<i>Vitis vinifera</i> berry metabolic composition during maturation: Implications of defoliation

Rossouw, Gerhard; Šuklje, Katja; Smith, Jason; Barril, Célia; Deloire, Alain; Holzapfel, Bruno

doi:10.1111/ppl.12715

Cited by 16 publications

(5 citation statements)

References 42 publications

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“…Reductions in shoot weight are accentuated by long-term water deficit [6]. Thus, water deficit has a cumulative effect, probably due to reduced starch and sucrose accumulation in the perennial organs [65][66][67]. This is important since the sugars accumulated in the trunk and roots are the first carbohydrates to be used during the following spring's growth.…”

Section: Effects Of Vine Water Status On Vegetative Growthmentioning

confidence: 99%

Effects of Vine Water Status on Yield Components, Vegetative Response and Must and Wine Composition

Baeza¹,

Junquera²,

Peiro³

et al. 2019

Advances in Grape and Wine Biotechnology

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Despite Vitis vinifera L. is a drought-tolerant species-rainfed traditionally grown in a very diversity of climates-irrigation has more and more become a usual practice aimed to obtain regular yields along seasons and to control must composition. Results on vineyard irrigation are dependent on the timing, length and intensity of the water deficit. From budbreak to flowering, shoot growth is very sensitive to water stress, while reproductive growth is almost unaffected. Severe water deficit during fruit set can reduce yield by affecting ovary cell multiplication and expansion. During maturation water stress induces yield reduction by limiting berry growth; along this phase must composition is also affected. There is a positive, linear relationship between must sugar content and available water; however, no relationship has been found to either total acidity or pH. Biosynthesis of anthocyanins and fruity aromas is enhanced by water deficit. Usually, wines from moderate irrigation treatments scored the highest. There is a general agreement that severe, long water deficits diminish must quality, leaf area, fertility and yield, and it has a negative carryover effect on the next seasons by limiting wood reserves to be used the following seasons.

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Section: Effects Of Vine Water Status On Vegetative Growthmentioning

confidence: 99%

Effects of Vine Water Status on Yield Components, Vegetative Response and Must and Wine Composition

Baeza¹,

Junquera²,

Peiro³

et al. 2019

Advances in Grape and Wine Biotechnology

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“…The impact of leaf senescence on berry YAN is further indicated by the parallel timing between the respective beginning of leaf senescence (and thus the N remobilisation from the leaf) and the increase of the FAN value in the berries in both the senescence treatments. No causal relationship, however, can be proven from the parallel timing in the data alone; a rearrangement of reserves as the cause of the N increase in the berry as described by Rossouw et al (2018) is also conceivable. However, as the main reserve bodies (roots, stem) also show an increase in N concentration between veraison and harvest (Verdenal et al 2021), they generally appear to be N sinks rather than N sources during this stage.…”

Section: Discussionmentioning

confidence: 99%

Ethephon‐induced leaf senescence increases the concentration of yeast‐assimilable nitrogen in grape must (Vitis viniferacv. Riesling)

Hendgen

Schubert

Löhnertz

2021

Aust J Grape and Wine Res

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Background and Aims Leaf senescence induces a massive shift of the nitrogen (N) allocation within plants, but its influence on the storage of yeast‐assimilable N (YAN) in grapevine berries is unclear. The aim of this work was to investigate whether the YAN concentration in grape must can be increased by a targeted induction of leaf senescence. Methods and Results Leaf senescence was induced in two consecutive seasons by an ethephon treatment of grapevines (Vitis vinifera cv. Riesling) before harvest, and its effect on the amino acid and ammonium balance of berries and must, as well as on alcoholic fermentation performance was investigated. The ethephon‐induced senescence caused a significant increase in YAN concentration in berries and must, based on a general increase in most amino acids. Compared to natural senescence, the ethephon treatment led to a lower proline : arginine ratio, a lower sugar concentration in the must and a lower grape yield. Conclusions Ethephon‐induced leaf senescence enhances the nutritional value of grapes and improves the fermentability of grape must. Significance of the Study Our results enable wine producers to improve the nitrogen use efficiency of vines and to ensure a balanced N nutrition of the yeast.

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“…4 Additionally, vine growth, berry sugar accumulation, and anthocyanin biosynthesis are influenced by carbon concentrations. 8,13,14 Various important chemical reactions are affected by the hydrogen content, including respiration and carbohydrate accumulation. Furthermore, hydrogen is involved in the formation of multiple compounds, such as sugars, starch, amino acids, and organic acids.…”

Section: Introductionmentioning

confidence: 99%

Exploration of Global and Specialized Near-Infrared Calibrations for the Quantification of Nutritional Content in Grapevine Organs, Berry Phenological Stages, and Shoot Lignification

van Wyngaard,

Blancquaert,

Nieuwoudt

et al. 2024

Appl Spectrosc

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Current infrared spectroscopy applications in the field of viticulture are moving toward direct in-field measuring techniques. However, limited research is available on quantitative applications using direct measurement of fresh tissue. The few studies conducted have combined the spectral data from various cultivars, growing regions, grapevine organs, and phenological stages during model development. The spectral data from these heterogeneous samples are combined into a single data set and analyzed jointly during quantitative analysis. Combining the spectral information of these diverse samples into a global data set could be an unsuitable approach and could yield less accurate prediction results. Spectral differences among samples could be overlooked during model development and quantitative analysis. The development of specialized calibrations should be considered and could lead to more accurate quantitative analyses. This study explored a model optimization strategy attempting global and specialized calibrations. Global calibrations, containing data from multiple organs, berry phenological, and shoot lignification stages, were compared to specialized calibrations per organ or stage. The global calibration for organs contained data from shoots, leaves, and berries and produced moderately accurate prediction results for nitrogen, carbon, and hydrogen. The specialized calibrations per organ yielded more accurate calibrations with a coefficient of determination in validation (R2val) at 90.65% and a root mean square error of prediction (RMSEP) at 0.32% dry matter (DM) for the berries’ carbon calibrations. The leaves and shoots carbon calibrations had R2val and RMSEP at 84.99%, 0.34% DM, and 90.06%, 0.37% DM, respectively. The specialized calibrations for nitrogen and hydrogen showed similar improvements in prediction accuracy per organ. Specialized calibrations per phenological and lignification stage were also explored. Not all stages showed improvement, however, most stages had comparable or improved results for the specialized calibrations compared to the global calibrations containing all phenological or lignification stages. The results indicated that both global and specialized calibrations should be considered during model development to optimize prediction accuracy.

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Vitis vinifera berry metabolic composition during maturation: Implications of defoliation

Cited by 16 publications

References 42 publications

Effects of Vine Water Status on Yield Components, Vegetative Response and Must and Wine Composition

Effects of Vine Water Status on Yield Components, Vegetative Response and Must and Wine Composition

Ethephon‐induced leaf senescence increases the concentration of yeast‐assimilable nitrogen in grape must (Vitis viniferacv. Riesling)

Exploration of Global and Specialized Near-Infrared Calibrations for the Quantification of Nutritional Content in Grapevine Organs, Berry Phenological Stages, and Shoot Lignification

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