SEARCH

SEARCH BY CITATION

References

  • [1]
    Ponnamperuma, F.N. (1984) Straw as a source of nutrients for wetland rice. In: Organic Matter and Rice, pp. 117–136. International Rice Research Institute, Los Baños.
  • [2]
    Karim, A.J.M.S, Egashira, K, Yamada, Y, Haider, J, Nahar, K (1995) Long-term application of organic residues to improve soil properties and to increase crop yield in terrace soil of Bangladesh. J. Fac. Agric. Kyushu Univ. 39, 149165.
  • [3]
    Cassman, K.G, De Datta, S.K, Amarante, S.T, Liboon, S.P, Samson, M.I, Dizon, M.A (1996) Long-term comparison of the agronomic efficiency and residual benefits of organic and inorganic nitrogen sources for tropical lowland rice. Exp. Agric. 32, 427444.
  • [4]
    Adachi, K, Chaitep, W, Senboku, T (1997) Promotive and inhibitory effects of rice straw and cellulose application on rice plant growth in pot and field experiments. Soil Sci. Plant Nutr. 43, 369386.
  • [5]
    Matsuguchi, T. (1979) Factors affecting heterotrophic nitrogen fixation in submerged rice soils. In: Nitrogen and Rice, pp. 207–222. International Rice Research Institute, Los Baños.
  • [6]
    Ladha, J.K, Tirol, A.C, Daroy, M.L.G, Caldo, G, Ventura, W, Watanabe, I (1986) Plant-associated N2 fixation (C2H2 reduction) by five rice varieties, and relationship with plant growth characters as affected by straw incorporation. Soil Sci. Plant Nutr. 32, 91106.
  • [7]
    Santiago-Ventura, T, Bravo, M, Daez, C, Ventura, V, Watanabe, I, App, A.A (1986) Effects of N-fertilizers, straw, and dry fallow on the nitrogen balance of a flooded soil planted with rice. Plant Soil 93, 405411.
  • [8]
    Ladha, J.K, Tirol-Padre, A, Daroy, M.L.G, Punzalan, G, Watanabe, I (1987) The effects on N2 fixation (C2H2 reduction), bacterial population and rice plant growth of two modes of straw application to a wetland rice field. Biol. Fertil. Soils 5, 106111.
  • [9]
    Rice, W.A, Paul, E.A (1972) The organisms and biological processes involved in asymbiotic nitrogen fixation in waterlogged soil amended with straw. Can. J. Microbiol. 18, 715723.
  • [10]
    Yoneyama, T, Lee, K.K, Yoshida, T (1977) Decomposition of rice residues in tropical soils. IV. The effect of rice straw on nitrogen fixation by heterotrophic bacteria in some Philippine soils. Soil Sci. Plant Nutr. 23, 287295.
  • [11]
    Adachi, K, Watanabe, I, Kobayashi, M, Takahashi, E (1989) Effect of application of glucose, cellulose, and rice straw on nitrogen fixation (acetylene reduction and soil-nitrogen components) in anaerobic soil. Soil Sci. Plant Nutr. 35, 235243.
  • [12]
    Kanungo, P.K, Ramakrishnan, B, Rao, V.R (1997) Placement effects of organic sources on nitrogenase activity and nitrogen-fixing bacteria in flooded rice soils. Biol. Fertil. Soils 25, 103108.
  • [13]
    Reddy, K.R, Patrick, W.H (1979) Nitrogen fixation in flooded soil. Soil Sci. 128, 8085.
  • [14]
    Matsuguchi, T. and Yoo, I.D. (1981) Stimulation of phototrophic N2 fixation in paddy fields through rice straw application. In: Nitrogen Cycling in Southeast Asian Wet Monsoonal Ecosystems (Wetselaar, R., Simpson, J.R. and Rosswall, T., Eds.), pp. 18–25. Australian Academy of Science, Canberra.
  • [15]
    Okuda, A, Yamaguchi, M, Kobayashi, M (1960) Nitrogen-fixing microorganisms in paddy soils. V. Nitrogen fixation in mixed culture of photosynthetic bacteria (Rhodopseudomonas capsulatus species) with other heterotrophic bacteria (1). Soil Plant Food 6, 3539.
