Optimization of production of xylanases with low cellulases in Fusarium solani by means of a solid state fermentation using statistical experimental design / Optimización de la producción de xilanasas con celulasas bajas en Fusarium solani mediante una fermentación del estado sólido utilizando diseño experimental estadístico

Resumen La demanda de xilanasas fúngicas en los procesos biotecnológicos industriales muestra un claro aumento en todo el mundo, por lo que hay un interés en ajustar las condiciones de producción de xilanasas microbianas. En este estudio se optimizó la capacidad del hongo Fusarium solani para producir xilanasas extracelulares con escasa actividad celulolítica mediante el diseño de Box-Wilson. Se determinaron las mejores condiciones de cultivo para obtener una preparación enzimática cruda con una actividad xilanolítica significativa y poca actividad celulolítica. En la mayoría de los tratamientos, la actividad xilanolítica fue mayor que la actividad celulolítica. Se observó un efecto negativo sobre la producción de endoxilanasas, p-xilosidasasy endocelulasascon el aumento de la concentración dexilano. El aumento del tiempo de incubación afectó adversamente la producción de endocelulasas y p-xilosidasas. De acuerdo con el modelo matemático y las pruebas experimentales, es posible producir endoxilanasas con una actividad endocelulasa mínima aumentando el tiempo de incubación y la concentración de sulfato de amonio. Las condiciones de cultivo óptimas para producir una mayor cantidad de endoxilanasas (10,65 U/mg) y mínima cantidad de endocelulasas fueron 2,5% (p/v) de xilano y 5, 2 y 0,4 g/l de extracto de levadura, sulfato de amonio y urea, respectivamente, con 120 h de incubación.

Resumen La demanda de xilanasas fúngicas en los procesos biotecnológicos industriales muestra un claro aumento en todo el mundo, por lo que hay un interés en ajustar las condicionesde producción de xilanasas microbianas. En este estudio se optimizó la capacidad del hongo Fusarium solani para producir xilanasas extracelulares con escasa actividad celulolítica medi-ante el dise˜no de Box-Wilson. Se determinaron las mejores condiciones de cultivo para obteneruna preparación enzimática cruda con una actividad xilanolítica significativa y poca actividad celulolítica. En la mayoría de los tratamientos, la actividad xilanolítica fue mayor que laactividad celulolítica. Se observó un efecto negativo sobre la producción de endoxilanasas, xylanolytic activity and little cellulolytic activity. In most treatments, the xylanolytic activity was higher than the cellulolytic activity. A negative effect on the production of endoxylanases, p-xylosidases and endocellulases was observed with the increasing of xylan concentration. Increasing the incubation time adversely affected the production of endocellulases and p-xylosidases. According to the mathematical model and experimental tests, it is possible to produce endoxylanases with minimal endocellulase activity increasing incubation time and the concentration of ammonium sulfate. The optimal culture conditions to produce a greater amount of endoxylanases (10.65 U/mg) and low endocellulases from F. solani were: 2.5% (w/v) xylan, 5.0, 2.0 and 0.4g/l, of yeast extract, ammonium sulfate and urea, respectively, with 120 h of incubation.

A Thermotolerant Xylan-Degrading Enzyme Is Produced by Streptomyces malaysiensis AMT-3 Using by-Products From the Food Industry

Abstract This study evaluated the production of endoxylanases by Streptomyces malaysiensis AMT-3 in submerged fermentation using by-products of the food industry at 28ºC. In shake-flasks experiments, the highest endoxylanase activity of 45.8 U.mL-1 was observed within 6 days in a medium containing (w/v) 2.5% wheat bran and 1.2% corn steep liquor. The same culture conditions were used to evaluate the enzyme production in a 2 L stirred tank reactor under different agitation (300, 450 and 600 rev.min-1) and aeration (30 and 60 L.h-1) conditions. The use of 450 rev.min-1 coupled to an aeration of 90 L.h-1 resulted on 81.3 U.mL-1 endoxylanase activity within 5 days. The effect of temperature and pH on endoxylanase activity and stability showed the highest activity at 60 ºC and pH 6.0. Zymography showed the presence of three xylanolytic bands with molecular masses of 690, 180 and 142 kDa. The results showed that the thermotolerant actinobacterial endoxylanase can be produced in high titers using by-product of the food industry.

