Stable Isotope Composition of Organic Compounds Transported in the Phloem of European Beech - Evaluation of Different Methods of Phloem Sap Collection and Assessment of Gradients in Carbon Isotope Composition during Leaf-to-Stem Transport

 

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Abstract

The analysis of stable isotope composition (δ¹³C, δ¹⁵N, δ¹⁸O) of phloem-transported organic matter is a useful tool for assessing short-term carbon and water balance of trees. A major constraint of the general application of this method to trees at natural field sites is that the collection of phloem sap with the “phloem bleeding” technique is restricted to particular species and plant parts. To overcome this restriction, we compared the contents (amino compounds and sugars) and isotope signatures (δ¹³C, δ¹⁵N, δ¹⁸O) of phloem sap directly obtained from incisions in the bark (bleeding technique) with phloem exudates where bark pieces were incubated in aqueous solutions (phloem exudation technique with and without chelating agents [EDTA, polyphosphate] in the initial sampling solution, which prevent blocking of sieve tubes). A comparable spectrum of amino compounds and sugars was detected using the different techniques. O, C, or N compounds in the initial sampling solution originating from the chelating agents always decreased precision of determination of the respective isotopic signatures, as indicated by higher standard deviation, and/or led to a significant difference of mean δ as compared to the phloem bleeding technique. Hence, depending on the element from which the ratio of heavy to light isotope is determined, compounds lacking C, N, and/or O should be used as chelating agents in the exudation solution. In applying the different techniques, δ¹³C of organic compounds transported in the phloem of the twig (exudation technique with polyphosphate as chelating agent) were compared with those in the phloem of the main stem (phloem bleeding technique) in order to assess possible differences in carbon isotope composition of phloem carbohydrates along the tree axis. In July, organic compounds in the stem phloem were significantly enriched in ¹³C by > 1.3 ‰ as compared to the twig phloem, whereas this effect was not observed in September. Correlation analysis between δ¹³C and stomatal conductance (G_s) revealed the gradient from the twigs to the stem observed in July may be attributed to temporal differences rather than to spatial differences in carbon isotope composition of sugars. As various authors have produced conflicting results regarding the enrichment/depletion of ¹³C in organic compounds in the leaf-to-stem transition, the different techniques presented in this paper can be used to provide further insight into fractionation processes associated with transport of C compounds from leaves to branches and down the main stem.

