Biodegradation of feather keratin with a PEGylated protease of Chryseobacterium gleum

Present study deals with the covalent modification of keratinolytic protease of Chryseobacterium gleum with higher enzyme activity, improved stability, non-immunogenicity and reusability. Protease of C. gleum showing feather degradation ability was modified by covalent attachment to polyethylene glycol. This modification culminated the change in electrophoretic mobility of protease in acrylamide gel. The modified enzyme showed 1.4 times more catalytic activity with better stability than native in aqueous system containing whole feathers as keratin. It showed improved pH, thermal, storage and solvent stability with a broadened range of pH (7–9) and temperature (25–50 °C) than native. The differentiation between modified and native enzyme was authenticated through UV–vis spectroscopy, SEM, XRD, FTIR and DSC. This modification of protease proved to be non-immunogenic in rats. The enzyme extracted after first run could be used for several cycles which clearly demonstrated its reusability in catalytic bioprocess of keratin degradation.     

Biodegradation of feather waste by extracellular keratinases and gelatinases from Bacillus spp.

In this study, three feather degrading bacterial strains were isolated from agroindustrial residues from a Brazilian poultry farm. Three Gram-positive, spore-forming, rod-shaped bacteria and were identified as B. subtilis 1271, B. licheniformis 1269 and B. cereus 1268 using biochemical, physiologic and molecular methods. These Bacillus spp. strains grew and produced keratinases and peptidases using chicken feather as the sole source of nitrogen and carbon. B. subtilis 1271 degraded feathers completely after 7 days at room temperature and produced the highest levels of keratinase (446 U ml^?1). Feather hydrolysis resulted in the production of serine, glycine, glutamic acid, valine and leucine as the major amino acids. Enzymography and zymography analyses demonstrated that enzymatic extracts from the Bacillus spp. effectively degraded keratin and gelatin substrates as well as, casein, hemoglobin and bovine serum albumin. Zymography showed that B. subtilis 1271 and B. licheniformis 1269 produced peptidases and keratinases in the 15?C140 kDa range, and B. cereus produced a keratinase of ~200 kDa using feathers as the carbon and nitrogen source in culture medium. All peptidases and keratinases observed were inhibited by the serine specific peptidase inhibitor phenylmethylsulfonyl fluoride (PMSF). The optimum assay conditions of temperature and pH for keratinase activity were 40?C50°C and pH 10.0 for all strains. For gelatinases the best temperature and pH ranges were 50?C70°C and pH 7.0?C11. These isolates have potential for the biodegradation of feather wastes and production of proteolytic enzymes using feather as a cheap and eco-friendly substrate.     

Production of alkaline protease in a low-cost medium by alkalophilic Bacillus sp. and properties of the enzyme

The main object of this research was to obtain a large amount of alkaline protease in a low-cost medium, for which purpose Bacillus sp. B21-2 was isolated from soil. The enzyme production by this strain reached the maximum level of 15,000 u/ml in a short cultivation time of 24–28 h in alkaline medium consisting of cheap materials such as soybean meal and bonito extract. The optimum pH and temperature for activity of the purified enzyme were 11.5 and 60°C respectively. The enzyme was stable up to 50°C but inactivated after 10 min at 60°C. The enzyme activity was completely inhibited by diisopropylfluorophosphate.     

Characterization of a novel <Emphasis Type="Italic">Stenotrophomonas</Emphasis> isolate with high keratinase activity and purification of the enzyme

A feather-degrading bacterium was isolated from poultry decomposition feathers in China. The strain, named L1, showed significant feather-degrading activity because it grew and reproduced quickly on basal medium containing 10 g/L of native feather as the source of energy, carbon, and nitrogen. According to the phenotypic characteristics and 16S rRNA profile, the isolate belongs to Stenotrophomonas maltophilia. Keratinase activity of the isolate was determined during cultivation on raw feathers at different temperatures and initial pH. Maximum growth and feather-degrading activity of the bacterium were observed at 40°C and initial pH ranging from 7.5 to 8.0. The crude enzyme was purified by ammonium sulphate precipitation, Sephadex G-100 chromatographic and ceramic hydroxyapatite (CHT) chromatographic. Its molecular mass estimated as 35.2 kDa in SDS-PAGE. The enzyme had an optimum activity at the pH was 7.8 and the temperature was 40°C. The keratinase was wholly inhibited by a serine protease inhibitor, PMSF. Its activity was activated or inhibited by different metal ions. The keratinase activity of enzyme from strain L1 functioned on different keratins, such as feather, hair, wool, horn, and so on.     

