 IVES 9 IVES Conference Series 9 Long-Term impact of elevated CO2 exposure on grapevine physiology (Vitis vinifera L. cvs. Riesling & Cabernet Sauvignon)

Long-Term impact of elevated CO2 exposure on grapevine physiology (Vitis vinifera L. cvs. Riesling & Cabernet Sauvignon)

Abstract

Over the next 25 years, the Intergovernmental Panel on Climate Change (IPCC 2013) predicts a ~20% increase in atmospheric carbon dioxide (CO₂) concentration compared to the current level. Concurrently, temperatures are steadily rising. Grapevines, known for their climate sensitivity, will show changes in phenology, physiological processes and grape compositions in response. Investigating eco-physiological processes provides insights into the response of field-grown grapevines to elevated CO₂ conditions. A Free Air Carbon Dioxide Enrichment (FACE) facility was established in the Rheingau region of Germany. Two grapevine varieties (Vitis vinifera L., cvs. Riesling and Cabernet Sauvignon) were planted, with the VineyardFACE comprising three rings with ambient atmospheric CO₂(approx. 400 – 420 ppm from 2014 to 2023, aCO₂) and three rings with elevated CO₂concentration (+20% to ambient; eCO₂). Abaxial leaf imprints revealing that both varieties reached their highest stomatal density in the early years of the study. Riesling leaves exhibited a higher density compared to Cabernet Sauvignon. In a warmer year like 2020, both varieties responded with a lower density. With continuously exposition to eCO₂ the differences in stomatal conductance became increasingly negligible. The net photosynthesis of both varieties peaked in the later and warmer period of the study (2018 – 2022), with plants under elevated CO₂ concentration achieving significantly higher assimilation rates. Accompanying this, plants under aCO₂ conditions exhibited a higher non-photochemical quenching, whereas electron transport rate and photochemical quenching under eCO₂ conditions were higher. Long-term studies are necessary to estimate the consequences for growers in the future.

Download the abstract

DOI:

Publication date: June 13, 2024

Issue: Open GPB 2024

Type: Article

Authors

Susanne Tittmann^*, Lilian Schmidt, Manfred Stoll

University Geisenheim, Department of general and organic viticulture, Von-Lade-Str. 1, D-65366 Geisenheim, Germany

Contact the author*

Keywords

climate change, viticulture, grapevine physiology, elevated CO₂ concentration, FACE facility

Citation

Fingerprinting the origin of rosé wines with a new high throughput polyphenomics method

Wine is a widely consumed alcoholic beverage with a high commercial value. More specifically, the worldwide consumption of rosé wine has increased by 20% since 2002[1]. But because of its high commercial value, it can become a subject of fraud, and authenticity control is necessarily required. More than one hundred polyphenols have been recently quantified in various rosé wines [2]. They are key components defining color, taste and quality of wines. Their amount and composition depend on many different factors such as grape variety, winemaking and age of the wine. In this study, the influence of geographic origin of some rosé French wines was investigated. An original and very fast UPLC-QTOF-MS method was developed and used to predict the geographic origin authenticity of rosé wines.

On quality assurance of winemaking components

This report examines product quality assurance issues arising when technological aids and food additives are utilized in winemaking.

Mapping of canopy features in commercial vineyards using machine vision

Vineyard canopy features such canopy porosity and fruit exposure influenced microclimate, fungal disease incidence and grape composition. An objective, rapid and non-invasive method to assess and map the canopy status is needed to apply in precision viticulture. A new method for canopy status assessment and mapping based on non-invasive machine vision was applied in commercial vineyards in this work.

Exploring the inner secrets of grapevine: a journey through plant-microbe interactions

Throughout centuries of anthropocentric breeding, plants have been selectively bred to enhance their quality traits and yield, often overlooking the importance of neglected attributes, like those involved in the interactions with beneficial microorganisms. This phenomenon led to an alteration in the distribution of photosynthetic products, shifting from defence mechanisms to growth, commonly described as ‘domestication syndrome’. Addressing the losses stemming from this condition is imperative just as unravelling the concealed communication between grapevines and beneficial microorganisms.

Harnessing biodiversity to improve grapevine rootstock adaptation to drought

Drought is one of the most challenging threats for viticulture because of its impact on reducing yield and on the composition of grapes.

Long-Term impact of elevated CO2 exposure on grapevine physiology (Vitis vinifera L. cvs. Riesling & Cabernet Sauvignon)

Abstract

Authors

Contact the author*

Keywords

Tags

Citation

Related articles…

Fingerprinting the origin of rosé wines with a new high throughput polyphenomics method

On quality assurance of winemaking components

Mapping of canopy features in commercial vineyards using machine vision

Exploring the inner secrets of grapevine: a journey through plant-microbe interactions

Harnessing biodiversity to improve grapevine rootstock adaptation to drought

Links

Newsletter

Contact Information

Follow us