Functional convergence in water use of trees from different geographical regions: a meta-analysis

详细信息    查看全文

• 作者：Jose Kallarackal (1) (2)
  Dennis O. Otieno (1)
  Bj?rn Reineking (3)
  Eun-Young Jung (1)
  Mark W. T. Schmidt (4)
  André Granier (5)
  John D. Tenhunen (1)
  
• 关键词：Sapflow density ; Transpiration ; Tree water use ; Wood density ; Water transport
• 刊名：Trees - Structure and Function
• 出版年：2013
• 出版时间：June 2013
• 年：2013
• 卷：27
• 期：3
• 页码：787-799
• 全文大小：359KB
• 参考文献：1. Alsheimer M, K?stner B, Falge E, Tenhunen JD (1998) Temporal and spatial variation in transpiration of Norway spruce stands within a forested catchment of the Fichtelgebirge, Germany. Ann des Sci For 55:103-93 CrossRef
  2. Augspurger CK (1983) Seed dispersal of the tropical tree / Platyposdium elegans and the escape of its seedlings from fungal pathogens. J Ecol 71:759-71 CrossRef
  3. Baker TR, Phillips OL, Malhi Y, Almeida S, Arroyo L, Di Fiore A, Erwin T, Killeen TJ, Laurance SG, Laurance WF, Lewis SL, Lloyd J, Monteagudo A, Neill DA, Patino S, Pitman NCA, Natalino J, Silva JNM, Va’squez Martinez R (2004) Variation in wood density determines spatial patterns in Amazonian forest biomass. Glob Change Biol 10:545-62 CrossRef
  4. Barbour MM, Whitehead D (2003) A demonstration of the theoretical prediction that sap velocity is related to wood density in the conifer / Dacrydium cupressinum. New Phytol 158:477-88 CrossRef
  5. Barbour MM, Hunt JE, Walcroft AS, Rogers GND, McSeveny TM, Whitehead D (2005) Components of ecosystem evaporation in a temperate coniferous rainforest, with canopy transpiration scaled using sapwood density. New Phytol 165:549-58 CrossRef
  6. Bernier PY, Bréda N, Granier A, Rauleir F, Mathieu F (2002) Validation of a canopy gas exchange model and derivation of a soil water modifier for transpiration for sugar maple ( / Acer saccharum Marsh.) using sap flow density measurements. Forest Ecol Manag 163:185-96 CrossRef
  7. Berry SL, Roderick ML (2005) Plant water relations and the fiber saturation point. New Phytol 168:25-7 CrossRef
  8. Borchert R (1994) Soil and stem water storage determine phenology and distribution of Dry Tropical forest trees. Ecology 75:1437-449 CrossRef
  9. Braun HJ (1970) Funktionelle Histologie der sekundaeren Sprossachse. Borntraeger, Berlin
  10. Bréda N, Cochard H, Dreyer E, Granier A (1993) Water transfer in a mature oak stand ( / Quercus petraea): seasonal evolution and effects of a severe drought. Can J Forest Res 23:1136-143 CrossRef
  11. Bucci SJ, Goldstein G, Meinzer FC, Scholz FG, Franco AC, Bustamante M (2004) Functional convergence in hydraulic architecture and water relations of tropical savanna trees: from leaf to whole plant. Tree Physiol 24:891-99 CrossRef
  12. Bucci SJ, Fabian GS, Goldstein G, Meinzer FC, Arce ME (2009) Soil water availability and rooting depth as determinants of hydraulic architecture of Patagonian woody species. Oecologia 160:631-41 CrossRef
  13. Chave J, Muller-Landau HC, Baker TR, Easdale TA, Steege H, Webb CO (2006) Regional and phylogenetic variation of wood density across 2456 Neotropical tree species. Ecol Appl 16:2356-367 CrossRef
  14. Chave J, Coomes D, Jansen S, Lewis SL, Swenson NG, Zanne AE (2009) Towards a worldwide wood economics spectrum. Ecol Lett 12:351-66
  15. Chen KZ, Zhang YH, Zhao L (2008) Analysis of least absolute deviations. Biometrika 95:107-22 CrossRef
  16. Cienciala E, Ku?era J, Malmer A (2000) Tree sap flow and stand transpiration of two / Acacia mangium plantations in Sabah, Borneo. J Hydrol 236:109-20 CrossRef
  17. Clearwater MJ, Meinzer FC, Andrade JL, Goldstein G, Holbrook NM (1999) Potential errors in measurement of nonuniform sap flow using heat dissipation probes. Tree Physiol 19:681-87 CrossRef
