Your search keyword '"Crépin, L."' showing total 2 results

1. Management of Multiple Nitrogen Sources during Wine Fermentation by Saccharomyces cerevisiae.

Author

Crépin L, Truong NM, Bloem A, Sanchez I, Dequin S, and Camarasa C

Subjects

Amino Acids metabolism, Biomass, Carbon metabolism, Culture Media analysis, Food Industry, Food Microbiology, Fruit and Vegetable Juices, Isotope Labeling, Metabolic Networks and Pathways, Metabolism, Saccharomyces cerevisiae growth & development, Sugars metabolism, Vitis chemistry, Wine analysis, Fermentation, Nitrogen chemistry, Nitrogen metabolism, Saccharomyces cerevisiae metabolism, Wine microbiology

Abstract

During fermentative growth in natural and industrial environments, Saccharomyces cerevisiae must redistribute the available nitrogen from multiple exogenous sources to amino acids in order to suitably fulfill anabolic requirements. To exhaustively explore the management of this complex resource, we developed an advanced strategy based on the reconciliation of data from a set of stable isotope tracer experiments with labeled nitrogen sources. Thus, quantifying the partitioning of the N compounds through the metabolism network during fermentation, we demonstrated that, contrary to the generally accepted view, only a limited fraction of most of the consumed amino acids is directly incorporated into proteins. Moreover, substantial catabolism of these molecules allows for efficient redistribution of nitrogen, supporting the operative de novo synthesis of proteinogenic amino acids. In contrast, catabolism of consumed amino acids plays a minor role in the formation of volatile compounds. Another important feature is that the α-keto acid precursors required for the de novo syntheses originate mainly from the catabolism of sugars, with a limited contribution from the anabolism of consumed amino acids. This work provides a comprehensive view of the intracellular fate of consumed nitrogen sources and the metabolic origin of proteinogenic amino acids, highlighting a strategy of distribution of metabolic fluxes implemented by yeast as a means of adapting to environments with changing and scarce nitrogen resources. IMPORTANCE A current challenge for the wine industry, in view of the extensive competition in the worldwide market, is to meet consumer expectations regarding the sensory profile of the product while ensuring an efficient fermentation process. Understanding the intracellular fate of the nitrogen sources available in grape juice is essential to the achievement of these objectives, since nitrogen utilization affects both the fermentative activity of yeasts and the formation of flavor compounds. However, little is known about how the metabolism operates when nitrogen is provided as a composite mixture, as in grape must. Here we quantitatively describe the distribution through the yeast metabolic network of the N moieties and C backbones of these nitrogen sources. Knowledge about the management of a complex resource, which is devoted to improvement of the use of the scarce N nutrient for growth, will be useful for better control of the fermentation process and the sensory quality of wines., (Copyright © 2017 American Society for Microbiology.)

Published

2017

2. Efficient ammonium uptake and mobilization of vacuolar arginine by Saccharomyces cerevisiae wine strains during wine fermentation.

Author

Crépin L, Sanchez I, Nidelet T, Dequin S, and Camarasa C

Subjects

Amino Acids, Biomass, Factor Analysis, Statistical, Glutamine metabolism, Ions, Nitrogen pharmacology, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae growth & development, Vacuoles drug effects, Ammonium Compounds metabolism, Arginine metabolism, Fermentation drug effects, Saccharomyces cerevisiae metabolism, Vacuoles metabolism, Wine microbiology

Abstract

Background: Under N-limiting conditions, Saccharomyces cerevisiae strains display a substantial variability in their biomass yield from consumed nitrogen -in particular wine yeasts exhibit high growth abilities- that is correlated with their capacity to complete alcoholic fermentation, a trait of interest for fermented beverages industries. The aim of the present work was to assess the contribution of nitrogen availability to the strain-specific differences in the ability to efficiently use N-resource for growth and to identify the underlying mechanisms. We compared the profiles of assimilation of several nitrogen sources (mostly ammonium, glutamine, and arginine) for high and low biomass-producing strains in various conditions of nitrogen availability. We also analyzed the intracellular fate of nitrogen compounds., Results: Strains clustered into two groups at initial nitrogen concentrations between 85 and 385 mg N.L(-1): high biomass producers that included wine strains, were able to complete fermentation of 240 g.L(-1) glucose and quickly consume nitrogen, in contrast to low biomass producers. The two classes of strains exhibited distinctive characteristics that contributed to their differential capacity to produce biomass. The contribution of each characteristic varied according to nitrogen availability. In high biomass producers, the high rate of ammonium uptake resulted in an important consumption of this preferred nitrogen source that promoted the growth of these yeasts when nitrogen was provided in excess. Both classes of yeast accumulated poor nitrogen sources, mostly arginine, in vacuoles during the first stages of growth. However, at end of the growth phase when nitrogen had become limiting, high biomass producers more efficiently used this vacuolar nitrogen fraction for protein synthesis and further biomass formation than low biomass producers., Conclusions: Overall, we demonstrate that the efficient management of the nitrogen resource, including efficient ammonium uptake and efficient use of the amino acids stored in vacuoles during the late stages of growth, might lead to high biomass production by wine yeasts.

Published

2014