Analysis of volatile compounds production kinetics: A study of the impact of nitrogen addition and temperature during alcoholic fermentation.

Among the different compounds present in the must, nitrogen is an essential nutrient for the management of fermentation kinetics, also playing a major role in the synthesis of fermentative aromas. Fermentation temperature is yet another variable that affects fermentation duration and the production of fermentative aromas in wine. The main objective of this study was thus to evaluate the combined effects of nitrogen addition-at the start of the fermentation process or during the stationary phase-at different fermentation temperatures on both fermentation kinetics and aroma synthesis kinetics. To study the impact of these three parameters simultaneously, we used an innovative transdisciplinary approach associating an online GC-MS system with an original modeling approach: a Box-Behnken experimental design combined with response surface modeling and GAM modeling. Our results indicated that all three factors studied had significant effects on fermentation and aroma production kinetics. These parameters did not impact in the same way the different families of volatile compounds. At first, obtained data showed that reduction of ester accumulation in the liquid phase at high temperature was mainly due to important losses by evaporation but also to modifications of yeast metabolic capabilities to synthetize these compounds. In a noticeable way, optimal temperature changed for liquid accumulation of the two classes of esters-23°C for acetate ester and 18°C for ethyl esters-because biological impact of temperature was different for the two chemical families. Moreover, the study of these three factors simultaneously allowed us to show that propanol is not only a marker of the presence of assimilable nitrogen in the medium but above all a marker of cellular activity. Finally, this work enabled us to gain a deeper understanding of yeast metabolism regulation. It also underlines the possibility to refine the organoleptic profile of a wine by targeting the ideal combination of fermentation temperature with initial and added nitrogen concentrations. Such observation was particularly true for isoamyl acetate for which interactions between the three factors were very strong.

Comprehensive study of the dynamic interaction between SO2 and acetaldehyde during alcoholic fermentation.

In this work, we focused on the effect of the initial content of SO2 in synthetic grape juice on yeast metabolism linked to the production of acetaldehyde. Lengthening of the lag phase duration was observed with an increase in the initial SO2 content. Nevertheless, an interesting finding was a threshold value of an initial SO2 content of 30 mg L-1 in the juice led to equilibrium between intracellular SO2 diffusion and SO2 production from the sulfate pool by yeast. The ratios of free and bound acetaldehydes were measured during fermentation, and the maximum accumulation of free acetaldehyde was observed when SO2 concentration equilibrium between diffusion and production was reached in the fermenting juice. Moreover, it was observed that SO2 addition resulted in significant changes in the synthesis of aroma compounds. Production of volatile molecules related to sulfur metabolism (methionol) was changed. But, more surprisingly, synthesis of some volatile carbon compounds (diacetyl, isoamyl alcohol, isobutyl alcohol, phenyl ethanol and their corresponding esters) was also altered because of major disruptions in the NADPH/NADP+ redox equilibrium. Finally, we demonstrated that acetaldehyde bound to SO2 could not be metabolized by the yeast during the time course of fermentation and that only free acetaldehyde could impact metabolism.

Comprehensive Study of the Evolution of the Gas-Liquid Partitioning of Acetaldehyde during Wine Alcoholic Fermentation.

Determining the gas-liquid partitioning ( Ki) of acetaldehyde during alcoholic fermentation is an important step in the optimization of fermentation control with the aim of minimizing the accumulation of this compound, which is responsible for the undesired attributes of green apples and fresh-cut grass in wines. In this work, the effects of the main fermentation parameters on the Ki of acetaldehyde were assessed. Ki values were found to be dependent on the temperature and composition of the medium. A nonlinear correlation between the evolution of the Ki and fermentation progress was observed, attributable to the strong retention effect of ethanol at low concentrations, and it was demonstrated that the partitioning of this specific molecule was not influenced by the CO2 production rate. A model was developed that quantifies the Ki of acetaldehyde with a very accurate prediction, as the difference between the observed and predicted values did not exceed 9%.

