New Fungus-Resistant Grapevine Vitis and V. vinifera L. × M. rotundifolia Derivative Hybrids Display a Drought-Independent Response in Thiol Precursor Levels.

The use of new disease-resistant grapevine varieties is a long-term but promising solution to reduce chemical inputs in viticulture. However, little is known about water deficit effects on these varieties, notably regarding berry composition. The aim of this study was to characterize the primary metabolites and thiol precursors levels of 6 fungi-resistant varieties and Syrah. Vines were grown under field conditions and under different water supply levels, and harvested at the phloem unloading arrest. A great variability among varieties regarding the levels of thiol precursors was observed, with the highest concentration, of 539 µg/kg, being observed in 3176-N, a hybrid displaying red fruits. Water deficit negatively and equally impacted the accumulation of sugars, organic acids, and thiol precursors per berry and per plant, with minor effects on their concentration. The observed losses of metabolites per cultivation area suggest that water deficits can lead to significant economic losses for the producer.

Unravelling copper effect on the production of varietal thiols during Colombard and Gros Manseng grape juices fermentation by Saccharomyces cerevisiae.

Nowadays the rapidly increasing organic vineyard management with the utilization of copper as sole fungal control pesticide against downy mildew raises once again the question of copper impact on varietal thiols in wine. For this purpose, Colombard and Gros Manseng grape juices were fermented under different copper levels (from 0.2 to 3.88 mg/l) to mimic the consequences in must of organic practices. The consumption of thiol precursors and the release of varietal thiols (both free and oxidized forms of 3-sulfanylhexanol and 3-sulfanylhexyl acetate) were monitored by LC-MS/MS. It was found that the highest copper level (3.6 and 3.88 mg/l for Colombard and Gros Manseng respectively) significantly increased yeast consumption of precursors (by 9.0 and 7.6% for Colombard and Gros Manseng respectively). For both grape varieties, free thiol content in wine significantly decreased (by 84 and 47% for Colombard and Gros Manseng respectively) with the increase of copper in the starting must as already described in the literature. However, the total thiol content produced throughout fermentation was constant regardless of copper conditions for the Colombard must, meaning that the effect of copper was only oxidative for this variety. Meanwhile, in Gros Manseng fermentation, the total thiol content increased along with copper content, resulting in an increase up to 90%; this suggests that copper may modify the regulation of the production pathways of varietal thiols, also underlining the key role of oxidation. These results complement our knowledge on copper effect during thiol-oriented fermentation and the importance of considering the total thiol production (reduced+oxidized) to better understand the effect of studied parameters and differenciate chemical from biological effects.

New Light on the Varietal Thiols Pathway during Alcoholic Fermentation: Role of 3-S-(N-Acetyl-cysteinyl)-hexan-1-ol (NAC3SH).

For many years, knowledge on thiol precursors has been limited to S-conjugates of glutathione (G3SH), cysteine (Cys3SH), and later on the dipeptides γ-GluCys and CysGly. In this work, we took the parallel between precursor degradation and the glutathione-mediated detoxification pathway a step further by considering a new type of derivative, 3-S-(N-acetyl-l-cysteinyl)hexanol (NAC3SH). This compound was synthesized and then added to the existing liquid chromatography with tandem mass spectrometry (LC-MS/MS) method of thiol precursors. This intermediate was only identified during alcoholic fermentation in synthetic must spiked with G3SH (1 mg/L or 2.45 µmol/L) in the presence of copper with concentration above 1.25 mg/L, which demonstrates for the first time the existence of this new derivative (until 126 µg/L or 0.48 µmol/L) and the capacity of the yeast to produce such a compound. Its status as a precursor was also studied during fermentation, in which a release of 3-sulfanylhexanol was noted corresponding to a conversion yield close to 0.6%. This work completed the thiol precursor's degradation pathway in Saccharomyces cerevisiae in synthetic conditions with a new intermediate, confirming its connection with the xenobiotic detoxification pathway and giving new insights on the precursor's fate.