  18. Cornelius J (1994) Heritabilities and additive genetic coefficients of variation in forest trees. Can J Forest Res 24:372-79 CrossRef
  19. Denslow JS (1980) Gap partitioning among tropical rain forest trees. Biotropica (Suppl) 12:47-5 CrossRef
  20. Diawara A, Loustau D, Berbigier P (1991) Comparison of two methods for estimating the evaporation of a / Pinus pinaster (Ait.) stand: sap flow and energy balance with sensible heat flux measurements by an eddy covariance method. Agr Forest Meteorol 54:49-6 CrossRef
  21. Edwards WRN (1986) Precision weighing lysimetry for trees, using a simplified tared-balance design. Tree Physiol 1:127-44 CrossRef
  22. Enquist BJ, West GB, Charnov EL, Brown JH (1999) Allometric scaling of production and life history variation in vascular plants. Nature 401:907-11 CrossRef
  23. Favrichon V (1994) Classification des espèces arborées en groupes fonctionnels en vue de la réalisation d’un modèle de dynamique de peuplement en forêt Guyannaise Rev. Ecol Terre Vie 49:379-02
  24. Fearnside PM (1997) Wood density for estimating forest biomass in Brazilian Amazonia. Forest Ecol Manag 90:59-7 CrossRef
  25. Ford CR, Mcguire MA, Mitchell RJ, Teskey RO (2004) Assessing variation in the radial profile of sap flux density in / Pinus species and its effect on daily water use. Tree Physiol 24:241-49 CrossRef
  26. Giambelluca TW, Scholz FG, Bucci SJ, Meinzer FC, Goldstein G, Hoffmann WA, Franco AC, Buchert MP (2009) Evapotranspiration and energy balance of Brazilian savannas with contrasting tree density. Agric For Meteorol 149:1365-376
  27. Goldstein G, Andrade JL, Meinzer FC, Holbrook NM, Cavelier J, Jackson P, Celis A (1998) Stem water storage and diurnal patterns of water use in tropical forest canopy trees. Plant Cell Environ 21:397-06 CrossRef
  28. Gondwe BRN, Lerer S, Stisen S, Marín L, Rebolledo-Vieyra M, Merediz-Alonso G, Bauer-Gottwein P (2010) Hydrogeology of the south-eastern Yucatan Peninsula: new insights from water level measurements, geochemistry, geophysics and remote sensing. J Hydrol 389:1-7
  29. Granier A (1987) Evaluation of transpiration in a Douglas-fir stand by means of sap flow measurements. Tree Physiol 3:309-20 CrossRef
  30. Granier A, Claustres JP (1989) Relations hydriques dans un épicéa ( / Picea abies L.) en conditions naturelles : variations spatiales. Oecologia Plantarum 10:295-10
  31. Granier A, Biron P, K?stner B, Gay LW, Najjar G (1996a) Comparisons of xylem sap flow and water vapour flux at the stand level and derivation of canopy conductance for Scots pine. Theor Appl Climatol 53:115-22 CrossRef
  32. Granier A, Biron P, Bréda N, Pontailler JY, Saugier B (1996b) Transpiration of trees and forest stands: short and longterm monitoring using sapflow methods. Glob Change Biol 2:265-74 CrossRef
  33. Grattapaglia D, Bertolucci FLG, Penchel R, Sederoff RR (1996) Genetic mapping of quantitative trait loci controlling growth and wood quality traits in / Eucalyptus grandis using a maternal half-sib family and RAPD markers. Genetics 144:1205-214
  34. Hacke UG, Sperry JS (2001) Functional and ecological xylem anatomy. In: Perspectives in Plant Ecology, Evolution and Systematics, Vol 4/2, Urban & Fischer , Germany, pp 97-15
  35. Hacke UG, Sperry JS, Pittermann J (2000) Drought experience and cavitation resistance in six desert shrubs of the Great Basin, Utah. Bas. Appl Ecol 1:31-1 CrossRef
  36. Hacke UG, Sperry JS, Pockman WT, Davis SD, McCulloh KA (2001) Trends in wood density and structure are linked to prevention of xylem implosion by negative pressure. Oecologia 126:457-61 CrossRef
  37. Jacobsen AL, Pratt RB, Davis SD, Ewers FW (2008) Comparative community physiology: nonconvergence in water relations among three semi-arid shrub communities. New Phytol 180:100-13 CrossRef
