5)
The inhibition effect of partially purified chitinase enzyme from B. diminuta KT277492on F. solani (A) and A. alternata (B).

DISCUSSION

Chitin is usually thought as a kind of renewable polysaccharides and organic nitrogenous substance that only second respectively to cellulose and protein in abundance ¹1 Hao Z, Yujie C, Xiangru L, Xiaoli Z, Zhiyou F, Dabing, Z. Optimization of nutrition factors on chitinase production from a newly isolated Chitiolyticbacter meiyuanensis. ‎Braz. J. Microbiol. 2011; 3:177-186.. Several studies stated that chitin derivatives are of interest to people due to their diverse important applications. Therefore, isolating novel chitinase producing microorganisms and production optimization for high productivity are of great importance to the industry. In this context, a novel bacterial isolate B. diminuta KT277492 with strong chitinolytic activity was studied for statistical optimization of chitinase production.

In this study, the Plackett-Burman design was used to determine the most important factors influencing B. diminuta KT277492 chitinase production. There are many reports describing the use of this method in medium optimization with several microorganisms including pseudomonas, paenibacillus¹³13 Tasharrofi N, Sina A, Mehdi F, Hossein R, Mohammad RK, Mohammad AF. Optimization of Chitinase Production by Using Plackett-Burman Design and Response Surface Methodology. Bacillus pumilusIRAN J PHARM RES. 2011; 10(4): 759-768.^,³⁰30 Singh AK, Mehta G, Chhatpar HS. Optimization of medium constituents for improved chitinase production by Paenibacillus sp. D1 using statistical approach. Applied micro. 2009; 49: 708- 714., Alcaligenes xylosoxydans²⁶26 Vaidya RJ, Shah IM, Vyas PR, Chhatpar HS. Production of chitinase and its optimization isolate Alcaligenesxylosoxydans: Potential in antifungal biocontrol. from a novelW. J.Microbiol. Biotech. 2011; 17: 691-696., Pantoea dispersa³¹31 Gohel V, Chaudhary T, Vyas P, Chhatpar HS. Statistical screening of medium components for the production of chitinase by the marine isolate . Pantoea dispersaBiochem. Eng. J. 2006; 28: 50-56., Streptomyces³²32 HanY, Zhiyong L, Miao X, Zhang F. Statistical optimization of medium components to improve the chitinase activity of Streptomyces sp. Da11 associated with the South China Sea sponge . Craniella australiensisProcess Biochem. 2008; 43: 1088-1093., Azadirachta indica³³33 Prakash G, Srivastava K. Statistical media optimization for cell growth and azadirachtin production in A. Juss suspension cultures. Azadirachta indicaProcess Biochem. 2005; 40: 3795-3800., and Bacillus circulans³⁴34 Volken de Souza CF, Flores SH, Ayub MAZ. Optimization of medium composition for production of transglutaminase by BL32 using statistical experimental design. Bacillus circulansProcess Biochem. 2006; 41: 1186-1192. Based on Plackett-Burman design results it was found that among eleven tested components, chitin, yeast extract and KH₂PO₄ exhibit statistically significant effect on chitinase enzyme production. These results agree with several studies that showed chitin is a major inducer in chitinase production by many bacteria such Stenotrophomonas maltophilia³⁵35 Khan MA, Rifat H, Mahboob A, Abdin,MZ, Saleem J. Optimization of culture media for enhanced chitinase production from a novel strain of using response surface methodology. stenotrophomonas maltophiliaJ. Microbiol. Biotechnol. 2010; 20(11): 1597–1602., paenibacillus¹³13 Tasharrofi N, Sina A, Mehdi F, Hossein R, Mohammad RK, Mohammad AF. Optimization of Chitinase Production by Using Plackett-Burman Design and Response Surface Methodology. Bacillus pumilusIRAN J PHARM RES. 2011; 10(4): 759-768.^,³⁰30 Singh AK, Mehta G, Chhatpar HS. Optimization of medium constituents for improved chitinase production by Paenibacillus sp. D1 using statistical approach. Applied micro. 2009; 49: 708- 714. and Bacillus pumilus¹³13 Tasharrofi N, Sina A, Mehdi F, Hossein R, Mohammad RK, Mohammad AF. Optimization of Chitinase Production by Using Plackett-Burman Design and Response Surface Methodology. Bacillus pumilusIRAN J PHARM RES. 2011; 10(4): 759-768..

