Control of microbial methane production in wetland rice fields (original) (raw)
- Achtnich C, Bak F & Conrad R (1995) Competition for electron donors among nitrate reducers, ferric iron reducers, sulfate reducers, and methanogens in anoxic paddy soil. Biol Fertil Soils 19: 65–72
Google Scholar - Armstrong W (1979) Aeration in higher plants. Adv Bot Res 7: 226–332
Google Scholar - Arth I, Frenzel P and Conrad R (1998) Denitrification coupled to nitrification in the rhizosphere of rice. Soil Biol Biochem 30: 509–515
Google Scholar - Asakawa S & Hayano K (1995) Populations of methanogenic bacteria in paddy field soil under double cropping conditions (rice-wheat). Biol Fertil Soils 20: 113–117
Google Scholar - Aulakh MS, Wassmann R & Rennenberg H (2001) Methane emisions from rice fields — quantification, mechanisms, role of management, and mitigation options. Adv Agronomy 70: 193–260
Google Scholar - Begg CBM, Kirk GJD, Mackenzie AF & Neue HU (1994) Root-induced iron oxidation and pH changes in the lowland rice rhizosphere. New Phytol 128: 469–477
Google Scholar - Bodelier PLE, Hahn AP, Arth IR & Frenzel P (2000a) Effects of ammonium-based fertilisation on microbial processes involved in methane emission from soils planted with rice. Biogeochemistry 51: 225–257
Google Scholar - Bodelier PLE, Roslev P, Henckel T & Frenzel P (2000b) Stimulation by ammonium-based fertilizers of methane oxidation in soil around rice roots. Nature 403: 421–424
Google Scholar - 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
Google Scholar - Botz R, Pokojski HD, Schmitt M & Thomm M (1996) Carbon isotope fractionation during bacterial methanogenesis by CO2 reduction. Org Geochem 25: 255–262
Google Scholar - Bronson KF, Neue HU, Singh U & Abao EB (1997) Automated chamber measurements of methane and nitrous oxide flux in a flooded rice soil. 1. Residue, nitrogen, and water management. Soil Sci Soc Am J 61: 981–987
Google Scholar - Buendia LV, Neue HU, Wassmann R, Lantin RS, Javellana AM, Xu YC, Makarim AK, Corton TM & Charoensilp N (1997) Understanding the nature of methane emission from rice ecosystems as basis of mitigation strategies. Appl Energy 56: 433–444
Google Scholar - Burke RA (1993) Possible influence of hydrogen concentration on microbial methane stable hydrogen isotopic composition. Chemosphere 26: 55–67
Google Scholar - Butterbach-Bahl K, Papen H & Rennenberg H (1997) Impact of gas transport through rice cultivars on methane emission from rice paddy fields. Plant, Cell Environ 20: 1175–1183
Google Scholar - Cai ZC, Xing GX, Yan XY, Xu H, Tsuruta H, Yagi K & Minami K (1997) Methane and nitrous oxide emissions from rice paddy fields as affected by nitrogen fertilisers and water management. Plant Soil 196: 7–14
Google Scholar - Cao MK, Dent JB & Heal OW (1995) Modeling methane emissions from rice paddies. Global Biogeochem Cycles 9: 183–195
Google Scholar - Chidthaisong A & Conrad R (2000) Turnover of glucose and acetate coupled to reduction of nitrate, ferric iron and sulfate and to methanogenesis in anoxic rice field soil. FEMS Microbiol Ecol 31: 73–86
Google Scholar - Chidthaisong A, Inubushi K, Muramatsu Y & Watanabe I (1996) Production potential and emission of methane in flooded rice soil microcosms after continuous application of straws. Microbes Environ 11: 73–78
Google Scholar - Chidthaisong A, Rosenstock B & Conrad R (1999) Measurement of monosaccharides and conversion of glucose to acetate in anoxic rice field soil. Appl Environ Microbiol 65: 2350–2355
Google Scholar - Chin KJ & Conrad R (1995) Intermediary metabolism in methanogenic paddy soil and the influence of temperature. FEMS Microbiol Ecol 18: 85–102
Google Scholar - Chin KJ, Hahn D, Hengstmann U, Liesack W & Janssen PH (1999a) Characterization and identification of numerically abundant culturable bacteria from the anoxic bulk soil of rice paddy microcosms. Appl Environ Microbiol 65: 5042–5049
