α-Acetolactate decarboxylase immobilized in chitosan: A highly stable biocatalyst to prevent off-flavor in beer.

In this work, we studied the covalent immobilization of α-acetolactate decarboxylase (ALDC) on glutaraldehyde activated chitosan beads for application in beers to prevent off-flavor. The immobilized preparation was characterized regarding yield, efficiency, activity recovery, thermal and pH stabilities, and operational stability in beer. The concentration of activating agent was evaluated and at the best condition an immobilization yield of 84% and activity recovery of 9.1% were verified. Optimal pH was 6.0 for free and immobilized enzymes, however, the immobilized enzyme showed higher relative activity at the tested pH, with emphasis on the pH range from 5.0 to 6.5. Besides, immobilized enzyme showed stabilization factor of almost sevenfold at 60°C compared to free form. The immobilized biocatalyst was tested in repeated batches in beer for α-acetolactate conversion to acetoin, and after 12 cycles the enzyme presented 80% of its initial activity. To date, this is the most stable immobilized preparation of ALDC reported.

Development of a biocomposite based on alginate/gelatin crosslinked with genipin for ß-galactosidase immobilization: Performance and characteristics.

In this work, we studied the development of a biocomposite formulated with alginate and gelatin, crosslinked with genipin for application as support for ß-galactosidase immobilization. Also, the biocomposites with the immobilized enzyme were characterized by thermal analyses and SAXS (size, density, and interconnectivity of alginate rods) for a detailed analysis of the microstructure, as well as the thermal and operational stabilities of the enzyme. The structural modifications of the biocomposite determined by SAXS demonstrate that the addition of both genipin and enzyme produced a significant reduction in size and density of the Ca(II)-alginate rods. Immobilized ß-galactosidase could be stored for 175 days under refrigeration maintaining 80% of its initial activity. Moreover, 90% of its relative activity was kept after 11 reuses in a batch process of lactose hydrolysis. Thus, the biocomposite proved to be effective as support for enzyme immobilization.

High performance biocatalyst based on ß-d-galactosidase immobilized on mesoporous silica/titania/chitosan material.

A new support for the immobilization of ß-d-galactosidase from Kluyveromyces lactis was developed, consisting of mesoporous silica/titania with a chitosan coating. This support presents a high available surface area and adequate pore size for optimizing the immobilization efficiency of the enzyme and, furthermore, maintaining its activity. The obtained supported biocatalyst was applied in enzyme hydrolytic activity tests with o-NPG, showing high activity 1223 Ug-1, excellent efficiency (74%), and activity recovery (54%). Tests of lactose hydrolysis in a continuous flow reactor showed that during 14 days operation, the biocatalyst maintained full enzymatic activity. In a batch system, after 15 cycles, it retained approximately 90% of its initial catalytic activity and attained full conversion of the lactose 100% (±12%). Additionally, with the use of the mesoporous silica/titania support, the biocatalyst presented no deformation and fragmentation, in both systems, demonstrating high operational stability and appropriate properties for applications in food manufacturing.

Designing a Support for Lipase Immobilization Based On Magnetic, Hydrophobic, and Mesoporous Silica.

A mesoporous, magnetic, and hydrophobic material was designed step by step to act as a support for lipase immobilization. Its pore size (8.0 nm) is compatible with the size of lipase from Thermomyces lanuginosus (TLL), and its hydrophobic surface (contact angle of a water drop = 125°) was planned to interact with lipase on its interfacially activated form (open conformation). The presence of magnetite particles provides magnetic retrieval of the material and enables recyclability of the biocatalysts. Regarding immobilization parameters, the hydrophobic support was tested in comparison to the unmodified hydrophilic support in phosphate buffer solution (50 mmol L-1, pH 7.5) at 25 °C. Hydrophobicity was found to be critical for the amount of immobilized TLL (immobilization yield of 97% versus 36% for the hydrophilic support), whereas the hydrophilic support favors the native conformational state and substrate access to the enzyme's catalytic site (specific activity of 5.7 versus 4.7 U g-1 for the hydrophobic support, even when it has higher TLL content). Therefore, the hydrophobic support immobilizes higher amounts of TLL and the hydrophilic support keeps the enzyme hyperactivated. Last, due to the stronger interactions of TLL with hydrophobic surfaces, the hydrophobic support offers better preservation of enzyme activity in repeated cycles (76% of activity retained after three cycles versus 50% for the hydrophilic support).

