Litcius/Paper detail

The DroughtBox: A new tool for phenotyping residual branch conductance and its temperature dependence during drought

Lise M. Billon, Chris J. Blackman, Hervé Cochard, Éric Badel, Adnane Hitmi, Julien Cartailler, Romain Souchal, José Manuel Torres Ruiz

2020Plant Cell & Environment70 citationsDOI

Abstract

Abstract Xylem hydraulic failure is a major driver of tree death during drought. However, to better understand mortality risk in trees, especially during hot‐drought events, more information is required on both rates of residual water‐loss from small branches ( g res ) after stomatal closure, as well as the phase transition temperature ( T p ), beyond which g res significantly increases. Here, we describe and test a novel low‐cost tool, the DroughtBox, for phenotyping g res and T p across species. The system consists of a programmable climatically controlled chamber in which branches dehydrate and changes in the mass recorded. Test measurements show that the DroughtBox maintains stable temperature and relative humidity across a range of set points, a prerequisite for getting accurate g res and T p values. Among a study group of four conifer and one angiosperm species, we observed a range of g res (0.44–1.64 mmol H 2 O m −2 s −1 ) and T p (39.4–43.8°C) values. Furthermore, the measured time to hydraulic failure varied between two conifers species and was shortened in both species following a heatwave event. The DroughtBox is a reliable and customizable tool for phenotyping g res and T p , as well as for testing models of time to hydraulic failure that will improve our ability to assess climate change impacts on plants.

Topics & Concepts

XylemRelative humidityStomatal conductanceResidualHorticultureEnvironmental scienceClimate changeRange (aeronautics)HumidityBiologyBotanyAtmospheric sciencesEcologyMaterials scienceMathematicsMeteorologyPhysicsPhotosynthesisAlgorithmComposite materialPlant Water Relations and Carbon DynamicsTree-ring climate responsesForest ecology and management