Anaerobic microflora of everglades sediments: effects of nutrients on population profiles and activities
暂无分享,去创建一个
H. Drake | N. Aumen | C. Wagner | H L Drake | M Schmittroth | N G Aumen | C Kuhner | C Wagner | A Griesshammer | C. Kuhner | M. Schmittroth | A. Grießhammer
[1] Krishna R. Reddy,et al. Methane Production and Emissions from Four Reclaimed and Pristine Wetlands of Southeastern United States , 1994 .
[2] M. Winfrey,et al. Temperature limitation of methanogenesis in aquatic sediments , 1976, Applied and environmental microbiology.
[3] J. Breznak. Acetogenesis from Carbon Dioxide in Termite Guts , 1994 .
[4] E. A. Henry,et al. Mercury methylation in aquatic systems affected by acid deposition. , 1991, Environmental pollution.
[5] R. Bartha,et al. Sulfate-Reducing Bacteria: Principal Methylators of Mercury in Anoxic Estuarine Sediment , 1985, Applied and environmental microbiology.
[6] A. Nozhevnikova,et al. Acetogenesis at Low Temperature , 1994 .
[7] Stephen H. Zinder,et al. Physiological Ecology of Methanogens , 1993 .
[8] Derek R. Lovley,et al. Methanogenesis from Methanol and Methylamines and Acetogenesis from Hydrogen and Carbon Dioxide in the Sediments of a Eutrophic Lake , 1983, Applied and environmental microbiology.
[9] R. E. Hungate,et al. The Roll-Tube Method for Cultivation of Strict Anaerobes , 1972 .
[10] R. Delaune,et al. Long-Term Nutrient Accumulation Rates in the Everglades , 1993 .
[11] H. Drake,et al. Characterization of the H2- and CO-dependent chemolithotrophic potentials of the acetogens Clostridium thermoaceticum and Acetogenium kivui , 1990, Journal of bacteriology.
[12] J. Wood,et al. Synthesis of Methyl-mercury Compounds by Extracts of a Methanogenic Bacterium , 1968, Nature.
[13] D. I. Sebacher,et al. Methane emissions from the Florida Everglades: Patterns of variability in a regional wetland ecosystem , 1989 .
[14] O. Regnell. The effect of pH and dissolved oxygen levels on methylation and partitioning of mercury in freshwater model systems. , 1994, Environmental pollution.
[15] A. Gordon,et al. Denitrification in Marl and Peat Sediments in the Florida Everglades , 1986, Applied and environmental microbiology.
[16] K. Rutchey,et al. Inland Wetland Change Detection in the Everglades Water Conservation Area 2A Using a Time Series of Normalized Remotely Sensed Data , 1995 .
[17] Krishna R. Reddy,et al. Spatial distribution of soil nutrients in a northern Everglades marsh: water conservation area 1 , 1994 .
[18] H. Drake,et al. Effects of environmental parameters on the formation and turnover of acetate by forest soils , 1995, Applied and Environmental Microbiology.
[19] M. Yamada. Formation of methylmercury compounds from inorganic mercury by Clostridium cochlearium , 1972 .
[20] Ronald D. Jones,et al. Potential rates of methanogenesis in sawgrass marshes with peat and marl soils in the everglades , 1992 .
[21] H. Drake,et al. Nitrate as a preferred electron sink for the acetogen Clostridium thermoaceticum , 1993, Journal of bacteriology.
[22] J. Jones,et al. Interaction of acetogens and methanogens in anaerobic freshwater sediments , 1985, Applied and environmental microbiology.
[23] L. Harris,et al. Everglades: The Ecosystem and its Restoration. , 1995 .
[24] R. Bartha,et al. Carbon Flow in Mercury Biomethylation by Desulfovibrio desulfuricans , 1990, Applied and environmental microbiology.
[25] R. E. Hungate. Chapter IV A Roll Tube Method for Cultivation of Strict Anaerobes , 1969 .
[26] H. Drake. Acetogenesis, Acetogenic Bacteria, and the Acetyl-CoA “Wood/Ljungdahl” Pathway: Past and Current Perspectives , 1994 .
[27] J. Yavitt,et al. Methane production in contrasting wetland sites: Response to organic‐chemical components of peat and to sulfate reduction , 1990 .