It has been suggested that for most microorganisms the optimum chitin concentration for chitinase induction is in the range of 10-20 gl^-1²⁵25 Sandhya C, Adapa LK, Nampoothiri KM, Binod P, Szakacs G, Padney A. Extracellular chitinase production by in submerged fermentation. Trichoderma harzianumJ. Basic Microbiol. 2004; 44: 49-58.. In our investigation, we found that the optimum chitin concentration for chitinase production by B. diminuta KT277492 is 8 gl^-1, which is considerably lower than the range given above. On the other hand ¹³13 Tasharrofi N, Sina A, Mehdi F, Hossein R, Mohammad RK, Mohammad AF. Optimization of Chitinase Production by Using Plackett-Burman Design and Response Surface Methodology. Bacillus pumilusIRAN J PHARM RES. 2011; 10(4): 759-768. demonstrated that the optimum chitin concentration for chitinase production by Bacillus pumilus is 4.76 gl^-1, which is considerably lower than the range we demonstrated.

The study of effect of additional nitrogen sources on chitinase production demonstrated that yeast extract as compared to urea and peptone, was found to have positive effect on chitinase production. According to Nawani and Kapadnis ¹⁷17 Nawani NN, Kapadnis BP. novel chitinolytic bacterium isolated from a freshwater pond for shrimp Optimization of chitinase production using statistics based experimental designs. Process biochem. 2005; 40: 651-660., this may be due to the presence of chitin or growth factors in yeast extract. On the contradiction some other nitrogen sources including peptone and urea are reported to enhance chitinase production ³⁶36 Akhir SM, Abd-Aziz S, Salleh MM, Rahman RAM. Optimisation of chitinase enzyme production from shrimp waste using TH-1 by Response Surface Methods. Bacillus licheniformisBiotech. 2009; 8:120-125. indicating that other mechanisms may be involved. The production of chitinolytic enzymes is also affected by minerals; we examined the effect of KH₂PO₄, K₂HPO₄, MgSO₄ and Na₂SO₄. KH₂PO₄ was found to have significant effect, while experiments showed that K₂HPO₄, MgSO₄ and Na₂SO₄ had negative effect. ³⁵35 Khan MA, Rifat H, Mahboob A, Abdin,MZ, Saleem J. Optimization of culture media for enhanced chitinase production from a novel strain of using response surface methodology. stenotrophomonas maltophiliaJ. Microbiol. Biotechnol. 2010; 20(11): 1597–1602. work showed that MgSO₄·7H₂O and KH₂PO₄ exerts positive effects on chitinase secretion in the presence of chitin. The maximum chitinase production was 832.87 IUL^-1. While Khan et al ³⁵35 Khan MA, Rifat H, Mahboob A, Abdin,MZ, Saleem J. Optimization of culture media for enhanced chitinase production from a novel strain of using response surface methodology. stenotrophomonas maltophiliaJ. Microbiol. Biotechnol. 2010; 20(11): 1597–1602. found that, maximum chitinase production from Stenotrphomonas maltophilia was 110 IUL^-1 using medium containing 4.94 gl^-1chitin, 5.56 gl^-1maltose, 0.62 gl^-1yeast extract, 1.33 gl^-1 KH₂PO₄, and 0.65 gl^-1MgSO₄·7H₂O. The chitinase producers appear potential candidates of biological control of pathogenic fungi. Several bacterial species are being reported as biofungicide. One of such bacteria was Bacillus subtilis TV-125 showed antifungal activity against Fusarium culmorum which is a pathogenic fungus that cause decomposition of roots of vegetables ³⁷37 Senol M, Nadaroglu H, Dikbas N, Kotan R. Purification of Chitinase enzymes from bacteria TV-125, investigation of kinetic properties and antifungal activity against Bacillus subtilisFusarium culmorum.Ann. of Clinical Micro. and Antimic., 2014; 13: 35.. These results agree with our findings where the partially purified B. diminuta KT277492 chitinase enzyme showed good antifungal activity against pathogenic F. solani, and A. alternata. According to our findings, chitinase enzyme produced from the novel isolate B. diminuta KT277492 is expected to be used in the agriculture against fungal infections as biocontrol agent.

