Novel Protease from Aspergillus tamarii URM4634: Production and Characterization Using Inexpensive Agroindustrial Substrates by Solid-State Fermentation

Abstract

This study reports the protease production from Aspergillus tamarii using agroindustrial residues as substrate for solid-state fermentation (SSF) and biochemical characterization. The highest protease production was obtained using wheat bran as substrate at 72 h fermentation with maximum proteolytic activity of 401.42 U/mL, collagenase of 243.0 U/mL and keratinase of 19.1 U/mL. The protease exhibited KM = 18.7 mg/mL and Vmax = 28.5 mg/mL/min. The optimal pH was 8.0 and stable in a wide pH range (5.0 - 11.0) during 24 h. The optimum temperature was 40°C. The proteolytic activity was inhibited by Cu2+ (33.98%) and Hg2+ (22.69%). The enzyme was also inhibited by PMSF (65.11%), indicating that is a Serine Protease. These properties suggest that alkaline protease from A. tamarii URM4634 is suitable for application in food industries and leather processing. Additionally, the present findings opened new vistas in the utilization of wheat bran and other effective agroindustrial wastes as substrates for SSF.

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da Silva, O. , de Oliveira, R. , Souza-Motta, C. , Porto, A. and Porto, T. (2016) Novel Protease from Aspergillus tamarii URM4634: Production and Characterization Using Inexpensive Agroindustrial Substrates by Solid-State Fermentation. Advances in Enzyme Research, 4, 125-143. doi: 10.4236/aer.2016.44012.

1. Introduction

Proteases catalyze the cleavage of peptide bonds in proteins, are the class of enzymes having applications in both physiological and commercial fields. Among all the different commercial enzymes, microbial protease in particular, consisting of more than 25% of biomolecules produced for industrial application and 65% of all the industrial enzymes sales in the world due to their applications in several industrial sectors like in the detergent, food, pharmaceuticals, chemicals, leather, paper and pulp and silk industries [1] [2] [3] [4] .

Proteases can be obtained from several sources, including plants, animals, and microorganisms. Even though a wide variety of microbial proteases are available, the use of these enzymes on industrial scale is still limited by their high production costs and the fact that their activity is often limited to a restricted range of biochemical characteristics [5] .

The Solid State Fermentation (SSF) is especially suitable for the fungi growth because their moisture requirements are lower compared to the bacteria. In this technique, the enzymes produced are more concentrated than those in submerged fermentation. SSF is an inexpensive technique and can be widely applied to agricultural products or by-products as substrates. Furthermore, the substrate must be easy to handle, inexpensive and easy to purchase. The overall cost of enzyme production is very high (due to high cost of substrates and mediums used). Therefore, development of novel processes to increase the yield of proteases with respect to their industrial requirements coupled with lowering down the production cost is highly appreciable from the commercial point of view [6] .

SSF is also a cost-effective process as it uses agroindustrial wastes, like seeds, peels, husks, bark, and bran to produce valuable bioactive molecules. Another important advantage of SSF is the higher growth rate exhibited by fungi on solid substrate as compared to submerged fermentation; the morphology of filamentous fungi allows them to colonize the substrate surface and matrix in search of nutrients, consequently secreting higher levels of metabolites and enzymes [5] .

Filamentous fungi, such as Aspergillus spp., are explored for the production of industrial enzymes due to their ability to grow on solid or liquid substrates and having a large production of extracellular enzymes. Some strains from Aspergillus genus are considered non-toxic, recognized as a safe microorganism by the Food and Drug Administration (FDA), denominated Generally Recognized as Safe (GRAS), and used for human and animal nutrition [5] [6] [7] .

In the Brazilian scenario, which is heavily focused on agriculture economy; especially soy, wheat, corn and sugarcane, the technological potential for efficient reuse of agro industrial waste can contribute to the development of high added value products such as enzymes, organic acids, flavors and fragrances, pigments, polysaccharides and hormones, adding value to this residue produced in large quantities [5] .

