Grapevine cv. tempranillo grafted onto 110R and SO4 rootstocks —gas exchange parameters
Data files
Feb 27, 2025 version files 33.16 KB
Abstract
Severe water stress can lead to hydraulic disfunction, reducing plant conductance or even causing death. Some plants exhibit hydraulic vulnerability segmentation between organs to reduce this risk. However, its role in influencing drought tolerance and resistance in grafted plants, such as grapevine, remains unclear.
This study aimed to evaluate the physiological responses, drought tolerance, hydraulic vulnerability segmentation and xylem anatomy of two-year-old Vitis vinifera cv. Tempranillo scion grafted onto two rootstocks: 110-Richter (110R) and Sélection Oppenheim 4 (SO4). After subjecting the plants to drought conditions until the onset of embolism in the leaf (P12), we analysed the physiological consequences during recovery.
Grapevine exhibits hydraulic vulnerability segmentation not only within scion organs but also between the scion and rootstock. Although no differences in scion drought tolerance and embolism resistance were observed between combinations, Tempranillo-110R exhibited higher leaf minimum conductance, leaf P12 values and root biomass. In contrast, Tempranillo-SO4 displayed larger vessel diameter and higher hydraulic conductance. These differences may explain the slower recovery of Tempranillo-110R compared to Tempranillo-SO4, which showed higher stomatal and root-to-stem hydraulic conductance.
These findings suggest that rootstock selection should consider drought resilience alongside vigour and productivity, especially given the increasing the concurrence of severe drought periods due to climate change.
https://doi.org/10.5061/dryad.ht76hdrrq
Description of the data and file structure
In the second group of plants (n=6), vine water status and leaf gas exchange measurements were conducted in the plants maintained under field conditions at WW, WD, R1 and R2 stages. Predawn leaf water potential (ΨPD) and midday stem water potential (Ψstem) were measured using a pressure chamber (Model 600, PMS Instruments, USA) in fully expanded leaves. ΨPD measurements were taken before sunrise, between 05:00 and 06:00, while Ψstem measurements were conducted at solar noon on leaves that had been covered for 1 h inside a zip-lock bag with metallized high-density polyethylene reflective film (Sonoco RF, Sonoco Products Co., USA), to halt transpiration and allow the Ψleaf to equilibrate with the stem potential. Gas exchange measurements, including leaf AN, gs, and transpiration (E) were performed on sunny days in the mid-morning (09:00-11:00) using a Li-6400 gas exchange analyser (Li-cor Inc., USA) equipped with an open-top chamber in similar leaves than the ones used for Ψstem determination. From these measurements, intrinsic water use efficiency (WUEi) (Flexas et al., 2010) and hydraulic conductance from root to stem (Kroot-stem) (Tsuda and Tyree, 2000) were calculated. Briefly, it consists in calculating the hydraulic conductance between the root and the stem as the quotient of the maximum leaf transpiration (E) rate and the difference in water potential between the soil, assumed to be in equilibrium with pre-dawn water potential (ΨPD), and the stem (Ψstem) at noon.
Files and variables
File: Field_Data_.xlsx
Description:
Variables
- Photsynthesis (Photo)
- Stomatal conductance (Cond)
- Water Use Efficiency (WUE)
- Leaf transpiration (Trmmol)
- Number of leaves (Nº leaves)
- Tasa aparición hojas (Leaf growth rate)
- Predawn leaf water potential (Ypredawn)
- Stem water potential (Ystem)
- Root-to-stem hydraulic conductance (Kroot-stem)
- Plan hydraulic conductance (Kplant)
Code/software
Microsof Excel is the only software needed to view this file.