ABSTRACT
During certain wine fermentation processes, yeasts, and mainly non-Saccharomyces strains, produce and secrete enzymes such as ß-glucosidases, proteases, pectinases, xylanases and amylases. The effects of enzyme activity on the aromatic quality of wines during grape juice fermentation, using different co-inoculation strategies of non-Saccharomyces and Saccharomyces cerevisiae yeasts, were assessed in the current study. Three strains with appropriate enological performance and high enzymatic activities, BSc562 (S. cerevisiae), BDv566 (Debaryomyces vanrijiae) and BCs403 (Candida sake), were assayed in pure and mixed Saccharomyces/non-Saccharomyces cultures. ß-Glucosidase, pectinase, protease, xylanase and amylase activities were quantified during fermentations. The aromatic profile of pure and mixed cultures was determined at the end of each fermentation. In mixed cultures, non-Saccharomyces species were detected until day 4-5 of the fermentation process, and highest populations were observed in MSD2 (10% S. cerevisiae/90% D. vanrijiae) and MSC1 (1% S. cerevisiae/99% C. sake). According to correlation and multivariate analysis, MSD2 presented the highest concentrations of terpenes and higher alcohols which were associated with pectinase, amylase and xylanase activities. On the other hand, MSC1 high levels of ß-glucosidase, proteolytic and xylanolytic activities were correlated to esters and fatty acids. Our study contributes to a better understanding of the effect of enzymatic activities by yeasts on compound transformations that occur during wine fermentation.
Subject(s)
Fermentation , Fungi/enzymology , Saccharomyces/enzymology , Volatile Organic Compounds , Wine , Biomass , Carbohydrate Metabolism , Gas Chromatography-Mass Spectrometry , Hydrolysis , Solid Phase Microextraction , Vitis , Volatile Organic Compounds/analysis , Wine/analysisABSTRACT
Saccharomyces and non-Saccharomyces yeasts release enzymes that are able to transform neutral compounds of grape berries into active aromatic compounds, a process that enhances the sensory attributes of wines. So far, there exists only little information about enzymatic activity in mixed cultures of Saccharomyces and non-Saccharomyces during grape must fermentations. The aim of the present work was to determine the ability of yeasts to produce extracellular enzymes of enological relevance (ß-glucosidases, pectinases, proteases, amylases or xylanases) in pure and mixed Saccharomyces/non-Saccharomyces cultures during fermentation. Pure and mixed cultures of Saccharomyces cerevisiae BSc562, Hanseniaspora vinae BHv438 and Torulaspora delbrueckii BTd259 were assayed: 1% S. cerevisiae/99% H. vinae, 10% S. cerevisiae/90% H. vinae, 1% S. cerevisiae/99% T. delbrueckii and 10% S. cerevisiae/90% T. delbrueckii. Microvinifications were carried out with fresh must without pressing from Vitis vinifera L. c.v. Pedro Jiménez, an autochthonous variety from Argentina. Non-Saccharomyces species survived during 15-18days (BTd259) or until the end of the fermentation (BHv438) and influenced enzymatic profiles of mixed cultures. The results suggest that high concentrations of sugars did not affect enzymatic activity. ß-Glucosidase and pectinase activities seemed to be adversely affected by an increase in ethanol: activity diminished with increasing fermentation time. Throughout the fermentation, Saccharomyces and non-Saccharomyces isolates assayed produced a broad range of enzymes of enological interest that catalyze hydrolysis of polymers present in grape juice. Vinifications carried out by a pure or mixed culture of BTd259 (99% of T. delbrueckii) showed the highest production of all enzymes assayed except for ß-glucosidase. In mixed cultures, S. cerevisiae outgrew H. vinae, and T. delbrueckii was only detected until halfway the fermentation process. Nevertheless, their secreted enzymes could be detected throughout the fermentation process. Our results may contribute to a better understanding of the microbial interactions and the influence of some enzymes on vinification environments.
Subject(s)
Enzymes/metabolism , Fermentation , Saccharomyces/enzymology , Wine/microbiology , Yeasts/enzymology , Amylose , Argentina , Biomass , Cellulases/metabolism , Ethanol/metabolism , Hydrogen-Ion Concentration , Pectins/metabolism , Time Factors , Wine/analysis , Xylose/metabolismABSTRACT
Las células inmovilizadas tienen aplicación potencial en la producción de biocombustibles posibilitando la reutilización de biomasa, el empleo de diversas configuraciones de reactores y sistemas de cultivo, el manejo de altas densidades celulares alcanzando altas productividades volumétricas, y la simplificación de operaciones de procesamiento de salida. El objetivo del presente estudio fue evaluar la influencia del diámetro de las perlas y la densidad celular en la producción de etanol con Saccharomyces uvarum inmovilizada en alginato al 2% (p/v). Para ello se evaluaron tres diámetros de perlas de 2, 2,5 y 3 mm. Las células inmovilizadas fueron cultivadas en medio con 12% (p/v) de glucosa en biorreactores de columna sin agitación a 28 ºC, y se operaron cuatro lotes consecutivos de 48 horas cada uno. En cada lote se cuantificó el consumo de glucosa y se determinó la cantidad de etanol producido. Los rendimientos máximos de etanol para las esferas de 2, 2,5 y 3 mm de diámetro fueron 81, 83 y 97% del rendimiento teórico. La máxima productividad volumétrica de etanol fue 1,2 g/L-1/h-1 con un consumo de glucosa de 99,8% al término del lote, correspondiente a las columnas con perlas de 3 mm y con una producción de 0,017 g de etanol por esfera. La producción de etanol acumulada en cada sistema fue 178, 189 y 200 g/L-1 para 2, 2,5 y 3 mm respectivamente, encontrándose una relación directa con el diámetro de perla e inversa respecto a la densidad celular. Los rendimientos de etanol obtenidos son superiores a los reportados para la misma especie.