Biochemical characterization of psychrophilic Mn-superoxide dismutase from newly isolated Exiguobacterium sp. OS-77

Many types of superoxide dismutases have been purified and characterized from various bacteria, however, a psychrophilic Mn-superoxide dismutase (MnSOD) has not yet been reported. Here, we describe the purification and the biochemical characterization of the psychrophilic MnSOD from Exiguobacterium sp. strain OS-77 (EgMnSOD). According to 16S rRNA sequence analysis, a newly isolated bacterium strain OS-77 belongs to the genus Exiguobacterium. The optimum growth temperature of the strain OS-77 is 20 °C. The EgMnSOD is a homodimer of 23.5 kDa polypeptides determined by SDS-PAGE and gel filtration analysis. UV-Vis spectrum and ICP-MS analysis clearly indicated that the homogeneously purified enzyme contains only a Mn ion as a metal cofactor. The optimal reaction pH and temperature of the enzyme were pH 9.0 and 5 °C, respectively. Notably, the purified EgMnSOD was thermostable up to 45 °C and retained 50 % activity after 21.2 min at 60 °C. The differential scanning calorimetry also indicated that the EgMnSOD is thermostable, exhibiting two protein denaturation peaks at 65 and 84 °C. The statistical analysis of amino acid sequence and composition of the EgMnSOD suggests that the enzyme retains psychrophilic characteristics.     

Purification and characterization of an efficient poultry feather degrading-protease from Myrothecium verrucaria

The purpose of this work was to characterize an alkaline protease from the filamentous fungus Myrothecium verrucaria and to explore its capability to degrade native poultry feathers. The enzyme was purified to homogeneity using a single chromatographic step. Recovery was high, 62%, with a specific activity of 12,851.8 U/mg protein. The enzyme is a small monomeric protein with a molecular mass of 22 ± 1.5 kDa. It presented pH optimum of 8.3 and was stable over a broad pH range (5.0–12.0). The temperature optimum was 37°C, with thermal stability at temperatures up to 45°C. The enzyme presented an efficiency of 80.3% in the degradation of poultry feather meal, releasing amino acids and soluble peptides. It was able to hydrolyze β-keratin without necessity of chemical or enzymatic reduction of the disulphide bonds. Considering that, everyday, poultry-processing plants produce feathers as a waste products, this protease can be useful in biotechnological processes aiming to improve the transformation of poultry feathers through solubilization of β-keratin into usable peptides. Furthermore, it can also be useful in processes aiming to reduce the environmental pollution caused by the accumulation of feathers.     

Highly stable laccase from repeated-batch culture of Funalia trogii ATCC 200800

The effect of temperature, pH, different inhibitors and additives on activity and stability of crude laccase obtained from repeated-batch culture of white rot fungus Funalia trogii ATCC 200800 was studied. The crude enzyme showed high activity at 55–90°C, which was maximal at 80–95°C. It was highly stable within the temperature intervals 20–50°C. The half life of the enzyme was about 2 h and 5 min at 60°C and 70°C, respectively. pH optimum of fungal laccase activity was revealed at pH 2.5. The enzyme from F. trogii ATCC 200800 was very stable between pH values of 3.0–9.0. NaN₃ and KCN were detected as the most effective potent enzyme inhibitors among different compounds tested. The fungal enzyme was highly resistant to the various metal ions, inorganic salts, and organic solvents except propanol, at least for 5 min. Because of its high stability and efficient decolorization activity, the use of the crude F. trogii ATCC 200800 laccase instead of pure enzyme form may be a considerably cheaper solution for biotechnological applications.     

