Luciana De Vero

Succession of Selected Strains of Acetobacter pasteurianus and Other Acetic Acid Bacteria in Traditional Balsamic Vinegar

ABSTRACT The application of a selected Acetobacter pasteurianus strain for traditional balsamic vinegar production was assessed. Genomic DNA was extracted from biofilms after enrichment cultures on GYC medium (10% glucose, 1.0% yeast extract, 2.0% calcium carbonate) and used for PCR/denaturing gradient gel electrophoresis, 16S rRNA gene sequencing, and enterobacterial repetitive intergenic consensus/PCR sequencing. Results suggested that double-culture fermentation is suitable for traditional balsamic vinegar acetification.

Fermentative aptitude of non- Saccharomyces wine yeast for reduction in the ethanol content in wine

Abstract Over the last few decades, there has been a progressive increase in the ethanol content in wines due to global climate change and to the new wine styles that are associated with increased grape maturity. This increased ethanol content can have negative consequences on the sensory properties of the wines, human health, and economic aspects. Several microbiological approaches for decreasing the ethanol content have been suggested, such as strategies based on genetically modified yeasts, the adaptive evolution of yeasts, and the use of non-Saccharomyces yeast. In the present study, we investigated the interspecies and intraspecies variability of some non-Saccharomyces wine yeast species under anaerobic fermentation conditions. Across different grape juices and fermentation trials, Hanseniaspora uvarum, Zygosaccharomyces sapae, Zygosaccharomyces bailii, and Zygosaccharomyces bisporus promoted significant reductions in ethanol yield and fermentation efficiency in comparison with Saccharomyces cerevisiae. The diversion of alcoholic fermentation and the abundant formation of secondary compounds might explain the marked reduction in ethanol yield, as determined through the segregation of the majority of the strains according to their species attributes observed using principal component analysis. These data suggest that careful evaluation of interspecies and intraspecies biodiversity can be carried out to select yeast that produces low-ethanol yields.

Improved wine yeasts by direct mating and selection under stressful fermentative conditions

Hybridization of yeasts allows whole-genome modifications that can be exploited to obtain global improvements in industrial traits, such as those involved in the winemaking industry. In our work we applied direct mating to achieve the construction of hybrids and we subsequently applied these hybrids in fermentation trials under stressful conditions, in order to select hybrid strains with improved technological traits. Five hybrids, obtained from six parental strains by direct spore conjugation, were validated through PCR amplification of highly variable minisatellite-containing genes; the validation phase also revealed three meiotic derivative strains, characterized by contracted number of repeats. Analysis of the mating-type locus in the homozygous spore progeny of parental strains provided useful insights into the understanding of hybridization yields and unveiled some irregularities in yeast autodiploidization mechanism. The fermentative trials were followed by chemical analysis; afterwards principal component analysis allowed the metabolic footprinting of wine yeasts and the selection of the two best industrial candidates, which display superior phenotypes in fermentative fitness and secondary metabolite production, respectively.

Evolved Saccharomyces cerevisiae wine strains with enhanced glutathione production obtained by an evolution‐based strategy

In winemaking, the application of glutathione (GSH) has been the subject of ever-growing interest because of its important role in limiting must and wine oxidation and in protecting various aromatic compounds. Glutathione concentration in wine is highly variable, involving as it does several factors from must, through alcoholic fermentation, to yeast strain activity. Consequently, the development of new wine yeast strains able to improve flavor stability is in great demand. To generate evolved Saccharomyces cerevisiae strains with enhanced GSH production, we have applied an evolution-based strategy that combines the sexual recombination of spores with the application of molybdate, which is toxic for the cells at high concentration, as specific selective pressure. Eight molybdate-resistant strains were selected and further screened for GSH production in synthetic grape must and in microvinification assay. By this nongenetically modified strategy, we obtained two evolved strains, Mo21T2-5 and Mo21T2-12, both able to enhance GSH content in wine with an increase of 100% and 36%, respectively, compared with the parental strain 21T2, and 120% and 50% compared with initial GSH content in the must.

High-glutathione producing yeasts obtained by genetic improvement strategies: a focus on adaptive evolution approaches for novel wine strains

Glutathione (GSH) is the most abundant non-protein thiol in living organisms. Due to its important antioxidant role, it is widely used in medicine, as a food additive, and in the cosmetic industry. Recently, GSH has received growing attention in winemaking because of its ability to control oxidative spoilage damage and to protect various aromatic compounds. Indeed, GSH concentration in wine is highly variable and several factors are involved in its regulation, ranging from grape must to yeast fermentation activity. This short review aims at highlighting the common genetic strategies, useful for obtaining wine yeasts with enhanced GSH production, paying particular attention to the adaptive evolution approaches. Moreover, other strategies, such as random mutagenesis, metabolic engineering and hybridization have been briefly reviewed with a stress on both their strengths and weaknesses in terms of actual feasibility and acceptance by wine consumers.