Google Scholar - Chin KJ, Lukow T & Conrad R (1999b) Effect of temperature on structure and function of the methanogenic archaeal community in an anoxic rice field soil. Appl Environ Microbiol 65: 2341–2349
Google Scholar - Cicerone RJ & Shetter JD (1981) Sources of atmospheric methane: measurements in rice paddies and a discussion. J Geophys Res 86: 7203–7209
Google Scholar - Conrad R (1989) Control of methane production in terrestrial ecosystems. In: Andreae MO & Schimel DS (eds) Exchange of Trace Gases between Terrestrial Ecosystems and the Atmosphere. Dahlem Konferenzen, pp 39–58. Wiley, Chichester
Google Scholar - Conrad R (1993) Mechanisms controlling methane emission from wetland rice fields. In: Oremland RS (ed) The Biogeochemistry of Global Change: Radiative Trace Gases, pp 317–335. Chapman & Hall, New York
Google Scholar - Conrad R (1999) Contribution of hydrogen to methane production and control of hydrogen concentrations in methanogenic soils and sediments [review]. FEMS Microbiol Ecol 28: 193–202
Google Scholar - Conrad R & Klose M (1999) Anaerobic conversion of carbon dioxide to methane, acetate and propionate on washed rice roots. FEMS Microbiol Ecol 30: 147–155
Google Scholar - Conrad R & Klose M (2000) Selective inhibition of reactions involved in methanogenesis and fatty acid production on rice roots. FEMS Microbiol Ecol 34: 27–34
Google Scholar - Conrad R, Klose M & Claus P (2000) Phosphate inhibits acetotrophic methanogenesis on rice roots. Appl Environ Microbiol 66: 828–831
Google Scholar - Crutzen PJ (1995) The role of methane in atmospheric chemistry and climate. In: vonEngelhardt W, Leonhardt-Marek S, Breves G & Giesecke D (eds) Ruminant Physiology: Digestion, Metabolism, Growth and Reproduction, pp 291–315. Enke, Stuttgart
Google Scholar - Dannenberg S & Conrad R (1999) Effect of rice plants on methane production and rhizospheric metabolism in paddy soil. Biogeochemistry 45: 53–71
Google Scholar - DeDatta SK (1995) Nitrogen transformations in wetland rice ecosystems. Fertilizer Res 42: 193–203
Google Scholar - Denier van der Gon HAC and Neue HU (1995) Influence of organic matter incorporation on the methane emission from a wetland rice field. Global Biogeochem Cycles 9: 11–22
Google Scholar - Fetzer S & Conrad R (1993) Effect of redox potential on methanogenesis by Methanosarcina barkeri. Arch Microbiol 160: 108–113
Google Scholar - Fetzer S, Bak F & Conrad R (1993) Sensitivity of methanogenic bacteria from paddy soil to oxygen and desiccation. FEMS Microbiol Ecol 12: 107–115
Google Scholar - Fey A & Conrad R (2000) Effect of temperature on carbon and electron flow and on the archaeal community in methanogenic rice field soil. Appl Environ Microbiol 66: 4790–4797
Google Scholar - Fey A, Chin KJ & Conrad R (2001) Thermophilic methanogens in rice field soil. Environ Microbiol 3: 295–303
Google Scholar - Frenzel P, Bosse U & Janssen PH (1999) Rice roots and methanogenesis in a paddy soil: ferric iron as an alternative electron acceptor in the rooted soil. Soil Biol Biochem 31: 421–430
Google Scholar - Frenzel P, Rothfuss F & Conrad R (1992) Oxygen profiles and methane turnover in a flooded rice microcosm. Biol Fertil Soils 14: 84–89
Google Scholar - Gaudin R & Dupuy J (1999) Ammoniacal nutrition of transplanted rice fertilized with large urea granules. Agronomy J 91: 33–36
Google Scholar - Gelwicks JT, Risatti JB & Hayes JM (1994) Carbon isotope effects associated with aceticlastic methanogenesis. Appl Environ Microbiol 60: 467–472
Google Scholar - Gilbert B & Frenzel P (1998) Rice roots and CH4 oxidation — the activity of bacteria, their distribution and the microenvironment. Soil Biol Biochem 30: 1903–1916
