Water relations in tree physiology: where to from here?

We look back over 50 years of research into the water relations of trees, with the objective of assessing the maturity of the topic in terms of the idea of a paradigm, put forward by Kuhn in 1962. Our brief review indicates that the physical processes underlying the calculation of transpiration are well understood and accepted, and knowledge of those processes can be applied if information about the leaf area of trees, and stomatal conductance, is available. Considerable progress has been made in understanding the factors governing stomatal responses to environment, with insights into how the hydraulic conducting system of trees determines the maximum aperture of stomata. Knowledge about the maximum stomatal conductance values likely to be reached by different species, and recognition that stomatal responses to increasing atmospheric vapor pressure deficits are in fact responses to water loss from leaves, provides the basis for linking these responses to information about hydraulic conductance through soil–root–stem–branch systems. Improved understanding in these areas is being incorporated into modern models of stomatal conductance and responses to environmental conditions. There have been significant advances in understanding hydraulic pathways, including cavitation and its implications. A few studies suggest that the major resistances to water flux within trees are not in the stem but in the branches. This insight may have implications for productivity: it may be advantageous to select trees with the genetic propensity to produce short branches in stands with open canopies. Studies on the storage of water in stems have provided improved understanding of fluxes from sapwood at different levels. Water stored in the stems of large trees may provide up to 20–30% daily sap flow, but this water is likely to be replaced by inflows at night. In dry conditions transpiration by large trees may be maintained from stored water for up to a week, but flows from storage may be more important in refilling cavitated xylem elements and hence ensuring that the overall hydraulic conductivity of stems is not reduced. Hydraulic redistribution of water in the soil may make a contribution to facilitating root growth in dry soils and modifying resource availability. We conclude that the field of tree water relations is mature, in the sense that the concepts underlying models describing processes and system responses to change are well-tested and accepted and there are few, if any, serious anomalies emerging. Models are essentially formal statements about the way we think systems work. They are always subject to further testing, refinement and improvements. Gaps in knowledge appear within the framework of accepted concepts and mechanisms research is needed to fill those gaps. The models currently available can be used to scale estimates of transpiration from leaf to landscape levels and predict species responses to drought. The focus in tree water relations has shifted to examine the climatic thresholds at which drought, high temperatures and vapor pressure deficits cause mortality. Tree death may be caused by hydraulic collapse following irreversible cavitation or extremely low water potentials, but recent research indicates that the relative sensitivity of stomatal conductance and whole-plant hydraulic conductance plays a major role in determining plant responses to drought.

[1]  R. Oren,et al.  Responses of sap flux and stomatal conductance of Pinus taeda L. trees to stepwise reductions in leaf area , 1998 .

[2]  Frederick R. Adler,et al.  Limitation of plant water use by rhizosphere and xylem conductance: results from a model , 1998 .

[3]  S. Running,et al.  Physiological control of water flux in conifers , 1975, Oecologia.

[4]  D. Eamus,et al.  Seasonal changes in hydraulic conductance, xylem embolism and leaf area in Eucalyptus tetrodonta and Eucalyptus miniata saplings in a north Australian savanna , 2000 .

[5]  Richard H. Waring,et al.  Characteristics of Trees Predisposed to Die , 1987 .

[6]  T. Kira,et al.  A QUANTITATIVE ANALYSIS OF PLANT FORM-THE PIPE MODEL THEORY : II. FURTHER EVIDENCE OF THE THEORY AND ITS APPLICATION IN FOREST ECOLOGY , 1964 .

[7]  Nathan Phillips,et al.  Tree water storage and its diurnal dynamics related to sap flow and changes in stem volume in old-growth Douglas-fir trees. , 2007, Tree physiology.

[8]  Julian A. Licata,et al.  Time series diagnosis of tree hydraulic characteristics. , 2004, Tree physiology.

[9]  G. Goldstein,et al.  Hydraulic Capacitance: Biophysics and Functional Significance of Internal Water Sources in Relation to Tree Size , 2011 .

