Effect of plants on methane production, oxidation and emission

Chinese Journal of Applied Ecology

Volumn 14, Issue 8, 2003, Pages 1379-1384

  Ding, Weixin ^a   Cai, Zucong ^a  

^a INSTITUTE OF GEOLOGY AND GEOPHYSICS   (China)

Author keywords

Methane emission; Methane oxidation; Methane production; Plant; Root exudates

Indexed keywords

METHANE;

EXUDATION; METHANOGENESIS; OXIDATION; ROOT SYSTEM; SOIL EMISSION; SOIL-VEGETATION INTERACTION;

ARTICLE; METABOLISM; OXIDATION REDUCTION REACTION; PLANT; PLANT ROOT; SOIL;

METHANE; OXIDATION-REDUCTION; PLANT ROOTS; PLANTS; SOIL;

EID: 0141484549     PISSN: 10019332     EISSN: None     Source Type: Journal    
DOI: None     Document Type: Article

References (82)

1. Adhya TK, Rath AK, Gupta PK, et al. 1994. Methane emission from flooded rice fields under irrigated conditions. Biol Fert Soil, 18:245-248
2. Amaral JA, Ren T, Knowles R. 1998. Atmospheric methane consumption by forest soils and extracted bacteria at different pH values. Appl Environ Microbiol, 64:2397-2402
3. Aulakh MS, Wassmann R, Rennenberg H, et al. 2000. Pattern and amount of aerenchyma relate to variable methane transport capacity of different rice cultivars. Plant Biol, 2:182-194
4. Bacha RE, Hossner LR. 1977. Characteristics of coatings formed on rice roots as affected by iron and manganese additions. Soil Sci Soc Am J, 41:931-935
5. Banker BC, kludze HK, Alford DP, et al. 1995. Methane sources and sinks in paddy rice soils: Relationship to emissions. Agric Ecosys Environ, 553:243-251
6. Bartlett KB, Crill PM. Sass RL, et al. 1992. Methane emissions from tundra environments in Yyukon-kuskokwim Delta, Alaska. J Geophys Res. 97(D15):16645-16660
7. Blake DR, Rowland SR. 1988. Continuing worldwide increase in tropospheric methane 1978-1987. Science, 239:1129-1131
8. Bont JAM de, Lee KK, Bouldin DF. 1978. Bacterial oxidation of methane in a rice paddy. Ecol Bull, 26:91-96
9. Bosse U, Frenzel P. 1997. Activity and distribution of methane-oxidizing bacteria in flooded rice soil microcosms and in rice plants (Oryza sativa ). Appl Environ Microbiol, 63:1199-1207
10. Bouwman AF. 1990. Soil and Greenhouse Effect. Chichester: John Wiley and Sons.
11. 4) in southern peatlands. Soil Biol Biochem, 24:1089-1099
12. Butterbech-bahl K, Papen H, Rennenberg H. 1997. Impact of gas transport through rice cultivars on methane emission from paddy fields. Plant Cell Environ, 20:1175-1183
13. Cai Z-C. 1999. Methane emission from paddy soils. In: Ma Y-J, Chen J-F eds. Change in Paddy Soil Materials and its Effect on Eco-environment. Beijing: Science Press. 123-144 (in Chinese)
14. Calhoun A, King GM. 1997. Regulation of root-associated methanotrophy by oxygen availability in the rhizosphere of two aquatic macrophytes. Appl Environ Microbiol, 63:3051-3058
15. 2 exchange. Global Biogeochem Cyc, 11:15-27
16. Chanton JP, Whiting GJ, Showers WJ, et al. 1992. Methane flux from Peltandra virginica: Stable isotope tracing and chamber effects. Global Biogeochem Cyc, 6:15-31
17. Charholm M. 1985. Possible roles for roots, bacteria, protozoa and fungi in supplying nitrogen to plants. In: Fritter A, Atkinson D, Read D, Usher M eds. Ecological Interactions in Soil. Oxford: Blackwell Scientific. 355-365
18. 4 in a northern Minnesota peatland. Global Biogeochem Cyc, 14:1095-1108
19. 13C-labelled rice straw, Soil Biol Biochem, 29:1173-1181
20. Conlin TSS, Crowder AA. 1989. Location of radial oxygen loss and zones of potential iron uptake in a grass and two non-grass emergent species. Can J Bot, 67:717-722
21. Crowder A, Macfie SM. 1986. Seasonal deposition of ferric hydroxide plaque on roots of wetland plant. Can J Bot, 64:2120-2124
22. Dacey JWH. 1980. Internal winds in water lilies: An adaptation for life in anaerobic sediments. Science, 210:1017-1019