Google Scholar - Glissmann K & Conrad R (1999) Fermentation pattern of methanogenic degradation of rice straw in anoxic paddy soil. FEMS Microbiol Ecol 31: 117–126
Google Scholar - Glissmann K & Conrad R (2002) Saccharolytic activity and its role as a limiting step in methane formation during the anaerobic degradation of rice straw in rice paddy soil. Biol Fertil Soils, 35: 62–67
Google Scholar - Großkopf R, Janssen PH & Liesack W (1998a) Diversity and structure of the methanogenic community in anoxic rice paddy soil microcosms as examined by cultivation and direct 16S rRNA gene sequence retrieval. Appl Environ Microbiol 64: 960–969
Google Scholar - Großkopf R, Stubner S & Liesack W (1998b) Novel euryarchaeotal lineages detected on rice roots and in the anoxic bulk soil of flooded rice microcosms. Appl Environ Microbiol 64: 4983–4989
Google Scholar - Hengstmann U, Chin KJ, Janssen PH & Liesack W (1999) Comparative phylogenetic assignment of environmental sequences of genes encoding 16S rRNA and numerically abundant culturable bacteria from an anoxic rice paddy soil. Appl Environ Microbiol 65: 5050–5058
Google Scholar - Holzapfel-Pschorn A, Conrad R & Seiler W (1985) Production, oxidation and emission of methane in rice paddies. FEMS Microbiol Ecol 31: 343–351
Google Scholar - Houghton JT, Meira Filho LG, Lim B, Treanton K, Mamaty I, Bonduki Y, Griggs DJ & Callander BA (1997) Revised 1996 IPCC Guidelines for National Greenhouse Gas Inventories: Reference Manual, vol 3. Bracknell, UK: Intergovernmental Panel on Climate Change (IPCC)
Google Scholar - Hua X, Guangxi X, Cai ZC & Tsuruta H (1997) Nitrous oxide emissions from three rice paddy fields in China. Nutrient Cycl Agroecosyst 49: 23–28
Google Scholar - Huang Y, Sass RL & Fisher FM (1998) A semi-empirical model of methane emission from flooded rice paddy soils [review]. Global Change Biology 4: 247–268
Google Scholar - Jäckel U & Schnell S (2000) Suppression of methane emission from rice paddies by ferric iron fertilization. Soil Biol Biochem 32: 1811–1814
Google Scholar - Jetten MSM, Stams AJM & Zehnder AJB (1990) Acetate threshold and acetate activating enzymes in methanogenic bacteria. FEMS Microbiol Ecol 73: 339–344
Google Scholar - Khalil MAK, Rasmussen RA & Shearer MJ (1998a) Effects of production and oxidation processes on methane emissions from rice fields. J Geophys Res 103: 25233–25239
Google Scholar - Khalil MAK, Rasmussen RA, Shearer MJ, Chen ZL, Yao H & Yang J (1998b) Emissions of methane, nitrous oxide, and other trace gases from rice fields in China. J Geophys Res 103: 25241–25250
Google Scholar - Kimura M (2000) Anaerobic microbiology in waterlogged rice fields. In: Bollag JM & Stotzky G (eds) Soil Biochemistry, vol 10, pp 35–138. Marcel Dekker, New York
Google Scholar - Kimura M & Tun CC (1999) Microscopic observation of the decomposition process of leaf sheath of rice straw and colonizing microorganisms during the cultivation period of paddy rice. Soil Sci Plant Nutr 45: 427–437
Google Scholar - Klüber HD & Conrad R (1998a) Effects of nitrate, nitrite, NO and N2O on methanogenesis and other redox processes in anoxic rice field soil. FEMS Microbiol Ecol 25: 301–318
Google Scholar - Klüber HD & Conrad R (1998b) Inhibitory effects of nitrate, nitrite, NO and N2O on methanogenesis by Methanosarcina barkeri and Methanobacterium bryantii. FEMS Microbiol Ecol 25: 331–339
Google Scholar - Krüger M, Eller G, Conrad R & Frenzel P (2002) Seasonal variation in pathways of CH4 production and in CH4 oxidation in rice fields determined by stable isotopes and specific inhibitors. Global Change Biology 8: 265–280
Google Scholar - Krüger M, Frenzel P & Conrad R (2001) Microbial processes influencing methane emission from rice fields. Global Change Biol 7: 49–63.