Genetic variation and expression changes associated with molybdate resistance from a glutathione producing wine strain of Saccharomyces cerevisiae

Glutathione (GSH) production during wine fermentation is a desirable trait as it can limit must and wine oxidation and protect various aromatic compounds. UMCC 2581 is a Saccharomyces cerevisiae wine strain with enhanced GSH content at the end of wine fermentation. This strain was previously derived by selection for molybdate resistance following a sexual cycle of UMCC 855 using an evolution-based strategy. In this study, we examined genetic and gene expression changes associated with the derivation of UMCC 2581. For genetic analysis we sporulated the diploid UMCC 855 parental strain and found four phenotype classes of segregants related to molybdate resistance, demonstrating the presence of segregating variation from the parental strain. Using bulk segregant analysis we mapped molybdate traits to two loci. By sequencing both the parental and evolved strain genomes we identified candidate mutations within the two regions as well as an extra copy of chromosome 1 in UMCC 2581. Combining the mapped loci with gene expression profiles of the evolved and parental strains we identified a number of candidate genes with genetic and/or gene expression changes that could underlie molybdate resistance and increased GSH levels. Our results provide insight into the genetic basis of GSH production relevant to winemaking and highlight the value of enhancing wine strains using existing variation present in wine strains.

A multi-phase approach to select new wine yeast strains with enhanced fermentative fitness and glutathione production

The genetic improvement of winemaking yeasts is a virtually infinite process, as the design of new strains must always cope with varied and ever-evolving production contexts. Good wine yeasts must feature both good primary traits, which are related to the overall fermentative fitness of the strain, and secondary traits, which provide accessory features augmenting its technological value. In this context, the superiority of “blind,” genetic improvement techniques, as those based on the direct selection of the desired phenotype without prior knowledge of the genotype, was widely proven. Blind techniques such as adaptive evolution strategies were implemented for the enhancement of many traits of interest in the winemaking field. However, these strategies usually focus on single traits: this possibly leads to genetic tradeoff phenomena, where the selection of enhanced secondary traits might lead to sub-optimal primary fermentation traits. To circumvent this phenomenon, we applied a multi-step and strongly directed genetic improvement strategy aimed at combining a strong fermentative aptitude (primary trait) with an enhanced production of glutathione (secondary trait). We exploited the random genetic recombination associated to a library of 69 monosporic clones of strain UMCC 855 (Saccharomyces cerevisiae) to search for new candidates possessing both traits. This was achieved by consecutively applying three directional selective criteria: molybdate resistance (1), fermentative aptitude (2), and glutathione production (3). The strategy brought to the selection of strain 21T2-D58, which produces a high concentration of glutathione, comparable to that of other glutathione high-producers, still with a much greater fermentative aptitude.

Oxidative fermentations and exopolysaccharides production by acetic acid bacteria: a mini review

Acetic acid bacteria are versatile organisms converting a number of carbon sources into biomolecules of industrial interest. Such properties, together with the need to limit chemical syntheses in favor of more sustainable biological processes, make acetic acid bacteria appropriate organisms for food, chemical, medical, pharmaceutical and engineering applications. At current, well-established bioprocesses by acetic acid bacteria are those derived from the oxidative pathways that lead to organic acids, ketones and sugar derivates. Whereas emerging applications include biopolymers, such as bacterial cellulose and fructans, which are getting an increasing interest for the biotechnological industry. However, considering the industrial demand of high performing bioprocesses, the production yield of metabolites obtained by acetic acid bacteria, is still not satisfying. In this paper we review the major acetic acid bacteria industrial applications, considering the current status of bioprocesses. We will also describe new biotechnological advances in order to optimize the industrial production, offering also an overview on future directions.

Understanding genetic changes underlying the molybdate resistance and the glutathione production in Saccharomyces cerevisiae wine strains using an evolution-based strategy

In this work we have investigated the genetic changes underlying the high glutathione (GSH) production showed by the evolved Saccharomyces cerevisiae strain UMCC 2581, selected in a molybdate-enriched environment after sexual recombination of the parental wine strain UMCC 855. To reach our goal, we first generated strains with the desired phenotype, and then we mapped changes underlying adaptation to molybdate by using a whole-genome sequencing. Moreover, we carried out the RNA-seq that allowed an accurate measurement of gene expression and an effective comparison between the transcriptional profiles of parental and evolved strains, in order to investigate the relationship between genotype and high GSH production phenotype. Among all genes evaluated only two genes, MED2 and RIM15 both related to oxidative stress response, presented new mutations in the UMCC 2581 strain sequence and were potentially related to the evolved phenotype. Regarding the expression of high GSH production phenotype, it included over-expression of amino acids permeases and precursor biosynthetic enzymes rather than the two GSH metabolic enzymes, whereas GSH production and metabolism, transporter activity, vacuolar detoxification and oxidative stress response enzymes were probably added resulting in the molybdate resistance phenotype. This work provides an example of a combination of an evolution-based strategy to successful obtain yeast strain with desired phenotype and inverse engineering approach to genetic characterize the evolved strain. The obtained genetic information could be useful for further optimization of the evolved strains and for providing an even more rapid approach to identify new strains, with a high GSH production, through a marked-assisted selection strategy.