| Literature DB >> 26574193 |
Pauline S Bouche1,2,3, Sylvain Delzon2,3, Brendan Choat4, Eric Badel5, Timothy J Brodribb6, Regis Burlett2,3, Hervé Cochard5, Katline Charra-Vaskou5, Bruno Lavigne2,3, Shan Li1, Stefan Mayr7, Hugh Morris1, José M Torres-Ruiz2,3, Vivian Zufferey8, Steven Jansen1.
Abstract
Plants can be highly segmented organisms with an independently redundant design of organs. In the context of plant hydraulics, leaves may be less embolism resistant than stems, allowing hydraulic failure to be restricted to distal organs that can be readily replaced. We quantified drought-induced embolism in needles and stems of Pinus pinaster using high-resolution computed tomography (HRCT). HRCT observations of needles were compared with the rehydration kinetics method to estimate the contribution of extra-xylary pathways to declining hydraulic conductance. High-resolution computed tomography images indicated that the pressure inducing 50% of embolized tracheids was similar between needle and stem xylem (P50 needle xylem = -3.62 MPa, P50 stem xylem = -3.88 MPa). Tracheids in both organs showed no difference in torus overlap of bordered pits. However, estimations of the pressure inducing 50% loss of hydraulic conductance at the whole needle level by the rehydration kinetics method were significantly higher (P50 needle = -1.71 MPa) than P50 needle xylem derived from HRCT. The vulnerability segmentation hypothesis appears to be valid only when considering hydraulic failure at the entire needle level, including extra-xylary pathways. Our findings suggest that native embolism in needles is limited and highlight the importance of imaging techniques for vulnerability curves.Entities:
Keywords: Conifer; direct visualization of water content; embolised tracheids; hydraulic failures; wall deformation
Mesh:
Year: 2015 PMID: 26574193 DOI: 10.1111/pce.12680
Source DB: PubMed Journal: Plant Cell Environ ISSN: 0140-7791 Impact factor: 7.228