Google Scholar - Krylova NI & Conrad R (1998) Thermodynamics of propionate degradation in methanogenic paddy soil. FEMS Microbiol Ecol 26: 281–288
Google Scholar - Krylova NI, Janssen PH & Conrad R (1997) Turnover of propionate in methanogenic paddy soil. FEMS Microbiol Ecol 23: 107–117
Google Scholar - Krzycki JA, Kenealy WR, DeNiro MJ & Zeikus JG (1987) Stable carbon isotope fractionation by Methanosarcina barkeri during methanogenesis from acetate, methanol, or carbon dioxide-hydrogen. Appl Environ Microbiol 53: 2597–2599
Google Scholar - Leadbetter JR & Breznak JA (1996) Physiological ecology of Methanobrevibacter cuticularis sp nov and Methanobrevibacter curvatus sp nov, isolated from the hindgut of the termite Reticulitermes flavipes. Appl Environ Microbiol 62: 3620–3631
Google Scholar - Lehmann-Richter S, Großkopf R, Liesack W, Frenzel P & Conrad R (1999) Methanogenic archaea and CO2-dependent methanogenesis on washed rice roots. Environ Microbiol 1: 159–166
Google Scholar - Liesack W, Schnell S & Revsbech NP (2000) Microbiology of flooded rice paddies [Review]. FEMS Microbiol Rev 24: 625–645
Google Scholar - Lu Y, Wassmann R, Neue HU & Huang C (1999) Impact of phosphorus supply on root exudation, aerenchyma formation and methane emission of rice plants. Biogeochemistry 47: 203–218
Google Scholar - Lueders T & Friedrich M (2000) Archaeal population dynamics during sequential reduction processes in rice field soil. Appl Environ Microbiol 66: 2732–2742
Google Scholar - Mayer HP & Conrad R (1990) Factors influencing the population of methanogenic bacteria and the initiation of methane production upon flooding of paddy soil. FEMS Microbiol Ecol 73: 103–112
Google Scholar - Minami K (1994) Methane from rice production. Fertil Res 37: 167–179
Google Scholar - Mosier AR, Duxbury JM, Freney JR, Heinemeyer O, Minami K & Johnson DE (1998) Mitigating agricultural emissions of methane [review]. Climatic Change 40: 39–80
Google Scholar - Neue HU & Roger PA (2000) Rice agriculture: factors controlling emissions. In: Khalil MAK (ed) Atmospheric Methane. Its Role in the Global Environment, pp 134–169. Springer, Berlin
Google Scholar - Neue HU & Scharpenseel HW (1987) Decomposition pattern of 14C-labeled rice straw in aerobic and submerged rice soils of the Philippines. Sci Total Environ 62: 431–434
Google Scholar - Nouchi I & Mariko S (1993) Mechanism of methane transport by rice plants. In: Oremland RS (ed) Biogeochemistry of Global Change, pp 336–352. Chapman & Hall, New York
Google Scholar - Potter CS (1997) An ecosystem simulation model for methane production and emission from wetlands. Global Biogeochem Cycles 11: 495–506
Google Scholar - Ramakrishnan B, Lueders T, Conrad R & Friedrich M (2000) Effect of soil aggregate size on methanogenesis and archaeal community structure in anoxic rice field soil. FEMS Microbiol Ecol 32: 261–270
Google Scholar - Ratering S & Conrad R (1998) Effects of short-term drainage and aeration on the production of methane in submerged rice soil. Global Change Biol 4:397–407
Google Scholar - Ratering S & Schnell S (2000) Localization of iron-reducing activity in paddy soil by profile studies. Biogeochemistry 48: 341–365
Google Scholar - Rath AK, Mohanty SR, Mishra S, Kumaraswamy S, Ramakrishnan B & Sethunathan N (1999) Methane production in unamended and rice-straw-amended soil at different moisture levels. Biol Fertil Soils 28: 145–149
Google Scholar - Reddy KR, Patrick Jr. WH & Lindau CW (1989) Nitrification-denitrification at the plant root-sediment interface in wetlands. Limnol Oceanogr 34: 1004–1013