Highly stable novel silica/chitosan support for ß-galactosidase immobilization for application in dairy technology.

ß-d-Galactosidase is an important enzyme in the dairy industry, and the enzyme from the yeast Kluyveromyces lactis is most widely used. Here, we report immobilization of the enzyme on a silica/chitosan composite support, devised to have 10% and 20% chitosan (SiQT10 and SiQT20, respectively). Morphological and textural characterizations showed that chitosan is dispersed in micrometric regions in silica. For comparison, a silica organofunctionalized with 3-aminopropyltrimethoxysilane (SiO2aptms) was prepared. Performance of the biocatalysts was tested for lactose hydrolysis, and the enzyme immobilized in SiQT10 and SiQT20 composites showed higher efficiency (62% and 47%, respectively) compared with the enzyme in SiO2aptms. Operational stability in this system was evaluated for the first time. After 200 h of continuous use in a fixed-bed reactor, SiQT10 remained with approximately 90% activity. Thus, in addition to demonstrating compatibility for food processing, these results align the enzyme stabilization properties of chitosan with the mechanical resistance of silica.

Kinetics and Thermodynamics of Thermal Inactivation of β-Galactosidase from Aspergillus oryzae

ABSTRACT For optimization of biochemical processes in food and pharmaceutical industries, the evaluation of enzyme inactivation kinetic models is necessary to allow their adequate use. Kinetic studies of thermal inactivation of β-galactosidase from Aspergillus oryzae were conducted in order to critically evaluate mathematical equations presented in the literature. Statistical analysis showed that Weibull model presented the best adequacy to residual enzymatic activity data through the processing time and its kinetic parameters as a function of the temperature, in the range of 58-66 ºC. The investigation suggests the existence of a non-sensitive heat fraction on the enzyme structure, which is relatively stable up to temperatures close to 59 ºC. Thermodynamic parameters were evaluated and showed that such β-galactosidase presents activation energy of 277 kJ mol-1 and that the enzyme inactivation is due to molecular structural changes. Results shown that the enzyme is quite stable for biotechnological applications.

Effects of immobilization, pH and reaction time in the modulation of α-, ß- or γ-cyclodextrins production by cyclodextrin glycosyltransferase: Batch and continuous process.

This study reports the immobilization of a ß-CGTase on glutaraldehyde pre-activated silica and its use to production of cyclodextrins in batch and continuous reactions. We were able to modulate the cyclodextrin production (α-, ß- and γ-CD) by immobilization and changing the reaction conditions. In batch reactions, the immobilized enzyme reached to maximum productions of 4.9mgmL-1 of α-CD, 3.6mgmL-1 of ß-CD and 3.5mgmL-1 of γ-CD at different conditions of temperature, pH and reaction time. In continuous reactor, varying the residence time and pH it was possible to produce at pH 4.0 and 141min of residence time preferentially γ-CD (0.75 and 3.36mgmL-1 of α- and γ-CD, respectively), or at pH 8.0 and 4.81min α- and ß-CDs (3.44 and 3.51mgmL-1).

Immobilization of Thermomyces lanuginosus lipase by different techniques on Immobead 150 support: characterization and applications.