  • [16]
    Okuda, A, Yamaguchi, M, Kobayashi, M, Katayama, T (1961) Nitrogen-fixing microorganisms in paddy soils: VIII. Nitrogen fixation in mixed culture of photosynthetic bacteria (Rhodopseudomonas capsulatus species) with other heterotrophic bacteria (2). Soil Sci. Plant Nutr. 7, 146151.
  • [17]
    Kobayashi, M, Katayama, T, Okuda, A (1965) Nitrogen-fixing microorganisms in paddy soils XIII. Nitrogen fixation in mixed culture of photosynthetic bacteria (R. capsulatus species) with other heterotrophic bacteria (3). Association with B. subtilis. Soil Sci. Plant Nutr. 11, 7477.
  • [18]
    Katayama, T, Kobayashi, M, Okuda, A (1965) Nitrogen-fixing microorganisms in paddy soils XIV. Nitrogen fixation in mixed culture of photosynthetic bacteria (R. capsulatus species) with other heterotrophic bacteria (4). Association with B. megaterium. Soil Sci. Plant Nutr. 11, 7883.
  • [19]
    Kobayashi, M, Katayama, T, Okuda, A (1965) Nitrogen-fixing microorganisms in paddy soils XV. Nitrogen fixation in a mixed culture of photosynthetic bacteria (R. capsulatus) with other heterotrophic bacteria (5). Association with Azotobacter agilis. Soil Sci. Plant Nutr. 11, 99103.
  • [20]
    Yagi, K, Minami, K (1990) Effect of organic matter application on methane emission from some Japanese paddy fields. Soil Sci. Plant Nutr. 36, 599610.
  • [21]
    Sass, R.L, Fisher, F.M, Harcombe, P.A, Turner, F.T (1991) Mitigation of methane emissions from rice fields: Possible adverse effects of incorporated rice straw. Glob. Biogeochem. Cycles 5, 275287.
  • [22]
    Wassmann, R, Neue, H.U, Alberto, M.C.R, Lantin, R.S, Bueno, C, Llenaresas, D, Arah, J.R.M, Papen, H, Seiler, W, Rennenberg, H (1996) Fluxes and pools of methane in wetland rice soils with varying organic inputs. Environ. Monit. Assess. 42, 163173.
  • [23]
    Watanabe, A, Kimura, M (1998) Effect of rice straw application on CH4 emission from paddy fields. IV. Influence of rice straw incorporated during the previous cropping period. Soil Sci. Plant Nutr. 44, 507512.
  • [24]
    Bossio, D.A, Horwath, W.R, Mutters, R.G, van Kessel, C (1999) Methane pool and flux dynamics in a rice field following straw incorporation. Soil Biol. Biochem. 31, 13131322.
  • [25]
    Wang, B, Xu, Y, Wang, Z, Li, Z, Ding, Y, Guo, Y (1999) Methane production potentials of twenty-eight rice soils in China. Biol. Fertil. Soils 29, 7480.
  • [26]
    Asakawa, S, Hayano, K (1995) Populations of methanogenic bacteria in paddy field soil under double cropping conditions (rice-wheat). Biol. Fertil. Soils 20, 113117.
  • [27]
    Rothfuss, F, Conrad, R (1993) Vertical profiles of CH4 concentrations, dissolved substrates and processes involved in CH4 production in a flooded Italian rice field. Biogeochemistry 18, 137152.
  • [28]
    Ueki, A, Nishida, S, Kumakura, M, Kaku, N, Kainuma, Y, Hattori, C, Fujii, H, Ueki, K (1999) Effects of organic matter application, temperature, and sunshine duration on seasonal and annual variations of methanogenic activity in wetland rice field soil. Soil Sci. Plant Nutr. 45, 811823.
  • [29]
    Gunsalus, R.P, Romesser, J.A, Wolfe, R.S (1978) Preparation of coenzyme M analogues and their activity in the methyl coenzyme M reductase system of Methanobacteriukm thermoautotrophicum. Biochemistry 17, 23742377.
  • [30]
    Sparling, R, Daniels, L (1987) The specificity of growth inhibition of methanogenic bacteria by bromoethansulfonate. Can. J. Microbiol. 33, 11321136.
  • [31]
    Hoshino, Y. and Satoh, T. (1986) 3. Phototrophic bacteria. In: Biseibutsu-no-bunrihou (Yamasato, K., Udagawa, S., Kodama, T. and Morichi, T., Eds.), pp. 499–505. R&D Planning, Tokyo.