Google Scholar - Revsbech NP, Pedersen O, Reichardt W & Briones A (1999) Microsensor analysis of oxygen and pH in the rice rhizosphere under field and laboratory conditions. Biol Fertil Soils 29: 379–385
Google Scholar - Rosencrantz D, Rainey FA & Janssen PH (1999) Culturable populations of Sporomusa spp. and Desulfovibrio spp. in the anoxic bulk soil of flooded rice microcosms. Appl Environ Microbiol 65: 3526–3533
Google Scholar - Roy R, Klüber HD & Conrad R (1997) Early initiation of methane production in anoxic rice soil despite the presence of oxidants. FEMS Microbiol Ecol 24: 311–320
Google Scholar - Sass RL & Fisher FM (1997) Methane emissions from rice paddies — a process study summary. Nutrient Cycling Agroecosyst 49: 119–127
Google Scholar - Sass RL, Fisher FM, Harcombe PA & Turner FT (1991) Mitigation of methane emissions from rice fields: Possible adverse effects of incorporated rice straw. Global Biogeochem Cycles 5: 275–287
Google Scholar - Schink B (1997) Energetics of syntrophic cooperation in methanogenic degradation. Microbiol Molec Biol Rev 61: 262–280
Google Scholar - Scholten JCM & Conrad R (2000) Energetics of syntrophic propionate oxidation in defined batch and chemostat cocultures. Appl Environ Microbiol 66: 2934–2942
Google Scholar - Schütz H, Holzapfel-Pschorn A, Conrad R, Rennenberg H & Seiler W (1989) A 3-year continuous record on the influence of day-time, season, and fertilizer treatment on methane emission rates from an Italian rice paddy. J Geophys Res 94: 16405–16416
Google Scholar - Schütz H, Schröder P & Rennenberg H (1991) Role of plants in regulating the methane flux to the atmosphere. In: Sharkey TD, Holland EA, Mooney HA (eds) Trace Gas Emissions by Plants, pp 29–63. Academic Press, San Diego
Google Scholar - Schütz H, Seiler W & Conrad R (1990) Influence of soil temperature on methane emission from rice paddy fields. Biogeochemistry 11: 77–95
Google Scholar - Schütz H, Seiler W & Rennenberg H (1990) Soil and land use related sources and sinks of methane (CH4) in the context of the global methane budget. In: Bouwman AF (ed) Soils and the Greenhouse Effect, pp 269–285. Wiley, Chichester
Google Scholar - Segers R (1998) Methane production and methane consumption — a review of processes underlying wetland methane fluxes [review]. Biogeochemistry 41: 23–51
Google Scholar - Shearer MJ & Khalil MAK (1993) Rice agriculture: emissions. In: Khalil MAK (ed) Atmospheric Methane: Sources, Sinks, and Role in Global Change, pp 230–253. Springer, Berlin
Google Scholar - Sigren LK, Lewis ST, Fisher FM & Sass RL (1997) Effects of field drainage on soil parameters related to methane production and emission from rice paddies. Global Biogeochem Cycles 11: 151–162
Google Scholar - Summons RE, Franzmann PD & Nichols PD (1998) Carbon isotope fractionation associated with methylotrophic methanogenesis. Org Geochem 28: 465–475
Google Scholar - Suratno W, Murdiyarso D, Suratmo FG, Anas I, Saeni MS & Rambe A (1998) Nitrous oxide flux from irrigated rice fields in West Java. Environ Pollut 102: 159–166
Google Scholar - Tsutsuki K & Ponnamperuma FN (1987) Behavior of anaerobic decomposition products in submerged soils. Effects of organic material amendment, soil properties, and temperature. Soil Sci Plant Nutr 33: 13–33
Google Scholar - vanHulzen JB, Segers R, vanBodegom PM & Leffelaar PA (1999) Temperature effects on soil methane production: an explanation for observed variability. Soil Biol Biochem 31: 1919–1929