Pilot-scale evaluation the enological traits of a novel, aromatic wine yeast strain obtained by adaptive evolution.

In the competitive context of the wine market, there is a growing interest for novel wine yeast strains that have an overall good fermentation capacity and that contribute favorably to the organoleptic quality of wine. Using an adaptive evolution strategy based on growth on gluconate as sole carbon source, we recently obtained wine yeasts with improved characteristics in laboratory-scale fermentations. The characteristics included enhanced fermentation rate, decreased formation of acetate and greater production of fermentative aroma. We report an evaluation of the potential value of the evolved strain ECA5™ for winemaking, by comparing its fermentation performance and metabolite production to those of the parental strain in pilot-scale fermentation trials, with various grape cultivars and winemaking conditions. We show that the evolved strain has outstanding attributes relative to the parental wine yeast strain, and in particular the production of less volatile acidity and greater production of desirable volatile esters, important for the fruity/flowery character of wines. This study highlights the potential of evolutionary engineering for the generation of strains with a broad range of novel properties, appropriate for rapid application in the wine industry.

A comparison of laboratory and pilot-scale fermentations in winemaking conditions.

We investigated the influence of the fermenter size on alcoholic fermentation. Experiments were carried out at pilot scale, in 100-L fermenters, and at laboratory scale, in stirred and static 1-L fermenters. Two musts, Grenache blanc and Sauvignon, were fermented with and without the addition of solid particles from grape musts. Highly clarified must fermentation kinetics was strongly affected by the scale of the experiment, with slower fermentation occurring in the 100-L fermenter. Alcohol, ester, and thiol synthesis in clarified sauvignon must fermentation was also strongly correlated with the fermentation scale. Addition of solid particles from grape tended to reduce the effects on kinetics associated with increasing the scale of the fermentation, by increasing the maximum rate of CO(2) production, and by shortening the duration of fermentation. The addition of such particles also decreased the effects of scaling up the fermentation on the concentration of some volatile compounds, i.e., isoamyl acetate, ethyl octanoate, but did not decrease this effect for other compounds, such as isobutyl acetate, isobutanol, and 3-mercaptohexanol.

Impact of oxygen addition during enological fermentation on sterol contents in yeast lees and their reactivity towards oxygen.

During enological fermentations, superfluous oxygen consumption by yeast cells is observed. The superfluous oxygen consumed by the yeast cells is mainly related to the operation of non-respiratory oxygen consumption pathways resulting in an overall decrease in the total sterol fraction in yeast. On the other hand, yeast lees remaining at the end of alcoholic fermentations exhibit specific oxygen utilization rates ranging from 1 to 4 micromol O2 h- 10(-10) cells from the second to the thirteenth month of wine aging. This oxygen consumption capacity of yeast lees was independent of residual cell viability. In this study, we investigated the potential relationship between the oxygen added to commercial yeast strains during enological fermentation and the capacity of the corresponding yeast lees to interact with oxygen. Additions of low (7 mg l(-)) and excess (37 mg l(-1)) amounts of oxygen at the end of the cell growth phase were compared in terms of repercussions on the oxygen consumption activity of the corresponding yeast lees. As expected, the superfluous oxygen consumption by yeast cells during fermentation had a positive influence on the fermentation kinetics and increased cell biomass formation. Oxygen consumption rates and the total capacity of oxygen consumption by the corresponding yeast lees clearly decreased when oxygen was added during fermentation. This marked decrease in yeast lees reactivity towards oxygen was concomitantly related to an increase in ergosterol synthesis and to oxygen-dependent sterol degradation. Such degradation occurred when oxygen was added in excess. Therefore, oxygenation control during fermentation appears to be a potential way to optimize both the fermentation kinetics and control yeast lees reactivity towards oxygen. For practical applications, oxygenation control during alcoholic fermentation may be considered as a general tool for decreasing the highly reductive effect of yeast lees during wine aging.