terclim by ICS banner
IVES 9 IVES Conference Series 9 EFFECT OF FUMARIC ACID ON SPONTANEOUS FERMENTATION IN GRAPE MUST

EFFECT OF FUMARIC ACID ON SPONTANEOUS FERMENTATION IN GRAPE MUST

Abstract

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). Our aim was to study the effect of FA addition in natural grape must without SO₂ on alcoholic and malolactic fermentation. AF was performed on Muscat of Alexandria grape must without SO₂ under two different conditions. i) Grape must 1 without FA, pH 3.49 and ii) Grape must 2 with 0.6 g/L of FA, pH 3.39; both had an L-malic acid concentration of 1.44 g/L. AF was developed at 20°C and spontaneously, monitored by must density determination. The evolution of L-malic acid and FA was monitored enzymatically⁵ and plate counts were performed for Saccharomyces, non-Saccharomyces and LAB populations. In both grape musts, no significant differences were observed in the development of AF. In grape must 1 MLF was performed during AF and produced a lactic bite. A progressive decrease in FA was observed in grape must 2 during AF, reaching 0.087 g/L at the end. From the wine obtained from grape must 2, two conditions were prepared i) a wine uncorrected with FA with a concentration of 0.087 g/L and ii) a wine with FA correction to 0.6 g/L. MLF was tried to take place at a temperature of 20°C under two new conditions, i) spontaneous and ii) with inoculation of O. oeni VP41 (Lallemand S.A.). MLF was monitored following the evolution of L-malic acid and LAB populations by plate count. MLF was not performed in all conditions, except for wines without FA correction inoculated with LAB. In conclusion, the addition of FA in must at pH 3.5 without SO₂ with low initial LAB populations may be an effective strategy to prevent MLF during AF in conditions of absence of SO₂. However, FA supplementation in the grape juice will not inhibit the subsequent development of the MFL in the wine, since a large part of this acid is metabolized by the yeasts, being necessary supplementing with FA again to ensure the non-development of malolactic fermentation in the case of high LAB populations.

 

1. SUMBY, K.M., BARTLE, L., GRBIN, P.R. JIRANEK V., 2019. Measures to improve wine malolactic fermentation, Applied Microbiology and Biotechnology, vol 103, pp. 2033–2051.
2. Bauer R., Dicks L. M. T. 2004. Control of malolactic fermentation in wine A Review, South African Journal for Enology and Viticulture 25:74⟨88.
3. OIV, 2021. International Organization of Vine and Wine. Summary of Resolutions Adopted in 2021 by the 19th General Assembly of the OIV- Paris (France).
4. Morata A., Bañuelos M. A., López C., Song C., Vejarano R., Loira I., PALOMERO F. , Suarez Lepe J. A. 2020. Use of fumaric acid to control pH and inhibit malolactic fermentation in wines, Food Additives & Contaminants: Part A, 37:2, 228-238
5. FERNÁNDEZ-VÁSQUEZ D., ROZÈS N., CANALS J.M., BORDONS A., REGUANT C., ZAMORA F. 2021. New enzymatic method for estimating fumaric acid in wines. OENO One 2021, 3, 273-281.

DOI:

Publication date: February 9, 2024

Issue: OENO Macrowine 2023

Type: Poster

Authors

Violeta García-Viñola¹, Montse Poblet¹, Albert Bordons², Fernando Zamora³, Joan Miquel Canals³, Cristina Reguant² y Nicolas Rozès¹

1. Grup de Biotecnologia Microbiana dels Aliments, Departament de Bioquímica i Biotecnologia, Facultat d’Enologia, Universitat Rovira i Virgili
2. Grup de Biotecnologia Enològica, Departament de Bioquímica i Biotecnologia, Facultat d’Enologia, Universitat Rovira i Virgili.
3. Grup de Tecnologia Enològica Departament de Bioquímica i Biotecnologia, Facultat d’Enologia, Universitat Rovira i Virgili.