In this study, we evaluated the inexpensive production of proteases from several GRAS fungal strains, using agroindustrial waste: wheat grains, Canadian lentils, amaranth flakes, soybean grains, nuggets sunflower, oat bran and wheat bran. The different residues used as substrate can modify fungi metabolic expression and produce enzymes with distinct characteristics, which can be applied in the biotechnological industry in many ways. The combination of the microbial cell and different substrates comprises metabolic and biotransformation process that can generate several cellular products. Additionally, the microorganism and substrate selection plus the biochemical characteristic of the enzyme produced are important factors to evaluate its biotechnological potential and target the possible applications for industrial processes [5] [6] [7] [8] . The aim of this study was to produce in different agroindustrial substrates and characterize extracellular protease from Aspergillus tamarii URM4634 by Solid-state Fermentation.

2. Material and Methods

2.1. Microorganism

The thirty-four Aspergillus strains used for screening were provided by the “Micoteca- URM” of Mycology Department, Centre of Biological Sciences of Federal University of Pernambuco (UFPE), Recife-PE, Brazil. The strain was preserved in mineral oil [9] , maintaining at 28˚C in a Czapek Dox Agar medium. The microorganisms were grown in reactivation broth: 1% peptone; 0.3% beef extract; 2% glucose and 1000 mL of distilled water (pH 7.0). After 5 days of growth, microorganisms were inoculated in Czapek Dox agar for 7 days at 30˚C.

2.2. Screening and Culture Condition for Microorganisms of Aspergillus Genus

Inoculum spores were produced in Czapek Dox Agar tubes inclined containing a culture seven-days-old culture grown at 30˚C and suspended in a 3.0 mL of a solution consisting of 0.9% NaCl and 0.01% Tween 80, which was previously sterilized at 121˚C for 20 min. Aspergillus strains were inoculated (104 spores/mL) in soybean flour medium MS-2 [10] . The submerged fermentation (SmF) was performed in 250 mL-Erlenmeyer flasks contained 50 mL of production medium at pH 7.2, for 72 h, 120 rpm at 30˚C.

After fermentation, the culture medium was centrifuged at 3000 g for 15 min at 4˚C to obtain the supernatant (enzyme crude extract). The screening of the microorganisms was performed in two steps. The first one was performed in submerged fermentation (SmF) and the second step was performed in solid-state fermentation (SSF), using different substrates.

2.3. Protease Production by Solid-State Fermentation (SSF)

The substrates used for screening by SSF were: Wheat grains, Wheat bran, Oat bran, Soybeans, Canadian Lentils, Flakes amaranth, Quinoa flakes and Nuggets Sunflower, obtained in the local market in the city of Garanhuns, Pernambuco, Brazil.

SSF was performed in 125mL-Erlenmeyer flasks containing 5 g of each agroindustrial substrate, nutrition solution and 107 spores/mL, corresponding to 40% moisture content. SSF was run for 72 h at 30˚C and the protease extract was obtained by addition of 7.5 mL of 0.1 M sodium phosphate (pH 7.0) per gram of fermented material and homogenized in shaker for 2 h. Solids were removed by centrifugation at 3000 g for 15 min at 4°C, and the supernatant was used as enzyme crude extract.

The experiments for protease production were performed according to a 23-full factorial design. The analyzed variables were: Substrate (3, 5 and 7 g); Moisture (30%, 40% and 50%); Temperature (25˚C, 30˚C and 35˚C). The central point runs were performed in quadruplicate to allow for pure error estimation. All graphic statistical analyses were made using the software Statistica 8.0 [11] .

2.4. Determination of Proteases Activities

The protease activity was measured using azocasein as substrate described by Ginther [12] . One activity unit (U) was expressed as the amount of enzyme able to lead to a 0.1 increase in absorbance at 420 nm within 1 h.

The collagenase activity was performed using the Azocoll method described by Chavira et al. [13] . One activity unit (U) was expressed as the amount of enzyme able to lead to a 0.1 increase in absorbance ate 520 nm with 3 h.

The Keratinase activity was assayed by Anbu et al. [14] . One unit of the keratinase activity was expressed as the amount of enzyme able to lead to a 0.1 increase in absorbance at 280 nm with 1 h.

