ABSTRACT
Background: In this work, the xylanase production by Penicillium chrysogenum F-15 strain was investigated using agroindustrial biomass as substrate. The xylanase was purified, characterized and applied in hemicellulose hydrolysis. Results: The highest xylanase production was obtained when cultivation was carried out with sugar cane bagasse as carbon source, at pH 6.0 and 20°C, under static condition for 8 d. The enzyme was purified by a sequence of ion exchange and size exclusion chromatography, presenting final specific activity of 834.2 U·mg·prot-1. T he molecular mass of the purified enzyme estimated by SDS-PAGE was 22.1 kDa. The optimum activity was at pH 6.5 and 45°C. The enzyme was stable at 40°C with half-life of 35 min, and in the pH range from 4.5 to 10.0. The activity was increased in the presence of Mg+2 and Mn+2 and reducing agents such as DTT and ßmercaptoethanol, but it was reduced by Cu+2 and Pb+2 . The xylanase presented Km of 2.3 mM and Vmax of 731.8 U·mg·prot-1 with birchwood xylan as substrate. This xylanase presented differences in its properties when it was compared to the xylanases from other P. chrysogenum strains. Conclusion: The xylanase from P. chrysogenum F-15 showed lower enzymatic activity on commercial xylan than on hemicellulose from agroindustry biomass and its biochemistry characteristics, such as stability at 40°C and pH from 4.0 to 10.0, shows the potential of this enzyme for application in food, feed, pulp and paper industries and for bioethanol production.
Subject(s)
Penicillium chrysogenum/metabolism , Polysaccharides/metabolism , Endo-1,4-beta Xylanases/biosynthesis , Temperature , Enzyme Stability , Biomass , Endo-1,4-beta Xylanases/isolation & purification , Electrophoresis, Polyacrylamide Gel , Hydrogen-Ion Concentration , HydrolysisABSTRACT
Background: Xylanases are considered one of the most important enzymes in many industries. However, their low thermostability hampers their applications in feed pelleting, pulp bleaching, and so on. The main aim of this work was to improve the thermostability of Trichoderma ressei xylanase 2 (Xyn2) by introducing disulfide bonds between the N-terminal and α-helix and the ß-sheet core. Results: In this work, two disulfide bonds were separately introduced in the Xyn2 to connect the N-terminal and α-helix to the ß-sheet core of Xyn2. The two disulfide bonds were introduced by site-directed mutagenesis of the corresponding residues. The half-life of the mutants Xyn2C1452 (disulfide bond between ß-sheets B2 and B3) and Xyn2C59149 (disulfide bond between ß-sheets A5 and A6) at 60°C was improved by approximately 2.5- and 1.8-fold compared to that of the wild type Xyn2. In addition, the enzyme's resistance to alkali and acid was enhanced. Conclusion: Our results indicated that the connection of the N-terminal and α-helix to the ß-sheet core is due to the stable structure of the entire protein.
Subject(s)
Trichoderma/enzymology , Xylosidases/metabolism , Disulfides/metabolism , Mass Spectrometry , Temperature , Trichoderma/genetics , Trichoderma/metabolism , Xylans/metabolism , Xylosidases/genetics , Enzyme Stability , Kinetics , Mutagenesis, Site-Directed , Hydrogen-Ion Concentration , MutationABSTRACT
Background: Xylanases and β-D-xylosidases are the most important enzymes responsible for the degradation of xylan, the second main constituent of plant cell walls. Results: In this study, the main extracellular xylanase (XYL I) and p-xylosidase (BXYL I) from the fungus Penicillium janczewskii were purified, characterized and applied for the hydrolysis of different substrates. Their molecular weights under denaturing and non-denaturing conditions were, respectively, 30.4 and 23.6 kDa for XYL I, and 100 and 200 kDa for BXYL I, indicating that the latter is homodimeric. XYL I is highly glycosylated (78%) with optimal activity in pH 6.0 at 65°C, while BXYL I presented lower sugar content (10.5%) and optimal activity in pH 5.0 at 75°C. The half-lives of XYL I at 55, 60 and 65°C were 125,16 and 6 min, respectively. At 60°C, BXYL I retained almost 100% of the activity after 6 h. NH4+,Na+, DTT and β-mercaptoethanol stimulated XYL I, while activation of BXYL I was not observed. Interestingly, XYL I was only partially inhibited by Hg2+, while BXYL I was completely inhibited. Xylobiose, xylotriose and larger xylooligosaccharides were the main products from xylan hydrolysis by XYL I. BXYL I hydrolyzed xylobiose and larger xylooligosaccharides with no activity against xylans. Conclusion: The enzymes act synergistically in the degradation of xylans, and present industrial characteristics especially in relation to optimal activity at high temperatures, prolonged stability of BXYL I at 60°C, and stability of XYL I in wide pH range.
