Biosynthesis, purification, and biochemical properties of an alkaline-thermostable keratinase derived from Bacillus cereus J6
Publié en ligne: 17 mars 2025
Reçu: 30 oct. 2024
Accepté: 10 févr. 2025
DOI: https://doi.org/10.2478/amns-2025-0831
Mots clés
© 2025 Rongxian Zhang et al., published by Sciendo
This work is licensed under the Creative Commons Attribution 4.0 International License.
Keratin, a kind of insoluble fibrous biopolymer, features dense disulfide bonds, hydrophobic interactions, non-covalent interaction, etc. These interactions contribute to keratin’s intricate network architecture, the tight packaging of keratin’s supercoiled polypeptide chain and cross-linked protein chains [1-3]. These characteristics enable keratin to show extraordinary resistance to the hydrolysis of common proteolytic enzymes, and mechanical factors [2, 4]. Keratin-rich waste byproducts, such as feathers from poultry processing, hair, nails, animal horns and hooves from the livestock industry, epidermal tissues and wool from leather and textile industries, are continuously generated by both human daily activities and industrial manufacturing processes.
Keratinase (EC 3.4.21/24/99.11), synthesized by multiple microorganisms, including fungi (e.g.,
The synthesis of microbial keratinase is regulated by multiple factors. Keratin-based substrates, available carbon and nitrogen sources, pH, fermentation temperature, and other conditions all play crucial roles in determining the production levels of microbial keratinase [11]. Moreover, considering its vast potential in numerous vital biotechnological applications across industrial sectors, the comprehensive characterization of keratinase is of great importance. Here, a keratinase-producing
Most of the reagents, such as type-I collagen, BSA, casein, protease inhibitors, inorganic minerals and surfactants, were purchased from Macklin (Shanghai, China). Soluble keratin (5%) was bought from J&K (Beijing, China). The molecular-related materials were bought from Takara (Beijing, China). Feathers were obtained from Hongmeng Market in Xinxiang, Henan province, China.
Keratinase activity was measured by the colorimetric method with 1% soluble keratin serving as the substrate, as described by Zhang et al. [14].
The poultry soil samples were collected from Xinxiang, Henan, China. Microorganisms with capability to produce keratinase were isolated using the feather as keratin/inducer as well as the sole carbon/nitrogen source, using the method described by Zhang et al. [14].
The target strain was identified through morphological characteristics, physiological and biochemical test, and molecular biological identification. The target bacterial partial 16S rRNA gene was amplified by using the pair of oligonucleotide primers [(5’- GAGAGTTTGATCCTGGCTCAG-3’) and (5’- CTACGGCTACCTTGTTACGA-3’)] and subsequently ligated to T-vector. Then, the target sequence was obtained by GeneCreate (Wuhan, Hubei, China) through sequencing the resulting vector. Furthermore, the sequence was uploaded and blasted against sequences in NCBI.
Keratinase production profile of Strain J6: The strain was inoculated into the basic medium with the inoculum size of 2% and cultured at 37°C, and 200 rpm. The enzyme yield was determined every 4 h. Thereby, the dynamics of enzyme biosynthesis by Strain J6 was further analyzed.
Because of the existence of insoluble substances, specifically feather powder, within the medium, it is difficult to accurately quantify the microbial biomass. Consequently, the enzyme yield is adopted as the definitive measurement criterion for optimizing the composition of the medium.
Determination of the factors and their levels: The impacts of the chicken feather inducer, nitrogen sources (peptone, yeast extract, (NH4)2SO4, NH4Cl, urea, and NaNO3), carbon sources (glucose, lactose, maltose, sucrose, starch, and dextrin), and mineral salts (MgSO4, ZnSO4, CaCl2, MnCl2, FeSO4 and FeSO4) were investigated via the single-factor method.
Orthogonal experiments: The orthogonal method was used to determine the fermentation medium that is most suitable for Strain J6 to produce keratinase, providing support for increasing the yield of keratinase and the fermentation efficiency. Based on the above-mentioned experiments’ results, an appropriate orthogonal experimental array L9(34) was selected to obtain the optimal composition of the fermentation medium (Table 1).