[10]  E. Schulze,et al.  Water and Plant Life , 1976, Ecological Studies.

[11]  F. Crick,et al.  Molecular Structure of Nucleic Acids: A Structure for Deoxyribose Nucleic Acid , 1953, Nature.

[12]  M. Adams,et al.  The redistribution of soil water by tree root systems , 1998, Oecologia.

[13]  T. Hinckley,et al.  CHAPTER 3 – TEMPERATE HARDWOOD FORESTS , 1981 .

[14]  H. L. Penman Natural evaporation from open water, bare soil and grass , 1948, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[15]  F. Tardieu Will Increases in Our Understanding of Soil-Root Relations and Root Signalling Substantially Alter Water Flux Models? , 1993 .

[16]  D. Eamus,et al.  Seasonal Changes in Leaf Water Characteristics of Eucalyptus tetrodonta and Terminalia ferdinandiana Saplings in a Northern Australian Savanna , 1999 .

[17]  D. Whitehead CHAPTER 2 – CONIFEROUS FORESTS AND PLANTATIONS , 1981 .

[18]  Richard H. Waring,et al.  Sapwood water storage: its contribution to transpiration and effect upon water conductance through the stems of old‐growth Douglas‐fir , 1978 .

[19]  Chengquan Huang,et al.  Forest disturbance across the conterminous United States from 1985-2012: The emerging dominance of forest decline , 2016 .

[20]  M. Adams,et al.  Water availability and branch length determine δ13C in foliage of Pinus pinaster , 2000 .

[21]  M. G. Ryan,et al.  Hydraulic Limits to Tree Height and Tree Growth , 1997 .

[22]  R. Waring,et al.  Plant Moisture Stress: Evaluation by Pressure Bomb , 1967, Science.

[23]  J. Landsberg CHAPTER 6 – APPLE ORCHARDS , 1981 .

[24]  N. McDowell,et al.  The mechanisms of carbon starvation: how, when, or does it even occur at all? , 2010, The New phytologist.

[25]  James W. Jones,et al.  Dynamic concepts in biology. , 1969 .

[26]  D. Whitehead The Estimation of Foliage Area from Sapwood Basal Area in Scots Pine , 1978 .

[27]  Paolo De Angelis,et al.  Reconciling the optimal and empirical approaches to modelling stomatal conductance , 2011 .

[28]  Ray Leuning,et al.  A coupled model of stomatal conductance, photosynthesis and transpiration , 2003 .

[29]  F. Stuart Chapin,et al.  Plant Water Relations , 2008 .

[30]  Physiology Passioura,et al.  Accountability, Philosophy and Plant , 1979 .

[31]  George W. Koch,et al.  The limits to tree height , 2004, Nature.

[32]  P. Jerie,et al.  Ethylene as a Growth Hormone in Peach Fruit. , 1976 .

[33]  R. Zimmermann,et al.  Canopy transpiration and water fluxes in the xylem of the trunk of Larix and Picea trees — a comparison of xylem flow, porometer and cuvette measurements , 1985, Oecologia.

[34]  Nathan Phillips,et al.  Survey and synthesis of intra‐ and interspecific variation in stomatal sensitivity to vapour pressure deficit , 1999 .

[35]  Kathy Steppe,et al.  Responses of tree species to heat waves and extreme heat events. , 2015, Plant, cell & environment.

[36]  John L. Monteith,et al.  A reinterpretation of stomatal responses to humidity , 1995 .

[37]  R. Bergström,et al.  Ungulates as drivers of tree population dynamics at module and genet levels , 2003 .

[38]  F. Meinzer,et al.  Stomatal and hydraulic conductance in growing sugarcane: stomatal adjustment to water transport capacity* , 1990 .

[39]  I. R. Cowan,et al.  Stomatal function in relation to leaf metabolism and environment. , 1977, Symposia of the Society for Experimental Biology.

