Interaction of Flooding with Carbon Metabolism of Forest Trees

J. Kreuzwieser; E. Papadopoulou; H. Rennenberg

doi:10.1055/s-2004-817882

Plant Biology, Table of Contents

Plant Biol (Stuttg) 2004; 6(3): 299-306
DOI: 10.1055/s-2004-817882

Review Article

Georg Thieme Verlag Stuttgart KG · New York

Interaction of Flooding with Carbon Metabolism of Forest Trees

J. Kreuzwieser¹ , E. Papadopoulou¹ , H. Rennenberg¹

¹Albert-Ludwigs-Universität Freiburg, Institut für Forstbotanik und Baumphysiologie, Professur für Baumphysiologie, Freiburg, Germany

Abstract

Waterlogging and flooding cause oxygen deprivation in the root system of trees. Since oxygen is essentially for mitochondrial respiration, this process cannot be maintained under anoxic conditions and must be replaced by other pathways. For the roots it is therefore a matter of survival to switch from respiration to alcoholic fermentation. Due to the low efficiency of this process to yield energy equivalents (ATP), energy and carbon metabolism of trees are usually strongly affected by oxygen deprivation, even if a rapid switch from respiration to fermentation is achieved. The roots can compensate for the low energy yield of fermentation either (1) by decreasing the demand for energy by a reduction of energy-dependent processes such as root growth and/or nutrient uptake, or (2) by consuming more carbohydrates per unit time in order to generate sufficient energy equivalents. In the leaves of trees, flooding and waterlogging cause a decline in the rates of photosynthesis and transpiration, as well as in stomatal conductance. It is assumed that, due to reduced phloem transport, soluble sugars and starch accumulate in the leaves of flooded trees, thereby negatively affecting the sugar supply of the roots. Thus, root growth and survival is negatively affected by both changes in root internal carbon metabolism and impaired carbon allocation to the roots by phloem transport. In addition, accumulation of toxic products of fermentation in the roots, such as acetaldehyde, can further impair root metabolism. A main feature of tolerance against flooding and waterlogging of trees seems to be the steady supply of carbohydrates to the roots in order to maintain alcoholic fermentation; in addition, roots of tolerant trees seem to avoid accumulation of fermentation-derived ethanol and acetaldehyde. From studies with flooding tolerant and non-tolerant tree species, it is hypothesized that (1) the transport of ethanol produced in the roots under hypoxic conditions into the leaves via the transpiration stream, (2) its conversion into acetyl-CoA in the leaves, and (3) its use in the plant's general metabolism, are mechanisms of flooding tolerance of trees.