CONCLUSIONS

The evaluation of medium components for B. diminuta KT277492 chitinase production was done using the Plackett- Burman statistical method. Out of eleven components chitin, yeast extract and KH₂PO₄ were found to be the most significant variables and further optimization using response surface optimization technique. The enzyme production increased from 95 to 832.87 IUL^-1and this is presented about 8.767-fold increase. Partially purified chitinase enzyme obtained from B. diminuta KT277492 showed good inhibitory effects against two pathogenic fungi.

REFERENCES

¹
Hao Z, Yujie C, Xiangru L, Xiaoli Z, Zhiyou F, Dabing, Z. Optimization of nutrition factors on chitinase production from a newly isolated Chitiolyticbacter meiyuanensis. ‎Braz. J. Microbiol. 2011; 3:177-186.
²
Chang SC, Wang JT, Vandamme P, Hwang JH, Chang PS. Adefensive roles for chitinases. In: Jolle’s, Muzzarelli, R.A.A. (Eds.). 2004; 72: 1057-1083.
³
Graham LS, Sticklen MB. Plant chitinases of , Serratia marcescensCan. J. Microbiol.1994; 15: 689–696.
⁴
Boman HG. Peptide antibiotics and their role in innate immunity. Annu. Rev. lmmunol., (1995); 13: 61-92.
⁵
Patil RS, Ghormande V, Deshpande MV. Chitinolytic enzymes: an exploration. Enzyme Microb Technol. 2000; 26: 473-483.
⁶
Abdel-Aziz SM, Moharam ME, Hamed HA, Mouafi FE. Extracellular Metabolites Produced by a Novel Strain, NRC-14: 1. Some Properties of the Chitinolytic System. Bacillus alveiNew York Science Journal. 2012; 5(1): 53- 62.
⁷
Sim T, Oh JCS. Spent brewery as substrate for the production of cellulase by QM 94114. Trichoderma reeseiJ Ind Microbiol. 1990; 5: 153–8.
⁸
Ashour WE, Hamed ER, El-Diwany AI, Swelim MA, Abd El Aty AA. Isolation and Characterization of Plant Growth-Promoting Rhizobacteria from Rhizosphere and Evaluation of their Potential Substances Produced. Trigonella foenum- graecum LRes. J. Pharm., Biol. Chem. Sci. 2016; 7(3):130-143.
⁹
Murao S, Kawada T, Itoh H, Oyama H, Shin T.Purification and characterization of a novel type of chitinase from . Vibrio alginolyticusBiosci Biotech Bioch. 1992; 56: 368 369.
¹⁰
Mathur A, Anita R, Gunjan B, Shikha B. Isolation of Bacillus producing chitinase from soil: production and purification of chito oligosaccharides from chitin extracted from fresh water crustaceans and antimicrobial activity of chitinase. Resent Res. Sci. Technol. 2011; 3: 1-6.
¹¹
Kamal K, Brian G. Biological control of plant pathogens. Plant Health Inst. Doi: 10. 1094/PHI. A. 1117.02. 2011.
» https://doi.org/Doi: 10. 1094/PHI. A. 1117.02. 2011
¹²
Mendonsa ES, Vartak PH, Rao JU, Deshpande MV. An enzyme from that degrades insect cuticles for biocontrol of . Myrothecium verrucariaAedes aegypti mosquitoBiotechnol Lett.1996; 18: 373–376. doi: 10. 1007/BF00143454.
» https://doi.org/doi: 10. 1007/BF00143454
¹³
Tasharrofi N, Sina A, Mehdi F, Hossein R, Mohammad RK, Mohammad AF. Optimization of Chitinase Production by Using Plackett-Burman Design and Response Surface Methodology. Bacillus pumilusIRAN J PHARM RES. 2011; 10(4): 759-768.
¹⁴
Lu Y, Mei L. Optimization of fermentation conditions for P450 BM-3monooxygenase production by hybrid design methodology. J. Zhejiang Univ. Sci. B.2007; 8: 27-32.
¹⁵
Plackett RL, Burman JP. The design of optimum multifactorial experiments. Biometrica. 1944;33: 305-325.
¹⁶
Myers RH, Montgomery D. Response Surface Methodology: Process and Product Optimization Using Designed Experiments. 2002. Wiley, New York.
¹⁷
Nawani NN, Kapadnis BP. novel chitinolytic bacterium isolated from a freshwater pond for shrimp Optimization of chitinase production using statistics based experimental designs. Process biochem. 2005; 40: 651-660.
¹⁸
Souza M, Roberto IC, Milagres AMF. Solid-State fermentation for xylanase production by using response surface methodology. Thermoascus aurantiacusAppl Microbiol Biotechnol. 1999;52: 768–772.