2.5. Determination of Biomass Estimation by Glucosamine Level

Fungal biomass estimation was carried out according to Castro et al. [8] by measuring the levels of glucosamine, the basic unit of chitin. Glucosamine was detected by spectrometry after depolymerization of the chitin and the N-acetyl glucosamine content, which is proportional to the fungal biomass. The measurements were taken after the acid hydrolysis of the biomass at 100˚C where glucosamine hydrochloride undergoes successive reductions leading to chromogen III formation, which then reacts with a dimethyl-p-aminobenzaldehyde solution (Erlich solution) and produces red coloration that can be detected at 530 nm.

2.6. Mycotoxin Detection

2.6.1. Coconut Milk Based Medium Test

Coconut milk agar medium (CMA) were based on Lin and Dianese [15] with some modifications. The pH was adjusted to 6.9 with 2M NaOH. Bacto agar (15 g/L) was added, the mixture heated to boiling and autoclaved at 121˚C for 20 min. The plate center was inoculated with a concentration 104 spores/mL and 5 μL of spore suspension was incubated in the dark at 28˚C. The presence or absence of a fluorescence ring in the agar surrounding the colonies under UV-A 365 nm light after seven days of incubation was noted and the results were scored as positive or negative for mycotoxin production.

2.6.2. Ammonia Vapour Test

Briefly, 25 mL of YES agar was inoculated as single colonies in the center of Petri-dishes and incubated in the dark at 28˚C [16] [17] . After three days, a set of Petri-dishes were inverted over 2.0 mL of ammonium hydroxide. This was repeated with another set after seven days. After ten minutes, the undersides of aflatoxin producing isolates turned from pink to red color, but no color change occurred in the non-toxic isolates.

2.7. Determination of the Kinetic Parameters (KM, Vmax)

The kinetic parameters of the enzyme were determined using different concentrations of azocasein (2 ≤ S0 ≤ 100 mg/mL) for protease activity (section 2.4). All tests were carried out in triplicate and results were expressed as average values. Statistical analysis was performed using standard deviations of experimental data from the average values.

2.8. Biochemical Characterization

For biochemical characterization, the optimal activity and stability of enzymes at different pH and temperature, effects of metal ions and inhibitors were tested using enzymes produced in the best fermentation condition from Aspergillus tamarii URM4634 by SSF, according to 2.4 section.

2.8.1. Effect of pH on Proteolytic Activity and Stability

The optimum pH for protease activity was determined using different buffers 0.2 M: citrate-phosphate (pH 5.0 - 7.0), Tris-HCl (pH 7.0 - 8.5) and glycine-NaOH (pH 8.5 - 11.0). The effect of pH on stability of the enzyme was verified by a previous incubation of the enzyme crude extract with above buffers at 5˚C. Aliquots were analyzed to determine residual protease activity at time intervals 0 h, 4 h, 8 h and 24 h.

2.8.2. Effect of Temperature on Proteolytic Activity and Stability

The temperature effect was determined by performing the protease activity at temperatures from 5˚C to 90˚C. The temperature stability was measured by keeping the enzyme extract in the absence of substrate at temperatures from 5˚C to 90˚C. Aliquots were rapidly cooled ±25˚C, to ensure efficient refolding of the molecules of the enzyme optionally reversibly inactivated, were withdraw every 60 min to determine the residual activity at different times (0, 60, 120 and 180 min).

2.8.3. Effects of Metal Ions on the Proteolytic Activity

Protease activity was assessed in the presence of ions, as inhibitors or activators of activity. The effect of ionic solutions was evaluated at concentrations of 5 mM and 10 mM in 0.2 M Tris-HCl pH 7.2. The following ions were used: ZnSO4∙7H2O, MgSO4∙7H2O, CuSO4∙5H2O, FeSO4∙7H2O, CaCl2, HgCl2∙4H2O, KCl and NaCl, and incubated at 28˚C for 30 min. The enzyme activity without ions was considered as control (100%) and the Protease activity was determined by the method described in 2.4 Section.

2.8.4 Effects of Inhibitors on Proteolytic Activity

To evaluate the effect of inhibitors on enzyme activity, the crude extract was exposed to the following protease inhibitors: Phenylmethylsulfonyl fluoride (10 mM), 2-merca- ptoethanol (10 mM)), Ethylenediaminetetraacetic acid (10 mM), Pepstatin A (1 mM) and Iodoacetic acid (10 mM) and were performed at 25˚C for 30 min. The enzyme activity without inhibitor was considered as control (100%).

