The Impact of a Commercial Biostimulant on the Grape Mycobiota of Vitis vinifera cv. Barbera.

Reducing the use of fungicides, insecticides, and herbicides in order to limit environmental pollution and health risks for agricultural operators and consumers is one of the goals of European regulations. In fact, the European Commission developed a package of measures (the European Green Deal) to promote the sustainable use of natural resources and strengthen the resilience of European agri-food systems. As a consequence, new plant protection products, such as biostimulants, have been proposed as alternatives to agrochemicals. Their application in agroecosystems could potentially open new scenarios regarding the microbiota. In particular, the vineyard microbiota and the microbiota on the grape surface can be affected by biostimulants and lead to different wine features. The aim of this work was to assess the occurrence of a possible variation in the mycobiota due to the biostimulant application. Therefore, our attention has been focused on the yeast community of grape bunches from vines subjected to the phytostimulant BION®50WG treatment. This work was carried out in the CREA-VE experimental vineyard of Vitis vinifera cv. Barbera in Asti (Piedmont, Italy). The composition of fungal communities on grapes from three experimental conditions such as IPM (integrated pest management), IPM+BION®50WG, and IPM+water foliar nebulization was compared by a metabarcoding approach. Our results revealed the magnitude of alpha and beta diversity, and the microbial biodiversity index and specific fungal signatures were highlighted by comparing the abundance of yeast and filamentous fungi in IPM and BION®50WG treatments. No significant differences in the mycobiota of grapevines subjected to the three treatments were detected.

Genome Sequence of Oenococcus oeni OE37, an Autochthonous Strain Isolated from an Italian White Wine.

Oenococcus oeni OE37 is an autochthonous strain that was isolated from a Chardonnay wine from Piedmont (Italy) during spontaneous malolactic fermentation. Here, the OE37 genome sequence is presented, and a brief description of the main genes is reported.

Yeast distribution in Grignolino grapes growing in a new vineyard in Piedmont and the technological characterization of indigenous Saccharomyces spp. strains.

The aim of this study was to characterize the yeast consortium isolated from Grignolino grapes in a newly planted vineyard in Piedmont (Italy) via analysis of the intra-vineyard yeast distribution of grape samples from single rows. A two-phase approach allowed the identification of culturable yeasts present on grape skins and, through an enriching procedure via grape fermentation, the isolation of low frequency non-Saccharomyces and Saccharomyces spp. fermentative species, including S. paradoxus, which is highly unusual during grape fermentation, along with the intra-specific characterization of S. cerevisiae isolates. Culture-based molecular techniques revealed a grape yeast microbiota formed by (in order of abundance) Hanseniaspora uvarum, the yeast-like fungus Aerobasidium pullulans, Candida zemplinina, Pichia kluyveri, Candida californica, Curvibasidium cygneicollum, Meyerozima caribbica, Rhodotorula babjevae, Metschnikowia pulcherrima and Cryptococcus flavescens. Technological properties of isolated Saccharomyces spp. strains were analysed, identifying strains, including S. paradoxus, potentially suitable as an ecotypical starter for territorial wines.

Key norisoprenoid compounds in wines from early-harvested grapes in view of climate change.

In view of climate change, the scheduling of an early harvest may be an agronomic option to limit wine alcohol, provided that a satisfactory content of secondary metabolites can be ensured in grapes. To better understand the link between grape ripening, seasonal trend and wine aroma, the aromatic expression of Barbera and Pinot Noir wines produced with early harvested grapes was assessed. Attention was focused on C13 norisoprenoids during both alcoholic fermentation and after three months of storage. At the end of fermentation, the highest ß-damascenone content was detected in wines obtained from less ripe grapes, the content subsequently increased significantly after three months of storage; however, the levels of ß-ionone decreased significantly during the same period. The reduction of wine alcohol as a result of harvesting earlier, especially for Barbera, was associated with optimal aromatic levels as well as good technological parameters.