Orthogonal experimental design of four factors and three levels
| Level | Factor | |||
|---|---|---|---|---|
| A feather (g/L) | B Lactose (g/L) | C Urea (g/L) | D MgSO4 (g/L) | |
| 1 | 7.5 | 2.5 | 7.5 | 0.9 |
| 2 | 10 | 5 | 10 | 1 |
| 3 | 12.5 | 7.5 | 12.5 | 1.1 |
Subsequently, a comprehensive validation process was implemented, involving three independent batches of experiments for the optimal fermentation medium derived from the orthogonal experiment. Each of these batches was also replicated three times.
The fermentation conditions of the strain were also optimized, including initial pH, fermentation temperature, inoculum size and rotary speed, by employing a single-factor optimization approach.
The enzyme purification procedures were executed below 10°C. All the buffers used here were filtered through 0.22-μm filter membranes. The crude supernatant harboring the keratinase was treated with ammonium sulfate precipitation (ASP) at a saturation level of 70%. The resulting precipitate was efficiently collected by centrifugation (8000 rpm, 4°C, 30 min) and subsequently solubilized in 20 mmol/L Tris-HCl buffer. Then, the resultant mixture was subjected to an overnight dialysis procedure against the same buffer to ensure salt removal. The keratinase obtained through ASP was further purified using a Toyopearl DEAE-650 M chromatography (Greenherbs science and technology, Beijing, China), which was previously equilibrated with Tris-HCl buffer for a volume equivalent to 3-4 times the column volume, facilitating the loading of the desalted keratinase sample. Subsequently, the column was eluted with the buffer containing NaCl at concentrations of 0.2 mol/L to 0.8 mol/L. Meanwhile, both the activity and protein concentration of the keratinase (J6 keratinase) therein were precisely determined, thereby enabling a comprehensive evaluation of the purification outcome and the quality of the purified keratinase.
Protein quantification was carried out by using protein assay kit based on the Bradford method. Additionally, SDS-PAGE was carried out using 5% stacking and 12% separating polyacrylamide gels.
The activities of the enzyme were measured in the pH range of 6.0-12.0 at a buffer concentration of 20 mmol/L. And the residual activities of keratinase were detected after the enzyme was remained in the corresponding pH conditions for 60 min at 20°C. Moreover, the influence of temperatures in the range of 30-70°C on keratinase activity was measured to obtain its optimal temperature. Furthermore, the thermostability of the keratinase was measured by remaining the enzyme at the respective temperature for 60 min and subsequently monitoring its residual activity levels.
The impacts of various chemical agents on keratinase activity were investigated. Keratinase activities were assayed under the enzyme’s optimal pH and temperature conditions in the presence of multiple metal ions at 5 mmol/L, well-known protease inhibitors at 1 mmol/L, the reducing agent at 1 mmol/L, and surfactants at 1%. The enzyme’s activity without any chemicals served as the control.
Diverse substrates (wool, chicken feather, keratin, casein, Type-I collagen) were employed to test enzymatic activity of the keratinase at its optimal pH and temperature. Specifically, the soluble substrates were prepared at the concentration of 1%, then evaluate the keratinase’s activities by the keratinase assay method. For the insoluble substrates, the reaction system contained the suspended 0.05 g of substrates in 0.5 mL buffer solution, and 0.05 mL keratinase. The reaction time was 60 min. Afterward, add 1.0 mL of 10% trichloroacetic acid (TCA) solution to stop the reaction, and centrifuge (15,000 rpm, 10 min). Measure the absorbance of supernatant at 280 nm (OD280). For each reaction, use the reaction system with TCA added before the substrate as a control. The enzyme activity is defined as follows: in the above reaction system, a 0.01 increase in OD280 is considered as one unit.
