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Ibrahim Bourbia
University of Tasmania
Research interests: Plant water relations, drought stress, xylem vulnerability, In-situ monitoring of plant gas exchange and water stress, soil-plant water transport dynamics
Poster Number / Talk Time

9

Abstract:

Xylem cavitation isolates leaky flowers during water stress in pyrethrum

IBRAHIM BOURBIA, MADELINE CARINS-MURPHY, ALISTAIR GRACIE, TIMOTHY BRODRIBB

School of Natural Sciences, University of Tasmania, Private Bag 55, Hobart, Tas., 7001 Australia

Flowers underpin plant evolution, genetic legacy and global food supply. They are exposed to similar evaporative conditions as leaves, yet floral physiology is a product of different selective forces. We used Tanacetum cinerariifolium, a perennial daisy, to examine the response of flowers to whole-plant water stress, determining if flowers constitute a liability during drought, and how this species has adapted to minimize risk associated with reproduction. We determined the relative transpiration cost of flowers and leaves and confirmed that flowers in this species are xylem-hydrated. The relative water stress tolerance of leaves and flowers then was compared using xylem vulnerability measurements linked with observed tissue damage during an acute drought treatment. Flowers were a major source of water loss during drought but the xylem supplying them was much more vulnerable to cavitation than leaves. This xylem vulnerability segmentation was confirmed by observations that most flowers died whereas leaves were minimally affected during drought. Early cavitation and hydraulic isolation of flowers during drought benefits the plant by slowing the dehydration of perennial vegetative organs and delaying systemic xylem damage. Our results highlight the need to understand flower xylem vulnerability as a means of predicting plant reproductive failure under future drought.