23. Denier van der, Gon HAC, Neue HU. 1996. Oxidation of methane in the rhizosphere of rice plants. Biol Fert Soils, 22:359-366
24. Dlugokeneky EJ, Maasarie KA, Lang PM, et al. 1998. Continuing decline in the growth rate of the atmospheric methane burden. Nature, 393:447-450
25. Drew MC, Lynch JM. 1980. Soil anaerobiosis, microorganisms, and root function. Ann Rev Phytopathol, 18:37-66
26. Epp MA, Chanton JP. 1993. Rhizospheric methane oxidation determined via the methyl fluoride inhibition technique. J Geophys Res, 98:18413-18422
27. Flessa, H. Fischer WR. 1992. Plant induced changes in the redox potentials of rice rhizospheres. Plant Soil, 143:55-60
28. 4 production and oxidation. Biogeochemistry, 51:91-112
29. Fukuzaki S, Nishio N, Nagai S. 1990. Kinetics of the methanogenic fermentation of acetate. Appl Environ Microbiol, 56:3158-3163
30. Gilbert B, Frenzel P. 1995. Metrhanotrophic bacteria in the rhizosphere of rice microcosms and their effect an porewater methane concentration and methane emission. Biol Fert Soil, 20:93-100
31. 4 oxidation: The activity of bacteria, their distribution and the microenvironment. Soil Biol Biochem, 30:1903-1916
32. 4 on presence and activity of the indigenous methanotrophic community in rice, field soil. Environ Microbiol, 2:666-679
33. 2 in rice plant. Soil Sci Plant Nutr, 30:125-136
34. 2 by rice roots. Soil Sci Plant Nutr, 28:491-494
35. Hogan KB, Hoffman JS, Thompson AM. 1991. Methane on the greenhouse agenda. Nature, 354:181-182
36. Holzapfel-pschorn A, Conrad R, Seiler W. 1986. Effects of vegetation on the emission of methane from submerged paddy soil. Plant Soil, 92:223-233
37. Horst WJ, Wagner A, Marschner H. 1982. Mucilage protects root meristems from aluminium injury. Z Pflanzenphysiol, 105:435-444
38. 4 emission on soil, cultivars and grain yield. Global Change Biol, 3: 491-500
39. Jensen CR, Stolzy LH, Letey J. 1967. Tracer studies of oxygen diffusion through roots of barley, corn, and rice. Soil Sci, 103:23-29
40. Kawaguchi K, et al. 1983. Trans. Ji H-J, Sun H-X, Sun C-Q. 1985. Pedology of Paddy Field. Beijing: Agricultural Press. (in Chinese)
41. Kilham OW, Alexander M. 1984. A basis for organic matter accumulation in soil under anaerobiosis. Soil Sci, 137:419-427
42. Kimura M, Asiai K, Watanabe A, et al. 1992. Suppression of methane fluxes from flooded paddy soil with rice plants by foliar spray of nitrogen fertilizers. Soil Sci Plant Nutr. 38: 735-740
43. 4 production in rice rhizosphere. Soil Sci Plant Nutr, 37:55-60
44. King GM, Roslev P, Skovgard H. 1990. Distribution and rate of methane oxidation in sediments of the Florida Everglades. Appl Environ Microbiol, 6:2902-2911
45. King GM. 1996. In situ analysis of methane oxidation associated with the roots and rhizomes of the burweed, Sparganium eurycarpum, in a Maine wetland. Appl Environ Microbiol, 62:4545-4555
46. Kludze HK, Delaune RD. 1995 Aerenchya formation and methane and oxygen exhange in rice. Soil Scie Soc Am J, 59:939-945
47. Kumar AA, Jain MC. 1997. Methane emission from two Indian soils planted with different rice cultivars. Biol Fert Soils, 25:285-289
48. Lee KK, Holst RW, Watanabe I, et al. 1981. Gas transport through rice. Soil Sci Plant Nutr, 27:151-168
49. Lelieveld J, Crutzen PJ. 1992. Indirect chemical effects of methane on climate warming. Nature, 355:339-342
50. Leliveld J, Crutzen PJ, Dentener FJ. 1998. Changing concentration, lifetime and climate forcing of atmospheric methane. Tellus, 50: 128-150
51. Lin M, You C-B. 1989. Root exudates of rice (Oryza sativa L) and its interaction with Alcaligenes faecalis. Sci Agric Sin, 22:6-12(in Chinese)
52. Lu Y, wassmann R, Neue HU, et al. 2000. Methanogenic responses to exogenous substrates in anaerobic rice soils. Soil Biol Biochem. 32:1683-1690
53. Magnussont T. 1993. Carbon dioxide and methane formation in forest mineral and peat soil during aerobic and anaerobic incubations. Soil Biol Biochem, 25:877-883
