Thermal Characterization of Purified Glucose Oxidase from A Newly Isolated Aspergillus Niger UAF-1.

An intracellular glucose oxidase was isolated from the mycelium extract of a locally isolated strain of Aspergillus niger UAF-1. The enzyme was purified to a yield of 28.43% and specific activity of 135 U mg(-1) through ammonium sulfate precipitation, anion exchange and gel filtration chromatography. The enzyme showed high affinity for D-glucose with a Km value of 2.56 mM. The enzyme exhibited optimum catalytic activity at pH 5.5. Temperature optimum for glucose oxidase, catalyzed D-glucose oxidation was 40 degrees C. The enzyme showed a high thermostability having a half-life 30 min, enthalpy of denaturation 99.66 kJ mol(-1) and free energy of denaturation 103.63 kJ mol(-1). These characteristics suggest the use of glucose oxidase from Aspergillus niger UAF-1 as an analytical reagent and in the design of biosensors for clinical, biochemical and diagnostic assays.

Introduction

Glucose oxidase (GOD, β-D-glucose: oxygen 1-oxidoreductase, EC 1.1.3.4) is an important enzyme, which catalyzes the oxidation of β-D-glucose to D-glucono-1, 5-lactone and hydrogen peroxide and finally to gluconic acid using molecular oxygen as electron acceptor [1]. It is widely used in the removal of traces of oxygen and/or glucose from different foods such as dried eggs, beer, wine and fruit juices, as a source of hydrogen peroxide in food preservation and in gluconic acid production [2]. Clinical applications of glucose oxidase in diagnostic tests are likely to be most promising of its applications. The catalytic properties of glucose oxidase form the basis of assaying body fluids such as blood and urine for glucose. A new application for glucose oxidase is its use in biosensors for the determination of glucose [3, 4].

The mycelia fungi Aspergillus niger, Penicillium amagasakiense and P. notatum serve as industrial producers of glucose oxidase. The carbon sources employed in the production of glucose oxidase from Aspergillus niger are mainly glucose and sucrose. The use of cheaper carbon sources appears to be essential for the improvement of process economy [5]. It is generally accepted that the suitability of an enzyme for practical purposes depends on its thermal stability and stability in various media [6]. Thermodynamic parameters are also important for inactivation studies of enzymes [7]. In order to exploit new industrial potentials of glucose oxidase, it is necessary to investigate new microbial strains and to understand the structure-stability relationship of this important enzyme. In this manuscript, we describe the kinetics and thermodynamics of irreversible thermal inactivation of glucose oxidase from a newly isolated A. niger UAF-1 strain grown on corn steep liquor.

Materials and Methods

Organism and Inoculum preparation

Pure culture of Aspergillus niger was obtained from National Fungal Culture Collection of Pakistan (NFCCP), Department of Plant Pathology, University of Agriculture, Faisalabad. It was maintained on potato dextrose agar (PDA) slants at 4°C. Inoculum was prepared by transferring spores from 5–6 days old slant culture, into 250 mL Erlenmeyer flask containing 50 mL of sterile Vogel medium. The medium composition was (NH4NO3, 2; KH2PO4, 5; MgSO4.7H2O, 0.2; peptone, 1; (NH4)2SO4, 4; trisodium citrate, 5; yeast extract, 2 and glucose 50) g L−1. pH of the medium was adjusted to 5.5 and flasks were incubated on a rotary shaker at 220 rpm at 30°C for 48 h to get homogenous spore suspension [8].

Production of glucose oxidase

The basal salt medium contained, corn steep liquor 2% (w/v) as substrate along with glucose 2, urea 0.3, CaCO3 0.05 and KH2PO4 0.04% to achieve higher glucose oxidase yield using submerged fermentation. Experiments were carried out at initial pH 5.5 and 30°C, unless CaCO3 was added in the growth medium (resulting in an initial pH 6.5 to 6.8). The flasks were inoculated with 5 mL of pure culture and incubated in rotary shaker operating at 150 rpm for 36 hours for glucose oxidase production [9]. Various parameters were optimized to obtain the maximum yield of the enzyme glucose oxidase which were substrate concentration, pH, temperature, fermentation period, urea, KH2PO4, CaCO3, MgSO4.7H2O and glucose. All the experiments were conducted in triplicate and the results were expressed as mean ± standard deviation.

Analytical

Total proteins were estimated by Biuret method [10], using bovine serum albumin as the standard. Glucose oxidase activity was determined with the help of a coupled o-dianisidine-peroxidase reaction as described by Worthington et al. [11].