Application of statistical experimental design for optimization of keratinases production by Bacillus pumilus A1 grown on chicken feather and some biochemical properties

A new keratinolytic enzyme-producing bacterium was isolated from slaughter house polluted water and identified as Bacillus pumilus A1. Medium composition and culture conditions for the keratinases production by B. pumilus A1 were optimized using two statistical methods: Plackett–Burman design applied to find the key ingredients and conditions for the best yield of enzyme production and central composite design used to optimize the concentration of the five significant variables: feathers meal, soy peptone, NaCl, KCl, and KH₂PO₄. The medium optimization resulted in a 3.4-fold increase in keratinase production (87.73 U/ml) compared to that of the initial medium (25.9 U/ml). The zymography analysis shows the presence of at least five keratinolytic enzymes. The keratinolytic activity of the extracellular proteinases was examined by incubation with non-autoclaved chicken feathers. Complete solubilisation of whole feathers was observed after a 6-h incubation at temperatures ranging from 45 °C to 60 °C. The crude enzyme exhibited maximal activity at 60 °C and pH 8.5 or 55 °C and pH 9.0 using casein or keratin as substrates, respectively.     

Biodegradation of feather waste by keratinase produced from newly isolated Bacillus licheniformis ALW1

Keratinase are proteolytic enzymes which have gained much attention to convert keratinous wastes that cause huge environmental pollution problems. Ten microbial isolates were screened for their keratinase production. The most potent isolate produce 25.2?U/ml under static condition and was primarily identified by partial 16s rRNA gene sequence as Bacillus licheniformis ALW1. Optimization studies for the fermentation conditions increased the keratinase biosynthesis to 72.2?U/ml (2.9-fold). The crude extracellular keratinase was optimally active at pH 8.0 and temperature 65?°C with 0.7% soluble keratin as substrate. The produced B. licheniformis ALW1 keratinase exhibited a good stability over pH range from 7 to 9 and over a temperature range 50–60?°C for almost 90?min. The crude enzyme solution was able to degrade native feather up to 63% in redox free system.     

Isolation and characterization of a new <Emphasis Type="Italic">Bacillus</Emphasis> sp. 50-3 with highly alkaline keratinase activity from <Emphasis Type="Italic">Calotes versicolor</Emphasis> faeces

A new native feather-degrading bacterium has been isolated from the faeces of the agamid lizard Calotes versicolor, collected from the Beijing Zoo in China. The isolate, which has been identified as Bacillus sp. 50-3 based on morphological and biochemical and 16S rDNA tests, was shown to degrade native feather completely at 37°C and pH 7.0 within 36 h when using chicken feathers as the sole carbon and nitrogen source. Bacillus sp. 50-3 presented optimum growth at 37°C and pH 7.0 in feather meal medium. Under these conditions, the maximum keratinase activity (680 ± 25 U/ml) was also achieved. The keratinase of Bacillus sp. 50-3 was active over a broad range of pH values and temperatures toward azokeratin, and presented an optimum pH and temperature of 10.0 and 60°C, respectively. Furthermore, it was relatively heat-and alkali-stable. Inhibitor studies showed that it seemed to belong to the serine-metalloprotease type. Therefore, the enzyme from Bacillus sp. 50-3 is a novel, high alkaline keratinase, suggesting its potential use in biotechnological processes.     