¹⁹
Kuddus SM, Ahmad RIZ. Isolation of novel chitinolytic bacteria and production optimization of extracellular chitinase. J of genetic engen & biote. 2013; 11:39-46.
²⁰
Sudhakar P, Nagarajan P. Production of chitinase by solid state fermentation from . Serratia marcescensInternational Journal of Chem.Tech. Research. 2011; 3(2): 590-598.
²¹
Miller GL. Use of dinitrosalicylic acid reagent for determination of reducing sugars. Anal Chem. 1959; 31: 426–8.
²²
Ulhoa CJ, Peberdy JF. Regulation of chitinase synthesis in . Serratia marcescensJ Gen Microbiol. 1991; 14: 2163–9.
²³
Roberts A, Selitrenkoff N. Colloidal chitin preparations. J Gen Microbiol, 1985; 134: 169–76.
²⁴
Shehata AN, Abd El Aty AA. Optimization of process parameters by statistical experimental designs for the production of naringinase enzyme by marine fungi. Hindawi Publishing Corporation International J of Chem.Engineering, Article ID 273523, 10 pages. 2014
²⁵
Sandhya C, Adapa LK, Nampoothiri KM, Binod P, Szakacs G, Padney A. Extracellular chitinase production by in submerged fermentation. Trichoderma harzianumJ. Basic Microbiol. 2004; 44: 49-58.
²⁶
Vaidya RJ, Shah IM, Vyas PR, Chhatpar HS. Production of chitinase and its optimization isolate Alcaligenesxylosoxydans: Potential in antifungal biocontrol. from a novelW. J.Microbiol. Biotech. 2011; 17: 691-696.
²⁷
Adinarayana K, Ellaiah P, Srinivasulu B, Bhavani R, Adinarayana G. Response surface methodological approach to optimize the nutritional parameters for neomycin production by under solid-state fermentation. Streptomyces marinensisProcess Biochem. 2003; 38:1565-1572.
²⁸
Shehata AN, Abd El Aty AA. Improved production and partial characterization of chitosanase from a newly isolated KM651986 and its application for chitosan oligosaccharides. Chaetomium globosumJ of Chem.and Pharm. Research, 2015; 7: 727-740.
²⁹
Mostafa FA, Abd El Aty AA, Hamed ER, Eid BM, Ibrahim NA. Enzymatic, kinetic and anti-microbial studies on culture filtrate and . Aspergillus terreusAllium cepa seeds extract and their potent applicationsBioca and Agricu Biotech.2016;5:116–122.
³⁰
Singh AK, Mehta G, Chhatpar HS. Optimization of medium constituents for improved chitinase production by Paenibacillus sp. D1 using statistical approach. Applied micro. 2009; 49: 708- 714.
³¹
Gohel V, Chaudhary T, Vyas P, Chhatpar HS. Statistical screening of medium components for the production of chitinase by the marine isolate . Pantoea dispersaBiochem. Eng. J. 2006; 28: 50-56.
³²
HanY, Zhiyong L, Miao X, Zhang F. Statistical optimization of medium components to improve the chitinase activity of Streptomyces sp. Da11 associated with the South China Sea sponge . Craniella australiensisProcess Biochem. 2008; 43: 1088-1093.
³³
Prakash G, Srivastava K. Statistical media optimization for cell growth and azadirachtin production in A. Juss suspension cultures. Azadirachta indicaProcess Biochem. 2005; 40: 3795-3800.
³⁴
Volken de Souza CF, Flores SH, Ayub MAZ. Optimization of medium composition for production of transglutaminase by BL32 using statistical experimental design. Bacillus circulansProcess Biochem. 2006; 41: 1186-1192.
³⁵
Khan MA, Rifat H, Mahboob A, Abdin,MZ, Saleem J. Optimization of culture media for enhanced chitinase production from a novel strain of using response surface methodology. stenotrophomonas maltophiliaJ. Microbiol. Biotechnol. 2010; 20(11): 1597–1602.
³⁶
Akhir SM, Abd-Aziz S, Salleh MM, Rahman RAM. Optimisation of chitinase enzyme production from shrimp waste using TH-1 by Response Surface Methods. Bacillus licheniformisBiotech. 2009; 8:120-125.
³⁷
Senol M, Nadaroglu H, Dikbas N, Kotan R. Purification of Chitinase enzymes from bacteria TV-125, investigation of kinetic properties and antifungal activity against Bacillus subtilisFusarium culmorum.Ann. of Clinical Micro. and Antimic., 2014; 13: 35.