References

• 1 Adams M. A., Grierson P. F.. Stable isotopes at natural abundance in terrestrial plant ecology and ecophysiology: An update.  Plant Biology. (2001);  3 299-310
  Article in Thieme ConnectPubMedGoogle Scholar
• 2 Barbour M. M., Farquhar G. D.. Relative humidity- and ABA-induced variation in carbon and oxygen isotope ratios of cotton leaves.  Plant, Cell and Environment. (2000);  23 473-485
  CrossrefPubMedGoogle Scholar
• 3 Brendel O.. Does bulk needle δ¹³C reflect short-term discrimination?.  Annals of Forest Science. (2001);  58 135-141
  PubMedGoogle Scholar
• 4 Cernusak L. A., Pate J. S., Farquhar G. D.. Diurnal variation in the stable isotope composition of water and dry matter in fruiting Lupinus angustifolius under field conditions.  Plant, Cell and Environment. (2002);  25 893-907
  CrossrefPubMedGoogle Scholar
• 5 Cernusak L. A., Arthur D. J., Pate J. S., Farquhar G. D.. Water relations link carbon and oxygen isotope discrimination to phloem sap sugar concentration in Eucalyptus globulus. .  Plant Physiology. (2003);  131 1544-1554
  CrossrefPubMedGoogle Scholar
• 6 Damesin C., Lelarge C.. Carbon isotope composition of current-year shoots from Fagus sylvatica in relation to growth, respiration and use of reserves.  Plant, Cell and Environment. (2003);  26 207-219
  CrossrefPubMedGoogle Scholar
• 7 Deniro M. J., Epstein S.. Mechanism of carbon isotope fractionation associated with lipid biosynthesis.  Science. (1977);  197 261-263
  PubMedGoogle Scholar
• 8 Fotelli M. N., Rennenberg H., Holst T., Mayer H., Geßler A.. Carbon isotope composition of various tissues of beech (Fagus sylvatica) regeneration is indicative of recent environmental conditions within the forest understorey.  New Phytologist. (2003);  159 229-244
  CrossrefPubMedGoogle Scholar
• 9 Geßler A., Schrempp S., Matzarakis A., Mayer H., Rennenberg H., Adams M. A.. Radiation modifies the effect of water availability on the carbon isotope composition of beech (Fagus sylvatica L.).  New Phytologist. (2001);  50 653-664
  PubMedGoogle Scholar
• 10 Geßler A., Keitel C., Nahm N., Rennenberg H.. Water shortage affects the water and nitrogen balance in Central European beech forests.  Plant Biology. (2004);  6 289-298
  Article in Thieme ConnectPubMedGoogle Scholar
• 11 Granier A., Biron P., Koestner B., Gay L. W., Najjar G.. Comparisons of xylem sap flow and water vapour flux at the stand level and derivation of canopy conductance for Scots pine.  Theoretical and Applied Climatology. (1996);  53 115-122
  CrossrefPubMedGoogle Scholar
• 12 Handley L. L., Austin A. T., Robinson D., Scrimgeour C. M., Raven J. A., Heaton T. H. E., Schmidt S., Stewart G. R.. The ¹⁵N natural abundance (δ¹⁵N) of ecosystem samples reflects measures of water availability.  Australian Journal of Plant Physiology. (1999);  26 185-199
  PubMedGoogle Scholar
• 13 Helle G., Schleser G. H.. Beyond CO₂-fixation by Rubisco - an interpretation of ¹³C/¹²C variations in tree rings from novel intra-seasonal studies on broad-leaf trees.  Plant, Cell and Environment. (2004);  27 367-380
  CrossrefPubMedGoogle Scholar
• 14 Hobbie E. A., Werner R. A.. Intramolecular, compound-specific, and bulk carbon isotope patterns in C₃ and C₄ plants: a review and synthesis.  New Phytologist. (2004);  161 371-385
  CrossrefPubMedGoogle Scholar
• 15 Hobbie E. A., Rygiewicz P. T., Tingey D. T., Johnson M. G., Olszyk D. M.. Turnover of fine roots estimated through natural ¹³C isotopic analyses.  Plant and Soil. (2002);  247 233-242
  CrossrefPubMedGoogle Scholar
• 16 Keitel C.. Isotope signatures (δ¹³C, δ¹⁸O, δ¹⁵N) as a measure of environmental effects on the physiology of trees in the northern and southern hemisphere. PhD thesis, University of Freiburg, Germany. (2004)
  Google Scholar
• 17 Keitel C., Adams M. A., Holst T., Matzarakis A., Mayer H., Rennenberg H., Geßler A.. Carbon and oxygen isotope composition of organic compounds in the phloem sap provides a short-term measure for stomatal conductance of European beech (Fagus sylvatica L.).  Plant, Cell and Environment. (2003);  26 1157-1168
  CrossrefPubMedGoogle Scholar
• 18 Korol R. L., Kirschbaum M. U. F., Farquhar G. D., Jeffreys M.. Effects of water status and soil fertility on the C-isotope signature in Pinus radiata. .  Tree Physiology. (1999);  19 551-562
  PubMedGoogle Scholar
• 19 Leavitt S. W., Long A.. Stable-carbon isotope variability in tree foliage and wood.  Ecology. (1986);  67 1002-1010
  PubMedGoogle Scholar