[40]  N. McDowell,et al.  Mechanisms of plant survival and mortality during drought: why do some plants survive while others succumb to drought? , 2008, The New phytologist.

[41]  Arana,et al.  Progress in Photosynthesis Research , 1987, Springer Netherlands.

[42]  J. Stewart Measurement and prediction of evaporation from forested and agricultural catchments , 1984 .

[43]  D. Eamus,et al.  Convergence in hydraulic architecture, water relations and primary productivity amongst habitats and across seasons in Sydney. , 2004, Functional plant biology : FPB.

[44]  N. Breda,et al.  Temperate forest trees and stands under severe drought: a review of ecophysiological responses, adaptation processes and long-term consequences , 2006 .

[45]  Y. Malhi,et al.  Death from drought in tropical forests is triggered by hydraulics not carbon starvation , 2015, Nature.

[46]  R. Fraser The structure of deoxyribose nucleic acid. , 2004, Journal of structural biology.

[47]  R. Waring,et al.  Generalizing plant-water relations to landscapes , 2011 .

[48]  R. Waring,et al.  Notes: Conifer Foliage Mass Related to Sapwood Area , 1974 .

[49]  Moshe Shachak,et al.  Harvester ant response to spatial and temporal heterogeneity in seed availability: pattern in the process of granivory , 2000, Oecologia.

[50]  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.

[51]  E. Schulze,et al.  Leaf nitrogen, photosynthesis, conductance and transpiration : scaling from leaves to canopies , 1995 .

[52]  Joe Landsberg,et al.  Chapter 8 - Modelling Tree Growth: Concepts and Review , 2011 .

[53]  François Tardieu,et al.  Variability among species of stomatal control under fluctuating soil water status and evaporative demand: modelling isohydric and anisohydric behaviours , 1998 .

[54]  F. Meinzer,et al.  Size- and age-related changes in tree structure and function , 2011 .

[55]  Hsin-I Wu,et al.  Scaling theory to extrapolate individual tree water use to stand water use , 1995 .

[56]  K. Oleson,et al.  Modeling stomatal conductance in the earth system: linking leaf water-use efficiency and water transport along the soil–plant–atmosphere continuum , 2014 .

[57]  S. Running Environmental control of leaf water conductance in conifers , 1976 .

[58]  D. F. Parkhurst,et al.  Stomatal responses to humidity in air and helox , 1991 .

[59]  N. Buchmann,et al.  Towards an advanced assessment of the hydrological vulnerability of forests to climate change-induced drought. , 2014, The New phytologist.

[60]  N. McDowell,et al.  Larger trees suffer most during drought in forests worldwide , 2015, Nature Plants.

[61]  D. Nepstad,et al.  Amazon drought and its implications for forest flammability and tree growth: a basin‐wide analysis , 2004 .

[62]  Maurizio Mencuccini,et al.  The ecological significance of long-distance water transport: short-term regulation, long-term acclimation and the hydraulic costs of stature across plant life forms , 2003 .

[63]  P. F. Scholander,et al.  Sap Pressure in Vascular Plants , 1965, Science.

[64]  T. Dawson Hydraulic lift and water use by plants: implications for water balance, performance and plant-plant interactions , 1993, Oecologia.

[65]  Remko A. Duursma,et al.  Physiological Ecology of Forest Production: Principles, Processes and Models , 2010 .

[66]  H. Gholz Applications of Physiological Ecology to Forest Management , 1997 .

[67]  T. Kuhn,et al.  The Structure of Scientific Revolutions. , 1964 .

[68]  T. K. Spidsø,et al.  Effect of acid rain on pine needles as food for capercaillie in winter , 1993, Oecologia.

[69]  J. Monteith,et al.  Principles of Environmental Physics , 2014 .

[70]  I. E. Woodrow,et al.  A Model Predicting Stomatal Conductance and its Contribution to the Control of Photosynthesis under Different Environmental Conditions , 1987 .

[71]  J. Sperry,et al.  Influence of nutrient versus water supply on hydraulic architecture and water balance in Pinus taeda , 2000 .

