Constant hydraulic supply and ABA dynamics facilitate the trade-offs in water and carbon
Water-use efficiency
Mechanics and Transport in Unsaturated Soils
Atmospheric Science
550
Plant Science
Stomatal conductance
drought
Horticulture
Thermal Effects on Soil
Environmental science
SB1-1110
Transpiration
abscisic acid
Engineering
stomatal regulation
Soil water
Soil Water Characteristic
Vapour Pressure Deficit
Photosynthesis
Biology
Civil and Structural Engineering
2. Zero hunger
Soil science
Global and Planetary Change
Global Forest Drought Response and Climate Change
leaf position
Causes and Impacts of Climate Change Over Millennia
Soil Water Retention
vapor pressure deficit
Canopy
Botany
Plant culture
Plant Science ; abscisic acid ; drought ; leaf age ; leaf position ; ; stomatal regulation ; vapor pressure deficit
15. Life on land
Solanum lycopersicum L.
6. Clean water
Agronomy
ddc:
Earth and Planetary Sciences
Chemistry
Soil Hydraulic Properties
Environmental Science
Physical Sciences
Edaphic
leaf age
DOI:
10.3389/fpls.2023.1140938
Publication Date:
2023-03-17T05:40:10Z
AUTHORS (5)
ABSTRACT
Carbon-water trade-offs in plants are adjusted through stomatal regulation. Stomatal opening enables carbon uptake and plant growth, whereas plants circumvent drought by closing stomata. The specific effects of leaf position and age on stomatal behavior remain largely unknown, especially under edaphic and atmospheric drought. Here, we compared stomatal conductance (gs) across the canopy of tomato during soil drying. We measured gas exchange, foliage ABA level and soil-plant hydraulics under increasing vapor pressure deficit (VPD). Our results indicate a strong effect of canopy position on stomatal behavior, especially under hydrated soil conditions and relatively low VPD. In wet soil (soil water potential > -50 kPa), upper canopy leaves had the highest gs (0.727 ± 0.154 mol m-2 s-1) and assimilation rate (A; 23.4 ± 3.9 µmol m-2 s-1) compared to the leaves at a medium height of the canopy (gs: 0.159 ± 0.060 mol m2 s-1; A: 15.9 ± 3.8 µmol m-2 s-1). Under increasing VPD (from 1.8 to 2.6 kPa), gs, A and transpiration were initially impacted by leaf position rather than leaf age. However, under high VPD (2.6 kPa), age effect outweighed position effect. The soil-leaf hydraulic conductance was similar in all leaves. Foliage ABA levels increased with rising VPD in mature leaves at medium height (217.56 ± 85 ng g-1 FW) compared to upper canopy leaves (85.36 ± 34 ng g-1 FW). Under soil drought (< -50 kPa), stomata closed in all leaves resulting in no differences in gs across the canopy. We conclude that constant hydraulic supply and ABA dynamics facilitate preferential stomatal behavior and carbon-water trade-offs across the canopy. These findings are fundamental in understanding variations within the canopy, which helps in engineering future crops, especially in the face of climate change.
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