[28] Ronald D. Jones,et al. Nutrient limitations on microbial respiration in peat soils with different total phosphorus content , 1993 .
[29] Nicolas S. Bloom,et al. Comparison of distillation with other current isolation methods for the determination of methyl mercury compounds in low level environmental samples , 1993 .
[30] A. Zehnder,et al. Geochemistry and biogeochemistry of anaerobic habitats. , 1988 .
[31] R. Knowles,et al. Methane Metabolism in a Temperate Swamp , 1994, Applied and environmental microbiology.
[32] D. Scheidt,et al. Ultra trace level mercury in the Everglades ecosystem, a multi-media canal pilot study , 1995 .
[33] M. Kerner. Coupling of microbial fermentation and respiration processes in an intertidal mudflat of the Elbe estuary , 1993 .
[34] Ralph Mitchell,et al. Sulfate stimulation of mercury methylation in freshwater sediments , 1992 .
[35] R. Ebinghaus,et al. Accumulation of mercury(II) and methylmercury by microbial biofilms , 1993 .
[36] D. Lovley,et al. Intermediary Metabolism of Organic Matter in the Sediments of a Eutrophic Lake , 1982, Applied and environmental microbiology.
[37] I. Berdicevsky,et al. Transformations of inorganic mercury by Candida albicans and Saccharomyces cerevisiae , 1991, Applied and environmental microbiology.
[38] D. Schimel. Microbial production and consumption of greenhouse gases: Methane, nitrogen oxides, and halomethanes , 1993 .
[39] T. Dalsgaard,et al. Nitrate Reduction in a Sulfate-Reducing Bacterium, Desulfovibrio desulfuricans, Isolated from Rice Paddy Soil: Sulfide Inhibition, Kinetics, and Regulation , 1994, Applied and environmental microbiology.
[40] M. Hamdy,et al. Formation of methyl mercury by bacteria. , 1975, Applied microbiology.
[41] J. Cole. Physiology, Biochemistry and Genetics of Nitrate Dissimilation to Ammonia , 1990 .
[42] R. Bartha,et al. Enzymatic catalysis of mercury methylation by Desulfovibrio desulfuricans LS , 1994, Applied and environmental microbiology.
[43] R. Bartha,et al. Cobalamin-mediated mercury methylation by Desulfovibrio desulfuricans LS , 1993, Applied and environmental microbiology.
[44] L. Daniels,et al. The specificity of growth inhibition of methanogenic bacteria by bromoethanesulfonate , 1987 .
[45] Glenn R. Gibson,et al. Sulphate-reducing Bacteria: List of Contributors , 2007 .
[46] Steven M. Davis,et al. Fluctuations in sawgrass and cattail densities in Everglades Water Conservation Area 2A under varying nutrient, hydrologic and fire regimes. , 1993 .
[47] H. Drake,et al. Acetate Synthesis in Soil from a Bavarian Beech Forest , 1994, Applied and environmental microbiology.
[48] J. Ferry. Fermentation of Acetate , 1993 .
[49] B. Schink. Diversity, Ecology, and Isolation of Acetogenic Bacteria , 1994 .
[50] R. Bartha,et al. The Sulphate-Reducing Bacteria , 1979 .
[51] A. Tunlid,et al. Laboratory Study of Chemical Speciation of Mercury in Lake Sediment and Water under Aerobic and Anaerobic Conditions , 1991, Applied and environmental microbiology.
[52] R. Ebinghaus,et al. Transformations of mercury species in the presence of Elbe river bacteria , 1993 .
[53] J. Yavitt,et al. Control of carbon mineralization to CH4 and CO2 in anaerobic,Sphagnum-derived peat from Big Run Bog, West Virginia , 1987 .
[54] J. Yavitt,et al. Potential methane production and methane oxidation rates in peatland ecosystems of the Appalachian m , 1988 .
[55] Ronald D. Jones,et al. CARBON MINERALIZATION IN PRISTINE AND PHOSPHORUS‐ENRICHED PEAT SOILS OF THE FLORIDA EVERGLADES , 1995 .
[56] A. Priemé,et al. Production and emission of methane in a brackish and a freshwater wetland , 1994 .
[57] H. Schöler,et al. Determination of mercury species in natural waters at picogram level with on-line RP C18 preconcentration and HPLC-UV-PCO-CVAAS , 1995 .