Immobilized cells have a potential use in biofuel production. They also allow re-using biomass, using diverse reactor configurations and culture systems, handling high cell densities to obtain high volumetric productivities and to simplify the downstream processing. The purpose of this work was to evaluate the influence of bead diameter and cell density on ethanol production using immobilized Saccharomyces uvarum in 2% (w/v) alginate. For that, three bead diameters (2, 2.5 and 3 mm) were evaluated. Immobilized cells were cultured on a 12% (w/v) glucose medium in column bioreactors without agitation at 28 °C for four 48 hrepeated batches. For each batch, both glucose consumption and ethanol produced were measured. Maximum yields for 2, 2.5 and 3 mm bead diameters were 81, 83 and 97% of theoretical yield. Maximum volumetric productivity of ethanol was 1.2 g/L-1/h-1 with 99.8% glucose consumption at the end of the batch, corresponding to the 3 mm bead diameter and the ethanol production per bead was 0.017 g. Accumulated ethanol production for each system was 178, 189 and 200 g/L-1 for 2, 2.5 y 3 mm bead diameter, respectively, being this directly related to bead diameter and inversely related to cell density. Ethanol yields were higher than those reported for the same species.
Subject(s)
Ethanol/isolation & purification , Ethanol/analysis , Ethanol/chemical synthesis , Saccharomyces/isolation & purification , Saccharomyces/enzymology , Saccharomyces/chemistryABSTRACT
The search of a microorganism with the ability to produce the enzyme beta-galactosidase was undertaken according with the requirements of the market, in economical, technological and sanitary terms. The process consisted of recovery and use of the effluent from milk and cheese used to feed pigs, producing at the same time different types of contamination; once investigated and adjusted the technological variables to produce the enzyme, and selected the most convenient microorganism for such purpose the acting upon the extraction, conservation and purification of the product were adjusted. Comparative results of conversion were obtained with different test, at laboratory scale and industrial plants, in similar conditions to those obtained with importation products.
Subject(s)
Fungal Proteins/isolation & purification , Galactosidases/isolation & purification , Microbiological Techniques , Milk , Saccharomyces/enzymology , beta-Galactosidase/isolation & purification , Animals , Cattle , Culture Media , Fermentation , Fungal Proteins/biosynthesis , Saccharomyces/growth & development , beta-Galactosidase/biosynthesisSubject(s)
DNA , Photochemistry , Saccharomyces/enzymology , Ultraviolet Rays , Chemical Precipitation , Chromatography, Gel , MethodsABSTRACT
Previous findings in the literature that rhein inhibits DPNH-linked mitochondrial oxidations by acting in the DPNH dehydrogenase region of the respiratory chain have been confirmed and extended. In the micromolar range rhein inhibits DPNH oxidase and DPNH-ferricyanide activities and the energy-linked reduction of DPNH by succinate in membrane preparations from heart, as wellas the DPNH dehydrogenase and transhydrogenase activities of the soluble, purified enzyme. The inhibition of the activities of the soluble enzyme are purely competitive with respect to substrate. These facts localize the primary inhibition site of rhein between substrate and FMN. In heart ETP a second noncompetitive inhibition is also present but is detectable only at very low (<10æM) rhein concentrations. Rhein also inhibits DPNH dehydrogenase in Candida utilis mitochondria and the purified enzyme from liver. On conversion of the heart enzyme to the low molecule weight DPNH-cytochrome reductase the typical effect of rhein disappears and is replaced by a slight stimulation or inhibition, depending on the electron acceptor used, showing that the substrate binding site is modified in this form of the enzyme. In beef liver mitochondria DPNH oxidation may appear insensitive to rhein, probably because of the strong binding of rhein to other proteins. To a lesser extent unspecific binding of rhein and resultant interference with the inhibition of DPNH dehydrogenase is also shown by BSA and by proteins in heart ETP. Rhein also inhibits transhydrogenations in mitochondria and at higher concentrations lactate and malate dehydrogenases but has no effect on sccinate, alcohol (liver nad yeast), and glucose-6-p dehydrogenases or on Neuospora DPN-ase, glucose-6-phosphatase, and amine oxidase. (SUMMARY)