Key words

Oxygen deficiency - carbon cycling - photosynthesis - transpiration

Full Text

References

1 Albrecht G., Biemelt S.. A comparative study on carbohydrate reserves and ethanolic fermentation in the roots of two wetland and non-wetland species after commencement of hypoxia. Physiologia Plantarum. (1998); 104 81-86
2 Albrecht G., Kammerer S., Praznik W., Wiedenroth E. M.. Fructan content of wheat seedlings (Triticum aestivum L.) under hypoxia and following re-aeration. New Phytologist. (1993); 123 471-476
3 Angeles G., Evert R. F., Kozlowski T. T.. Development of lenticels and adventitious roots in flooded Ulmus americana seedlings. Canadian Journal of Forest Research. (1986); 16 585-590
4 Angelov M. N., Sung S.-J. S., Doong R. L., Harms W. R., Kormanik P. P., Black Jr. C. C.. Long- and short-term flooding effects on survival and sink-source relationships of swamp-adapted tree species. Tree Physiology. (1996); 16 477-484
5 Bardossy A., Caspary H. J.. Detection of climate change in Europe by analyzing European atmospheric circulation patterns from 1881 to 1989. Theoretical and Applied Climatology. (1990); 42 155-167
6 Barta A. L.. Ethanol synthesis and loss from flooded roots of Medicago sativa L. and Lotus corniculatus L. Plant Cell and Environment. (1984); 7 187-191
7 Beckman T. G., Perry R. L., Flore J. A.. Short-term flooding affects gas exchange characteristics of containerized sour cherry trees. Hortscience. (1992); 27 1297-1301
8 Bertani A., Reggiani R.. Anaerobic metabolism in rice roots. Jackson, M. B., Davies, D. D., and Lambers, H., eds. Plant life under Oxygen Deprivation. The Hague, The Netherlands; SPB Academic Publishing (1991): 187-200
9 Biegelmaier K.-H.. Integriertes Rheinprogramm: Untersuchungen zur Hochwassertoleranz von Waldbäumen (Teil 1 und 2), LfU, Ref. 25-IRP. (1993)
10 Biegelmaier K.-H.. Auswirkungen des Hochwassers im Rheinauewald. AFZ. (2002); 15 801-803
11 Biemelt S., Hajirezaei M. R., Melzer M., Albrecht G., Sonnewald U.. Sucrose synthase activity does not restrict glycolysis in roots of transgenic potato plants under hypoxic conditions. Planta. (1999); 210 41-49
12 Blom C. W. P. M., Voesenek L. A. C. J.. Flooding: the survival strategies of plants. Trends in Ecology and Evolution. (1996); 11 290-295
13 Braendle R.. Überflutung und Sauerstoff. Brunold, C., Rüegsegger, A., and Brändle, R., eds. Stress bei Pflanzen. Bern, Stuttgart, Wien; UTB Verlag Paul Haupt (1997): 133-148
14 Castonguay Y., Nadeau P., Simard R. R.. Effects of flooding on carbohydrate and ABA levels in roots and shoots of alfalfa. Plant, Cell and Environment. (1993); 16 695-702
15 Colin-Belgrand M., Dreyer E., Biron P.. Sensitivity of seedlings from different oak species to waterlogging: effects on root growth and mineral nutrition. Annales des Sciences Forestières. (1991); 48 193-204
16 Crawford R. M. M., Finegan D. M.. Removal of ethanol from lodgepole pine roots. Tree Physiology. (1989); 5 53-61
17 Dister E.. Zur Hochwassertoleranz von Auenwaldbäumen an lehmigen Standorten. Verhandlungen der Gesellschaft für Ökologie, Mainz, Band 10. (1983): 325-336
18 Domingo R., Perez-Pastor A., Ruiz-Sanchez M. C.. Physiological responses of apricot plants grafted on two different rootstocks to flooding conditions. Journal of Plant Physiology. (2002); 159 725-732
19 Drew M. C.. Oxygen deficiency and root metabolism: Injury and acclimation under hypoxia and anoxia. Annual Reviews of Plant Molecular Biology. (1997); 48 223-250
20 Drew M. C.. Sensing soil oxygen. Plant Cell and Environment. (1990); 13 681-693
21 Drew M. C.. Oxygen deficiency in the roots environment an plant mineral nutrition. Jackson, M. B., Davies, D. D., and Lambers, H., eds. Plant Life under Oxygen Deprivation. The Hague, The Netherlands; SPB Academic Publishing (1991): 303-316
22 Drew M. C., Bazzaz F. A.. Variation in distribution of assimilates among plant parts in three populations of Populus deltoides. . Silvae Genetica. (1978); 27 189-193