Publication Dates

Publication in this collection
2016

History

Received
15 Jan 2016
Accepted
11 May 2016

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Hao Z, Yujie C, Xiangru L, Xiaoli Z, Zhiyou F, Dabing, Z. Optimization of nutrition factors on chitinase production from a newly isolated Chitiolyticbacter meiyuanensis. ‎Braz. J. Microbiol. 2011; 3:177-186.

[2] ²
Chang SC, Wang JT, Vandamme P, Hwang JH, Chang PS. Adefensive roles for chitinases. In: Jolle’s, Muzzarelli, R.A.A. (Eds.). 2004; 72: 1057-1083.

[3] ³
Graham LS, Sticklen MB. Plant chitinases of , Serratia marcescensCan. J. Microbiol.1994; 15: 689–696.

[4] ⁴
Boman HG. Peptide antibiotics and their role in innate immunity. Annu. Rev. lmmunol., (1995); 13: 61-92.

[5] ⁵
Patil RS, Ghormande V, Deshpande MV. Chitinolytic enzymes: an exploration. Enzyme Microb Technol. 2000; 26: 473-483.

[6] ⁶
Abdel-Aziz SM, Moharam ME, Hamed HA, Mouafi FE. Extracellular Metabolites Produced by a Novel Strain, NRC-14: 1. Some Properties of the Chitinolytic System. Bacillus alveiNew York Science Journal. 2012; 5(1): 53- 62.

[7] ⁷
Sim T, Oh JCS. Spent brewery as substrate for the production of cellulase by QM 94114. Trichoderma reeseiJ Ind Microbiol. 1990; 5: 153–8.

[8] ⁸
Ashour WE, Hamed ER, El-Diwany AI, Swelim MA, Abd El Aty AA. Isolation and Characterization of Plant Growth-Promoting Rhizobacteria from Rhizosphere and Evaluation of their Potential Substances Produced. Trigonella foenum- graecum LRes. J. Pharm., Biol. Chem. Sci. 2016; 7(3):130-143.

[9] ⁹
Murao S, Kawada T, Itoh H, Oyama H, Shin T.Purification and characterization of a novel type of chitinase from . Vibrio alginolyticusBiosci Biotech Bioch. 1992; 56: 368 369.

[10] ¹⁰
Mathur A, Anita R, Gunjan B, Shikha B. Isolation of Bacillus producing chitinase from soil: production and purification of chito oligosaccharides from chitin extracted from fresh water crustaceans and antimicrobial activity of chitinase. Resent Res. Sci. Technol. 2011; 3: 1-6.

[11] ¹¹
Kamal K, Brian G. Biological control of plant pathogens. Plant Health Inst. Doi: 10. 1094/PHI. A. 1117.02. 2011.
» https://doi.org/Doi: 10. 1094/PHI. A. 1117.02. 2011

[12] ¹²
Mendonsa ES, Vartak PH, Rao JU, Deshpande MV. An enzyme from that degrades insect cuticles for biocontrol of . Myrothecium verrucariaAedes aegypti mosquitoBiotechnol Lett.1996; 18: 373–376. doi: 10. 1007/BF00143454.
» https://doi.org/doi: 10. 1007/BF00143454

[13] ¹³
Tasharrofi N, Sina A, Mehdi F, Hossein R, Mohammad RK, Mohammad AF. Optimization of Chitinase Production by Using Plackett-Burman Design and Response Surface Methodology. Bacillus pumilusIRAN J PHARM RES. 2011; 10(4): 759-768.

[14] ¹⁴
Lu Y, Mei L. Optimization of fermentation conditions for P450 BM-3monooxygenase production by hybrid design methodology. J. Zhejiang Univ. Sci. B.2007; 8: 27-32.

[15] ¹⁵
Plackett RL, Burman JP. The design of optimum multifactorial experiments. Biometrica. 1944;33: 305-325.

[16] ¹⁶
Myers RH, Montgomery D. Response Surface Methodology: Process and Product Optimization Using Designed Experiments. 2002. Wiley, New York.