Isolation and purification of glucose oxidase

After fermentation mycelia were separated from the culture liquid by filtration and suspended in 0.1 M phosphate buffer (pH 6) and finally disrupted in a homogenizer [12]. The crude extract (200 mL) was subjected to 60–85% saturation with ammonium sulfate saturation [13]. After 24 hours the resulting precipitate was collected by centrifugation at 10,000 rpm for 20 minutes. Desalted sample was applied on DEAE-cellulose column (2.5 × 25 cm) equilibrated with 0.1 M phosphate buffer pH 6. The active fractions were pooled and then applied to sephadex G-150 column (2.5 × 25 cm). Glucose oxidase eluted as a single peak from gel filtration column.

SDS-PAGE and molecular mass determination

Finally, the enzyme was subjected to SDS-PAGE 10% to analyze the purity [14]. Standard proteins along with studied enzyme of 1 mg mL−1 each, was loaded on sephadex G-150 column and eluted with 0.1 M phosphate buffer, pH 6 to determine native molecular mass [15].

Effect of pH, temperature, activation energy and substrate

Effect of pH on glucose oxidase activity was determined by assaying the enzyme as mentioned before with the difference that the activity was determined at different pH ranging from 2–9 and in various buffer solutions as described earlier [16]. Temperatures ranging from 20–70°C, activation energy was determined from the Arrhenius plot [17] and it was assayed in the reaction mixtures containing variable amounts of glucose i.e. 5–40 mM) at pH 5.5. The data was analyzed according to Lineweaver-Burk plot to determine the values of kinetic constants (Vmax and Km).

Kinetics of thermal denaturation

Kinetic and thermodynamic parameters for irreversible thermal denaturation of glucose oxidase were determined by incubating the enzyme in 50 mM MES monohydrate buffer (pH 5.5) at a particular temperature. Aliquots were withdrawn at different times, cooled on ice for 3 h [18] and assayed for enzyme activity at 25°C. This procedure was repeated at five different temperatures ranging from 45 to 60°C. The data were fitted to first order plots (Fig. 4) and analyzed as described earlier [19]. The thermodynamic parameters for thermostability were calculated by rearranging the Eyring’s absolute rate equation derived from the transition state theory as described by Siddiqui et al. [20].

Fig. 4

Double reciprocal plot to determine the kinetic constants for D-glucose

kd = (kbT/h)e(−ΔH*/RT).e(ΔS*/R) (1)

Where,

h = Planck’s constant = 6.63 × 10–34 Js

kb = Boltzman’s constant (R/N) = 1.38 × 10–23 JK−1

R = gas constant = 8.314 JK−1 mol−1

N = Avogadro’s No. = 6.02 × 1023 mol−1

T = Absolute temperature

ΔH* (enthalpy of activation) = Ea − RT (2)

ΔG* (free energy of activation) = −RT ln (kd. h/kb.T) (3)

ΔS* (entropy of activation) = (ΔH* − ΔG*)/T (4)

Results and Discussion

Production of Glucose oxidase

In the present studies, corn steep liquor (CSL) was used for growth and glucose oxidase production by the Aspergillus niger UAF-1. Culture media containing 2% substrate was subjected to fermentation for 36 hours at pH 5.5, 30°C temperature and 5% inoculum size. The results indicated enzyme activity (6.06 U mL−1) in a medium containing 2% CSL. The findings of present study are in accordance with most of the research workers [21, 22]. For the optimization of substrate, growth media containing 2% corn steep liquor was found to be the best by Zareen [23]. Furthermore, no studies have been found about the utilization of corn steep liquor as a substrate/inducer for glucose oxidase production. So, we utilized CSL as a substrate for the said enzyme production to optimize the conditions of better production and to explore the application of CSL as substrate for glucose oxidase. Submerged fermentation was carried out for 24, 36, 48, 60 and 72 hours with 2% CSL. Enzyme obtained high activity i.e. 7.88 U mL−1, after 36 hours incubation, thereafter biosynthesis of enzyme decreased. Willis [24] optimized the fermentation media for the production of glucose oxidase by Aspergillus niger and obtained highest glucose oxidase yield after 48 h. While our results indicate the maximum production of the enzyme after 36 h. Media was supplemented with glucose as carbon additive and fermentation carried out under optimum conditions. Addition of 4% glucose to fermentation flasks (in triplicate) resulted in better glucose oxidase production with 23.74 U mL−1 activity. Kona et al. [25] showed that 6% sucrose resulted in the highest enzyme activity. It was observed after optimization of media that 2% substrate, 36 h of fermentation, pH 5.5, temperature 30°C, urea 0.3%, KH2PO4 0.6%, CaCO3 0.04% and glucose 4% proved to be best, while with addition of MgSO4.7H2O production of enzyme decreased [26, 27] (Fig. 1).

Fig. 1

Optimized conditions for the production of glucose oxidase from Aspergillus niger UAF-1.