23 Dreyer E.. Compared sensitivity of seedlings from 3 woody species (Quercus robur L., Quercus rubra L. and Fagus sylvatica L.) to water-logging and associated root hypoxia: effects on water relations and photosynthesis. Annales des Sciences Forestières. (1994); 51 417-429
24 Dreyer E., Colin-Belgrand M., Biron P.. Photosynthesis and shoot water status of seedlings from different oak species submitted to waterlogging. Annales des Sciences Forestières. (1991); 48 205-214
25 Ellenberg H.. Vegetation Mitteleuropas mit den Alpen. ISBN 3-80013-428-4. 989 pp. Stuttgart, Germany; Verlag Eugen Ulmer (1986)
26 Ellis M. H., Millar A. A., Llewellyn D. J., Peacock W. J., Dennis E. S.. Transgenic cotton (Gossypium hirsutum) overexpressing alcohol dehydrogenase shows increased ethanol fermentation but no increase in tolerance to oxygen deficiency. Australian Journal of Plant Physiology. (2000); 27 1041-1050
27 Else M. A., Tiekstra A. E., Croker S. J., Davies W. J., Jackson M. B.. Stomatal closure in flooded tomato plants involves abscisic acid and a chemical unidentified anti-transpirant in xylem sap. Plant Physiology. (1996); 112 239-247
28 Ewing K.. Tolerance of four wetland plant species to flooding and sediment deposition. Environmental and Experimental Botany. (1996); 36 131-146
29 Frye J., Grosse W.. Growth responses to flooding and recovery of deciduous trees. Zeitschrift fuer Naturforschung Section C Journal of Biosciences. (1992); 47 683-689
30 Gill C.. The flooding tolerance of woody species - a review. Forestry Abstracts. (1970); 31 671-688
31 Goldschmidt E. E., Huber S. G.. Regulation of photosynthesis by end-product accumulation in leaves of plants storing starch, sucrose and hexose sugars. Plant Physiology. (1992); 99 1443-1448
32 Good A. G., Muench D. G.. Long-term anaerobic metabolism in root tissue. Plant Physiology. (1993); 101 1163-1168
33 Good A. G., Paetkau D. H.. Identification and characterization of hypoxicaly induced maize lactate dehydrogenase gene. Plant Molecular Biology. (1992); 19 693-697
34 Gravatt D. A., Kirby C. J.. Patterns of photosynthesis and starch allocation in seedlings of four bottomland hardwood tree species subjected to flooding. Tree Physiology. (1998); 18 411-417
35 Graves W., Kroggel M. A., Widrlechner M. P.. Photosynthesis and shoot health of five birch and four alder taxa after drought and flooding. Journal of Environmental Horticulture.. (2002); 20 36-40
36 Hegerl G. C., von Storch H., Hasselmann K., Santer B. D., Cubasch U., Jones P. D.. Detecting anthropogenic climate change with an optimal fingerprint method. Report 142, Max-Planck-Institut für Meteorologie, Hamburg. (1994)
37 Heizmann U., Kreuzwieser J., Schnitzler J.-P., Brüggemann N., Rennenberg H.. Carbon transport in the xylem sap of young pedunculate oak (Quercus robur) trees. Plant Biology. (2001); 3 132-138
38 Hsu Y.-M., Tseng M.-J., Lin C.-H.. The fluctuation of carbohydrates and nitrogen compounds in flooded wax-apple trees. Botanical Bulletin of Academia Sinica (Taipei). (1999); 40 193-198
39 Huang B., Johnson J. W.. Root respiration and carbohydrate status of two wheat genotypes in response to hypoxia. Annals of Botany. (1995); 75 427-432
40 ICPR (International Commission for the Protection of the River Rhine) .Action Plan on Flood defence. URL: http://www.iksr.org . (1998)
41 IPCC (Intergovernmental Panel of Climate Change) .The regional impacts of climate change: an assessment of vulnerability. A Special Report of IPCC Working group II. Watson, R. T., Zinyowera, M. C., and Moss, R. H., eds. Port Chester, NY, USA; Cambridge University Press (1997)
42 Joly C. A.. Flooding tolerance in tropical trees. Jackson, M. B., Davies, D. D., and Lambers, H., eds. Plant Life under Oxygen Deprivation. The Hague, The Netherlands; SPB Academic Publishing (1991): 23-34
43 Kimmerer T. W.. Alcohol dehydrogenase and pyruvate decarboxylase activity in leaves and roots of eastern cottonwood (Populus deltoides Bartr,) and soybean (Glycine max L.). Plant Physiology. (1987); 84 1210-1213
44 Kolb R. M., Rawyler A., Braendle R.. Parameters affecting the early seedling development of four neotropical trees under oxygen deprivation stress. Annals of Botany. (2002); 89 551-558
