Aromatic and polyphenolic qualities of grapes and wines

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Current changes in ecoclimatic indicators can cause significant variations in vine phenology and grape ripening. Climate change modifies various abiotic factors (e.g. temperature, solar radiation, water availability) during the vine growth cycle, having a direct impact on the phenological phases of the vine, modulating the metabolic profile of the berries and activating the synthesis and accumulation of different compounds in the skin of the grapes, with consequences on the composition of the grapes. The increase in average and extreme temperatures of the summer months, as the main consequence of climate change, as well as changes in the pattern of rainfall during the ripening phase, lead to a greater concentration of sugars and a general change in the acid profile of the grapes , but also to the modification of the profiles of secondary metabolites.

Therefore, in several viticultural areas, maturation occurs when both the color and aroma profiles can be negatively influenced, which in the wine translates into a loss of typicality and expression of the terroir. Due to climate changes, a discrepancy is also noted between the different technological, phenolic and aromatic quality parameters since they are regulated by different biosynthetic pathways and therefore are influenced differently. Significant variations observed in temperature and rainfall patterns or conditions of limited water availability and high temperatures, which are lately characterizing the second part of berry development, can cause rapid development of individual berries during the hottest part of the season, the which can negatively influence the secondary metabolites that determine the color and aroma and therefore the quality of the grapes and wine.  

Solutions

 

Radiation and temperature

  • Early exposure to light before veraison: carotenoids and flavonoids were among the compounds most affected by higher levels of radiation. The fruit environment strongly regulates the production of carotenoids and flavonoids and it has been found that early exposure has a greater impact on their concentrations than treatments performed during or after ripening.

 

  • Avoid defoliation during the high T° period:   While higher selected carotenoids, flavonoids and free aromatic compounds were observed in the defoliated treatments, the higher temperatures appear to have been detrimental to the adaptation of the berries by limiting the production of these compounds and increasing their degradation rate, which further underlines the need to carry out activities such as defoliation when temperatures are still mild.

 

  • Avoid clusters with T° in the last phase of maturation:   Previous research has indicated that microclimatic conditions, which vary depending on the vintage, the appearance of the vineyard and the vigor of the vine, can influence the timing of the peak concentration of norisoprenoid precursors while the high temperatures during the last stages of grape ripening evidently lead to a decrease in total norisoprenoids. Radiation and extremely high temperatures can have negative effects. Grapes are also subject to burns if exposed directly to the sun, negative effects especially for free terpenes,  ; in aromatic varieties, during over-ripening and possible drying, they favor the accumulation of terpenes in glycosidic form, which will be slowly released during aging. Leave a few extra leaves to protect the bunches
  •  biostimulants,  hedging products

    In a context of climate change and excessive use of agrochemicals, sustainable approaches for environmental and human health such as the use of biostimulants in viticulture represent a potential option against abiotic and biotic threats. Biostimulants are organic compounds, microbes, or a combination of both, that stimulate the vital processes of the plant, allowing for high yields and good quality products. The application of these natural compounds has effects on plant physiology, pathogen development and leads to a different expression of plant genes responsible for the activation of metabolic pathways and plant defense responses. In the vine, they can trigger an innate immune response that leads to the synthesis of secondary metabolites, key compounds for the organoleptic properties of grapes and wines. Biostimulants, therefore, can improve the aromatic parameters of grapes, but their effect is different based on the product, the frequency and timing of application, and the chemical class of the compounds involved and to the cultivar examined.

    hedging products such as kaolin can protect the berry exocarp from light stress

     

     

    can enchant  polyphenolic and/or aromatic content: Methyl Jasmonate, abscisic acid, chitosan, yeast extract

     


     

Water stress 

 

  • avoid water stress: to maintain free terpenes in the Moscato    ;maintain correct grassing under the row and in the row. In the sub-row if there is humidity  leave more grass, if there is greater drought, remove it. The plant must feed on water in a balanced way. Working the soil between the rows is another important aspect: for example to keep it soft while cutting the grass by "stirring"; in the earth so that it becomes a nutritional element
  • increased content of organic substance in the soil, and with the presence and abundance of mycorrhizae, i.e. symbiosis between the roots and some fungi, which function as an extension of the system radical or by a consortium of microorganisms

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References

Mori, K., Goto-Yamamoto, N., Kitayama, M., & Hashizume, K. (2007). Loss of anthocyanins in red wine grapes at high temperature. Journal of experimental botany 58, 1935-1945.

De Orduna, R. M. (2010). Effects associated with climate change on the quality and production of grapes and wine. Food Research International 43, 1844-1855.

van Leeuwen, C., & Darriet, P. (2016). The impact of climate change on viticulture and wine quality. Journal of Wine Economics 11, 150-167.

Asproudi, A., Petrozziello, M., Cavalletto, S., and Guidoni, S. (2016). Precursors of grape aroma in cv. Nebbiolo influenced by the microclimate of the vine. Food Chemistry 211, 947-956.

Asproudi, A., Ferrandino, A., Bonello, F., Vaudano, E., Pollon, M., and Petrozziello, M. (2018). Main norisoprenoid compounds in wines from grapes harvested early in view of climate change. Food Chemistry 268, 143-152. doi: 10.1016/j.foodchem.2018.06.069.

van Leeuwen, C., Barbe, J.-C., Darriet, P., Geffroy, O., Gomès, E., Guillaumie, S., et al. (2020). Recent advances in understanding the effect of terroir on the aromas of grapes and wines. OENO One 54, 985. doi: 10.20870/oeno-one.2020.54.4.3983.

Monteiro, E.; Gonçalves, B.; Cortez, I.; Castro, I. The role of biostimulants as relievers of biotic and abiotic stresses in grapevine: a review. Plants (2022), 11, 396

Cataldo E. Fucile M., Mattii G. B. Biostimulants in viticulture: a sustainable approach against biotic and abiotic stresses. Plant Review (2022), 11, 162. Colla G.; Rouphael, Y., Biostimulants in horticulture. Skiing. Ortico. (2015), 196, 1-134

Written by Andriani Asproudi

This is a work in progress...


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