  • [32]
    Matsuguchi, T, Shimomura, T, Lee, S.K (1979) Factors regulating acetylene reduction assay for measuring heterotrophic nitrogen fixation in water-logged soils. Soil Sci. Plant Nutr. 25, 323336.
  • [33]
    Pfennig, N. and Trüper, H.G. (1989) Section 18. Anoxygenic phototrophic bacteria. In: Bergey's Manual of Systematic Bacteriology, Volume 3 (Staley, J.T., Bryant, M.P., Pfennig, N. and Holt, J.G., Eds.), pp. 1635–1709. Williams and Wilkins, Baltimore, MD.
  • [34]
    Haque, M.Z, Kobayashi, M, Fujii, K, Takahashi, E (1969) Seasonal changes of photosynthetic bacteria and their products. Soil Sci. Plant Nutr. 15, 5155.
  • [35]
    Krylova, N.I, Janssen, P.H, Conrad, R (1997) Turnover of propionate in methanogenic paddy soil. FEMS Microbiol. Ecol. 23, 107117.
  • [36]
    Rath, A.K, Mohanty, S.R, 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, 145149.
  • [37]
    Glissmann, K, Conrad, R (2000) Fermentation pattern of methanogenic degradation of rice straw in anoxic paddy soil. FEMS Microbiol. Ecol. 31, 117126.
  • [38]
    Patrick, W.H. Jr. and Reddy, C.N. (1978) Chemical changes in rice soils. In: Soils and Rice, pp. 361–379. International Rice Research Institute, Los Baños.
  • [39]
    Inubushi, K, Wada, H, Takai, Y (1984) Easily decomposable organic matter in paddy soil. IV. Relationship between reduction process and organic matter decomposition. Soil Sci. Plant Nutr. 30, 189198.
  • [40]
    Mayer, H.P, Conrad, R (1990) Factors influencing the population of methanogenic bacteria and the initiation of methane production upon flooding paddy soil. FEMS Microbiol. Ecol. 73, 103112.
  • [41]
    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, 6572.
  • [42]
    Gotoh, S, Onikura, Y (1971) Organic acids in a flooded soil receiving added rice straw and their effect on the growth of rice. Soil Sci. Plant Nutr. 17, 18.
  • [43]
    Watanabe, I. (1984) Anaerobic decomposition of organic matter in flooded rice soils. In: Organic Matter and Rice, pp. 237–258. International Rice Research Institute, Los Baños.
  • [44]
    Tsutsuki, K, Ponnamperuma, F.N (1987) Behavior of anaerobic decomposition products in submerged soils. Effects of organic material amendment, soil properties, and temperature. Soil Sci. Plant Nutr. 33, 1333.
  • [45]
    Chin, K.J, Conrad, R (1995) Intermediary metabolism in methanogenic paddy soil and the influence of temperature. FEMS Microbiol. Ecol. 18, 85102.
  • [46]
    Ferry, J.G (1992) Methane from acetate. J. Bacteriol. 174, 54895495.
  • [47]
    Roy, R, Klüber, H.D, Conrad, R (1997) Early initiation of methane production in anoxic rice soil despite the presence of oxidants. FEMS Microbiol. Ecol. 24, 311320.
  • [48]
    Klüber, H.D, Conrad, R (1998) Effects of nitrate, nitrite, NO and N2O on methanogenesis and other redox processes in anoxic rice field soil. FEMS Microbiol. Ecol. 25, 301318.
  • [49]
    Meyer, J, Kelley, B.C, Vignais, P.M (1978) Effect of light on nitrogenase function and synthesis in Rhodopseudomonas capsulata. J. Bacteriol. 136, 201208.
  • [50]
    Kern, M, Kamp, P.B, Paschen, A, Masepohl, B, Klipp, W (1998) Evidence for a regulatory link of nitrogen fixation and photosynthesis in Rhodobacter capsulatus via HvrA. J. Bacteriol. 180, 19651969.
  • [51]
    Schick, H.J (1971) Interrelationship of nitrogen fixation, hydrogen evolution and photoreduction in Rhodospirillum rubrum. Arch. Mikrobiol. 75, 102109.