[72]  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.

[73]  B. Law,et al.  Use of a simulation model and ecosystem flux data to examine carbon-water interactions in ponderosa pine. , 2001, Tree physiology.

[74]  J. Monteith Evaporation and environment. , 1965, Symposia of the Society for Experimental Biology.

[75]  M. G. Ryan,et al.  The hydraulic limitation hypothesis revisited. , 2006, Plant, cell & environment.

[76]  Theodore T. Kozlowski,et al.  Water deficits and plant growth , 1968 .

[77]  Andrea L. Bertozzi,et al.  The porous media model for the hydraulic system of a conifer tree: Linking sap flux data to transpiration rate , 2006, Ecological Modelling.

[78]  A. Granier Une nouvelle méthode pour la mesure du flux de sève brute dans le tronc des arbres , 1985 .

[79]  J. Landsberg 10 – Applications of Modern Technology and Ecophysiology to Forest Management , 1997 .

[80]  D. Ellsworth,et al.  Influence of soil porosity on water use in Pinus taeda , 2000, Oecologia.

[81]  M. Adams,et al.  Tree roots: conduits for deep recharge of soil water , 2017, Oecologia.

[82]  Richard H. Waring,et al.  The contribution of stored water to transpiration in Scots pine , 1979 .

[83]  B. Medlyn,et al.  A MAESTRO retrospective , 2004 .

[84]  R. Waring,et al.  Effects of branch length on carbon isotope discrimination in Pinus radiata. , 1996, Tree physiology.

[85]  P. Jarvis,et al.  Conducting sapwood area, foliage area, and permeability in mature trees of Piceasitchensis and Pinuscontorta , 1984 .

[86]  Joe Landsberg,et al.  Water Movement Through Plant Roots , 1978 .

[87]  F. Darwin Observations on stomata , 1898, Proceedings of the Royal Society of London.

[88]  Jehn-Yih Juang,et al.  The relationship between reference canopy conductance and simplified hydraulic architecture , 2009 .

[89]  E. Davidson,et al.  The role of deep roots in the hydrological and carbon cycles of Amazonian forests and pastures , 1994, Nature.

[90]  Richard H. Waring,et al.  Application of the pipe model theory to predict canopy leaf area. , 1982 .

[91]  S. Running,et al.  Water Uptake, Storage and Transpiration by Conifers: A Physiological Model , 1976 .

[92]  John Moncrieff,et al.  Forests at the Land–Atmosphere Interface , 2003 .

[93]  R. Oren,et al.  Water deficits and hydraulic limits to leaf water supply. , 2002, Plant, cell & environment.

[94]  Maurizio Mencuccini,et al.  Allocation, stress tolerance and carbon transport in plants: how does phloem physiology affect plant ecology? , 2015, Plant, cell & environment.

[95]  T. Kira,et al.  A QUANTITATIVE ANALYSIS OF PLANT FORM-THE PIPE MODEL THEORY : I.BASIC ANALYSES , 1964 .

[96]  B. Medlyn,et al.  MAESPA: a model to study interactions between water limitation, environmental drivers and vegetation function at tree and stand levels, with an example application to [CO 2 ] × drought interactions , 2012 .

[97]  T. Brodribb,et al.  Stem hydraulic supply is linked to leaf photosynthetic capacity: evidence from New Caledonian and Tasmanian rainforests , 2000 .

[98]  De Wit Dynamic concepts in biology , 2009 .

[99]  D. Doley CHAPTER 4 – TROPICAL AND SUBTROPICAL FORESTS AND WOODLANDS , 1981 .

[100]  S. Wofsy,et al.  Modelling the soil-plant-atmosphere continuum in a Quercus-Acer stand at Harvard Forest : the regulation of stomatal conductance by light, nitrogen and soil/plant hydraulic properties , 1996 .

[101]  Rafael Poyatos,et al.  A new look at water transport regulation in plants. , 2014, The New phytologist.