Oxygen transport in waterlogged plants

Waterlogging Signalling and Tolerance in Plants

Volumn , Issue , 2010, Pages 3-22

  Wegner, Lars H ^a  

^a KARLSRUHE INSTITUTE OF TECHNOLOGY   (Germany)

Author keywords

[No Author keywords available]

Indexed keywords

EID: 84920169803     PISSN: None     EISSN: None     Source Type: Book    
DOI: 10.1007/978-3-642-10305-6_1     Document Type: Chapter

References (55)

1. Afreen F, Zobayed SMA, Armstrong J, Armstrong W(2007) Pressure gradients along whole culms and leaf sheaths, and other aspects of humidity-induced gas transport in Phragmites australis. J Exp Bot 58:1651-1662.
2. Arber A (1920) Water plants. A study of aquatic angiosperms. Cambridge University Press, Cambridge, UK.
3. Armstrong J, Armstrong W (1991) A convective throughflow of gases in Phragmites australis (Cav.) Trin. ex Steud. Aquat Bot 39:75-88.
4. Armstrong J, Armstrong W, Beckett PM (1992) Phragmites australis: venturi- And humidityinduced pressure flows enhance rhizome aeration and rhizosphere oxidation. New Phytol 120:197-207.
5. Armstrong J, Armstrong W, Beckett PM, Halder JE, Lythe S, Holt R, Sinclair A (1996a) Pathways for aeration and the mechanisms and beneficial effects of humidity- And Venturi-induce convections in Phragmites australis (Cav.) Trin. ex. Steud. Aquat Bot 54:177-197.
6. Armstrong W, Armstrong J, Beckett PM (1996b) Pressurized ventilation in emergent macrophytes: The mechanism and mathematical modelling of humidity-induced convection. Aquat Bot 54:121-135.
7. Armstrong J, Jones RE, Armstrong W (2006) Rhizome phyllosphere oxygenation in Phragmites and other species in relation to redox potential, convective gas flow, submergence and aeration pathways. New Phytol 172:719-731.
8. Armstrong W (1964) Oxygen diffusion from the roots of some British bog plants. Nature (Lond) 204:801-802.
9. Armstrong W (1979) Aeration in higher plants. Adv Bot Res 7:225-332.
10. Armstrong W, Armstrong J (2005) Stem photosynthesis not pressurized ventilation is responsible for light-enhanced oxygen supply to submerged roots of alder (Alnus glutinosa). Ann Bot 96:591-612.
11. Armstrong W, Beckett PM (1987) Internal aeration and the development of stelar anoxia in submerged roots: A multishelled mathematical model combining axial diffusion of oxygen in the cortex with radial losses to the stele, the wall layers and the rhizosphere. New Phytol 105:221-245.
12. Armstrong W, Wright EJ (1975) Radial oxygem loss from roots: The theoretical basis for the manipulation of flux data obtained by the cylindrical plantinum electrode technique. Physiol Plant 35:21-26.
13. Armstrong W, Healy MT, Webb T (1982) Oxygen diffusion in pea. I Pore space resistance in the primary root. New Phytol 91:647-659.
14. Armstrong W, Healy MT, Lythe S (1983) Oxygen diffusion in pea II. Oxygen concentration in the primary root apex as affected by growth, the production of laterals and radial oxygen loss. New Phytol 94:549-559.
15. Armstrong W, Cousins D, Armstrong J, Turner W, Beckett PM (2000) Oxygen distribution in wetland plant roots and permeability barriers to gas-exchange with the rhizosphere: A microelectrode and modelling study with Phragmites australis. Ann Bot 86:687-703.
16. Armstrong W, Webb T, Darwent M, Beckett PM (2009) Measuring and interpreting critical oxygen pressures in roots. Ann Bot 103:281-293.
17. Bendix M, Tornberg T, Brix H (1994) Internal gas transport in Typha latifolia L and Typha angustifolia L. I. Humidity-induced pressurization and convective throughflow. Aquat Bot 49:75-90.
18. Blom CWPM (1999) Adaptations to flooding stress: from plant community to single molecule. Plant Biol 1:261-273.
19. Bowling DJF (1973) Measurement of a gradient of oxygen partial pressure across the intact root. Planta 111:323-328.
20. Brix H (1989) Gas exchange through dead culms of reed, Phragmites australis (Cav.) Trin. ex Steudel. Aquat Bot 35:81-98.
21. Brix H, Sorrell BK, Schierup H-H (1996) Gas fluxes achieved by in situ convective flow in Phragmites australis. Aquat Bot 54:151-163.
22. Colmer TD (2003) Long-distance transport of gases in plants: A perspective on internal aeration and radial oxygen loss from roots. Plant Cell Environ 26:17-36.
23. Colmer TD, Pedersen O (2008) Oxygen dynamics in submerged rice (Oryza sativa). New Phytol 178:326-334.
24. Colmer TD, Gibbered MR, Wiengweera A, Tinh TK (1998) The barrier to radial oxygen loss from roots of rice (Oryza sativa L) is induced by growth in stagnant solution. J Exp Bot 49:1431-1436.
25. Dacey JWH (1980) Internal winds in water lilies: An adaptation for life in aerobic environments. Science 210:1017-1019.
26. Dedes D, Woermann D (1996) Convective gas flow in plant aeration and thermo-osmosis: A model experiment. Aquat Bot 54:111-120.