2.9. Sodium Dodecyl Sulphate-Polyacrylamide Gel Electrophoresis (SDS-PAGE)

SDS-PAGE was carried out using a 12% polyacrylamide running gel according to the method of Laemmli [18] . The protein molecular markers were phosphorylase b (97.0 kDa), albumin (66.0 kDa), ovalbumin (45.0 kDa), carbonic anhydrase (30.0 kDa), trypsin inhibitor (20.1 kDa) and α-lactalbumin (14.4 kDa). Protein bands were detected by staining with Coomassie brilliant blue R-250 and protein molecular markers were detected by silver. SDS-PAGE was distained with a solution of methanol, acetic acid and water.

2.10. Zymogram

The proteolytic activity of the enzyme band was confirmed by zymogram analysis. To prepare a gelatin zymogram with 0.1% gelatin as substrate incorporated in the gel. Gels were loaded with 10 µL of concentrated supernatant, subject to electrophoresis at a constant current of 100 V at 25˚C and incubated for 30 min at room temperature with 2% (v/v) Triton X-100 and for 48h at 37˚C in 50 mMTris?HCl buffer and 15 mM CaCl2, pH 7.5. To azocasein zymogram with 0.1% azocasein as substrate incorporated in the gel. The azocasein was dissolved in Tris-HCl pH 8.8, keeping the same concentrations for performing the gelatin zymogram. Gels were finally stained and destained as described in the previous section.

3. Results and Discussion

3.1. Screening of Aspergillus for Protease Production

Thirty-four strains of Aspergillus were evaluated among soy-based medium (MS-2) showed that all activities between 0.43 and 34.13 U/mL (Table 1).

Table 1. Microorganisms of the aspergillus genus and their proteolytic activities after 72h of submerged fermentation in soybean flour medium (ms-2).

*PA-Protease activity.

Aspergillus flavus showed protease activity of 34.13 U/mL. However, this microorganism is known as mycotoxin producer such as aflatoxin B1 and B2, G1 and G2 and cyclopiazonic acid, being unfeasible its application in some biotechnological processes such as the food industry [19] [20] . Electrophoretic analysis and x-rays were used for the detection of aflatoxins in Aspergillus flavus isolates from seeds Cassi tora (L.), confirming the presence of mycotoxin [21] . The enzyme extract from Aspergillus tamarii URM4634 was selected (protease activity 29.90 U/mL and specific activity 498.33 U/mg).

Aspergillus tamarii URM4634 was also selected because the high protease production compared to other microorganisms and the absence of release of aflatoxins. The constituents of CMA have an effect on fluorescent pigment production in coconut culture [22] . Our findings showed that aflatoxins were not detected CMA on the presence of fluorescence ring. In ammonium hydroxide vapor test, Aspergillus tamarii URM4634 do not produced pinkish pigmentation on the reverse of colonies. Yazdani et al. [22] studied aflatoxin production from Aspergillus tamarii using two chromatography techniques (TLC and HPLC), CMA test and ammonium test not being found aflatoxins, in agreement to this study.

The study findings corroborate with the literature, emphasizing the potential of Aspergillus genus as a protease producer. Boer and Peralta [23] evaluated the proteases production by various soil fungi of Aspergillus genus. Several fungi used by them, showed protease production from Aspergillus tamarii by submerged fermentation technique, obtaining the maximum protease activity of 63.4 U/mL after 120 h.

In another study performed by Dhandapani et al. [24] a selection of microorganisms isolated from leather tannery, Aspergillus tamarii was selected as the best producer of alkaline protease in a bioreactor, showing protease activity of 1.61 U/mL.

In the second step of screening, wheat grains, Canadian lentils, amaranth flakes, soybean grains, nuggets sunflower, oat bran and wheat bran were used as substrates for solid-state fermentation and evaluation of A. tamarii URM4634 growth into the agroindustrial by-products. Filamentous fungi are the most widely microorganisms used in SSF because of their ability to grow in solid substrates even in the absence of free water [8] .

