Whole-plant hydraulic resistance and vulnerability segmentation in Acer saccharinum.

Hydraulic properties were studied in Acer saccharinum L., a riparian species that also grows well on a dry soil when transplanted. Hydraulic resistances were measured by two independent techniques: a new high-pressure flowmeter (HPFM) method and a conventional evaporative flux (EF) method. Vulnerability to cavitation was also investigated on petioles, stems and roots using a hydraulic conductivity technique. Vulnerability segmentation was found, i.e., roots, stems and petioles had different vulnerabilities to xylem dysfunction. Petioles were most vulnerable with 50% loss of hydraulic conductivity at -0.5 MPa, roots were least vulnerable (50% loss at -2.2 MPa) and stems were intermediate in vulnerability. The HPFM and the EF methods gave comparable results, except that the EF method gave a significantly higher value for resistance across petioles plus leaves. Native embolism was high enough to explain the discrepancy in resistance across petioles plus leaves between the HPFM and the EF methods, indicating that the HPFM estimates the minimum (potential) hydraulic resistance of plants. Whole-plant hydraulic resistance of A. saccharinum was low compared to resistances of other temperate species. The hydraulic characteristics of A. saccharinum were consistent with adaptation to its typical environment: low whole-plant resistance assures high transpiration rates in the presence of sufficient water, and vulnerability segmentation provides the ability to survive during droughts through shedding of expendable organs.

[1]  John S. Sperry,et al.  Intra‐ and inter‐plant variation in xylem cavitation in Betula occidentalis , 1994 .

[2]  J. Sperry,et al.  Pit Membrane Degradation and Air-Embolism Formation in Ageing Xylem Vessels of Populus tremuloides Michx , 1991 .

[3]  F. Ewers,et al.  The hydraulic architecture of trees and other woody plants , 1991 .

[4]  M. Zimmermann Xylem Structure and the Ascent of Sap , 1983, Springer Series in Wood Science.

[5]  M. Tyree,et al.  A dynamic model for water flow in a single tree: evidence that models must account for hydraulic architecture. , 1988, Tree physiology.

[6]  M. Tyree,et al.  Water Relations and Hydraulic Architecture of a Tropical Tree (Schefflera morototoni) : Data, Models, and a Comparison with Two Temperate Species (Acer saccharum and Thuja occidentalis). , 1991, Plant physiology.

[7]  J. Sperry,et al.  The Effect of Reduced Hydraulic Conductance on Stomatal Conductance and Xylem Cavitation , 1993 .

[8]  N. Breda,et al.  Water transfer in a mature oak stand (Quercus petraea) : Seasonal evolution and effects of a severe drought , 1993 .

[9]  William T. Pockman,et al.  Limitation of transpiration by hydraulic conductance and xylem cavitation in Betula occidentalis , 1993 .

[10]  Melvin T. Tyree,et al.  Hydraulic architecture of Acer saccharum and A. rubrum: comparison of branches to whole trees and the contribution of leaves to hydraulic resistance , 1994 .

[11]  P. Jarvis,et al.  Vertical Gradients of Water Potential and Tissue Water Relations in Sitka Spruce Trees Measured with the Pressure Chamber , 1974 .

[12]  S. Patiño,et al.  Dynamic measurements of root hydraulic conductance using a high-pressure flowmeter in the laboratory and field , 1995 .

[13]  S. Running Field Estimates of Root and Xylem Resistances in Pinus contorta using Root Excision , 1980 .

[14]  J. Roberts The Use of Tree-cutting Techniques in the Study of the Water Relations of Mature Pinus sylvestris L. I. THE TECHNIQUE AND SURVEY OF THE RESULTS , 1977 .

[15]  S. Patiño,et al.  Vulnerability to drought-induced cavitation of riparian cottonwoods in Alberta: a possible factor in the decline of the ecosystem? , 1994, Tree physiology.

[16]  M. J. B. DAVY,et al.  Water Transport , 1947, Nature.

[17]  M. Rieger Pressure- and Transpiration-induced Flow Methods for Estimating Hydraulic Resistance in Peach , 1989, HortScience.

[18]  S. Davis,et al.  Biophysical Perspectives of Xylem Evolution: is there a Tradeoff of Hydraulic Efficiency for Vulnerability to Dysfunction? , 1994 .

[19]  M. Zimmermann Hydraulic architecture of some diffuse-porous trees , 1978 .

[20]  P. Jarvis,et al.  A dynamic model for studying flow of water in single trees. , 1986, Tree physiology.

[21]  J. Sperry,et al.  Do woody plants operate near the point of catastrophic xylem dysfunction caused by dynamic water stress? : answers from a model. , 1988, Plant physiology.

[22]  J E Begg,et al.  Water potential gradients in field tobacco. , 1970, Plant physiology.

[23]  Paul J. Kramer,et al.  Water Relations of Plants , 1983 .

[24]  N. Breda,et al.  Vulnerability to air embolism of three European oak species (Quercus petraea (Matt) Liebl, Q pubescens Willd, Q robur L) , 1992 .

[25]  Hervé Cochard,et al.  Drought‐induced leaf shedding in walnut: evidence for vulnerability segmentation , 1993 .

[26]  A. Tyree,et al.  Vulnerability of Xylem to Cavitation and Embolism , 1989 .

[27]  M. Tyree,et al.  Hydraulic resistance in Acer saccharum shoots and its influence on leaf water potential and transpiration. , 1993, Tree physiology.

[28]  M. Tyree,et al.  Novel Methods of Measuring Hydraulic Conductivity of Tree Root Systems and Interpretation Using AMAIZED (A Maize-Root Dynamic Model for Water and Solute Transport) , 1994, Plant physiology.

[29]  Melvin T. Tyree,et al.  A method for measuring hydraulic conductivity and embolism in xylem , 1988 .