To explore the kinetic properties of J6 keratinase, soluble keratin at concentrations ranging from 0.1% to 5% was used. The assays were performed under the enzyme’s optimal pH and temperature settings. Subsequently, based on the Michaelis-Menten Equation, J6 keratinase’s kinetic parameters (
Discovery of novel keratinase-producing microorganisms serves as an important task for attaining breakthrough advancements in bioprocesses. Several samples were collected from chicken farms and utilized for screening and isolation of microbial strains with capability of producing keratinase. Totally, 23 isolates were found on the feather keratin medium in which the feather served as substrate/inducer and the sole carbon/nitrogen source. Through cross-screening with skim milk agar medium and feather keratin medium, 5 isolates were found to be capable of producing a relatively high ratio of the diameters of the clear zone to the bacterial colony on the skim milk agar medium. Among them, Strain J6 demonstrated a relatively high keratinase activity of 172 U/mL. Consequently, Strain J6 was used for further study.
The colonies of Strain J6 on LB agar plate displayed irregular edges and a slight white color. Microscopic observation revealed that the bacterium was Gram-positive and rod-shaped. Further molecular identification was carried out. Blast analysis indicated a 1473-bp fragment of the bacterial strain’s 16S rRNA gene showed 100% similarity to that of
Phylogenetic tree of Strain J6 constructed via Neighbor-joining method
As depicted in Figure 2A,
Keratinase production by
In general, the production of enzyme during microbial fermentation is regulated by the nutritional status of fermentation medium [2]. Therefore, the composition of medium and the corresponding levels of its components were determined. First, given that feather serving as the substrate/inducer as well as nitrogen/carbon source is usually important for the keratinase biosynthesis by feather-degrading microbial strains [17, 18], feather was chosen as a key factor. The experimental results demonstrated that at 10 g/L of feather powder,
The orthogonal experimental design method skillfully uses the orthogonal table’s “balanced dispersion and neat comparability” features. The experimental results are greatly scientifically reliable. So, it strongly supports optimizing experimental plans and finding optimal conditions, making research more efficient. Therefore, by employing the orthogonal design method, the four medium components (feather, lactose, urea, and MgSO4) and their corresponding levels were determined for further systematic optimization to enhance the yield of keratinase. Based on the above experimental results, an appropriate orthogonal experimental array L9(34) was selected (Table 1). Subsequently, the orthogonal experiments were executed in strict accordance with the factor-level combinations delineated in the orthogonal table, wherein each experimental group was replicated three times. As shown in Table 2, in exploring the impacts of four factors on enzyme generation, magnesium sulfate was determined to possess the preponderant influence. Subsequently, feather meal, lactose, and urea manifested their respective degrees of influence in a descending sequence. The optimal combination of the four factors (A2B1C1D3) was chicken feather 10 g/L, lactose 2.5 g/L, urea 7.5 g/L, and MgSO4 1.1 g/L. When
Results of orthogonal experiment
| Number | A | B | C | D | Keratinase yield (U/mL) |
|---|---|---|---|---|---|
| 1 | 1 | 1 | 1 | 1 | 375.55±3.12 |
| 2 | 1 | 2 | 2 | 2 | 179.8±5.93 |
| 3 | 1 | 3 | 3 | 3 | 359.9±6.49 |
| 4 | 2 | 1 | 2 | 3 | 401.4±9.84 |
| 5 | 2 | 2 | 3 | 1 | 342.55±3.16 |
| 6 | 2 | 3 | 1 | 2 | 208.9±9.53 |
| 7 | 3 | 1 | 3 | 2 | 186.9±42 |
| 8 | 3 | 2 | 1 | 3 | 307.25±4.78 |
| 9 | 3 | 3 | 2 | 1 | 294.9±2.65 |
| K1 | 305.08 | 321.28 | 297.23 | 337.67 | |
| K2 | 317.62 | 276.53 | 292.03 | 192.86 | |
| K3 | 263.02 | 288.9 | 296.45 | 356.18 | |
| R | 54.6 | 32.38 | 5.2 | 163.32 | |
| Order of priority: D > A > B > C | |||||
| Optimal Combination: A2B1C1D3 | |||||
Apart from the components of fermentation medium, the fermentation conditions of the strain were also optimized, including initial pH, fermentation temperature, inoculum size and rotary speed employing a single-factor optimization approach. As shown in Figure 3, the best fermentation conditions were determined as follows: the initial pH of 8.0, the temperature of 37°C, the inoculum size of 6% (v/v), and the rotational speed of 220 rpm. The optimal cultural temperature differed from those of
Impact of cultural conditions on
The enzyme was purified through a series of treatments including ASP and anion-exchange chromatography. This process was similar to that of
Purification of the keratinase produced by
| Procedures | Protein quantity (mg) | activity (U) | Specific activity (U/mg) | Purification fold | Recovery rate (%) |
|---|---|---|---|---|---|
| Supernatant | 53.25 | 24032 | 451.31 | 1.00 | 100 |
| ASP | 15.41 | 14256 | 925.19 | 2.05 | 59.32 |
| DEAE-650 M chromatography | 0.65 | 2739 | 4215.24 | 9.34 | 11.36 |
SDS-PAGE analysis of the purification of J6 keratinase. Lane M, protein marker; Lane 1, the crude B. cereus J6 keratinase; Lane 2, ASP; Lane 3, the target enzyme.