Subject(s)
Penicillium/enzymology , Xylosidases/isolation & purification , Xylosidases/metabolism , Temperature , Enzyme Stability , Carbohydrates , Electrophoresis , Hydrogen-Ion Concentration , Hydrolysis , Molecular WeightABSTRACT
In recent decades, increasing interest has been devoted to xylanolytic enzymes due to their potential use in many industrial processes. This study describes the production of xylanase, -xylosidase and -Larabinofuranosidase, belonging to the xylanolytic complex, by Penicillium janczewskii using brewer's spent grain as substrate for solid-state fermentation. The optimized conditions for high levels of xylanase, -xylosidase and -Larabinofuranosidase production were: 50% initial moisture, which was provided by Vogel's salt solution, seven days of cultivation at 20-30 °C. Fermentation enriched the bioproduct with some amino acids and did not add mycotoxins to it. The use of brewer's spent grain as substrate for fungal cultivation and enzyme production can both add value to this waste and reduce the production cost of xylanolytic enzymes.
Nas últimas décadas, há interesse crescente nas enzimas xilanolíticas devido à sua potencial utilização em muitos processos industriais. Este estudo descreve a produção de xilanase, -xilosidase e -Larabinofuranosidase, três enzimas do complexo xilanolítico, por Penicillium janczewski utilizando bagaço de cevada como substrato para fermentação em estado sólido. As condições selecionadas para a produção de elevados níveis de xilanase, - xilosidase e -L-arabinofuranosidase por esta linhagem fúngica foram 50% de umidade inicial, sendo esta fornecida por uma solução de sais de Vogel e cultivo por sete dias a 20-30 °C. O bioproduto fermentado foi enriquecido com alguns aminoácidos e se apresentou livre de micotoxinas. O uso do bagaço de cerveja como substrato para o cultivo de fungos e produção de enzimas não só pode agregar valor a esses resíduos, mas também reduzir o custo de produção de enzimas xilanolíticas.
Subject(s)
Penicillium , Hordeum , Substrates for Biological Treatment , Enzymes , FermentationABSTRACT
Many fungi are used in order to extract products from their metabolism through bioprocesses capable of minimizing adverse effects caused by agro- industrial wastes in the environment. The aim of this study was to evaluate the xylanase production by an Aspergillus niger strain, using agro-industrial wastes as substrate. Brewer's spent grain was the best inducer of xylanase activity. Higher levels of xylanase were obtained when the fungus was grown in liquid Vogel medium, pH 5.0, at 30ºC, during 5 days. The temperature for optimum activity was 50ºC and optimum pH 5.0. The enzyme was stable at 50ºC, with a half-life of 240 min. High pH stability was verified from pH 4.5 to 7.0. These characteristics exhibited by A. niger xylanase turn this enzyme attractive for some industrial applications, such as in feed and food industries. Additionally, the use of brewer's spent grain, an abundantly available and low-cost residue, as substrate for xylanase production can not only add value and decrease the amount of this waste, but also reduce xylanase production cost.