45 Kreuzwieser J., Fürniss S., Rennenberg H.. Impact of waterlogging on the N-metabolism of flood tolerant and non-tolerant tree species. Plant Cell and Environment. (2002); 25 1039-1049
46 Kreuzwieser J., Harren F. J. M., Laarhoven L.-J., Boamfa I., te Lintel-Hekkert S., Scheerer U., Hüglin C., Rennenberg H.. Acetaldehyde emission by the leaves of trees - correlation with physiological and environmental parameters. Physiologia Plantarum. (2001); 113 41-49
47 Kreuzwieser J., Kühnemann F., Martis A., Rennenberg H., Urban W.. Diurnal pattern of acetaldehyde emission by flooded poplar trees. Physiologia Plantarum. (2000); 108 79-86
48 Kreuzwieser J., Scheerer U., Rennenberg H.. Metabolic origin of acetaldehyde emitted by poplar (Populus tremula × P. alba) trees. Journal of Experimental Botany. (1999); 50 757-765
49 MacDonald R. C., Kimmerer T. W.. Ethanol in the stems of trees. Physiologia Plantarum. (1991); 82 582-588
50 MacDonald R. C., Kimmerer T. W.. Metabolism of transpired ethanol by eastern cottonwood (Populus deltoides Bartr). Plant Physiology. (1993); 102 173-179
51 Marschner H.. Mineral Nutrition of Higher Plants. London; Academic Press (1995)
53 Nunez-Elisea R., Schaffer B., Fisher J. B., Colls A. M., Crane J. H.. Influence of flooding on net CO₂ assimilation, growth and stem anatomy of Annona species. Annals of Botany. (1999); 84 771-780
54 Parolin P.. Submergence tolerance vs. escape from submergence: two strategies of seedling establishment in Amazonian floodplains. Environmental and Experimental Botany. (2002); 48 177-186
55 Perata P., Pozueta-Romero J., Akazawa T., Yamaguchi J.. Effect of anoxia on starch breakdown in rice and wheat seeds. Planta. (1992); 188 611-618
56 Pezeshki S. R.. Responses of baldcypress (Taxodium distichum) seedlings to hypoxia: Leaf protein content, ribulose-1,5-bisphosphate carboxylase/oxygenase activity and photosynthesis. Photosynthetica. (1994); 30 59-68
57 Pezeshki S. R., Chambers J. C.. Stomatal and photosynthetic response of sweet gum (Liquidambar styraciflua) to flooding. Canadian Journal of Forest Research. (1985 a); 15 371-375
58 Pezeshki S. R., Chambers J. C.. Response of cherrybark oak seedlings to short-term flooding. Forest Sciences. (1985 b); 31 760-771
59 Pezeshki S. R., Chambers J. C.. Variation in flood-induced stomatal and photosynthetic responses of three bottomland tree species. Forest Sciences. (1986); 32 914-923
60 Pezeshki S. R., Pardue J. H., DeLaune R. D.. Leaf gas exchange and growth of flood-tolerant and flood-sensitive tree species under low soil redox conditions. Tree Physiology. (1996); 16 453-458
61 Ponnamperuma F. N.. Effects of flooding on soils. Chapter 2. Kozlowski, T. T., ed. Flooding and Plant Growth. Orlando; Academic Press (1994): 9-193
62 Reece C. F., Riha S. J.. Role of root systems of Eastern larch and White spruce in response to flooding. Plant, Cell and Environment. (1991); 14 229-234
63 Roberts J. K. M., Callis J., Wemmer D., Walbot V., Jardetzky O.. Mechanism of cytoplasmic pH regulation in hypoxic maize root tips and its role in survival under hypoxia. Proceedings of the National Academy of Science. (1984); 81 3379-3383
64 Ruschen G., Klädtke J., Külls C., Ostermann R., Schwarz O., Volk H.. Abschlussbericht der FVA Freiburg zum Untersuchungsprogramm Ökologische Flutungen im Polder Altenheim. Forstliche Versuchs- und Forschungsanstalt (FVA), Abt. Landespflege, Freiburg, 54 S. (1997)
65 Sachs M. M.. Molecular genetic basis of metabolic adaptation to anoxia in maize and its possible utility for improving tolerance of crops to waterlogging. Jackson, M. B., Davies, D. D., and, Lambers, H., eds. Interacting Stresses on Plants in a Changing Climate. Berlin; Springer (1993): 375-395
66 Schlueter U., Albrecht G., Wiedenroth E.-M.. Content of water soluble carbohydrates under oxygen deprivation in plants with different flooding tolerance. Folia Geobotanica and Phytotaxonomica. (1996); 31 57-64