Google Scholar - Wang B, Neue HU & Samonte HP (1997) Effect of cultivar difference ('IR72', 'IR65598' and 'Dular') on methane emission. Agric Ecosyst Environ 62: 31–40
Google Scholar - Wang ZP, DeLaune RD, Masscheleyn PH & Patrick WH (1993) Soil redox and pH effects on methane production in a flooded rice soil. Soil Sci Soc Am J 57: 382–385
Google Scholar - Watanabe A & Kimura M (1998) Factors affecting variation in CH4 emission from paddy soils grown with different rice cultivars — a pot experiment. J Geophys Res 103: 18947–18952
Google Scholar - Watanabe A & Kimura M (1999) Influence of chemical properties of soils on methane emission from rice paddies. Comm Soil Sci Plant Anal 30: 2449–2463
Google Scholar - Watanabe A, Katoh K and Kimura M (1993) Effect of rice straw application on CH4 emission from paddy fields. 2. contribution of organic constituents in rice straw. Soil Sci Plant Nutr 39: 707–712
Google Scholar - Watanabe A, Takeda T & Kimura M (1999) Evaluation of origins of CH4 carbon emitted from rice paddies. J Geophys Res 104: 23623–23629
Google Scholar - Weber S, Stubner S & Conrad R (2001) Bacterial populations colonizing and degrading rice straw in anoxic paddy soil. Appl Environ Microbiol 67: 1318–1327
Google Scholar - Whiticar MJ (1999) Carbon and hydrogen isotope systematics of bacterial formation and oxidation of methane. Chem Geology 161: 291–314
Google Scholar - Wind T & Conrad R (1997) Localization of sulfate reduction in planted and unplanted rice field soil. Biogeochemistry 37: 253–278
Google Scholar - Wu XL, Chin KJ, Stubner A & Conrad R (2001) Functional patterns and temperature response of cellulose-fermenting microbial cultures containing different methanogenic communities. Appl Microbiol Biotechnol 65: 212–219
Google Scholar - Wu XL, Chin KJ, Conrad R (2002) Effect of temperature stress on structure and function of the methanogenic archaeal community in a rice field soil. FEMS Microbiol Ecol 32: 211–218.
Google Scholar - Wu XL, Conrad R (2001) Functional and structural response of a cellulose-degrading methanogenic microbiol community to multiple aeration stress at two different temperatures. Environ Microbiol 3: 355–362.
Google Scholar - Yagi K & Minami K (1990) Effect of organic matter application on methane emission from some Japanese paddy fields. Soil Sci Plant Nutr 36: 599–610
Google Scholar - Yagi K, Tsuruta H & Minami K (1997) Possible options for mitigating methane emission from rice cultivation. Nutr Cycl Agroecosyst 49: 213–220
Google Scholar - Yagi K, Tsuruta H, Kanda K & Minami K (1996) Effect of water management on methane emission from a Japanese rice paddy field: Automated methane monitoring. Global Biogeochem Cycles 10: 255–267
Google Scholar - Yao H & Conrad R (1999) Thermodynamics of methane production in different rice paddy soils from China, the Philippines and Italy. Soil Biol Biochem 31: 463–473
Google Scholar - Yao H & Conrad R (2000a) Electron balance during steady-state production of CH4 and CO2 in anoxic rice soil. Eur J Soil Sci 51: 369–378
Google Scholar - Yao H & Conrad R (2000b) Effect of temperature on reduction of iron and production of carbon dioxide and methane in anoxic wetland rice soils. Biol Fertil Soils 32: 135–141
Google Scholar - Yao H & Conrad R (2001) Thermodynamics of propionate degradation in anoxic paddy soil from different rice-growing regions. Soil Biol Biochem 33: 359–364
Google Scholar - Yao H, Conrad R, Wassmann R & Neue HU (1999) Effect of soil characteristics on sequential reduction and methane production in sixteen rice paddy soils from China, the Philippines, and Italy. Biogeochemistry 47: 269–295
Google Scholar