  38. Jarvis PG, McNaughton KG (1986) Stomatal control of transpiration: scaling up from leaf to region. Adv Ecol Res 15:1-9 CrossRef
  39. Jordan CF, Kline JR (1977) Transpiration of trees in a tropical rainforest. J Appl Ecol 14:853-60 CrossRef
  40. Kelliher FM, K?stner BMM, Hollinger DY, Byers JN, Hunt JE, McSeveny TM, Meserth R, Weir PL, Schulze E-D (1992) Evaporation, xylem sap flow, and tree transpiration in a New Zealand broad-leaved forest. Agr Forest Meteorol 62:53-3 CrossRef
  41. Kline JR, Reed KL, Waring RH, Stewart ML (1976) Field measurement of transpiration in Douglas-fir. J Appl Ecol 13:272-83 CrossRef
  42. Koenker R (2011) Quantreg: Quantile Regression. R package version 4.76. http://CRAN.R-project.org/package=quantreg
  43. K?stner BMM, Schulze E-D, Kelliher FM, Hollinger DY, Byers JN, Hunt JE, McSeveny TM, Meserth R, Weir PL (1992) Transpiration and canopy conductance in a pristine broad-leaved forest of / Nothofagus: an analysis of xylem sap flow and eddy correlation measurements. Oecologia 91:350-59 CrossRef
  44. K?stner B, Granier A, èermák J (1998) Sapflow measurements in forest stands: methods and uncertainties. Ann Sci For 55:13-7 CrossRef
  45. K?stner B, Falge E, Tenhunen JD (2002) Age-related effects on leaf area/sapwood area relationships, canopy transpiration and carbon gain of Norway spruce stands ( / Picea abies) in the Fichtelgebirge, Germany. Tree Physiol 22:567-74 CrossRef
  46. Kubota M, Tenhunen JD, Zimmermann R, Schmidt M, Adiku S, Kakubari Y (2005) Influences of environmental factors on the radial profile of sap flux density in / Fagus crenata growing at different elevations in the Naeba Mountains, Japan. Tree Physiol 25:545-56 CrossRef
  47. Meinzer FC (2003) Functional convergence in plant responses to the environment. Oecologia 134:1-1 CrossRef
  48. Meinzer FC, Goldstein G, Andrade JL (2001) Regulation of water flux through tropical forest canopy trees: do universal rules apply? Tree Physiol 21:19-6 CrossRef
  49. Milburn JA (1996) Sap ascent in vascular plants: challengers to the cohesion theory ignore the significance of immature xylem and the recycling of Munch water. Ann Bot-London 78:399-07 CrossRef
  50. Morris J, Ningnan Z, Zengjiang Y, Collopy J, Daping X (2004) Water use by fast-growing / Eucalyptus urophylla plantations in southern China. Tree Physiol 24:1035-044 CrossRef
  51. Motzer T, Munz N, Küppers M, Schmitt D, Anhuf D (2005) Stomatal conductance, transpiration and sap flow of tropical montane rain forest trees in the southern Ecuadorian Andes. Tree Physiol 25:1283-293 CrossRef
  52. O’Brien JJ, Oberbauer SF, Clark DB (2004) Whole tree xylem sap flow responses to multiple environmental variables in a wet tropical forest. Plant Cell Environ 27:551-67 CrossRef
  53. O’Grady AP, Cook PG, Eamus D, Duguid A, Wischusen JDH, Fass T, Worldege D (2009) Convergence of tree water use within an arid-zone woodland. Oecologia 160:643-55 CrossRef
  54. Olbrich BW (1991) The verification of the heat pulse velocity technique for estimating sap flow in / Eucalyptus grandis. Can J Forest Res 21:836-41 CrossRef
  55. Otieno DO, Schmidt MWT, Kurz-Besson C, Lobo Do Vale R, Pereira JS, Tenhunen JD (2007) Regulation of transpirational water loss in / Quercus suber trees in a Mediterranean-type ecosystem. Tree Physiol 27:1179-187 CrossRef
  56. Parolin P (2002) Radial gradients in wood specific gravity in trees of central Amazonian floodplains. IAWA Journal 23:449-57
  57. Pfautsch S, Bleby TM, Rennenberg H, Adams MA (2010) Sap flow measurements reveal influence of temperature and stand structure on water use of / Eucalyptus regnans forests. For Ecol Manag 259:1190-199
  58. Phillips N, Oren R (2001) Intra- and inter-annual variation in transpiration of a pine forest. Ecol Appl 11:385-96 CrossRef