The best agroindustrial substrate for protease production in SSF was wheat bran and showed protease activity of 340 U/mL (Figure 1). Zanine et al. [25] evaluated the wheat bran as substrate and observed great potential for moisture, as well as improved fermentation profile due to reduction of dry matter loss, and composed primarily of insoluble fibers and aleurone cells of germ, avoiding the drying process in solid-state fermentation. Study by Anandan et al. [26] has shown that when added wheat bran in media containing glucose and other nutrients sources, such as citrate, maltose, lactose and sucrose, Aspergillus tamarii NRRL20818showed excellent proteolytic activities. In another study with Aspergillus oryzae MTCC5341 and using rice bran and wheat bran as substrates, the last one increased the proteolytic activity of 25.6% compared with rice bran [7] .

Figure 1. Protease activity from Aspergillus tamarii URM4634 in solid-state fermentation in different agroindustrial substrates.

3.2. Full Factorial Design for Protease Production from A. tamarii URM4634 by Solid-State Fermentation

The best value of the protease activity was 404.67 U/mL, obtained from the average of the results of the central points (5 g wheat bran, 40% moisture at 30˚C) (Table 2) in 72 h of fermentation.

The analysis of the effects (Table 3) showed that only one variable had statistically significant effect, since the value of estimated effect was above the significance level (p < 0.05). For protease activity, the variable that showed significant effect on enzyme production was temperature, with negative effect, from 72 h of fermentation, indicating that decreasing temperature could enhance the protease production by A. tamarii URM4634.

Nascimento et al. [27] when studying the effect of the variables substrate, moisture and temperature to produce a protease from Mucor subtilissimus UCP1262 obtained the protease activity 48.33 U/mL in Solid-state Fermentation containing 3 g of wheat bran, 50% moisture at 30˚C. The amount of substrate and moisture showed no effect on the production of proteases by Brevibacterium linens DSM 20158 were obtained at 30˚C [28] . Both of works showed that temperature at 30˚C was responsible for the higher activity values. For the temperature is an important factor in the growth of the microorganism and proteases production.

The best condition was also tested for specific proteolytic activities such as collagenase (243.0 U/mL) and keratinase (19.1 U/mL), due to their biotechnological potential. Lima et al., [29] showed that a collagenase serine protease from Penicillium aurantiogriseum URM4622 exhibited activity of 164 U/mL. Siqueira et al. [30] studied a keratinase produced by solid-state fermentation of Aspergillus terreus exhibited activity of 677 U/mL.

Table 2. Results of protease production from Aspergillus tamarii URM4634 by solid-state fermentation performed according to the 23 full factorial design.

*PA―Protease Activity. (C)―Central points.

Table 3. Effect estimates of 23 full factorial design for protease production from Aspergillus tamarii URM4634 by solid-state fermentation.

*Statistically significant at 95% confidence level (p < 0.05).

3.3. Determination of the Microorganism Biomass

The evolution of fungal cellular growth in wheat bran was estimated by glucosamine level during 196 h of cultivation. A. tamarii URM4634 exhibited a maximum glucosamine level of 119.33 mg/g ± 4.8, after 96 h cultivation (Figure 2). The protease production showed a good correlation with the glucosamine content, resulting in activity of 530.16 U/mL ± 0.02, after 72 h cultivation, indicating an increase of the protease production with the increase of the biomass (glucosamine level). Incubation beyond this period did not result any further increase in biomass concentration but resulted in a slight decrease in enzyme level.

Similar values found in this study was also reported by Castro et al. [8] when eva-

Figure 2. Biomass estimation (glucosamine) and proteolytic activity from A. tamarii URM4634 in wheat bran solid-state fermentation.

luated different agroindustrial by-products such as wheat bran, soybean meal and cotton seed meal, showed glucosamine levels of 90.33 mg/g when grown in wheat bran, after 96 h of cultivation. Ramachandran et al. [31] exhibited 57 mg/g of biomass after 72 h of cultivation in wheat bran.

3.4. Kinetic Parameters of the Protease Activity

The KM and Vmax values were 18.7 mg/mL and 28.57 mg/mL/min, respectively. KM was related to the affinity of the enzyme toward azocasein substrate. Lineweaver-Burk plot of initial velocity of the extracellular protease from Aspergillus tamarii URM4634 is shown in Figure 3. The KM = 5.4 mg/mL were recorded for the detergent-compatible protease from Aspergillus terreus [32] . Ha et al. [33] has reported a commercial protease with KM = 24.9 mg/mL the fungus 31K in the degradation of meat proteins. Omolara et al. [34] reported a high KM = 40.13 mg/ml from Aspergillus niger, suggesting application in the meat processing industry.