Enhanced arginine biosynthesis and lower proteolytic profile as indicators of Saccharomyces cerevisiae stress in stationary phase during fermentation of high sugar grape must: A proteomic evidence.

A strain of Saccharomyces (S) cerevisiae (ISE19), which displayed an initial good adaptation to a high sugar medium with increased acetate and glycerol production but weak overall growth/fermentation performances, was selected during the alcoholic fermentation of Cortese grape must. To obtain insights into the metabolic changes that occur in the must during growth in particular conditions (high ethanol, high residual sugars and low nitrogen availability) leading to a sluggish fermentation or even fermentation arrest, comparative in-gel proteomic analyses were performed on cells grown in media containing 200g/L and 260g/L of glucose, respectively, while the YAN (Yeast Assimilable Nitrogen) concentration was maintained as it was. Two post-translationally different arginine synthases (pIs 5.6 and 5.8) were found in higher abundances in the high glucose-grown cells, together with an increased abundance of a glycosyltransferase involved in cell-wall mannans synthesis, and of two regulatory proteins (K7_Bmh1p and K7_Bmh2p) that control membrane transport. In parallel, a proteinase K-like proteolytic enzyme and three other protein fragments (Indolepyruvate decarboxylase 1, Fba1p and Eno1p) were present in lower abundances in the high glucose condition, where oxidative stress and cell cycle involved enzymes were also found to be less abundant. The overall results suggest that in stationary phase stress conditions, leading to stuck fermentation, S. cerevisiae ISE19 decreases cell replication, oxidative stress responses and proteolytic activity, while induces other metabolic modifications that are mainly based on cell-wall renewal, regulation of the solute transport across the cell membrane and de novo arginine synthesis.

New Genes Involved in Osmotic Stress Tolerance in Saccharomyces cerevisiae.

Adaptation to changes in osmolarity is fundamental for the survival of living cells, and has implications in food and industrial biotechnology. It has been extensively studied in the yeast Saccharomyces cerevisiae, where the Hog1 stress activated protein kinase was discovered about 20 years ago. Hog1 is the core of the intracellular signaling pathway that governs the adaptive response to osmotic stress in this species. The main endpoint of this program is synthesis and intracellular retention of glycerol, as a compatible osmolyte. Despite many details of the signaling pathways and yeast responses to osmotic challenges have already been described, genome-wide approaches are contributing to refine our knowledge of yeast adaptation to hypertonic media. In this work, we used a quantitative fitness analysis approach in order to deepen our understanding of the interplay between yeast cells and the osmotic environment. Genetic requirements for proper growth under osmotic stress showed both common and specific features when hypertonic conditions were induced by either glucose or sorbitol. Tolerance to high-glucose content requires mitochondrial function, while defective protein targeting to peroxisome, GID-complex function (involved in negative regulation of gluconeogenesis), or chromatin dynamics, result in poor survival to sorbitol-induced osmotic stress. On the other side, the competitive disadvantage of yeast strains defective in the endomembrane system is relieved by hypertonic conditions. This finding points to the Golgi-endosome system as one of the main cell components negatively affected by hyperosmolarity. Most of the biological processes highlighted in this analysis had not been previously related to osmotic stress but are probably relevant in an ecological and evolutionary context.

An event-specific method for the detection and quantification of ML01, a genetically modified Saccharomyces cerevisiae wine strain, using quantitative PCR.

The availability of genetically modified (GM) yeasts for winemaking and, in particular, transgenic strains based on the integration of genetic constructs deriving from other organisms into the genome of Saccharomyces cerevisiae, has been a reality for several years. Despite this, their use is only authorized in a few countries and limited to two strains: ML01, able to convert malic acid into lactic acid during alcoholic fermentation, and ECMo01 suitable for reducing the risk of carbamate production. In this work we propose a quali-quantitative culture-independent method for the detection of GM yeast ML01 in commercial preparations of ADY (Active Dry Yeast) consisting of efficient extraction of DNA and qPCR (quantitative PCR) analysis based on event-specific assay targeting MLC (malolactic cassette), and a taxon-specific S. cerevisiae assay detecting the MRP2 gene. The ADY DNA extraction methodology has been shown to provide good purity DNA suitable for subsequent qPCR. The MLC and MRP2 qPCR assay showed characteristics of specificity, dynamic range, limit of quantification (LOQ) limit of detection (LOD), precision and trueness, which were fully compliant with international reference guidelines. The method has been shown to reliably detect 0.005% (mass/mass) of GM ML01 S. cerevisiae in commercial preparations of ADY.