Muitos fungos são utilizados com a finalidade de extrair produtos de seu metabolismo, por meio de bioprocessos capazes de minimizar efeitos nocivos que resíduos agroindustriais causam ao meio ambiente. O objetivo deste estudo foi avaliar a produção de xilanases por uma linhagem de Aspergillus niger, empregando resíduos agroindustriais como substrato. O bagaço de malte foi o melhor resíduo indutor da atividade xilanásica. Maiores níveis de xilanases foram obtidos quando o fungo foi cultivado em meio líquido de Vogel, pH 5,0, a 30ºC, durante cinco dias. A temperatura ótima estabelecida para a atividade xilanásica foi a de 50ºC e o pH ótimo 5,0. A enzima foi estável a 50ºC, apresentando uma meia vida de 240 min. Elevada estabilidade enzimática foi verificada entre os pH 4,5 e 7,0. As características bioquímicas exibidas pela xilanase produzida por A. niger tornam esta enzima atraente para determinadas aplicações industriais, como as indústrias de ração animal e alimentícia. Adicionalmente, a utilização do bagaço de malte, um resíduo disponível em abundância e de baixo custo como substrato para a produção de xilanases poderá não somente adicionar valor a este resíduo, como também reduzir os custos de produção destas enzimas.
Subject(s)
Biochemical Reactions , Fungi , Industrial WasteABSTRACT
Microorganisms harbored by nature and guts of herbivorous animals can degrade different plant related biomass. One of the in-between steps for conversion of lignocellulosic biomass to ethanol entails isolation and identification of microorganisms that could convert pretreated biomass into a suitable form, which could then be fermented into bioethanol. We isolated 36 different microorganisms from hot spring, 6 from ruminant’s (goat) gut, 2 sample from hay spray on the basis of their ability to secrete enzymes that hydrolyzed different plant constituents. Similarly 3 microorganisms were isolated from the rotten wood available around Kathmandu University on the basis of utilization of xylose and glucose. 3 varieties of thermophiles, gut microorganism and microorganism from hay spray that showed the highest cellulolytic and xylanolytic activities by saccharification of cellulose and xylan into their monosaccharide glucose and xylose units respectively were then applied on different biomass (rice straw, corn stover and sugarcane bagasse). Before Saccharification biomass was made accessible for the digestion by enzymes through 3 different pretreatment strategies (3.35% H2SO4, NaOH and H2O2 with 1:10 substrate: chemical ratio) following thermal strategy of steam explosion. Also, different conditions like incubation time, pH and temperature for saccharification were assessed with the highest liberation of reducing sugar at pH 5, temperature of 5̊ C and incubation time of 4 days. Microorganism from rotten wood was able to utilize both xylose and glucose and yielded highest amount (5.567 mg/ml) of bioethanol.
ABSTRACT
A strain of the filamentous fungus Aspergillus niger was isolated and shown to possess extracellular xylanolytic activity. These enzymes have biotechnological potential and can be employed in various industries. This fungus produced its highest xylanase activity in a medium made up of 0.1% CaCO3, 0.5% NaCl, 0.1% NH4Cl, 0.5% corn steep liquor and 1% carbon source, at pH 8.0. A low-cost hemicellulose residue (powdered corncob) proved to be an excellent inducer of the A. niger xylanolytic complex. Filtration of the crude culture medium with suspended kaolin was ideal for to clarify the extract and led to partial purification of the xylanolytic activity. The apparent molecular mass of the xylanase was about 32.3 kDa. Maximum enzyme activity occurred at pH 5.0 and 55-60ºC. Apparent Km was 10.41 ± 0.282 mg/mL and Vmax was 3.32 ± 0.053 U/mg protein, with birchwood xylan as the substrate. Activation energy was 4.55 kcal/mol and half-life of the crude enzyme at 60ºC was 30 minutes. Addition of 2% glucose to the culture medium supplemented with xylan repressed xylanase production, but in the presence of xylose the enzyme production was not affected.