Mushtaq et al. [35] purified and characterized protease from Rhizopus oryzae with KM = 7.0 mg/mL for application in detergents industry. The characterization of the kinetic parameters of an alkaline protease produced by Penicillium nalgiovense [36] showed KM 18 times smaller and Vmax 28 times lower than present work, which presented to KM = 1.152 mg/mL and Vmax = 0.827 mg/mL/min, respectively. According to what has been reported, KM greater values of 5 mg/mL can be used in meat processing as well as detergents industries. However, it is known that the smaller values of KM greater are the affinity of the enzyme for the substrate.

3.5. The Effect of pH and Stability of Protease

Results of pH effect on enzyme activity and stability can be observed in Figure 4. The optimum pH for protease activity (417.67 U/mL) was obtained at pH 8.0 (0.2 M Tris- HCl). The same optimum pH (8.0) was found for alkaline protease from Aspergillus nidulans HA-10 [37] . Similar research with the protease from thermophilic fungus

Figure 3. Curve double reciprocal Lineweaver-Burk extracellular protease from Aspergillus tamarii URM4634 using azocasein as a substrate (R2 = 0.99).

Figure 4. Curve optimum pH and stability of the protease produced by Aspergillus tamarii URM4634 in different buffers for 24 h the reaction.

Myceliophthora sp., showed optimum pH 9.0 in SSF. On the other hand, the same protease and microorganism grown in submerged fermentation had its optimum pH 7.0 [2] , suggesting a different protease expression in both fermentation techniques.

The enzyme showed 91.66% and 91.18% of its activity relative to the pH 7.0 and 8.5 in same buffer. The protease retained its activity of 82.88% and 50.28% in 0.2M Glycine-NaOH buffer pH 9.0 and 10.0, respectively. The results show that the enzyme was stable over a wide pH range (6.0 ? 11.0).

The pH stability of the enzyme is important for enzymatic characterization, before being marketed. The protease produced by Aspergillus tamarii URM4634 was stable at all pH values tested, showing 70% residual activity at pH 5.0 and 86.7% in pH 11.0 until 24 h. This pH stability of the protease of A. tamarii URM4634 showed potential for possible industrial applications. Protease with alkaline properties can be used in leather, detergents and pharmaceutical industry [2] .

3.6. Optimum Temperature and Stability of Protease

The temperature is one of the most critical parameters to be controlled in bioprocesses [38] . The optimum temperature of the protease was 40˚C (Figure 5). At 25˚C, the enzyme showed relative activity of 78.25% and 24.93% at 80˚C. The activity was completely lost when exposed to 90˚C.

Yadav et al. [39] found the same optimum temperature for characterization of alkaline protease from Aspergillus flavus. In agreement to this study, Kranthi et al. [40] have reported optimum temperature for characterization of proteases from Aspergillus flavus using different oil seeds as substrate. However, an optimum temperature of 60˚C was reported in the characterization of protease from Aspergillus fumigatus and the protease showed 60% residual activity at 64˚C [41] . The protease produced by Aspergillus tamarii URM4634 showed more than 68% residual activity when compared to the same temperature as described by Hernández-Martínez et al. [41] . The protease was stable at 40˚C, decreasing sharply above 50˚C and completely losing the activity to 90˚C after 180 min.

3.7. Effect of Metal Ions on the Proteolytic Activity

Influences of ionic solutions were evaluated at concentrations of 5 mM and 10 mM (Table 4). The enzyme activity was not affected by ion K+ in both concentrations is important to emphasize the role of K+ ions in cell physiology. Furthermore, the enzyme activity was stimulated in the presence of Ca2+, Zn2+, Na+ and Mg2+ at a concentration of

Figure 5. Curve optimum temperature and stability of protease produced by Aspergillus tamarii URM4634 at different temperatures at 180 min.

Table 4. Effect of metal ions on protease activity from Aspergillus tamarii URM4634.