Short-term response of different Saccharomyces cerevisiae strains to hyperosmotic stress caused by inoculation in grape must: RT-qPCR study and metabolite analysis.

During the winemaking process, glycerol synthesis represents the first adaption response of Saccharomyces cerevisiae to osmotic stress after inoculation in grape must. We have implemented an RT-qPCR (Reverse Transcription-quantitative PCR) methodology with a preventive evaluation of candidate reference genes, to study six target genes related to glycerol synthesis (GPD1, GPD2, GPP2 and GPP1) and flux (STL1 and FPS1), and three ALD genes coding for aldehyde dehydrogenase involved in redox equilibrium via acetate production. The mRNA level in three strains, characterized by different metabolite production, was monitored in the first 120 min from inoculation into natural grape must. Expression analysis shows a transient response of genes GPD1, GPD2, GPP2, GPP1 and STL1 with differences among strains in term of mRNA abundance, while FPS1 was expressed constitutively. The transient response and different expression intensity among strains, in relation to the intracellular glycerol accumulation pattern, prove the negative feedback control via the HOG (High Osmolarity Glycerol) signalling pathway in S. cerevisiae wine strains under winery conditions. Among the ALD genes, only ALD6 was moderately induced in the hyperosmotic environment but not in all strains tested, while ALD3 and ALD4 were drastically glucose repressed. The intensity of transcription of ALD6 and ALD3 seems to be related to different acetate production found among the strains.

Quantitative expression analysis of mleP gene and two genes involved in the ABC transport system in Oenococcus oeni during rehydration.

Oenococcus oeni is recognized as the principal microorganism responsible for malolactic fermentation, and the control of its activity is of primary importance in winemaking. The aim of this study was to quantify the levels of expression of the malate transporter gene (mleP) and of two genes putatively involved in the ATP-binding cassette transport system (oeoe_1651, oeoe_0550) to better understand the physiological response of bacteria during rehydration. These genes coding for transporters were studied in different rehydration media. Initially, three different statistical algorithms were used to identify suitable reference genes to be used for the normalization of expression data in O. oeni during rehydration, and to this purpose, the best genes found were ddl and gyrB. The results showed that the genes for transporters of malate and sugar (mleP, oeoe_1651) were activated immediately after a few minutes of rehydration, when specific medium compositions were used.

Identification of reference genes suitable for normalization of RT-qPCR expression data in Saccharomyces cerevisiae during alcoholic fermentation.

Expression data from RT-qPCR (reverse transcription quantitative PCR) needs to be normalized to account for experimental variability among samples caused by differential yields of the transcripts in RNA extraction or in the reverse transcription. The most common method is to normalize against one or more reference genes (RG). We have selected RGs suitable for normalization of RT-qPCR raw data in Saccharomyces cerevisiae during alcoholic fermentation. The RGs were evaluated by three different statistical methods. The suitability of the selected RG sets was compared with ACT1, a commonly used non-validated single RG, by normalizing the expression of two target genes. Expression profiles of the target genes revealed the risk of misleading interpretation of expression data due to an unreliable RG.

An RT-qPCR approach to study the expression of genes responsible for sugar assimilation during rehydration of active dry yeast.