Uma linhagem do fungo filamentoso Aspergillus niger foi isolada e apresentou atividade xilanolítica extracelular. Estas enzimas possuem grande potencial biotecnológico e podem ser aplicadas em diversas indústrias. O fungo produziu sua maior atividade de xilanase em um meio contendo CaCO3 0,1%, NaCl 0,5%, NH4Cl 0,1%, 0,5% água de maceração de milho e 1% de fonte de carbono, em pH 8,0. Um resíduo lignocelulósico de baixo custo (sabugo de milho em pó) mostrou ser um excelente indutor do complexo xilanolítico em A. niger. A filtração do extrato cru com caulim foi ideal para a clarificação do extrato e levou à purificação parcial da enzima. A massa molecular aparente da xilanase foi de 32,3 kDa. A máxima atividade da enzima ocorreu em pH 5,0 e a 55-60ºC. O Km aparente foi de 10,41 ± 0,282 mg/mL e a Vmax foi de 3,32 ± 0,053 U/mg proteína, utilizando-se xilana birchwood como substrato. A energia de ativação foi de 4,55 kcal/mol, e a meia-vida da enzima a 60ºC foi de 30 minutos. A adição de 2% de glicose ao meio de cultura suplementado com xilana reprimiu a produção de xilanase, mas em presença de xilose a produção da enzima não foi afetada.
Subject(s)
Aspergillosis , Aspergillus niger , Industrial WasteABSTRACT
Hemicellulosic agricultural by-products such as corn stover (CS) are highly available materials which represent an opportunity to develop value added products. Native Aspergillus niger GS1 was used for solid-state fermentation (SSF) on alkali pre-treated CS (ACS) aimed to optimize xylanolytic enzymes production, and their effect on in vitro ruminal and true digestibility of ACS. Enzyme production was empirically modelled using a fractional factorial design 2(9-5), and the resulting significant factors were glucose, yeast extract and two mineral salts, which were arranged in a Draper-Lin optimization design at two levels. Predicted optimum xylanolytic activity of 33.6 U (mg protein)-1 was achieved at 48 hrs of SSF, and was validated by confirmatory experiments. ACS was incubated with a semipurified enzymatic extract (EE) showing a xylanolytic activity of 1600 U kg-1 dry ACS for 12 hrs before exposure to cow's ruminal liquid for 72 hrs, which led to 5 percent and 10 percent increase of in vitro ruminal and true digestibility, respectively. CS is a readily available by-product in different regions which after alkaline treatment and partial hydrolysis with the EE, may be advantageously used as supplement for ruminant feed.
Subject(s)
Animals , Animal Feed , Aspergillus niger/enzymology , Zea mays/chemistry , Carbon Dioxide , Cellulose/metabolism , Digestion , Fermentation , Polysaccharides/metabolism , Time Factors , Xylans/metabolismABSTRACT
Five types of agricultural wastes were used for the production of xylanolytic enzyme by Aspergillus flavus K-03. All wastes materials supported high levels of xylanase and beta-xylosidase production. A high level of proteolytic activity was observed in barley and rice bran cultures, while only a weak proteolytic activity was detected in corn cob, barley and rice straw cultures. Maximum production of xylanase was achieved in basal liquid medium containing rice barn as carbon source for 5 days of culture at pH 6.5 and 25degrees C. The xylanolytic enzyme of A. flavus K-03 showed low thermostability. The times required for 50% reduction of the initial enzyme activity were 90 min at 40degrees C, 13 min at 50degrees C, and 3 min at 60degrees C. Xylanolytic activity showed the highest level at pH 5.5~10.5 and more than 70% of the original activity was retained at pH 6.5 and 7.0. The higher stability of xylanolytic enzymes in the broad range of alkaline pH is useful for utilization of the enzymes in industrial process requiring in alkaline conditions. Moreover, the highest production of xylanolytic enzyme was obtained when 0.5% of rice bran was supplied in basal liquid medium. SDS-PAGE analysis revealed a single xylanase band of approximately 28.5 kDa from the culture filtrates.