一株羽毛降解菌的分离与鉴定

【目的】从土壤中分离并鉴定羽毛降解菌,测定其生长最适温度及起始pH,并观察酶活动态。【方法】采用系列稀释法和选择培养基法筛选目的菌株,基于16S rRNA基因序列及Biolog方法鉴定其分类地位,利用全自动生长曲线分析仪监测菌株的最适生长条件,并通过测定蛋白水解活性观察其酶活动态。【结果】从混合羽毛的土壤样品中筛选到一株羽毛降解菌,命名为菌株GIMN1.015,初步判定该菌株属于芽孢八叠球菌属(Sporosarcina)。最适生长pH为9.0,温度为30°C。蛋白水解活性最高值出现在培养后96 h。【结论】菌株GIMN1.015在利用羽毛角蛋白资源中具有潜在的应用价值。这是芽孢八叠球菌在羽毛降解方面的首次报道。     

Purification and characterization of pectin lyase secreted by Aspergillus flavus MTCC 10938

An indigenously isolated fungal strain Aspergillus flavus MTCC 10938 was subjected to pectin lyase (PNL) production under submerged fermentation conditions. The enzyme was purified to homogeneity from the culture filtrate of the fungus involving concentration by ultrafiltration, anion exchange chromatography on DEAE cellulose and gel filtration chromatography on Sephadex G-100. The purified PNL gave a single protein band in SDS-PAGE analysis with a relative molecular mass corresponding to 50 kDa. Using citrus pectin as the substrate the K _m and k _cat values of the enzyme were obtained as 1.7 mg/ml and 66 s^?1, respectively. The optimum pH of the purified PNL from A. flavus MTCC 10938 was 8.0 and up to 90% of its activity retained in the pH range from 3.0 to 11.0 after 24 h incubation. The optimum temperature of the purified enzyme was revealed at 55°C and it was completely stable up to 40°C when exposed for 30 min. The purified A. flavus MTCC 10938 PNL showed efficient retting of Crotalaria juncea fibres.     

Purification and characterization of a novel exocellular keratinase from Kocuria rosea

A keratinolytic protease activity secreted by Kocuria rosea when cultured in bioreactors using feathers as unique carbon and nitrogen source was purified and characterized. This novel keratinase activity was purified from the bioreaction broth growing media to apparent homogeneity after single step, (24-fold purification with a high yield of 54%) using DEAE column chromatography. The native molecular mass of the enzyme determined by gel filtration chromatography was 240 kDa. K. rosea extracellular keratinase was stable in a broad range of pH (8–11) and temperature (10–60 °C) profile with optimums at pH 10 and 40 °C. Crystalline soybean trypsin inhibitor (type I-S), 4-(2-aminoethyl) benzenesulfonyl floride (AEBSF) and chymostatin, strongly inhibited the keratinolytic activity indicating that the keratinase belongs to the serine protease family. The K_m for the soluble keratin degradation from feathers was 242 μM. The enzyme was resistant to denaturing or reducing agents such as dithiotreitol and 2-mercaptoethanol. All of the biochemical characteristics, raising the potential use of this enzyme in numerous industrial applications.     

Extracellular solvent stable cold-active lipase from psychrotrophic Bacillus sphaericus MTCC 7526: partial purification and characterization

Psychrotropic Bacillus sphaericus producing solvent stable cold-active lipase upon growth at low temperature was isolated from Gangotri glacier. Optimal parameters for lipase production were investigated and the strain was able to produce lipase even at 15 °C. An incubation period of 48 h and pH 8 was found to be conducive for cold-active lipase production. The addition of trybutyrin as substrate and lactose as additional carbon source increased lipase production. The enzyme was purified up to 17.74-fold by ammonium sulphate precipitation followed by DEAE cellulose column chromatography. The optimum temperature and pH for lipase activity were found to be 15 °C and 8.0, respectively. The lipase was found to be stable in the temperature range 20–30 °C and the pH range 6.0–9.0. The protein retained more than 83 % of its initial activity after exposure to organic solvents. The lipase exhibited significant stability in presence of acetone and DMSO retaining >90 % activity. The enzyme activity was inhibited by 10 mM CuSO₄ and EDTA but showed no loss in activity after incubation with other metals or inhibitors examined in this study.     