Agroindustrial biomass for xylanase production by Penicillium chrysogenum: purification, biochemical properties and hydrolysis of hemicelluloses

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.

Statistical optimization of thermo-alkali stable xylanase production from Bacillus tequilensis strain ARMATI

Background: Xylanase from bacteria finds use in prebleaching process and bioconversion of lignocelluloses into feedstocks. The xylanolytic enzyme brings about the hydrolysis of complex biomolecules into simple monomer units. This study aims to optimize the cellulase-free xylanase production and cell biomass of Bacillus tequilensis strain ARMATI using response surface methodology (RSM). Results: Statistical screening of medium constituents and the physical factors affecting xylanase and biomass yield of the isolate were optimized by RSM using central composite design at N = 30, namely 30 experimental runs with 4 independent variables. The central composite design showed 3.7 fold and 1.5 fold increased xylanase production and biomass yield of the isolate respectively compared to 'one factor at a time approach',inthe presence of the basal medium containing birchwood xylan (1.5% w/v) and yeast extract (1% w/v), incubated at 40°C for 24 h. Analysis of variance (ANOVA) revealed high coefficient of determination (R2)of0.9978 and 0.9906 for the respective responses at significant level (p < 0.05). The crude xylanase obtained from the isolate showed stability at high temperature (60°C) and alkaline condition (pH 9) up to 4 h of incubation. Conclusions: The cellulase-free xylanase showed an alkali-tolerant and thermo-stable property with potentially applicable nature at industrial scale. This statistical approach established a major contribution in enzyme production from the isolate by optimizing independent factors and represents a first reference on the enhanced production of thermo-alkali stable cellulase-free xylanase from B. tequilensis.

Production, purification, characterization and over-expression of xylanases from actinomycetes.

Xylanases are a group of depolymerizing enzymes often used for the hydrolysis of xylan (present in hemicellulose) to monomeric sugars and comprise endo-xylanases (EC 3.2.1.8) and β-xylosidases (EC 3.2.1.37). They often act in synergy with other enzymes for complete hydrolysis of hemicellulose. Xylanases find several industrial applications, for example in food and feed industries, paper and pulp industries and more recently have acquired a great role in biomass to biofuels program. Bacteria and fungi can best produce xylanases. Recent developments in rDNA technology have resulted in molecular cloning and expression of xylanases in heterologous and homologous hosts. In view of significance of the actinomycetes for the production of biotechnological products, attempts have been made in recent years to explore them for the production of industrial enzymes, including xylanses, aiming to find the enzyme with novel features. This review provides the state-of-art information and developments on the xylanases from actinomycetes, presenting the production, purification, characterization and over-expression from various actinomycetes cultures.

Improvement of xylanase production in solid state fermentation by alkali-tolerant Aspergillus fumigatus MKU1 using a fractional factorial design.

Optimization of media for the maximum production of xylanase by Aspergillus fumigatus MKUI was carried out using De Meo's fractional factorial design with seven components such as NaNO3, K2HPO4, MgSO4, FeSO4. KCl, peptone and yeast extract. A. fumigatus produced a maximum of 700 U/gds of enzyme after 48 hr of incubation (before optimization). After two steps of optimization, the medium designed favoured a 2.8 fold (1950 U/gds) increase in xylanase production by A. fumigatus. Optimized medium for Aspergillus fumigatus contained (g/l) NaNO3, 15; K2HPO4, 15; MgSO4, 5; FeSO4, 0.009; KCI, 0.5; peptone, 20; and yeast extract, 10.