Thermomyces lanuginosus lipase (TLL) was immobilized on native and modified Immobead 150, with epoxy groups removed by hydrolysis and oxidized to add aldehyde on its surface. Immobilizations on both supports were performed by adsorption, adsorption and cross-linking, covalent attachment, multipoint covalent attachment, and, for the modified support, multipoint covalent attachment using ethylenediamine. Biocatalysts were evaluated for thermal and solvent stabilities, and the best biocatalyst was also tested after incubation in ionic liquids and used in the synthesis of butyl butyrate and isoamyl butyrate. Multipoint covalent immobilized TLL on the native Immobead 150 (Emulti) showed a half-life of 5.32 h at 70 °C, being approximately 30 times more stable than its soluble form; it showed high stability in acetone, hexane, and isooctane. Its enzymatic activity was up to 40% when incubated in ionic liquids. Ester synthesis produced yields of esterification above 60% in 24 h. Of all immobilization protocols, the Emulti performed best concerning the thermal, solvent, and ionic liquids stabilities. Emulti was successfully applied to the synthesis of butyl butyrate and isoamyl butyrate, which are very important products for the food and beverage industries.

Continuous production of ß-cyclodextrin from starch by highly stable cyclodextrin glycosyltransferase immobilized on chitosan.

Cyclodextrin glycosyltransferase (CGTase) from Thermoanaerobacter sp. was covalently immobilized on glutaraldehyde-activated chitosan spheres and used in a packed bed reactor to investigate the continuous production of ß-cyclodextrin (ß-CD). The optimum temperatures were 75 °C and 85 °C at pH 6.0, respectively for free and immobilized CGTase, and the optimum pH (5.0) was the same for both at 60 °C. In the reactor, the effects of flow rate and substrate concentration in the ß-CD production were evaluated. The optimum substrate concentration was 4% (w/v), maximizing the ß-CD production (1.32 g/L) in a flow rate of 3 mL/min. In addition, the biocatalyst had good operational stability at 60 °C, maintaining 61% of its initial activity after 100 cycles of batch and 100% after 100 h of continuous use. These results suggest the possibility of using this immobilized biocatalyst in continuous production of CDs.

Diferenciação analítica de vinhos-base para espumantes de duas regiões vitícolas do Rio Grande do Sul / Analytical differentiation of the base wines for sparkling from two viticultural regions of Rio Grande do Sul

Os objetivos deste trabalho foram caracterizar e diferenciar vinhos-base para espumante (cultivares 'Chardonnay' e 'Pinot Noir') provenientes da Serra do Nordeste e Serra do Sudeste do Rio Grande do Sul por meio de parâmetros físico-químicos e elementos minerais combinados com técnicas de análise multivariada. Foram analisados nove parâmetros físico-químicos (densidade, grau alcoólico, extrato seco total, extrato seco reduzido, acidez total, acidez volátil, acidez fixa, pH e açúcares redutores), por espectrofotometria no infravermelho, e 11 elementos minerais (Al, B, Ba, Ca, Cu, Fe, K, Mg, Mn, Na e Sr), por espectrometria de emissão ótica com plasma indutivamente acoplado (ICP-OES). Os elementos encontrados em maiores concentrações foram K, Mg e Ca e, em menores concentrações, Ba, Fe, Sr e Al. A Análise de Componentes Principais (ACP) mostrou que há uma tendência natural de separação entre os vinhos-base da Serra do Nordeste e Serra do Sudeste. Por meio da Análise Discriminante (AD) foram obtidos cinco descritores (Mg, Ca, Mn, pH e grau alcoólico) para os vinhos-base da cultivar 'Chardonnay' e seis descritores (B, Mn, Fe, Na, pH e acidez volátil) para a cultivar 'Pinot Noir', com capacidade de classificar as amostras de vinhos-base de acordo com a origem geográfica. Os elementos Mn e Mg parecem ser aqueles com maior capacidade de discriminação entre os vinhos-base da Serra do Nordeste e Serra do Sudeste.