• 20 Livingston N. J., Spittlehouse D. L.. Carbon isotope fractionation in tree ring early and late wood in relation to intra-season water balance.  Plant, Cell and Environment. (1996);  19 768-774
  PubMedGoogle Scholar
• 21 Miller J. M., Williams R. J., Farquhar G. D.. Carbon isotope discrimination by a sequence of Eucalyptus species along a subcontinental rainfall gradient in Australia.  Functional Ecology. (2001);  15 222-232
  CrossrefPubMedGoogle Scholar
• 22 Minchin P. E. H., Thorpe M. R.. Measurement of unloading and reloading of photo-assimilate within the stem of bean.  Journal of Experimental Botany. (1987);  38 211-220
  PubMedGoogle Scholar
• 23 Pataki D. E., Oren R., Phillips N.. Responses of sap flux and stomatal conductance of Pinus taeda L. trees to stepwise reductions in leaf area.  Journal of Experimental Botany. (1998);  49 871-878
  CrossrefPubMedGoogle Scholar
• 24 Pate J. S., Arthur D.. δ¹³C analysis of phloem sap carbon: novel means of evaluating seasonal water stress and interpreting carbon isotope signatures of foliage and trunk wood of Eucalyptus globulus. .  Oecologia. (1998);  117 301-311
  CrossrefPubMedGoogle Scholar
• 25 Pate J. S., Shedley E., Arthur D., Adams M. A.. Spatial and temporal variations in phloem sap composition of plantation-grown Eucalyptus globulus. .  Oecologia. (1998);  117 312-322
  CrossrefPubMedGoogle Scholar
• 26 Peñuelas J., Filella I., Terradas J.. Variability of plant nitrogen and water use in a 100-m transect of a subdesertic depression of the Ebro valley (Spain) characterized by leaf δ¹³C and δ¹⁵N.  Acta Oecologica. (1999);  20 119-123
  CrossrefPubMedGoogle Scholar
• 27 Phillips D. L., Gregg J. W.. Uncertainty in source partitioning using stable isotopes.  Oecologia. (2001);  127 171-179
  CrossrefPubMedGoogle Scholar
• 28 Rennenberg H., Schneider S., Weber P.. Analysis of uptake and allocation of nitrogen and sulphur compounds by trees in the field.  Journal of Experimental Botany. (1996);  47 1491-1498
  PubMedGoogle Scholar
• 29 Scheidegger Y., Saurer M., Bahn M., Siegwolf R.. Linking stable oxygen and carbon isotopes with stomatal conductance and photosynthetic capacity: a conceptual model.  Oecologia. (2000);  125 350-357
  CrossrefPubMedGoogle Scholar
• 30 Schneider S., Geßler A., Weber P., v. Sengbusch D., Hanemann U., Rennenberg H.. Soluble N compounds in trees exposed to high loads of N: a comparison of spruce (Picea abies) and beech (Fagus sylvatica) grown under field conditions.  New Phytologist. (1996);  134 103-114
  PubMedGoogle Scholar
• 31 Syvertsen J. P., Smith M. L., Lloyd J., Farquhar G. D.. Net carbon dioxide assimilation, carbon isotope discrimination, growth, and water-use efficiency of Citrus trees in response to nitrogen status.  Journal of the American Society of Horticultural Science. (1997);  122 226-232
  PubMedGoogle Scholar
• 32 Taylor J. R.. An Introduction to Error Analysis. Oxford, UK; Oxford University Press (1982)
  Google Scholar
• 33 Van Bel A. J. E.. The phloem, a miracle of ingenuity.  Plant, Cell and Environment. (2003);  26 125-149
  CrossrefPubMedGoogle Scholar
• 34 Weibull J., Ronquist F., Brishammar S.. Free amino acid composition of leaf exudates and phloem sap.  Physiologia Plantarum. (1990);  92 222-226
  PubMedGoogle Scholar
• 35 Whitehead D., Jarvis P. G.. Coniferous forests and plantations. Kozlowski, T. T., ed. Water Deficits and Plant Growth, Vol. VI. San Diego; Academic Press (1981): 49-52
  Google Scholar
• 36 Xu Z. H., Saffigna P. G., Farquhar G. D., Simpson J. A., Haines R. J., Walker S., Osborne D. O., Guinto D.. Carbon isotope discrimination and oxygen isotope composition in clones of the F1 hybrid between slash pine and Caribbean pine in relation to tree growth, water-use efficiency and foliar nutrient concentration.  Tree Physiology. (2000);  20 1209-1217
  PubMedGoogle Scholar
• 37 Yoneyama T., Handley L. L., Scrimgeour C. M., Fisher D. B., Raven J. A.. Variations of the natural abundances of nitrogen and carbon isotopes in Triticum aestivum, with special reference to phloem and xylem exudates.  New Phytologist. (1997);  137 205-213
  CrossrefPubMedGoogle Scholar
• 38 Zimmermann M. H., Braun C. L.. Trees, Structure and Function. Berlin; Springer (1971)
  Google Scholar

C. Keitel

Environmental Biology Group
Research School of Biological Sciences
Australian National University

GPO Box 475

Canberra ACT 2601

Australia

Email: keitel@rsbs.anu.edu.au

Editor: W. W. Adams III