67 Schlueter U., Crawford R. M. M.. Long-term anoxia tolerance in leaves of Acorus calamus L. and Iris pseudacorus L. Journal of Experimental Botany. (2001); 52 2213-2225
68 Schmull M., Thomas F. M.. Morphological and physiological reactions of young deciduous trees (Quercus robur L., Q. petraea [Matt. ] Liebl., Fagus sylvatica L.) to waterlogging. Plant and Soil. (2000); 225 227-242
69 Schönwiese C.-D., Rapp J., Fuchs T., Denhard M.. Klimatrend Atlas Europa 1891 - 1990. Berichte des Zentrums für Umweltforschung, Nr. 20. (1993)
70 Schumann A. H.. Changes in hydrological time series - a challenge for water management in Germany. In Extreme Hydrological Events: Precipitation, Floods and Droughts. Proceedings of the Joint IAMAP-IAHS Meeting Yokohama, July 1993, Japan, IAHS 213. (1993): 95-102
71 Setter T. L., Ellis M., Laureles E. V., Ella E. S., Senadhira D., Mishra S. B., Sarkarung S., Datta S.. Physiology and genetics of submergence tolerance in rice. Annals of Botany. (1997); Suppl. A 67-77
72 Siebel H. N., van Wijk M., Blom C. W. P. M.. Can tree seedlings survive increased flood levels of rivers?. Acta Botanica Neerlandica. (1998); 47 219-230
73 Sij J. W., Swanson C. A.. Effects of petiole anoxia on phloem transport in squash. Plant Physiology. (1973); 51 368-371
74 Smith A. M., ap Rees T.. Pathway of carbohydrate fermentation in the roots of marsh plants. Planta. (1979 a); 146 327-334
75 Smith A. M., ap Rees T.. Effects of anaerobiosis on carbohydrate oxidation by roots of Pisum sativum. . Phytochemistry. (1979 b); 18 1453-1458
76 Smith A. M., Kalsi G., Woolhouse H. W.. Products of fermentation in the roots of alder (Alnus Mill.). Planta. (1984); 160 272-275
77 Späth V.. Zur Hochwassertoleranz von Auenwaldbäumen. Natur und Landschaft. (1988); 7/8 312-315
78 Subbaiah C. C., Zhang J., Sachs M. M.. Involvement of intracellular calcium in anerobic gene expression and survival of maize seedlings. Plant Physiology. (1994); 105 369-376
79 Tadege M., Brändle R., Kuhlemeier C.. Anoxia tolerance in tobacco roots: effects of overexpression of pyruvatedecarboxylase. Plant Journal. (1998); 14 327-335
80 Vartapetian B. B., Jackson M. B.. Plant adaptations to anaerobic stress. Annals of Botany. (1997); 79 3-20
81 Vartapetian B. B., Poljakova L. I.. Blocking of anaerobic protein synthesis destabilizes dramatically plant mitochondrial membrane ultrastructure. Biochemistry and Molecular Biology International. (1994); 33 405-410
82 Vu J. C. V., Yelenosky G.. Photosynthetic responses of Citrus trees to soil flooding. Physiologia Plantarum. (1991); 81 7-14
83 Wagner P. A., Dreyer E.. Interactive effects of waterlogging and irradiance on the photosynthetic performance of seedlings from three oak species displaying different sensitivities (Quercus robur, Q. petraea and Q. rubra). Annales des Sciences Forestières. (1997); 54 409-429
84 Waters I., Morrell S., Greenway H., Colmer T. D.. Effects of anoxia on wheat seedlings. 2. Influence of O₂ supply prior to anoxia on tolerance to anoxia, alcoholic fermentation, and sugar levels. Journal of Experimental Botany. (1991); 42 832-841
85 Xia J. H., Roberts J. K. M.. Improved cytoplasmic pH regulation, increased lactate efflux, and reduced cytoplasmic levels are biochemical traits expressed in root tips of whole maize seedlings acclimated to a low-oxygen environment. Plant Physiology. (1994); 105 651-657
86 Xia J. H., Saglio P. H.. Lactic acid efflux as a mechanism of hypoxic acclimation of maize root tips to anoxia. Plant Physiology. (1992); 100 40-46
87 Zhou D., Solomos T.. Effect of hypoxia on sugar accumulation, respiration, activities of amylase and starch phosphorylase, and induction of alternative oxidase and invertase during storage of potato tubers (Solanum tuberosum cv. Russet Burbank) at 1 °C. Physiologia Plantarum. (1998); 104 255-265

J. Kreuzwieser

Albert-Ludwig-Universität Freiburg
Institut für Forstbotanik und Baumphysiologie
Professur für Baumphysiologie

Georges-Köhler-Allee, Geb. 053/54

79110 Freiburg

Germany

Email: juergen.kreuzwieser@ctp.uni-freiburg.de

Guest Editor: F. Loreto