[17] ¹⁷
Nawani NN, Kapadnis BP. novel chitinolytic bacterium isolated from a freshwater pond for shrimp Optimization of chitinase production using statistics based experimental designs. Process biochem. 2005; 40: 651-660.

[18] ¹⁸
Souza M, Roberto IC, Milagres AMF. Solid-State fermentation for xylanase production by using response surface methodology. Thermoascus aurantiacusAppl Microbiol Biotechnol. 1999;52: 768–772.

[19] ¹⁹
Kuddus SM, Ahmad RIZ. Isolation of novel chitinolytic bacteria and production optimization of extracellular chitinase. J of genetic engen & biote. 2013; 11:39-46.

[20] ²⁰
Sudhakar P, Nagarajan P. Production of chitinase by solid state fermentation from . Serratia marcescensInternational Journal of Chem.Tech. Research. 2011; 3(2): 590-598.

[21] ²¹
Miller GL. Use of dinitrosalicylic acid reagent for determination of reducing sugars. Anal Chem. 1959; 31: 426–8.

[22] ²²
Ulhoa CJ, Peberdy JF. Regulation of chitinase synthesis in . Serratia marcescensJ Gen Microbiol. 1991; 14: 2163–9.

[23] ²³
Roberts A, Selitrenkoff N. Colloidal chitin preparations. J Gen Microbiol, 1985; 134: 169–76.

[24] ²⁴
Shehata AN, Abd El Aty AA. Optimization of process parameters by statistical experimental designs for the production of naringinase enzyme by marine fungi. Hindawi Publishing Corporation International J of Chem.Engineering, Article ID 273523, 10 pages. 2014

[25] ²⁵
Sandhya C, Adapa LK, Nampoothiri KM, Binod P, Szakacs G, Padney A. Extracellular chitinase production by in submerged fermentation. Trichoderma harzianumJ. Basic Microbiol. 2004; 44: 49-58.

[26] ²⁶
Vaidya RJ, Shah IM, Vyas PR, Chhatpar HS. Production of chitinase and its optimization isolate Alcaligenesxylosoxydans: Potential in antifungal biocontrol. from a novelW. J.Microbiol. Biotech. 2011; 17: 691-696.

[27] ²⁷
Adinarayana K, Ellaiah P, Srinivasulu B, Bhavani R, Adinarayana G. Response surface methodological approach to optimize the nutritional parameters for neomycin production by under solid-state fermentation. Streptomyces marinensisProcess Biochem. 2003; 38:1565-1572.

[28] ²⁸
Shehata AN, Abd El Aty AA. Improved production and partial characterization of chitosanase from a newly isolated KM651986 and its application for chitosan oligosaccharides. Chaetomium globosumJ of Chem.and Pharm. Research, 2015; 7: 727-740.

[29] ²⁹
Mostafa FA, Abd El Aty AA, Hamed ER, Eid BM, Ibrahim NA. Enzymatic, kinetic and anti-microbial studies on culture filtrate and . Aspergillus terreusAllium cepa seeds extract and their potent applicationsBioca and Agricu Biotech.2016;5:116–122.

[30] ³⁰
Singh AK, Mehta G, Chhatpar HS. Optimization of medium constituents for improved chitinase production by Paenibacillus sp. D1 using statistical approach. Applied micro. 2009; 49: 708- 714.

[31] ³¹
Gohel V, Chaudhary T, Vyas P, Chhatpar HS. Statistical screening of medium components for the production of chitinase by the marine isolate . Pantoea dispersaBiochem. Eng. J. 2006; 28: 50-56.

[32] ³²
HanY, Zhiyong L, Miao X, Zhang F. Statistical optimization of medium components to improve the chitinase activity of Streptomyces sp. Da11 associated with the South China Sea sponge . Craniella australiensisProcess Biochem. 2008; 43: 1088-1093.

[33] ³³
Prakash G, Srivastava K. Statistical media optimization for cell growth and azadirachtin production in A. Juss suspension cultures. Azadirachta indicaProcess Biochem. 2005; 40: 3795-3800.

[34] ³⁴
Volken de Souza CF, Flores SH, Ayub MAZ. Optimization of medium composition for production of transglutaminase by BL32 using statistical experimental design. Bacillus circulansProcess Biochem. 2006; 41: 1186-1192.

[35] ³⁵
Khan MA, Rifat H, Mahboob A, Abdin,MZ, Saleem J. Optimization of culture media for enhanced chitinase production from a novel strain of using response surface methodology. stenotrophomonas maltophiliaJ. Microbiol. Biotechnol. 2010; 20(11): 1597–1602.