  59. Phillips N, Oren R, Zimmermann R (1996) Radial patterns of xylem sap flow in non- diffuse- and ringporous tree species. Plant Cell Environ 19:983-90 CrossRef
  60. Phillips N, Bond BJ, McDowell NG, Ryan MG (2002) Canopy and hydraulic conductance in young, mature and old Douglas-fir trees. Tree Physiol 22:205-11 CrossRef
  61. Reyes G, Brown S, Chapman J, Lugo AE (1992) Wood densities of tropical tree species. General Technical Report SO-88. USDA Forest Service, Southern Forest Experiment Station, New Orleans
  62. Roderick ML, Berry SL (2001) Linking wood density with tree growth and environment: a theoretical analysis based on the motion of water. New Phytol 149:473-85 CrossRef
  63. R Development Core Team (2011) R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. ISBN 3-900051-07-0, URL http://www.R-project.org/
  64. Santiago LS, Kitajima K, Wright SJ, Mulkey SS (2004) Coordinated changes in photosynthesis, water relations and leaf nutritional traits of canopy trees along a precipitation gradient in lowland tropical forest. Oecologia 139:495-02 CrossRef
  65. Saugier B, Granier A, Pontailler JY, Dufrêne E, Baldocchi DD (1997) Transpiration of a boreal pine forest measured by branch bags, sapflow and micrometeorological methods. Tree Physiol 17:511-19 CrossRef
  66. Schaeffer SM, Williams DG, Goodrich DC (2000) Transpiration of cottonwood/willow forest estimated from sap flux. Agr Forest Meteorol 105:257-70 CrossRef
  67. Schiller G, Cohen Y (1995) Water regime of a pine forest under a Mediterranean climate. Agr Forest Meteorol 74:181-93 CrossRef
  68. Schmidt MWT (2007) Canopy transpiration of beech forests in Northern Bavaria—Structure and function in pure and mixed stands with oak at colline and montane sites. Ph.D. thesis, University of Bayreuth, Germany
  69. Schulze E-D, Leuning R, Kelliher FM (1995) Environmental regulation of surface conductance for evaporation from vegetation. Vegetatio 121:79-7 CrossRef
  70. Searson MJ, Thomas DS, Montagu KD, Conroy JP (2004) Wood density and anatomy of water-limited eucalypts. Tree Physiol 24:1295-302 CrossRef
  71. Siau JF (1984) Transport processes in wood. Springer, Berlin CrossRef
  72. Simpson WT, Sagoe JA (1991) Relative Drying Times of 650 Tropical Woods—Estimation by Green Moisture Content, Specific Gravity, and Green Weight Density. United States Department of Agriculture Forest Service, Forest Products Laboratory, General Technical Report FPL-GTR-71
  73. Smith DW, Tumey PR (1982) Specific density and caloric value of the trunk wood of white birch, black cherry, and sugar maple and their relationship to forest succession. Can J Forest Res 12:186-90 CrossRef
  74. Stratton L, Goldstein G, Meinzer FC (2000) Stem water storage capacity and efficiency of water transport: their functional significance in a Hawaiian dry forest. Plant Cell Environ 23:99-06 CrossRef
  75. Suzuki E (1999) Diversity in specific gravity and water content of wood among Bornean tropical rainforest trees. Ecol Res 14:211-24 CrossRef
  76. Teskey RO, Sheriff DW (1996) Water use by / Pinus radiata trees in a plantation. Tree Physiol 16:273-79 CrossRef
  77. Thomas SC (1996) Reproductive allometry in Malaysian rain forest trees: biomechanics verses optimal allocation. Evol Ecol 10:517-30 CrossRef
  78. Thomas DS, Montagu KD, Conroy JP (2004) Changes in wood density of / Eucalyptus camaldulensis due to temperature—the physiological link between water viscosity and wood anatomy. For Ecol Manag 193:157-65
  79. Vertessy RA, Benyon RG, O’Sullivan SK, Gribben PR (1995) Relationships between stem diameter, sapwood area, leaf area and transpiration in a young mountain ash forest. Tree Physiol 15:559-67 CrossRef