Keratinases and sulfide from <Emphasis Type="Italic">Bacillus subtilis</Emphasis> SLC to recycle feather waste

The aim of this study is to investigate the culture conditions of chicken feather degradation and keratinolytic enzyme production by the recently isolated Bacillus subtilis SLC and to evaluate the potential of the SLC strain to recycle feather waste discarded by the poultry industry. The SLC strain was isolated from the agroindustrial waste of a poultry farm in Brazil and was confirmed to belong to Bacillus subtilis by rDNA gene analysis. There was high keratinase production when the medium was at pH 8 (280 U ml⁻¹). Activity was higher using the inoculum propagated for 72 h on 1% whole feathers supplemented with 0.1% yeast extract. In the enzymatic extract, the keratinases were active in the pH range from 2.0 to 12.0 with a maximum activity at pH 10.0 and temperature 60°C. For gelatinase the best pH was 5.0 and the best temperature was 37°C. All keratinases are serine peptidases. The crude enzymatic extract degraded keratin, gelatin, casein, and hemoglobin. Scanning electron microscopy showed Bacillus cells adhered onto feather surfaces after 98 h of culture and degraded feather filaments were observed. MALDI-TOF mass spectrometric analysis showed multiple peaks from 522 to 892 m/z indicating feather degradation. The presence of sulfide was detected on extracellular medium probably participating in the breakdown of sulfide bridges of the feather keratin. External addition of sulfide increased feather degradation.     

Characterization of a cold-active lipase from Psychrobacter cryohalolentis K5T and its deletion mutants

A gene coding for cold-active lipase from the psychrotrophic Gram-negative bacterium Psychrobacter cryohalolentis K5^T isolated from a Siberian cryopeg has been cloned and expressed in Escherichia coli. The recombinant protein Lip1Pc with a 6× histidine tag at its C-terminus was purified by nickel affinity chromatography. With p-nitrophenyl dodecanoate (C12) as a substrate, the purified recombinant protein displayed maximum lipolytic activity at 25°C and pH 8.0. Increasing the temperature above 40°C and addition of various metal ions and organic solvents inhibited the enzymatic activity of Lip1Pc. Most nonionic detergents, such as Triton X-100 and Tween 20, slightly increased the lipase activity, while SDS completely inhibited it. To investigate the functional significance of the Lip1Pc N-terminal domain, we constructed five deletion mutants of this protein. The ND1 and ND2 mutants displayed specific activity reduced by 30–35%, while other truncated proteins were completely inactive. Both mutants demonstrated increased activity towards p-nitrophenyl decanoate (C10) and impaired utilization of C16 substrate. Although optimum reaction temperature of ND2 lowered to 20°C, it displayed enhanced stability by 44% after incubation at 40°C. The results prove that the N-terminal domain of Lip1Pc has a fundamental impact on the activity and stability of the protein.     

Characterization of an alkaline elastase from alkalophilic Bacillus Ya-B

The alkaline elastase produced by alkalophilic Bacillus Ya-B was a new type of proteinase which had a very high optimum pH and high elastolytic activity. It also had a high hydrolyzing activity against keratin and collagen. The molecular weight was determined to be 23 700 and 25 000 by ultracentrifugation analysis and SDS-polycrylamide gel electrophoresis, respectively. The isoelectric point was 10.6. The optimum reaction temperature was 60°C. Like many alkaline proteinases, this enzyme required Ca²⁺ for stability. The optimum reaction pH was 11.75 toward casein and elastin-orcein. The K_cat/K_m values of the enzyme to synthetic substrates were constant from pH 8.5 up to 12.75. The enzyme was stable in the pH range 5.0–10.0. The enzyme was inhibited by alkaline proteinase inhibitors Streptomyces subtilisin inhibitor and microbial alkaline proteinase inhibitor, but not by elastatinal or the metalloproteinase inhibitor metalloproteinase inhibitor. Sodium chloride inhibited the elastolytic activity but not the caseinolytic activity at a concentration below 0.2 M. The inhibitory effect of sodium chloride to elastolytic activity was much more prominent at pH 9.0 than at pH 11.5. More than 50% of the enzyme bound onto elastin in the pH range below the isoelectric point of this enzyme. The amino-terminal sequence of the enzyme was determined, and compared with those of subtilisin BPN′ and subtilisin Carlsberg. Extensive sequence homology was noted among these three enzymes.     