[36] ³⁶
Akhir SM, Abd-Aziz S, Salleh MM, Rahman RAM. Optimisation of chitinase enzyme production from shrimp waste using TH-1 by Response Surface Methods. Bacillus licheniformisBiotech. 2009; 8:120-125.

[37] ³⁷
Senol M, Nadaroglu H, Dikbas N, Kotan R. Purification of Chitinase enzymes from bacteria TV-125, investigation of kinetic properties and antifungal activity against Bacillus subtilisFusarium culmorum.Ann. of Clinical Micro. and Antimic., 2014; 13: 35.

Trial	Carbon source				Nitrogen source			Energy source		Metal ions		Chitinase enzyme activity IUL^-1
Trial	A: Chitin	B: Glucose	C: Starch	D: Fructose	E: Peptone	F: Yeast extract	G: Urea	H: KH₂PO₄	J: K₂HPO₄	K: MgSO₄	L: Na₂SO₄	Experimental	Predicted
1	-1 (0.5)	+1(8)	-1(2)	+1(8)	+1(5)	-1(1)	+1(5)	+1(3)	+1(3)	-1(0)	-1(0)	196±0.411	196.292
2	+1(5)	-1(2)	+1(8)	+1(8)	+1(5)	-1(1)	-1(1)	-1(0.5)	+1(3)	-1(0)	+1(5)	165.6±0.007	165.892
3	+1(5)	+1(8)	-1(2)	+1(8)	+1(5)	+1(5)	-1(1)	-1(0.5)	-1(0.5)	+1(5)	-1(0)	295±0.8747	295.292
4	+1(5)	-1(2)	-1(2)	-1(2)	+1(5)	-1(1)	+1(5)	+1(3)	-1(0.5)	+1(5)	+1(5)	207±0.015	206.708
5	-1(0.5)	+1(8)	+1(8)	+1(8)	-1(1)	-1(1)	-1(1)	+1(3)	-1(0.5)	+1(5)	+1(5)	000	000
6	-1(0.5)	-1(2)	+1(8)	-1(2)	+1(5)	+1(5)	-1(1)	+1(3)	+1(3)	+1(5)	-1(0)	175.5±0.005	175.208
7	+1(5)	+1(8)	-1(2)	-1(2)	-1(1)	+1(5)	-1(1)	+1(3)	+1(3)	-1(0)	+1(5)	397±0.008	396.708
8	-1(0.5)	+1(8)	+1(8)	-1(2)	+1(5)	+1(5)	+1(5)	-1(0.5)	-1(0.5)	-1(0)	+1(5)	107±0.02	106.708
9	+1(5)	+1(8)	+1(8)	-1(2)	-1(1)	-1(1)	+1(5)	-1(0.5)	+1(3)	+1(5)	-1(0)	209.9±0.383	209.86
10	-1(0.5)	-1(2)	-1(2)	+1(8)	-1(1)	+1(5)	+1(5)	-1(0.5)	+1(3)	+1(5)	+1(5)	148.8±0.038	149.092
11	+1(5)	-1(2)	+1(8)	+1(8)	-1(1)	+1(5)	+1(5)	+1(3)	-1(0.5)	-1(0)	-1(0)	365±0.159	365.292
12	-1(0.5)	-1(2)	-1(2)	-1(2)	-1(1)	-1(1)	-1(1)	-1(0.5)	-1(0.5)	-1(0)	-1(0)	77.5±0.003	77.2

Source	Sum of Squares	df	Mean Square	F-value	P-value Prob>F
Model	1.430E+005	10	14302.27	14010.39	0.0066significant
A-Chitin	72805.34	1	72805.34	71319.52	0.0024
B-Glucose	357.52	1	357.52	350.22	0.0340
C-Starch	7415.24	1	7415.24	7263.91	0.0075
E-Peptone	226.20	1	226.20	221.58	0.0427
F-Yeast extract	33316.94	1	33316.94	32637.00	0.0035
G-Urea	1262.80	1	1262.80	1237.03	0.0181
H-KH₂PO₄	9447.24	1	9447.24	9254.44	0.0066
J-K₂HPO₄	4852.14	1	4852.14	4753.12	0.0092
K-MgSo₄	6160.80	1	6160.80	6035.07	0.0082
L-Na₂SO₄	7178.52	1	7178.52	7032.02	0.0076
Residual	1.02	1	1.02
Cor Total	1.430E+005	11

