Login / Signup

Hydraulic integrity of plant organs during drought stress and drought recovery in herbaceous and woody plant species.

Annika E HuberPeter J MelcherTaryn L Bauerle
Published in: Journal of experimental botany (2022)
The relationship between root, stem, and leaf hydraulic status and stomatal conductance during drought (Field capacities: 100-25%) and drought recovery was studied in Helianthus annuus, and five tree species (Populus x canadensis, Acer saccharum, A. saccharinum, Picea glauca, and Tsuga canadensis). Measurements of stomatal conductance (gs), organ water potential and vessel embolism were performed and the following was observed: 1. Cavitation only occurred in the petioles and not the roots or stems of tree species regardless of drought stress; 2. In contrast, all H. annuus organs exhibited cavitation to an increasing degree from root to petiole; and 3. All species initiated stomatal closure before cavitation events occurred or expected turgor loss point was reached. After rewatering: 1. Cavitated vessels in petioles of Acer species recovered whereas those of P. x canadensis did not and leaves were shed; 2. In H. annuus cavitated xylem vessels were refilled in roots and petioles, but not in stems; and 3. Despite refilled embolisms in petioles of some species during drought recovery, gs never returned to pre-drought conditions. Conclusions are drawn with respect to the hydraulic segmentation hypothesis for above and below-ground organs, and the timeline of embolism occurrence and repair is discussed.
Keyphrases
  • climate change
  • arabidopsis thaliana
  • heat stress
  • plant growth
  • genetic diversity
  • magnetic resonance
  • machine learning