Macrowine 2021
IVES 9 IVES Conference Series 9 HEAT BERRY : Sensitivity of berries ripening to higher temperature and impact on phenolic compounds in wine

HEAT BERRY : Sensitivity of berries ripening to higher temperature and impact on phenolic compounds in wine

Abstract

The grapevine is an important economical crop that is very sensitive to climate changes and microclimate. The observations made during the last decades at a vineyard scale all concur to show the impact of climate change on vine physiology, resulting in accelerated phenology and earlier harvest (Jones and Davis 2000). It is well-known that berry content is affected by the ambient temperature. While the first experiences were primarily conducted on the impact of temperature on anthocyanin accumulation in the grape, few studies have focused on others component of phenolic metabolism, such as tannins. Due to their chemical structure they are involved in the sensation of astringency / bitterness and play a key role in the quality of wines (Downey, Dokoozlian, and Krstic 2006). In a context of climate change and global warming, it is necessary to ask the question of the effect of temperature on the metabolism and its impact on wine quality. One of the goals of the HEAT BERRY project is to understand the physiological basis of the response of secondary metabolism to heat and microclimate, in grape berries, and their resulting effects on wine chemistry and organoleptic properties. A passive heating system made of polycarbonate screens has been set up at the vineyard. Field experiments conducted on Cabernet Sauvignon showed that this system induces 1 to 3°C increase in berry temperature. The heating system was set up in June at fruit set, and berries juices were sampled and used for ripening analysis between veraison and harvest time. The results of ripening agreed with previous studies: phenolic maturity and extractability of anthocyanins were decreased on heated berries. Nowadays, it is well-known that tannins nature within different berry tissues has an impact on bitterness and astringency (skins tannins mainly participate to the sensation of astringency, while seeds tannins also contribute to bitterness) as well as the percentage of each berry part. But nothing was shown about the importance of a temperature increase on these aspects. Microvinifications were performed on ripe (and over-ripe) berries. First, tastings demonstrated significant differences between wines from heated berries and non-heated berries in accordance with ripening process and berry compounds. Second, phenolics compounds (tannins levels, Dpm, tannins composition) were analyzed in berries and in wines. The analytical results will be compared with the sensory analysis in order to better understand the qualitative impact of heat treatment on berries and wine properties. Overall, the aim of HEAT BERRY is to address the poor knowledge of the effects of high temperatures on berry composition and wines. This should provide useful clues for the adaptation of viticulture to climate change.

Publication date: May 17, 2024

Issue: Macrowine 2016

Type: Article

Authors

Julie Drappier*, Cécile Thibon, Darriet Philippe, Jing Wu, Laurence Geny-Denis, Michael Jourdes, Philippe Pieri, Robin Rabagliato, Serge Delrot

*ISVV

Contact the author

Tags

IVES Conference Series | Macrowine | Macrowine 2016

Citation

Related articles…

Moscatel vine-shoot extracts as grapevine biostimulant to increase the varietal aroma of Airén wines

There is a growing interest in the exploitation of vine-shoots waste, since they are often left or burned. Sánchez-Gómez et al. [1] have shown that vines-shoots aqueous extracts have significant contents of bioactive compounds, among which several polyphenols and volatiles are highlighted. Recent studied had demonstrated that the chemical composition of vine-shoots is enhanced when vine-shoots are toasted
[2,3]. The application of vegetable products in the vineyards has led to significant changes towards a more “Sustainable Viticulture”. An innovative foliar application for Airén vine-shoot extracts have been carried out to the vineyard. It has been shown that they act as grape biostimulants, improving certain wine quality characteristics [4].

Estimation of chemical age of red wines with the use of Fourier transform infrared spectroscopy (FT-IR) and chemometrics

The color of a red wine is one of the most important parameters of its quality, giving much information on its status, such as the grape variety used or the winemaking style. As the result of a complex equilibrium between different forms of anthocyanins and polymerization reactions which occur over the course of time, color can also serve as an indication of a wines’ age. For this purpose the “chemical age” i and ii indexes have been introduced by Somers in 1977. The chemical age index i measures the color absorbance after the addition of acetaldehyde while chemical index ii provides an indication of how much of the total red pigments are resistant to SO2 bleaching.

Ethyl esters interact with the major wine Thaumatin Like Protein VVTL1

The interactions among aromatic compounds and proteins is an important issue for the quality of foods and beverages. In wine, the loss of flavor after vinification is associated to bentonite treatment and this effect can be the result of the removal of aroma compounds which are bound wine proteins. This phenomenon was recently demonstrated for long chain fatty acids and their ethyl esters (1). Since these latter compounds are spectroscopically silent, their association with proteins is not easy to measure.

The commercial yeast strain as a significant source of variance for tyrosol and hydroxytyrosol in white wine

Tyrosol (TYR) and hydroxytyrosol (HYT) are bioactive phenols present in olive oil and wine, basic elements of the Mediterranean diet. TYR is reported in the literature for its interesting antioxidant, cardioprotective and anti-inflammatory properties. In wine, its concentration can reach values as high as about 40 mg/L
[Pour Nikfardjam et al. 2007] but, more frequently, this phenol – derived from yeast metabolism of tyrosine during fermentation – is present at lower levels, generally higher in red wines compared to whites. HYT was measured for the first time by Di Tommaso et al. [1998] in Italian wines – with maximum values of 4.20 mg/L and 1.92 mg/L for red and white wines, respectively – while definitely lower concentrations have been found later in Greek samples.

Testing the effectiveness of Cell-Wall material from grape pomace as fining agent for red wines

Lately several works highlighted the capacity of grape cell-wall material (CWM) to interact with proanthocyanidins (PA), indicating its potential use as fining agent for red wines.1–4 However, those studies were performed by using purified PAs and very high doses of CWM (almost ten-fold higher than those used in wine industry for other commercial fining agents). The present study focuses on the applicability of CWM from Cabernet sauvignon pomace as fining agent for red wines under real winery conditions. Grapes of cultivar Cabernet sauvignon were harvested at three different maturity levels
(unripe, mature, and overripe) and used for red winemaking. The pomace of such vinifications were used as source of CWM, and applied into red wines at two different concentrations: 0.2 g/L and 2.5 g/L.