Spirosoma xylofaga sp. nov., an oligotrophic pleomorphic bacterium from a myco-bacterial community of freshwater ecosystems

A novel aerobic bacterial strain Z-0088 was assigned to the genus Spirosoma on the basis of 16S rRNA analysis; it was isolated from a bacterial community of moderately acidic (pH 5.0) dystrophic, slightly humified water formed by xylotrophic fungi grown on decaying spruce wood. The cells are nonmotile, gramnegative, straight or curved rods, 0.5–1.5 × 1.0–6.0 μm; they may also be toroidal. The cells are usually single but can form spiral filaments containing from 4 to 13 coils; their reproduction is by division. Strain Z-0088 is an organoheterotroph utilizing xylan, inulin, xylose, sucrose, and N-acetylglucosamine as organic growth substrates. The bacterium is oligotrophic (the optimum substrate concentration is 0.5 g/L). It is characterized by high sensitivity to NaCl concentration; growth was completely suppressed at 1% NaCl. The strain grows in a pH range of 3.8–7.5 with the optimum at pH 5.5–6.5. The temperature range for growth was 13–35°C with the optimum at 28°C. The DNA G+C base content was 50.2 mol %. The ecophysiological features of strain Z-0088, such as oligotrophic, mesophilic, moderate acidophilic properties, and sensitivity to NaCl, support its designation as a representative of ombrophilic dissipotrophs. The strain is assigned to a novel species Spirosoma xylofaga sp. nov.     

Improvement of alkali stability and thermostability of Paenibacillus campinasensis Family-11 xylanase by directed evolution and site-directed mutagenesis

The extreme process condition of high temperature and high alkali limits the applications of most of natural xylanases in pulp and paper industry. Recently, various methods of protein engineering have been used to improve the thermal and alkalic tolerance of xylanases. In this work, directed evolution and site-directed mutagenesis were performed to obtain a mutant xylanase improved both on alkali stability and thermostability from the native Paenibacillus campinasensis Family-11 xylanase (XynG1-1). Mutant XynG1-1B43 (V90R/P172H) with two units increased in the optimum pH (pH 7.0–pH 9.0) and significant improvement on alkali stability was selected from the second round of epPCR library. And the further thermoduric mutant XynG1-1B43cc16 (V90R/P172H/T84C-T182C/D16Y) with 10 °C increased in the optimum temperature (60–70 °C) was then obtained by introducing a disulfide bridge (T84C-T182C) and a single amino acid substitution (D16Y) to XynG1-1B43 using site-directed mutagenesis. XynG1-1B43cc16 also showed higher thermostability and catalytic efficiency (k _cat /K _m ) than that of wild-type (XynG1-1) and XynG1-1B43. The attractive improved properties make XynG1-1B43cc16 more suitable for bioleaching of cotton stalk pulp under the extreme process condition of high temperature (70 °C) and high alkali (pH 9.0).     

Studies on Tannin Acyl Hydrolase of Microorganisms

Tannin acyl hydrolase (Tannase) from Asp. oryzae No. 7 was purified. The purified enzyme was homogenous on column chromatography (DEAE-Sephadex A50, Sephadex G100), ultra centrifugation and electrophoresis.

The molecular weight of the enzyme estimated by gel filtration method was about 200,000.

The enzyme was stable in the range of pH 3 to 7.5 for 12 hr at 5°C, and for 25 hr at the same temperature in the range of pH 4.5 to 6. The optimum pH for the reaction was 5.5. It was stable under 30°C (over one day, in 0.05 M-citrate buffer of pH 5.5), and the optimum temperature was 30~40°C (reaction for 20min). The activity was lost completely at 55°C in 20 min at pH 5.5, or at 85°C in 10 min at the same pH.

Any metal salt tested did not activate the enzyme, Zink chloride and cupric chloride inhibited the activity or denatured the enzyme. The activity was lost completely by dialysis against EDTA-solution at pH 7.25, although it was not affected by dialysis against deionized water.