ß-glucosidases from Saccharomyces cerevisiae: production, protein precipitation, characterization, and application in the enzymatic hydrolysis of delignified sugarcane bagasse.

ß-glucosidase is an essential enzyme for the enzymatic hydrolysis of lignocellulosic biomass, as it catalyzes the final stage of cellulose breakdown, releasing glucose. This paper aims to produce ß-glucosidase from Saccharomyces cerevisiae and evaluate the enzymatic degradation of delignified sugarcane bagasse. S. cerevisiae was grown in yeast peptone dextrose medium. Partial purification of the enzyme was achieved through precipitating proteins with ethanol, and the optimal activity was measured by optimizing pH and temperature. The effects of ions, glucose tolerance, and heat treatment were evaluated. Delignified sugarcane bagasse was hydrolyzed by the enzyme. ß-glucosidase showed a specific activity of 14.0712 ± 0.0207 U mg-1. Partial purification showed 1.22-fold purification. The optimum pH and temperature were 6.24 and 54 °C, respectively. ß-glucosidase showed tolerance to glucose, with a relative activity of 71.27 ± 0.16%. Thermostability showed a relative activity of 58.84 ± 0.91% at 90 °C. The hydrolysis of delignified sugarcane bagasse showed a conversion rate of 87.97 ± 0.10% in the presence of Zn2+, an ion that promoted the highest increase in enzymatic activity. S. cerevisiae produced an extracellular ß-glucosidase with good stability at pH and temperatures conventionally applied in the hydrolysis of lignocellulosic biomass, showing viability for industrial application.

Catalytic and thermodynamic properties of ß-glucosidases produced by Lichtheimia corymbifera and Byssochlamys spectabilis.

The objective of the present study was to optimize parameters for the cultivation of Lichtheimia corymbifera (mesophilic) and Byssochlamys spectabilis (thermophilic) for the production of ß-glucosidases and to compare the catalytic and thermodynamic properties of the partially purified enzymes. The maximum amount of ß-glucosidase produced by L. corymbifera was 39 U/g dry substrate (or 3.9 U/mL), and that by B. spectabilis was 77 U/g (or 7.7 U/mL). The optimum pH and temperature were 4.5 and 55 °C and 4.0 and 50 °C for the enzyme from L. corymbifera and B. spectabilis, respectively. ß-Glucosidase produced by L. corymbifera was stable at pH 4.0-7.5, whereas the enzyme from B. spectabilis was stable at pH 4.0-6.0. Regarding the thermostability, ß-glucosidase produced by B. spectabilis remained stable for 1 h at 50 °C, and that from L. corymbifera was active for 1 h at 45 °C. Determination of thermodynamic parameters confirmed the greater thermostability of the enzyme produced by the thermophilic fungus B. spectabilis, which showed higher values of ΔH, activation energy for denaturation (Ea), and half-life t(1/2). The enzymes were stable in the presence of ethanol and were competitively inhibited by glucose. These characteristics contribute to their use in the simultaneous saccharification and fermentation of vegetable biomass.

Production and partial purification of antifungal chitinase from Bacillus cereus VITSD3

The current work was designed to isolate and characterize chitin degrading bacteria. Among the 55 bacterial colonies isolated from 7 different soil samples, 4 isolates were capable of degrading chitinase, among which one strain VITSD3 was found to be potent. Based on the morphological, biochemical and molecular characterization of VITSD3 the isolate was confirmed as Bacillus cereus (Genbank accession number: KC961638), designated as Bacillus cereus VITSD3. The crude enzyme had a total activity of 220 U, precipitated with 44.8 U and 22.5 U for dialysed sample. The hydrolysed product NAG (N-Acetyl Glucosamine) from chitin was analysed by high-pressure liquid chromatography (HPLC).The molecular weight of the chitinase was determined using SDS PAGE and found to be 55 kDa. The partially purified chitinase produced from Bacillus cereus VITSD3 showed antifungal activity against Aspergillus fumigatus (18 mm), Aspergillus niger (6 mm) and Aspergillus flavus (15 mm). Hence the investigation suggests a potential benefit of partially purified chitinase extracted from Bacillus cereus VITSD3 which will serve as an excellent antifungal potential with therapeutic use.

O presente trabalho atual foi delineado para isolar e caracterizar bactérias degradadoras de quitina. Entre as 55 colónias bacterianas isoladas a partir de 7 amostras de solo diferentes, quatro isolados foram capazes de degradar quitinase, entre os quais uma estirpe, VITSD3, mostrou-se potente. Com base na caracterização morfológica, bioquímica e molecular de VIT D3 a soluto foi confirmada como Bacillus cereus (número de acesso Genbank: KC961638), designada como Bacillus cereus VITSD3. A enzima bruta tinha uma actividade total de 220 L, precipitou-se com 44,8 L e 22,5 L de amostra dialisada. O produto hidrolisado NAG (N-acetil-glucosamina) a partir de quitina foi analisado por cromatografia líquida de alta pressão (HPLC) .O peso molecular da quitinase foi determinado, utilizando-se SDS-PAGE e verificou-se ser 55 kDa. A quitinase parcialmente purificada produzida a partir de Bacillus cereus VITSD3 mostrou actividade antifúngica contra Aspergillus fumigatus (18 mm), Aspergillus niger (6 mm) e Aspergillus flavus (15 mm). Por isso, a investigação sugere um potencial benefício de quitinase parcialmente purificada extraída de Bacillus cereus VITSD3 o que poderá servir como um excelente potencial antifúngico para uso terapêutico.

Obtaining partial purified xylose reductase from Candida guilliermondii / Obtenção de xilose redutase de Candida guilliermondii parcialmente purificada

The enzymatic bioconversion of xylose into xylitol by xylose reductase (XR) is an alternative for chemical and microbiological processes. The partial purified XR was obtained by using the following three procedures: an agarose column, a membrane reactor or an Amicon Ultra-15 50K Centrifugal Filter device at yields of 40 percent, 7 percent and 67 percent, respectively.

A bioconversão enzimática da xilose em xilitol pela xilose redutase (XR) é uma alternativa para as vias química e microbiológica. Avaliouse a purificação parcial da XR, utilizando os três seguintes procedimentos: uma coluna de agarose, um reator com membrana ou tubos de ultracentrifugação Amicon Ultra-15 50K, com rendimento de 40 por cento, 7 por cento ou 67 por cento, respectivamente.

Obtaining partial purified xylose reductase from Candida guilliermondii.

The enzymatic bioconversion of xylose into xylitol by xylose reductase (XR) is an alternative for chemical and microbiological processes. The partial purified XR was obtained by using the following three procedures: an agarose column, a membrane reactor or an Amicon Ultra-15 50K Centrifugal Filter device at yields of 40%, 7% and 67%, respectively.

Obtaining partial purified xylose reductase from Candida guilliermondii

The enzymatic bioconversion of xylose into xylitol by xylose reductase (XR) is an alternative for chemical and microbiological processes. The partial purified XR was obtained by using the following three procedures: an agarose column, a membrane reactor or an Amicon Ultra-15 50K Centrifugal Filter device at yields of 40%, 7% and 67%, respectively.

A bioconversão enzimática da xilose em xilitol pela xilose redutase (XR) é uma alternativa para as vias química e microbiológica. Avaliouse a purificação parcial da XR, utilizando os três seguintes procedimentos: uma coluna de agarose, um reator com membrana ou tubos de ultracentrifugação Amicon Ultra-15 50K, com rendimento de 40%, 7% ou 67%, respectivamente.