54. Matsuo T, Futsuhara Y. Kikuchi F, et al. 1997. Science of the Rice Plant. Vol. 1. Morphology. Tokyo: Food and Agriculture Policy Research Center.
55. Minoda T, Kimura M. 1994. Contribution of photosynthesized carbon to the methane emitted from paddy fields. Geophys Res Lett, 21:2007-2010
56. 4 emitted to the atmosphere from paddy fields. J Geophys Res. 101:21091-21097
57. Mishra S, Rath AK, Adhya TK, et al. 1997. Effect of continuous and alternate water regimes on methane efflux from rice under greenhouse conditions. Biol Fert Soils, 24:399-405
58. Moorhead KK, Reddy KR. 1988. Regulation of root-associated methanotrophy by oxygen availability in the trhizosphere of two aquatic macrophytes. J Environ Qual, 17:138-142
59. Morrissey LA, Livingston GP. 1992. Methane emissions from Alaska arctic tundra: An assessment of local spatial variability. J Geophys Res, 97(D15):16661-16670
60. 2- from acid rain. Soil Biol Biochem, 27:893-903
61. Norton JM, Smith JL, Firestone MK. 1990. Carbon flow in the rhizosphere of ponderosa pine seedling. Soil Biol Biochem, 22:449-455
62. Nouchi I, Mariko S, Aoki K. 1990. Mechanism of methane transport from the rhizosphere through rice plants. Plant Physiol, 94:59-66
63. 2O: Global Emissions and Controls from Rice Fields and Other Agricultural and Industrial Sources, Japan, Tsukuba: National Institute of Agro-Environmental Sciences. 87-104
64. Papen H, Rennenberg H. 1990. Microbial processes involved in the emission of radioactively important trace gases. In: Trans 14th Int Soil Sci Congr, Vol. 2. Commission II. Kyoto: International Society of Soil Science. 232-237
65. Raimbault M, Rinaudo G, Garcia JL, et al. 1977. A device to study metabolic gases in the rhizosphere. Soil Biol Biochem, 9:193-196
66. Revsbecch NP, Pedersen O, Reichardt W. 1999. Microsensor analysis of oxygen and pH in the rice rhizosphere under field and laboratory conditions. Biol Fert Soils, 29:379-385
67. 4 efflux from a boreal mire: A growth chamber experiment. Oecologia, 119:349-356
68. 3 supply in boreal oligotrophic mire. Global Change Biol, 6:137-144
69. Sass RL, Fisher FM, Harcombe PA, et al. 1990. Methane production and emission in a Texas rice field. Global Biogeochem Cyc, 4: 47-68
70. Schutz H, Seiler W, Conrad R. 1989. Processes involved in formation and emission of methane in rice paddies. Biogeochemistry, 7:33-53
71. Smith LK, Lewis WW Jr. 1992. Seasonality of methane emissions from five lakes and associated wetlands of the Colorado Rockies. Global Biogeochem Cyc, 6:323-338
72. Teal JM, Kanwisher JW. 1966. Gas transport in the marsh grass, Spartina alterniflora. J Exp Bot, 17:356-361
73. 2 fluxes in peat. Soil Biol Biochem, 28:17-23
74. Van den Berg L, Patel GB, Clark DS, et al. 1976. Factors affecting rate of methane formation from acetic acid by enriched methanogenic cultures. Can J Microbiol, 22:1312-1319
75. Wang B, Neue HU, Samonte HP. 1997. Role of rice in mediating methane emission. Plant Soil, 189:107-115
76. Wassmann R, Aulakh MS. 2000. The role of rice plants in regulating mechanisms of methane missions. Biol Fert Soils, 31:20-29
77. Watanabe I, Hashimoto T. Shimoyama A. 1997. Methame-oxidizing activities and methanotrophic populations associated with wetland rice plants. Biol Fert Soils, 24:261-265
78. 2 removal and the role of plant roots. Soil Biol Biochem, 29:1257-1267
79. Williams RJ, Crawford RL. 1984. Methane production in Minnesota peatlands. Appl Environ Microbiol, 47:1266-1271
80. Wolin MJ. 1969. Volatile fatty acids and the inhibition of Escherichia coli growth by rumen fluid. Appl Microbiol, 17:83-87
81. 2 in anaerobic Sphagnum-derived peat from Big Run Bog, West Virginia. Biogeochemistry, 4:141-157
82. Zhang F-S. 1998. Nutrient Deficiency and Plant Rhizospheric Nutrition. Beijing: China Agricultural Press. (in Chinese)