terclim by ICS banner
IVES 9 IVES Conference Series 9 FUNGAL DIVERSITY AND DYNAMICS IN CHAMPAGNE VINEYARDS: FROM VINE TO WINE

FUNGAL DIVERSITY AND DYNAMICS IN CHAMPAGNE VINEYARDS: FROM VINE TO WINE

Abstract

Champagne is a well-known wine region in Northern France with distinct terroirs and three main grape varieties. As for any vineyard, wine quality is highly linked to the microbiological characteristics of the raw materials. However, Champagne grape microbiota, especially its fungal component, has yet to be fully characterized. Our study focused on describing this mycobiota, from vine to small scale model wine, for the two main Champagne grape varieties, Pinot Noir and Meunier, using complementary cultural and omics approaches.

Changes in microbial diversity and dynamics, especially mycobiota colonizing grapes, was evaluated at 5 berry ripening and vinification stages in 31 vineyards for two harvests. Grapes were collected at fruit set, veraison and harvest and micro-pressing (40 kg) and micro-vinifications (5L) of grape musts from each vineyard were performed.

For both harvests, fungal counts increased during berry ripening (although lower counts were observed in 2022 versus 2021), remained relatively high in musts before yeasts solely dominated in laboratory wines. Clear shifts in mycobiota diversity were observed from vine to laboratory wine for both years. Berries were dominated by yeasts (including filamentous Aureobasidium spp.) regardless of ripening stage with an increase in mold diversity during ripening. Cladosporium (7 species identified) were predominant in unmature berries before other molds colonized grapes, especially Penicillium (9 species identified) and Botrytis cinerea, from veraison onwards. Metagenetic analyses (equivalent to 450 samples in 2021) were well correlated with culture-dependent data. This approach confirmed the predominance of yeasts (Aureobasidium and Vishniacozyma) at both fruit set and veraison, in addition to Cladosporium, although higher fungal diversity and variability between musts was observed.

This unprecedent and thorough description of mycobiota from unmature berries to microvinified wines will clearly contribute to a better understanding of the fungal determinants of specific traits linked to wine quality or defects. Microbial co-occurrence networks and global analyses with the generated climatic data and vineyard practices is currently being explored to understand species interactions and identify factors shaping mycobiota composition.

DOI:

Publication date: February 9, 2024

Issue: OENO Macrowine 2023

Type: Article

Authors

Adrien Destanque1,2*, Adeline Picot1, Flora Pensec1, Nolwenn Rolland1, Audrey Pawtowski1, Sylvie Treguer-Fernandez1, Lau-rence Guérin2, Laurence Mercier2, Emmanuel Coton1, Marion Hervé2 and Monika Coton1

1. Univ Brest, INRAE, Laboratoire Universitaire de Biodiversité et Ecologie Microbienne, F-29280 Plouzané, France
2. Centre de Recherche Robert-Jean de Vogüé Moët Hennessy, 51530 Oiry, France

Contact the author*

Keywords

Mycobiota, Diversity, Metagenetics, Co-occurrence networks

Tags

IVES Conference Series | oeno macrowine 2023 | oeno-macrowine

Citation

Related articles…

EFFECT OF FUMARIC ACID ON SPONTANEOUS FERMENTATION IN GRAPE MUST

Malolactic fermentation (MLF)¹, the decarboxylation of L-malic acid into L-lactic acid, is performed by lactic acid bacteria (LAB). MLF has a deacidifying effect that may compromise freshness or microbiological stability in wines² and can be inhibited by fumaric acid [E297] (FA). In wine, can be added at a maximum allowable dose of 0.6 g/L³. Its inhibition with FA is being studied as an alternative strategy to minimize added doses of SO₂⁴. In addition, wine yeasts are capable of metabolizing and storing small amounts of FA and during alcoholic fermentation (AF).

THE INFLUENCE OF COMMERCIAL SACCHAROMYCES CEREVISIAE ON THE POLY-SACCHARIDES AND OTHER CHEMICAL PROFILES OF NEW ZEALAND PINOT NOIR WINES

Wine polysaccharides (PS) play an important role in balancing mouthfeel and stability of wine and even influence aroma volatility. Despite this, there is limited research into the effect of winemaking additives on the polysaccharide profile and other macromolecules of New Zealand (NZ) Pinot noir wine. In this study the influence of a selection of commercial S. cerevisiae strains on the chemical profile, including polysaccharides, of New Zealand Pinot noir (PN) wine was investigated. Research scale PN fermentations using five strains of commercially available S. cerevisiae (Lalvin EC1118 and RC212, Levuline BRG YSEO, Viallate Ferm R71 and R82) were undertaken. PS were qualified and quantified using HPLC-RID.

FLAVANOL COMPOSITION OF VARIETAL AND BLEND WINES MADE BEFORE AND AFTER FERMENTATION FROM SYRAH, MARSELAN AND TANNAT

Background: The Flavan-3-ol extraction from grape skin and seed during red-winemaking and their retention into wines depend on many factors, some of which are modified in the winemaking of blend wines. Recent research shows that Marselan, have grapes with high proportion of skins with high concentrations of flavanols, but produces red-wines with low proportion of skin derived flavanols, differently to the observed in Syrah or Tannat. But the factors explaining these differences are not yet understood.

S. CEREVISIAE AND O. ŒNI BIOFILMS FOR CONTINUOUS ALCOHOLIC AND MALOLACTIC FERMENTATIONS IN WINEMAKING

Biofilms are sessile microbial communities whose lifestyle confers specific properties. They can be defined as a structured community of bacterial cells enclosed in a self-produced polymeric matrix and adherent to a surface and considered as a method of immobilisation. Immobilised microorganisms offer many advantages for industrial processes in the production of alcoholic beverages and specially increasing cell densities for a better management of fermentation rates.

ALCOHOLIC FERMENTATION AND COLOR OF ROSÉ WINES: INVESTIGATIONS ON THE MECHANISMS RESPONSIBLE FOR SUCH DIVERSITY

Color is one of the key elements for the marketing of rosé wines due to their packaging in transparent bottles. Their broad color range is due to the presence of pigments belonging to phenolic compounds extracted from grapes or formed during the wine-making process. However, the mechanisms responsible for such diversity are poorly understood. The few investigations performed on rosé wines showed that their phenolic composition is highly variable, close to that of red wines for the darkest rosés but very different for light ones [1]. Moreover, large variations in the extent of color loss taking place during fermentation have been reported but the mechanisms involved and causes of such variability are unknown.