Purification of glucose oxidase

An intracellular glucose oxidase was purified from the culture of Aspergillus niger UAF-1 strain grown in submerged corn steep liquor medium. Disintegration of the mycelia resulted in a very high glucose oxidase activity in the mycelium extract. The specific activity of crude extract was 17.98 U mg−1 protein. The complete precipitation of the enzyme was observed at 85% ammonium sulfate. Purification of the enzyme on anion exchange column was 3.03 fold with 50.42% recovery. Sukhacheva et al. [15] subjected the P. funiculosum-433 glucose oxidase to 80% saturation and found 18 U mg−1 specific activity with 94% yield and 1.6 fold purification and it was applied to DEAE-cellulose column, resulted the decrease in protein contents, increased recovery of 56.2%. On gel filtration column, the enzyme was purified to 7.5 fold, specific activity of 135 U mg−1 with a yield of 28.43%. Liu et al. [28] pooled the fractions from DEAE- Sepharose and subjected to gel filtration, observed 36% recovery and 36 fold enrichment of the enzyme. These results are in accordance to this study, as indicated in Table 1.

Table 1

Summary of purification of Aspergillus niger UAF-1 glucose oxidase

Treatment	Total Activity (U)	Total protein (mg)	Specific activity (U mg−1)	Purification fold	% Recovery
Crude	2374	132	17.98	1	100
Ammonium sulfate precipitation	1589	74	21.47	1.19	66.93
Anion exchange chromatography	1197	22	54.41	3.03	50.42
Gel filtration chromatography	675	5	135	7.5	28.43

SDS-PAGE (10%) upon treatment of the purified enzyme with mercaptoethanol demonstrated a single band with a mobility corresponding to a molecular weight of 70 kDa. This indicated that the enzyme is formed of two identical subunits. The native and subunit molecular masses of glucose oxidase from Aspergillus niger UAF-1, have been determined on sephadex G-150 column and SDS-PAGE, which were found as 175 kDa and 170 kDa, respectively, Ferreira et al. [29] found that molecular mass of A. niger glucose oxidase is of 160 kDa and this finding is also supported by Zoldak et al. [30].

Effect of pH, temperature activation energy and Effect of substrate

Glucose oxidase from Aspergillus niger UAF-1 was active within the pH range of 4–8, while maximum activity was observed at pH 5.5 (Fig. 2). The activation energy (Ea) and optimum temperature of glucose oxidase was found to be 15.46 kJ mol−1 and 40°C respectively. It is obvious from the Arrhenius plot (Fig. 3) that the enzyme had a single conformation up to transition temperature. The change in pH affects the ionization of essential active site amino acid residues, which are involved in substrate binding and catalysis. The ionization of these residues may cause distortion of active site cleft and hence indirectly affect the enzyme activity. Our results favorably compare to those of Weibel and Bright [31], who reported that glucose oxidase is working in the pH range of 4–7 indicating 5.5 as optimum. Aspergillus niger UAF-1 enzyme showed a low Ea at 40°C that makes the enzyme superior to the enzyme from various other sources. Purified glucose oxidase having a protein content of 0.05 mg mL−1 was used for the kinetic and thermodynamic characterization. The Km and Vmax values obtained from Lineweaver-Burk plot were 2.56 mM and 43.5 U mg−1 protein (Fig. 4). Referring to properties of biotechnological relevance, the glucose oxidase of Aspergillus niger exhibited a high affinity for D-glucose as it has low Km value for the substrate as compared to a high Km value (0.033 M) of glucose oxidase isolated from the Aspergillus niger reported earlier [32]. This high substrate affinity and specificity, in addition to its long-term stability in the pH range 4–8, proved glucose oxidase of Aspergillus niger UAF-1 as a suitable biocatalyst for industrial applications. The rates of reaction of glucose oxidase from Aspergillus niger with glucose, 2-deoxyglucose, mannose, galactose and xylose have been measured and found that glucose reacts much faster than the other sugars with Km 0.11 M and Vmax of 2000 s−1M [33].

Fig. 2

Effect of pH on activity of Aspergillus niger UAF-1 glucose oxidase

Fig. 3

Arrhenius plot for determination of activation energy for the oxidation of D-glucose.

Thermal denaturation studies

Glucose oxidase from Aspergillus niger UAF-1 was thermally stable at 45°C with half-life of 173 minutes. However at 60°C it was less stable and displayed a half-life of 30 min under similar conditions (Fig. 5). The enzyme had a range of 99.79–99.66 kJ mol−1 enthalpy of denaturation (ΔH*) at 45°C–60°C. The value of free energy of thermal denaturation (ΔG*) for glucose oxidase was 103.47 kJ mol−1 at 45°C, showing a decreasing trend with increase in temperature. When entropy of inactivation (ΔS*) was calculated at each temperature, it showed negative values. Purified glucose oxidase from Aspergillus niger UAF-1 showed a ΔS* value of –11.92 J mol−1 K−1 at 60°C (Fig. 6, Table 2).