10 mM. However, the protease was inhibited by Hg2+ (22.69%) and Cu2+ (33.98%). Similarly results were obtained for alkaline protease produced by Aspergillus flavus [40] and Bacillus sp. P7 [42] where the Cu2+ ion showed the inhibition 26.7%. The effects of Ca2+ and Mg2+ in alkaline proteases from Bacillus firmus CAS7 [4] have been reported as stimulators, and K+ also did not affect the protease from Aspergillus tamarii URM4634. A study of the influence of ions was performed in the activity of an alkaline serine protease from Bacillus licheniformis NCIM-2042, where in the Zn2+ reduced the activity at 8.6% [43] , in contrast to the present study where Zn2+ ion stimulated protease activity at 11.36%.

3.8. Effect of Inhibitors on Proteolytic Activity

Enzyme activity was inhibited 65.11% by 1mM phenylmethylsulfonyl fluoride (PMSF), classifying the enzyme as a serine protease. It was also slightly inhibited by 10 mM Ethylenediaminetetraacetic acid (EDTA)-metalloprotease inhibitor (71.15%), 10 mM 2- mercaptoethanol-cysteine protease inhibitor (81.62%), but was not inhibited when subjected to 1 µM Pepstatin A―the aspartic protease inhibitor (Table 5). These results allowed the identification of protease crude extract produced by Aspergillus tamarii URM4634 as a serine protease.

The results of this study corroborate with results of the effect of the inhibitor, PMSF, on enzyme activity found by Bhunia et al. [43] indicating that the enzyme belongs to the class of serine proteases, but the effect of EDTA was not observed. Similar results were obtained for alkaline protease produced by Aspergillus flavus that was moderately affected by EDTA, expressing 78% of its residual activity and completely inhibited by PMSF, indicating that the protease belongs to the class of serine proteases [39] . Several proteases produced by Aspergillus has been characterized (Table 6). The characterization of proteases from Aspergillus tamarii was established according to similar characteristics of this enzyme compared to other proteases.

Table 5. Effect of inhibitors on the protease activity from Aspergillus tamarii URM4634.

Table 6. Biochemical properties of proteases from Aspergillus tamarii URM4634 and proteases from Aspergillus.

NA = Not Available.

3.9. SDS-PAGE and Zymogram

SDS-PAGE and Zymogram were applied to verify the electrophoretic profile of the enzyme extract by A. tamarii URM4634 (Figure 6). The obtained profile showed nine proteins with molecular weights of 18.2 kDa to 98.8 kDa. The nature of the proteolytic enzyme was also confirmed by zymogram with two different substrates: Gelatin (ZG) and Azocasein (ZA), using both substrates a hydrolyzed band appeared as a white band that corresponded to the position of the protease in the gel. The crude extract was used without purification, so the activity observed in the white band probably corresponded to more than one enzyme.

4. Conclusion

The results obtained in this study showed that the high levels of protease production by Aspergillus tamarii URM4634 could be achieved by adjusting the parameters, as the amount of substrate (5 g wheat bran), moisture (40%) and temperature (30˚C). The effect of temperature on the fermentation process showed a negative effect as an important factor, inducing the best protease production at 72 h. The biochemical characterization showed the optimum pH 8.0 and 40˚C and pH stability (5.0 - 11.0) and thermostability (10˚C - 40˚C). The enzyme is a serine protease and showed collagenolytic and keratinolytic activities. The protease produced by A. tamarii URM4634 showed enzymatic characteristics that are suitable for using in industrial applications as leather

Figure 6. Molecular weight determination of protease by Aspergillus tamarii URM4634 using SDS-PAGE (12%) and zymogram analysis of protease. MM: protein molecular weight standard; CE: crude extract; ZG: protease gelatin zymogram; ZA: protease azocasein zymogram.

processing and food industries, with low cost using wheat bran agroindustrial wastes as substrate.

Acknowledgements

The authors are greateful to FACEPE (Foundation for Science and Technology of the State of Pernambuco, Brazil) process IBPG-0257-5.07/14 for the scholarship to the first author, CNPq (National Council for Scientific and Technological Development, Brazil) and CAPES (National Council for the Improvement of Higher Education, Brazil) for the financial support.

Conflicts of Interest

The authors declare no conflicts of interest.

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