As shown in Figure 5A, the optimum temperature for the keratinase was 55°C, which is consistent with that of the keratinases from
Impact of temperature and pH
Enzymatic activities of the keratinase were assayed in the presence of metal ions, surfactants, reducing agent, and inhibitors (Table 4). Calcium ion, Mg2+, Zn2+ and Mn2+ at 5 mmol/L could evidently enhance the activity by 22.56%, 31.81%, 18.52% and 6.73% respectively. The promoting effects of Ca2+, Mg2+ and Mn2+ were in consistent with those of
Effects of chemicals on J6 keratinase
| Chemicals | Concentration | Relative activity (%) |
|---|---|---|
| Na+ | 5 mmol/L | 102.59±2.78 |
| K+ | 5 mmol/L | 99.03±2.93 |
| Mn2+ | 5 mmol/L | 106.73±2.25 |
| Ca2+ | 5 mmol/L | 122.56±2.19 |
| Mg2+ | 5 mmol/L | 131.81±5.14 |
| Zn2+ | 5 mmol/L | 118.52±3.52 |
| Cu2+ | 5 mmol/L | 60.87±4.53 |
| Al3+ | 5 mmol/L | 62.67±6.21 |
| Fe2+ | 5 mmol/L | 52.89±5.35 |
| Fe3+ | 5 mmol/L | 31.04±3.87 |
| Tween 20 | 1% | 115.67±3.14 |
| Tween 60 | 1% | 175.27±1.31 |
| Tween 80 | 1% | 150.16±2.31 |
| Triton X-100 | 1% | 106.06±0.52 |
| SDS | 1% | 84.30±2.56 |
| DTT | 1 mmol/L | 155.96±2.73 |
| EDTA | 1 mmol/L | 5.05±2.21 |
| PMSF | 1 mmol/L | Not detected |
Understanding enzyme’s substrate specificity can potentially guide the development of more efficient bioprocessing methods that harness the unique properties of this enzyme for targeted substrate degradation. The degradation effects of the keratinase on various substrates were illustrated in Figure 6. This keratinase showed wide substrate specificity, and outstanding degradation abilities for casein, BSA, and soluble keratin. Additionally, it exhibited relatively high activity against type-I collagen. Conversely, when dealing with insoluble substrates like wool and feathers, the enzyme showed low activity levels. This distinct substrate-specific activity profile of the keratinase not only offers profound insights into its catalytic characteristics but also has far-reaching implications for exploring its potential applications in relevant industries such as management and bioconversion of keratinous waste.
The enzymatic activity of the keratinase towards various substrates
The kinetic parameters of the purified
The kinetics of the purified keratinase
The discovery of an extracellular keratinase produced by the bacterium
This work was supported by the Science and Technology Project of Bijie City (Bike Joint [2023] No. 21), and the Guizhou Provincial Department of Education Natural Science Research Project ([2022] No. 069).