This research describes the base wines characterization and differentiation (cultivars Chardonnay and Pinot Noir) from Serra do Nordeste and Serra do Sudeste of Rio Grande do Sul by physicochemical parameters and mineral elements followed by multivariate statistical analysis. Nine physicochemical parameters (density, alcoholic content, total dry extract, reduced dry extract, total acidity, volatile acidity, fix acidity, pH and reducing sugars) were analyzed by infrared spectrofotometry and eleven mineral elements (Al, B, Ba, Ca, Cu, Fe, K, Mg, Mn, Na and Sr) by inductively coupled plasma optical emission spectrometry (ICP-OES). Elements K, Mg, and Ca were founded in higher concentrations and Ba, Fe, Sr, and Al were founded in lower ones. Principal Component Analysis (PCA) showed a natural separation tendency between wines from Serra do Nordeste and Serra do Sudeste. Five descriptors were obtained by Discriminant Analysis (DA) for base wines from cultivar Chardonnay (Mg, Ca, Mn, pH and alcoholic content) and six descriptors for base wines from cultivar Pinot Noir (B, Mn, Fe, Na, pH and volatile acidity). These descriptors were capable to classify samples of base wines according to geographical origin. Mn and Mg elements seem to be the elements with higher discrimination capacity between base wines from northwest Serra and Southeast Serra.

Production of ethanol from soybean hull hydrolysate by osmotolerant Candida guilliermondii NRRL Y-2075.

In this research, we studied the use of soybean hull hydrolysate (SHH) as a substrate for ethanol and xylitol production using an osmotolerant strain of Candida guilliermondii. The best acid hydrolysis of soybean hull achieved a recovery of 85 and 62% of xylose and mannose, respectively. Among detoxification treatments, activated charcoal 10% (w/v) showed the best results. Kinetic parameters obtained from the cultivation on four-fold concentrated SHH have shown that the osmotic pressure of this medium is higher than that supported by most osmophilic yeasts, revealing the osmotolerant characteristic of C. guilliermondii NRRL Y-2075. When cultivations were carried out on two times concentrated SHH, we obtained high yields of ethanol production, showing the prospect of SHH as a candidate for this biofuel production. Although xylose was present in high concentrations, no xylitol was produced, probably due to the presence of furfural acting as external electron acceptor or some varying cofactor preference of xylose reductase in this yeast strain.

Production of cyclodextrin glycosyltransferase by alkaliphilic Bacillus circulans in submerged and solid-state cultivation.

Cyclodextrin glycosyltransferase (CGTase; E.C. 2.4.1.19) is an industrially important enzyme, which is used to produce cyclodextrins (CDs). In this research, we report the use of experimental factorial design to find the best conditions of pH and temperature for CGTase production by Bacillus circulans var. alkalophilus. The optimized calculated values for the tested variables were, respectively, pH 9.7 and temperature 36 degrees C, with a CGTase activity of 615 U mL(-1). The CGTase production was further studied with the optimized process parameters on submerged cultivations (SC) and solid-state cultivations (SSC) using soybean industrial fibrous residue (SIFR). The maximum CGTase activity obtained on SC was 1,155 U mL(-1) under aerobic conditions. Cell growth and CGTase synthesis in SSC using SIFR as substrate was excellent, with CGTase activity of 32,776 U g ((SIFR))(-1). These results strongly support the use of SIFR for CGTase production since it is a non-expensive residue.

Statistical optimization of thermo-tolerant xylanase activity from Amazon isolated Bacillus circulans on solid-state cultivation.

A 2(2) factorial design was performed to find the best conditions of pH and temperature for xylanolytic activity of Bacillus circulans BL53 isolated from the Amazon environment. Solid-state cultivation was carried out on an inexpensive, abundant agro-industrial soybean residue. The central composite design (CCD) used for the analysis of treatment combinations showed that a second-order polynomial regression model was in good agreement with experimental results, with R(2) = 0.9369 (P < 0.05). The maximum activity was obtained at a high temperature (80 degrees C) and over a large pH range (4.0-7.0). Enzymatic activity was maintained in heated extracts up to 50 degrees C, suggesting that the xylanases of B. circulans BL53 are thermo-tolerant biocatalysts, being of interest for industrial processes. The crude enzyme extract hydrolyzed rice straw, sugar cane bagasse and soybean fiber and its activity was stimulated by Co(2+), Fe(3+), and beta-mercaptoethanol but inhibited by Mn(2+), Cu(2+), Ca(2+), Zn(2+), Ba(2+), Mg(2+) and by EDTA.