Fig. 5

Irreversible thermal inactivation of Aspergillus niger UAF-1 glucose oxidase. [Closed triangle (45°C), Open (48°C), Closed circle (52°C), Open circle (56°C) and Open square (60°C)].

Fig. 6

Arrhenius plots for determination of energy of activation for irreversible thermal inactivation of glucose oxidase.

Table 2

Kinetics and thermodynamics of irreversible thermal denaturation of glucose oxidase from Aspergillus niger UAF-1

Temp. (K)	kd (min−1)	t½ (min)	ΔH* kJ mol−1	ΔG* kJ mol−1	ΔS* J mol−1 K−1
318	0.004	173	99.79	103.47	−11.57
321	0.007	99	99.76	102.98	−10.03
325	0.012	58	99.73	102.84	−9.57
329	0.018	39	99.7	103.03	−10.12
333	0.023	30	99.66	103.63	−11.92

Thermostability is the ability of enzyme to resist against thermal unfolding in the absence of substrates, while thermophilicity is the capability of enzymes to work at elevated temperatures in the presence of substrate [34]. Purified glucose oxidase from Aspergillus niger UAF-1 showed appreciable stability and thermodynamic characteristics between 45–60°C. Thermal denaturation may occur in two steps as shown:

N ↔ U → D

Where, N (native enzyme), U (unfolded enzyme) that could be reversibly refolded upon cooling and D is the denatured enzyme formed after prolonged exposure to heat and therefore cannot be recovered on cooling. Glucose oxidase isolated from this Aspergillus niger strain was thermally stable and could be used for analytical and other industrial applications. The negative entropy of deactivation observed for glucose oxidase suggested that there was negligible disorderness as that of β-glucosidase from Aspergillus wentii or the transition state of α-amylase from Bacillus licheniformis was found to be more ordered as revealed by its negative ΔS* at high temperature of 80°C. According to [35] the values 81.8 kcal mol−1, 24.6 kcal mol−1 and 169.2 cal K−1 mol−1 of H*, G* and S* respectively, were obtained for standard Aspergillus niger glucose oxidase. A high value for free energy of thermal denaturation at 60°C indicated that glucose oxidase exhibited the resistance against thermal unfolding at higher temperatures. Gouda et al. [36] reported that Aspergillus niger glucose oxidase has an activation energy of irreversible thermal denaturation is 280 kJ mol−1, calculated from the Lumry-Eyring model. Our results are also in agreement with Godjevargova et al. [37]. Table 3 is also given to indicate the comparisons between the enzyme from Aspergillus niger UAF-1 and enzyme from some other sources.

Table 3

Comparison of various characteristics of purified glucose oxidase from Aspergillus niger UAF-1 with other sources

Characteristics	A. niger UAF-1 Glucose oxidase	Glucose oxidase from other sources
Activity enzyme (U)	675	NA
Specific activity (U mg−1)	135	NA
% age Yield	28.43	36a
Optimum pH	5.5	4–7b
Optimum temperature (°C)	40	>40b
Ea (kJ mol−1)	15.46	NA
Km (mM)	2.56	5.7c
Vmax (U mg−1)	43.5	925c
Molecular wt. (kDa)	170	160d
kd (min−1) (at 60°C)	0.023*	NA
t1/2 (min)	30*	NA
ΔH* (kJ mol−1)	99.66*	NA
ΔG* (kJ mol−1)	103.63*	88.3 kcal mol−1
ΔS* (J mol−1 K−1)	−11.92*	184 cal. mol−1

NA = Not reported

Glucose oxidase from Aspergillus niger (Liu et al.1998)

Glucose oxidase from Penicillium pinophilum (Rando et al. 1997)

Glucose oxidase from genetically modified P. amagasakiense (Witt et al. (1998)

Glucose oxidase from Aspergillus niger (Ferreira et al., 2005).

Results obtained at 60°C.

Conclusions

Glucose oxidase was isolated from the mycelium extract of a locally isolated strain of A. niger UAF-1. It was purified by using ammonium sulfate precipitation and chromatographic techniques and its yield and specific activity was 28.43%, 135 U mg−1 respectively. The enzyme showed high affinity for D-glucose with a Km value of 2.56 mM, exhibited optimum catalytic activity at pH 5.5 and optimum temperature for glucose oxidase, catalyzed D-glucose oxidation was 40°C. It showed a high thermostability having a half-life of 30 min, enthalpy of denaturation 99.66 kJ mol−1 and free energy of denaturation 103.63 kJ mol−1. These characteristics suggest the use of glucose oxidase from Aspergillus niger UAF-1 as an analytical reagent and in the design of biosensors for clinical, biochemical and diagnostic assays. However further studies are required to elucidate the broader implication of this enzyme.