Internal hydraulic redistribution prevents the loss of root conductivity during drought

Internal hydraulic redistribution prevents the loss of root conductivity during drought

Shrubs of the Great Basin desert in Utah are subjected to a prolonged summer drought with the potential consequence of reduced water transport capability of the xylem due to drought-induced cavitation. Hydraulic redistribution (HR) is the passive movement of water from deep to shallow soil through p...

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Bibliographic Details
Published in:Tree physiology Vol. 34; no. 1; pp. 39 - 48
Main Authors: Prieto, Iván, Ryel, Ronald J
Format: Journal Article
Language:English
Published: Canada 01-01-2014
Subjects:
Artemisia - physiology
Biological Transport
Droughts
Photosynthesis - physiology
Plant Leaves - physiology
Plant Stems - physiology
Plant Transpiration - physiology
Seasons
Soil - chemistry
Trees - physiology
Utah
Water - physiology
Xylem - physiology
Artemisia tridentata
hydraulic conductivity
Great Basin
hydraulic lift
embolism
root water transport
semi-arid systems
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Summary:Shrubs of the Great Basin desert in Utah are subjected to a prolonged summer drought with the potential consequence of reduced water transport capability of the xylem due to drought-induced cavitation. Hydraulic redistribution (HR) is the passive movement of water from deep to shallow soil through plant roots. Hydraulic redistribution can increase water availability in shallow soil and ameliorate drought stress, providing better soil and root water status, which could affect shallow root conductivity (Ks) and native root embolism. We tested this hypothesis in an Artemisia tridentata Nutt. mono-specific stand grown in a common garden in Utah. We enhanced HR artificially by applying a once a week deep-irrigation treatment increasing the water potential gradient between deep and shallow soil layers. Plants that were deep-watered had less negative water potentials and greater stomatal conductance and transpiration rates than non-watered control plants. After irrigation with labeled water (δD), xylem water in stems and shallow roots of watered shrubs was enriched with respect to control shrubs, a clear indication of deep water uptake and HR. Shallow root conductivity was threefold greater and shrubs experienced lower native embolism when deep-watered. We found clear evidence of water transfer between deep and shallow roots through internal HR that delayed depletion of shallow soil water content, maintained Ks and prevented root embolism. Overall, our results show a positive effect of HR on root water transport capacity in otherwise dry soil, with important implications for plant water status.
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ISSN:0829-318X
1758-4469
DOI:10.1093/treephys/tpt115