Trial number	Factor levels						Chitinase activity IUL^-1
	Chitin (A, gl^-1)		Yeast extract (B, gl^-1)		KH₂PO₄ (C, gl^-1)		Chitinase activity IUL^-1
	Coded	actual	coded	actual	coded	actual	Actual	Predicted
1	-1	2.00	-1	2.00	+1	3.00	352.295 ±0.022	352.188
2	0	5.00	-1.682	0.64	0	2.00	320.87 ±0.018	320.899
3	0	5.00	+1.682	7.36	0	2.00	510.65 ±0.024	510.547
4	-1.682	0.10	0	4.00	0	2.00	226.235 ±0.03	226.200
5	-1	2.00	+1	6.00	-1	1.00	363.76 ±0.008	363.883
6	0	5.00	0	4.00	0	2.00	742.432 ±0.881	742.714
7	0	5.00	0	4.00	0	2.00	742.432 ±0.141	742.714
8	0	5.00	0	4,00	0	2.00	742.432 ±0.016	742.714
9	+1	8.00	-1	2.00	+1	3.00	619.98 ±0.004	619.919
10	0	5.00	0	4.00	0	2.00	742.432±0.130	742.714
11	0	5.00	0	4.00	-1.682	0.32	716.87 ±0.025	716.625
12	-1	2.00	+1	6.00	+1	3.00	457.76 ±0.255	457.742
13	0	5.00	0	4.00	+1.682	3.68	813.76 ±0.317	813.391
14	+1	8.00	-1	2.00	-1	1.00	597.98 ±0.014	597.051
15	+1	8.00	+1	6.00	+1	3.00	832.87 ±0.282	832.821
16	+1	8.00	+1	6.00	-1	1.00	717.87 ±0.155	717.677
17	0	5.00	0	4.00	0	2.00	742.432 ±0.287	742.714
18	0	5.00	0	4.00	0	2.00	742.432±0.692	742.714
19	+1.682	10.05	0	4.00	0	2.00	725.88 ±0.127	725.839
20	-1	2.00	-1	2.00	-1	1.00	351.163 ±0.237	351.264

Source	Sum of Squares	df	Mean Square	F-value	P-value Prob>F
Model	6.902E+005	9	76684.97	4.623E+006	< 0.0001significant
A-Chitin	3.260E+005	1	3.260E+005	1.965E+007	< 0.0001
B-yeast extract	43415.52	1	43415.52	2.618E+006	< 0.0001
C-KH2PO4	11429.35	1	11429.35	6.891E+005	< 0.0001
AB	5762.98	1	5762.98	3.475E+005	< 0.0001
AC	219.12	1	219.12	13210.68	< 0.0001
BC	4318.36	1	4318.36	2.604E+005	< 0.0001
A²	1.332E+005	1	1.332E+005	8.028E+006	< 0.0001
B²	1.925E+005	1	1.925E+005	1.160E+007	< 0.0001
C²	943.64	1	943.64	56892.90	< 0.0001
Residual	0.17	10	0.017
Lack of Fit	0.17	5	0.033
Pure Error	0.000	5	0.000
Cor Total	6.902E+005	19

Brasil

Brasil

Applications of Plackett–Burman and Central Composite Design for the Optimization of Novel Brevundimonas diminuta KT277492 Chitinase Production, Investigation of its Antifungal Activity

ABSTRACT

INTRODUCTION

MATERIALS AND METHODS

Chemicals

Microorganism and maintenance

Culture conditions for chitinase enzymes production

Preparation of seed culture

Chitinase production medium

Effect of incubation period on the chitinase production

Chitinase activity assay

Statistical optimization of B.diminuta KT277492 chitinase enzyme

Screening of critical media components using Plackett–Burman design

Optimization of medium with the Response Surface Methodology

Partial purification of chitinase enzyme

In-vitro estimation of B.diminuta KT277492 chitinase antifungal activities

RESULTS

Chitinase enzyme production

Optimization of B.diminuta KT277492 chitinase production

Determination of the optimum incubation period

Evaluation of the factors affecting chitinase production

Optimization of the culture conditions by response surface design

In-vitro antifungal activity of B. diminuta KT277492 chitinase enzyme

DISCUSSION

CONCLUSIONS

REFERENCES

Publication Dates

History