Extreme undersaturation in the intercellular airspace of leaves: a failure of Gaastra or Ohm?

Rockwell, Fulton E.; Holbrook, N. Michèle; Jain, Piyush; Huber, Annika E; Sen, Sabyasachi; Stroock, Abraham D.

doi:10.1093/aob/mcac094

Cited by 14 publications

(5 citation statements)

References 58 publications

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“…Conversely, if airspace unsaturation or guard cell water relations is of particular interest, then we would like to know the conductance all the way to airspace and the guard cells. Technological advances enabling quantification of Ψ in vivo at leaf level, using intercellular gel sensors (Jain et al ., 2021; Rockwell et al ., 2022), or at the cellular level, using intracellular protein biosensors (Cuevas‐Velazquez et al ., 2021) may soon enable estimation of K ox dynamics according to both definitions.…”

Section: Benefits Of a Dynamic Koxmentioning

confidence: 99%

The dynamic multi‐functionality of leaf water transport outside the xylem

et al. 2023

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SummaryA surge of papers have reported low leaf vulnerability to xylem embolism during drought. Here, we focus on the less studied, and more sensitive, outside‐xylem leaf hydraulic responses to multiple internal and external conditions. Studies of 34 species have resolved substantial vulnerability to dehydration of the outside‐xylem pathways, and studies of leaf hydraulic responses to light also implicate dynamic outside‐xylem responses. Detailed experiments suggest these dynamic responses arise at least in part from strong control of radial water movement across the vein bundle sheath. While leaf xylem vulnerability may influence leaf and plant survival during extreme drought, outside‐xylem dynamic responses are important for the control and resilience of water transport and leaf water status for gas exchange and growth.

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Section: Benefits Of a Dynamic Koxmentioning

confidence: 99%

The dynamic multi‐functionality of leaf water transport outside the xylem

et al. 2023

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“…As with all methods of measuring K leaf or K s‐l (which encompasses K leaf ), our approach assumes a consistent gradient in Ψ across the mesophyll. Some authors have suggested that under extreme conditions, the Ψ gradient within the leaf may become very steep near the end of the flow path for liquid water (Cernusak et al ., 2018; Rockwell et al ., 2022; Wong et al ., 2022), and this would be partially hidden if only a small proportion of mesophyll cells were affected. The conditions used here did not include the extreme transpiration rates where unsaturated mesophyll humidity has been reported, but this might be an interesting focus for future work.…”

Section: Discussionmentioning

confidence: 99%

Stomatal response to VPD is not triggered by changes in soil–leaf hydraulic conductance in Arabidopsis or Callitris

Bourbia,

Brodribb

2024

New Phytologist

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Summary Stomatal closure under high VPDL (leaf to air vapour pressure deficit) is a primary means by which plants prevent large excursions in transpiration rate and leaf water potential (Ψleaf) that could lead to tissue damage. Yet, the drivers of this response remain controversial. Changes in Ψleaf appear to drive stomatal VPDL response, but many argue that dynamic changes in soil‐to‐leaf hydraulic conductance (Ks‐l) make an important contribution to this response pathway, even in well‐hydrated soils. Here, we examined whether the regulation of whole plant stomatal conductance (gc) in response to typical changes in daytime VPDL is influenced by dynamic changes in Ks‐l. We use well‐watered plants of two species with contrasting ecological and physiological features: the herbaceous Arabidopsis thaliana (ecotype Columbia‐0) and the dry forest conifer Callitris rhomboidea. The dynamics of Ks‐l and gc were continuously monitored by combining concurrent in situ measurements of Ψleaf using an open optical dendrometer and whole plant transpiration using a balance. Large changes in VPDL were imposed to induce stomatal closure and observe the impact on Ks‐l. In both species, gc was observed to decline substantially as VPDL increased, while Ks‐l remained stable. Our finding suggests that stomatal regulation of transpiration is not contingent on a decrease in Ks‐l. Static Ks‐l provides a much simpler explanation for transpiration control in hydrated plants and enables simplified modelling and new methods for monitoring plant water use in the field.

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“…However, it has been shown that under high ASD, patchiness (Mott & Buckley, 2000), or unsaturation may occur (Cernusak et al ., 2018), and the mixture of adaxial and abaxial fluxes might mask the occurrence of both. The failure of one or both of these assumptions compromizes the validity of the results, making their identification crucial (Rockwell et al ., 2022). The measurements presented in Fig.…”

Section: Discussionmentioning

confidence: 99%

Assessing the CO₂ concentration at the surface of photosynthetic mesophyll cells

et al. 2023

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We present a robust estimation of the CO 2 concentration at the surface of photosynthetic mesophyll cells (c w ), applicable under reasonable assumptions of assimilation distribution within the leaf. We used Capsicum annuum, Helianthus annuus and Gossypium hirsutumas model plants for our experiments.We introduce calculations to estimate c w using independent adaxial and abaxial gas exchange measurements, and accounting for the mesophyll airspace resistances.The c w was lower than adaxial and abaxial estimated intercellular CO 2 concentrations (c i ). Differences between c w and the c i of each surface were usually larger than 10 μmol mol −1 . Differences between adaxial and abaxial c i ranged from a few μmol mol −1 to almost 50 μmol mol −1 , where the largest differences were found at high air saturation deficits (ASD). Differences between adaxial and abaxial c i and the c i estimated by mixing both fluxes ranged from −30 to +20 μmol mol −1 , where the largest differences were found under high ASD or high ambient CO 2 concentrations.Accounting for c w improves the information that can be extracted from gas exchange experiments, allowing a more detailed description of the CO 2 and water vapor gradients within the leaf.

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Extreme undersaturation in the intercellular airspace of leaves: a failure of Gaastra or Ohm?

Cited by 14 publications

References 58 publications

The dynamic multi‐functionality of leaf water transport outside the xylem

The dynamic multi‐functionality of leaf water transport outside the xylem

Stomatal response to VPD is not triggered by changes in soil–leaf hydraulic conductance in Arabidopsis or Callitris

Assessing the CO₂ concentration at the surface of photosynthetic mesophyll cells

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Extreme undersaturation in the intercellular airspace of leaves: a failure of Gaastra or Ohm?

Cited by 14 publications

References 58 publications

The dynamic multi‐functionality of leaf water transport outside the xylem

The dynamic multi‐functionality of leaf water transport outside the xylem

Stomatal response to VPD is not triggered by changes in soil–leaf hydraulic conductance in Arabidopsis or Callitris

Assessing the CO2 concentration at the surface of photosynthetic mesophyll cells

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Product

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Assessing the CO₂ concentration at the surface of photosynthetic mesophyll cells