27. De Willingen P, van Noordwijk M (1984) Mathematical models on diffusion of oxygen to and within plant roots, with special emphasis on effects of soil-root contact. I. Derivation of the models. Plant Soil 77:215-231.
28. 2 loss in adventitious roots of Hordeum marinum. New Phytol 179:405-416.
29. Gibbs J, Turner DW, Armstrong W, Sivasithamparam K, Greenway H (1998) Response to oxygen deficiency in primary maize roots. II. Development of oxygen deficiency in the stele has limited short-term impact on radial hydraulic conductivity. Aust J Plant Physiol 25:759-763.
30. Greenwood DJ (1967) Studies on oxygen transport through mustard seedlings. New Phytol 66:597-606.
31. Grosse W (1996) The mechanism of thermal transpiration (=thermal osmosis). Aquat Bot 54: 101-110.
32. Grosse W, Schröder P (1984) Oxygen supply of roots by gas transport in alder trees. Zeitschr Naturf 93c:1186-1188.
33. Grosse W, Frye J, Lattermann S (1992) Root aeration in wetland trees by pressurized gas transport. Tree Physiol 10:2285-2295.
34. Grosse W, Schulte A, Fujita H (1993) Pressurized gas transport in two Japanese alder species in relation to their natural habitats. Ecol Res 8:151-158.
35. Jackson MB, Ishizawa K, Ito O (2009) Evolution and mechanism of plant tolerance in flooding stress. Ann Bot 103:137-142.
36. Jackson MB, Armstrong W (1999) Formation of aerenchyma and the process of plant ventilation in relation to soil flooding and submergence. Plant Biol 1:274-287.
37. Justin SHFW, Armstrong W (1987) The anatomical characteristics of roots and plant response to soil flooding. New Phytol 106:465-495.
38. Kaufmann I, Jakob P, Schneider HU, Zimmermann U, Wegner LH (2010) Kinetics of water loss and re-hydration in maize roots exposed to temporal water deprivation. An MR imaging study. New Phytol, submitted.
39. Lambers H, Smakman G (1978) Respiration of the roots of flood-tolerant and flood-intolerant Senecio species: Affinity for oxygen and resistance to cyanide. Physiol Plant 42:163-166.
40. Lambers H, Steingröver E (1978) Efficiency of root respiration of a flood-tolerant and a floodintolerant Senecio species as affected by low oxygen tension. Physiol Plant 42:179-184.
41. Lambers H, Steingröver E, Smakman G (1978) The significance of oxygen transport and of metabolic adaptation in flood-tolerance of Senecio species. Physiol Plant 43:277-281.
42. Mancuso S, Papeschi G, Marras AM (2000) A polarographic, oxygen-selective vibrating-microelectrode system for the spatial and temporal characterisation of transmembrane oxygen fluxes in plants. Planta 211:384-389.
43. Mainiero R, Kazda M (2005) Effects of Carex rostrata on soil oxygen in relation to soil moisture. Plant Soil 270:311-320.
44. Mevi-Schutz J, Grosse W (1988) A two-way gas transport system in Nelumbo nucifera. Plant Cell Environ 11:27-34.
45. Michael W, Cholodova VP, Ehwald R (1999) Gas and liquids in intercellular spaces of maize roots. Ann Bot 84:665-673.
46. 2 fluxes measurements reveal differential sensitivity of barley root tissues to hypoxia. Plant Cell Environ 29:1107-1121.
47. Raskin I, Kende H (1983) How does deep water rice solve its aeration problem. Plant Physiol 72:447-454.
48. Seago JL, Marsh LC, Stevens KJ, Soukup A, Votrubova O, Enstone DE (2005) A re-examination of the root cortex in wetland flowering plants with respect to aerenchyma. Ann Bot 96:565-579.
49. Skelton NJ, Allaway WG (1996) Oxygen and pressure changes measured in situ during flooding in roots of the Grey Mangrove Avicennia marina (Forssk.) Vierh. Aquat Bot 54:165-175.
50. Sorell BK, Brix H, Orr PT (1997) Eleocharis sphacelata: internal gas transport pathways and modelling of aeration by pressure flow and diffusion. New Phytol 136:433-442.
51. Thomson CJ, Greenway H (1991) Metabolic evidence for stelar anoxia in maize roots exposed to low O2 concentrations. Plant Physiol 96:1294-1301.
52. Van Noordwijk M, De Willingen P (1984) Mathematical models on diffusion of oxygen to and within plant roots, with spezial emphasis on effects of soil-root contact. Plant Soil 77:233-241.
53. Visser EJW, Colmer TD, Blom CWPM, Voesenek LACJ (2000) Changes in growth, porosity, and radial oxygen loss from adventitious roots of selected mono- And dicotyledonous wetland species with contrasting types of aerenchyma. Plant Cell Environ 23:1237-1245.
54. Vretare V, Weisner SEB (2000) Influence of pressurized ventilation on performance of an emergent macrophyte (Phragmites australis). J Ecol 88:978-987.
55. Westhoff M, Zimmermann D, Zimmermann G, Gessner P, Wegner LH, Bentrup FW, Zimmermann U (2009) Distribution and function of epistomatal mucilage plugs. Protoplasma 235:101-105.