  80. White D, Beadle C, Worledge D, Honeysett J, Cherry M (1998) The influence of drought on the relationship between leaf and conducting sapwood area in / Eucalyptus globulus and / Eucalyptus nitens. Trees 12:406-14
  81. Wiemann MC, Williamson GB (1988) Extreme radial changes in wood specific gravity in some tropical pioneers. Wood Fiber Science 20:344-49
  82. Wilson KB, Hanson PJ, Mulholland PJ, Baldocchi DD, Wullschleger SD (2001) A comparison of methods for determining forest evaporation and its components: sap-flow, soil water budget, eddy covariance and catchment water balance. Agri Forest Meteorol 106:153-68 CrossRef
  83. Woodcock DW (2000) Wood specific gravity of trees and forest types in the southern Peruvian Amazon. Acta Amazonica 30:589-99
  84. Woodcock D, Shier A (2002) Wood specific gravity and its radial variations: the many ways to make a tree. Trees 16:437-43
  85. Wullschleger SD, Meinzer FC, Vertessy RA (1998) A review of whole-plant water use studies in trees. Tree Physiol 18:499-12
  86. Wullschleger SD, Gunderson CA, Hanson PJ, Wilson KB, Norby RJ (2002) Sensitivity of stomatal and canopy conductance to elevated CO2 concentration—interacting variables and perspectives of scale. New Phytol 153:485-96 CrossRef
  87. Zimmermann MH (1983) Xylem Structure and the ascent of sap. Springer, Berlin
  
• 作者单位：Jose Kallarackal (1) (2)
  Dennis O. Otieno (1)
  Bj?rn Reineking (3)
  Eun-Young Jung (1)
  Mark W. T. Schmidt (4)
  André Granier (5)
  John D. Tenhunen (1)
  
  1. Department of Plant Ecology, University of Bayreuth, 95440, Bayreuth, Germany
  2. Sustainable Forest Management Division, Kerala Forest Research Institute, Peechi, 680653, Kerala, India
  3. BayCEER, GEO II, Universit?tsstr. 30, 95447, Bayreuth, Germany
  4. Faculty of Forest and Environment, Research Group Agroforestry, University of Applied Sciences of Eberswalde, Alfred-Moeller-Strasse 1, 16225, Eberswalde, Germany
  5. UMR INRA-UHP 1137 Ecologie et Ecophysiologie Forestières, IFR 110 Génomique, Ecophysiologie et Ecologie Fonctionnelle; Centre de Nancy, 54280, Champenoux, France
  
• ISSN：1432-2285

文摘

Functional convergence in water use of trees across species from diverse geographic locations was examined using data on tree water use parameters, with the intention of gaining an understanding on the capacity for water transport for trees with varying structural and functional traits. Wood density (ρw), which is reported to have a negative exponential relation with sap flow density (SFD), showed a bell-shaped curve when the daily SFD data from 101 tree species belonging to 35 angiosperm and gymnosperm families were plotted. The species came from 23 different geographical locations representing all continents. Trees were most efficient in water transport when the ρw was between 0.51 and 0.65?g?cm?. When the ρw increased or decreased from this range, there was a gradual fall in their water transport rate as indicated by lower daily SFD. The unexpected reduction in SFD with decreasing ρw is explained in terms of reduced conductance in the transport pathway, which is a precaution taken by the tree for avoiding cavitation or implosion in larger conducting tubes, which is characteristic of low density wood. The development of severe leaf water potential variations, which is frequently reported in such trees, supports this notion. The SFD versus ρw relation has a potentially wide applicability in predicting water use by forest stands with varying ρw. In addition, the occurrence of a high number of tree species with ρw values in the range of 0.51-.65?g?cm? across all continents examined points towards the importance of ρw in the evolutionary process as related to efficient functioning of the water transport mechanism.