Contact the author*

Keywords

Fumaric acid, Alcoholic fermentation, Malolactic fermentation, Spontaneous fermentation

Tags

IVES Conference Series | oeno macrowine 2023 | oeno-macrowine

Citation

Related articles…

EVALUATION OF INDIGENOUS CANADIAN YEAST STRAINS AS WINE STARTER CULTURES ON PILOT SCALE FERMENTATIONS

The interactions between geographical and biotic factors, along with the winemaking process, influence the composition and sensorial characteristics of wine¹. In addition to the primary end products of alcoholic fermentation, many secondary metabolites contribute to wine flavor and aroma and their production depends predominantly on the yeast strain carrying out the fermentation. Commercially available strains of S. cerevisiae help improve the reproducibility and predictability of wine quality. However, most commercial wine strains available on the market have been isolated from Europe, are genetically similar, and may not be the ideal strain to reflect the terroir of Canadian vineyards².

METHYL SALICYLATE, A COMPOUND INVOLVED IN BORDEAUX RED WINES PRODUCED WITHOUT SULFITES ADDITION

Sulfur dioxide (SO₂) is the most commonly used additive during winemaking to protect wine from oxidation and from microorganisms. Thus, since the 18th century, SO₂ was almost systematically present in wines. Recently, wines produced without any addition of SO₂ during all the winemaking process including bottling became more and more popular for consumers. A recent study dedicated to sensory characterization of Bordeaux red wines produced without added SO₂, revealed that such wines were perceived differently from similar wines produced with using SO₂ and were characterized by specific fruity aromas and coolness1,2.

UNRAVELING THE CHEMICAL MECHANISM OF MND FORMATION IN RED WINE DURING BOTTLE AGING : IDENTIFICATION OF A NEW GLUCOSYLATED HYDROXYKETONE PRO-PRECURSOR

During bottle aging, the development of wine aroma through low and gradual oxygen exposure is often positive in red wines, but can be unfavorable in many cases, resulting in a rapid loss of fresh, fruity flavors. Prematurely aged wines are marked by intense prune and fig aromatic nuances that dominate the desirable bouquet achieved through aging (Pons et al., 2013). This aromatic defect, in part, is caused by the presence of 3-methyl-2,4-nonanedione (MND). MND content was shown to be lower in nonoxidized red wines and higher in oxidized red wines, which systematically exceeds the odor detection threshold (62 ng/L).

ENRICHMENT OF THE OENOLOGICAL MALDI-TOF/MS PROTEIN SPECTRA DATABASE FOR RELIABLE OENOLOGICAL YEAST AND BACTERIA IDENTIFICATION

The Matrix Assisted Laser Desorption/Ionization–Time-Of-Flight Mass Spectrometry (MALDI-TOF MS) technology is commonly used in food and medical sector to identify yeast or bacteria species isolated from a nutritive culture media. Since a decade, brewery and oenology industries have been attracted to this method which combines fast analysis times, reliability and low cost of analysis. Briefly, this method is based on the comparison of the MALDI-TOF/MS protein spectra of an isolated colony of yeast or bacteria with those contain in a manufacturer’s reference protein spectra database. Initiated in 2015, the creation of the first oenological mass spectra database has proved to be essential for increase quality of species identification.

MOVING FROM SULFITES TO BIOPROTECTION: WHICH IMPACT ON CHARDONNAY WINE?

Over the last few years, several tools have been developed to reduce the quantity of sulfites used during winemaking, including bioprotection. Although its effectiveness in preventing the development of spoilage microorganisms has been proven, few data are available on the impact of sulfite substitution by bioprotection on the final product. The objective of this study was therefore to characterize Chardonnay wines with the addition of sulfite or bioprotection in the pre-fermentation stage. The effects of both treatments on resulting matrices was evaluated at several scales: analysis of classical oenological parameters, antioxidant capacity, phenolic compounds, non-volatile metabolome and sensory profile.