A short reactivation period in aqueous media is required for active dry yeast (ADY) to be utilised in winemaking. Rehydration restores the active metabolic conditions necessary for good fermentative and competitive abilities. We used a reverse transcription-quantitative PCR (RT-qPCR) method with relative quantification to investigate the expression of seven hexose transporter genes (HXT1-7) and one invertase-encoding gene (SUC2) during ADY rehydration in water with or without sucrose. For this, seven candidate reference genes were evaluated, and the three most stably expressed genes were selected and used for mRNA normalisation. The results show that, during the rehydration in the presence of sucrose, yeast cells are able to immediately hydrolyse this sugar into glucose and fructose as soon as they are introduced in the medium. Subsequently, differential glucose/fructose uptake occurs, which is mediated by hexose transporters. At the transcriptomic level, there is a strong induction of the high-affinity transporters, HXT2 and HXT4, and the low-affinity transporters, HXT3 and HXT1, when ADY is rehydrated with sucrose, while HXT5 and HXT6/7 are expressed at high levels with a moderate tendency to decrease. In water, the HXT2 gene was the only one of the transporter genes studied that showed significant variations. These results suggest that during rehydration, expression is not simply regulated by the affinity to hexose but is also controlled by other mechanisms that allow the cell to bypass glucose control. Moreover, the expression of SUC2 showed little variation in media with sucrose, suggesting that other invertases and/or posttranscriptional controls exist.

Biogenic amine production by contaminating bacteria found in starter preparations used in winemaking.

The aim of this work was to investigate if contaminating microorganisms, eventually present in bacteria and yeast preparations used as commercial starters in winemaking, have the ability to produce the biogenic amines histamine, putrescine and tyramine. Thirty commercial starters (14 yeasts Saccharomyces cerevisiae and 16 bacteria Oenococcus oeni) were cultured in synthetic broth and analyzed by TLC to detect amine production. Oenococcus oeni commercial preparations did not contain contaminants, but some yeast preparations resulted contaminated with amine-producing bacteria. Bacterial contaminants were isolated and analyzed for their ability to produce biogenic amines using HPLC and TLC. Decarboxylase genes were identified using PCR analysis followed by sequencing. Fermentations were performed in grape juice with two yeast commercial preparations containing bacterial contaminants to check if the potential biogenic amine production could happen also during winemaking. It was found that this production is possible; in particular, in the conditions used in this work, tyramine production was detected. Therefore, the results of this study have significance in relation to the risk of biogenic amines in wine. Moreover a novel species of Lactobacillus was found to be able to produce histamine.

Application of real-time RT-PCR to study gene expression in active dry yeast (ADY) during the rehydration phase.

During the industrial production of active dry yeast (ADY) and its subsequent use in winemaking, the yeast cell is subjected to drastic environmental changes that force it to undergo extensive metabolic modifications and changes in gene expression. In this study, we describe the use of real-time reverse transcription-polymerase chain reaction (RT-PCR) to monitor gene expression in ADY Saccharomyces cerevisiae during rehydration in different media. We used three statistical approaches to investigate the expression stability of eight potential reference genes during the rehydration process. The reference system thus obtained was used to normalize the expression values of three genes codifying for the ammonium transporters -- MEP1, MEP2, and MEP3 -- and two genes involved in the osmotic response-SIP18 and GPD1. The results suggested that for the target genes tested, the yeast reacted immediately to rehydration only when a fermentable carbon source was present in the medium. Furthermore, MEP2 expression was modulated by the ammonium concentration, indicating that nitrogen catabolite repression (NCR) is active during the rehydration phase.

Discrimination of Saccharomyces cerevisiae wine strains using microsatellite multiplex PCR and band pattern analysis.

We propose a rapid method for Saccharomyces cerevisiae strain identification based on multiplex PCR analysis of polymorphic microsatellite loci. Simple DNA extraction without the use of phenol, followed by a rapid PCR procedure optimised for multiplex amplification of loci SC8132X, YOR267C and SCPTSY7 and band pattern analysis of the fragments generated by agarose and polyacrylamide gel electrophoresis, has allowed us to distinguish among a panel of 30 tested commercial wine strains. This method was successfully performed in an ecological study where dominance between two strains was checked at two fermentation temperatures: 15 and 20 degrees C. The method should be useful for routine and low-budget discrimination of yeast strains, both in the wine and yeast production industries.