Chemoautotrophic Carbon Fixation Rates and Active Bacterial Communities in Intertidal Marine Sediments
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[1] J. D. Elsas,et al. Molecular Microbial Ecology Manual , 2013, Springer Netherlands.
[2] L. Tranvik,et al. Dark Carbon Fixation: An Important Process in Lake Sediments , 2013, PloS one.
[3] J. Middelburg. Chemoautotrophy in the ocean , 2011 .
[4] M. Nei,et al. MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. , 2011, Molecular biology and evolution.
[5] R. Amann,et al. Novel groups of Gammaproteobacteria catalyse sulfur oxidation and carbon fixation in a coastal, intertidal sediment. , 2011, Environmental microbiology.
[6] J. Middelburg,et al. Different proxies for the reactivity of aquatic sediments towards oxygen: A model assessment , 2010 .
[7] J. Middelburg,et al. Trophic specialisation of metazoan meiofauna at the Håkon Mosby Mud Volcano: fatty acid biomarker isotope evidence , 2009 .
[8] A. Smaal,et al. Introduction, establishment and expansion of the Pacific oyster Crassostrea gigas in the Oosterschelde (SW Netherlands) , 2009, Helgoland Marine Research.
[9] T. Lueders,et al. 13C-isotope analyses reveal that chemolithoautotrophic Gamma- and Epsilonproteobacteria feed a microbial food web in a pelagic redoxcline of the central Baltic Sea. , 2009, Environmental microbiology.
[10] D. Beer,et al. Functioning of intertidal flats inferred from temporal and spatial dynamics of O2, H2S and pH in their surface sediment , 2009 .
[11] J. Hayes,et al. Stable carbon-isotopic compositions of lipids isolated from the ammonia-oxidizing chemoautotroph Nitrosomonas europaea , 2008 .
[12] R. Glud. Oxygen dynamics of marine sediments , 2008 .
[13] L. Wick,et al. Differences of heterotrophic 13CO2 assimilation by Pseudomonas knackmussii strain B13 and Rhodococcus opacus 1CP and potential impact on biomarker stable isotope probing. , 2008, Environmental microbiology.
[14] Garth D Ehrlich,et al. Insights into the Genome of Large Sulfur Bacteria Revealed by Analysis of Single Filaments , 2007, PLoS biology.
[15] Martin A. J. Parry,et al. Discoveries in Rubisco (Ribulose 1,5-bisphosphate carboxylase/oxygenase): a historical perspective , 2007, Photosynthesis Research.
[16] G. King,et al. Disparate distributions of chemolithotrophs containing form IA or IC large subunit genes for ribulose-1,5-bisphosphate carboxylase/oxygenase in intertidal marine and littoral lake sediments. , 2007, FEMS microbiology ecology.
[17] C. Heip,et al. Bioturbation: a fresh look at Darwin's last idea. , 2006, Trends in ecology & evolution.
[18] U. Werner,et al. Surficial and deep pore water circulation governs spatial and temporal scales of nutrient recycling in intertidal sand flat sediment , 2006 .
[19] J. Kromkamp,et al. Phospholipid-derived fatty acids as chemotaxonomic markers for phytoplankton: application for inferring phytoplankton composition , 2006 .
[20] F. Meysman,et al. Predicted tortuosity of muds , 2006 .
[21] Marc Strous,et al. Structural identification of ladderane and other membrane lipids of planctomycetes capable of anaerobic ammonium oxidation (anammox) , 2005, The FEBS journal.
[22] R. Sassen,et al. Lipid Biomarkers and Carbon Isotope Signatures of a Microbial (Beggiatoa) Mat Associated with Gas Hydrates in the Gulf of Mexico , 2005, Applied and Environmental Microbiology.
[23] C. Heip,et al. Similar rapid response to phytodetritus deposition in shallow and deep-sea sediments , 2005 .
[24] J. Hollibaugh,et al. Distribution of RuBisCO Genotypes along a Redox Gradient in Mono Lake, California , 2004, Applied and Environmental Microbiology.
[25] M. Trimmer,et al. Anaerobic Ammonium Oxidation Measured in Sediments along the Thames Estuary, United Kingdom , 2003, Applied and Environmental Microbiology.
[26] C. Knief,et al. Linking autotrophic activity in environmental samples with specific bacterial taxa by detection of 13C-labelled fatty acids. , 2003, Environmental microbiology.
[27] Stefan Schouten,et al. Bicarbonate uptake by marine Crenarchaeota. , 2003, FEMS microbiology letters.
[28] R. Meyer,et al. Application of the isotope pairing technique in sediments where anammox and denitrification coexist , 2003 .
[29] H. Boschker,et al. Nitrification in the Schelde estuary: methodological aspects and factors influencing its activity. , 2002, FEMS microbiology ecology.
[30] Stefan Schouten,et al. Widespread occurrence of structurally diverse tetraether membrane lipids: evidence for the ubiquitous presence of low-temperature relatives of hyperthermophiles. , 2000, Proceedings of the National Academy of Sciences of the United States of America.
[31] C. Heip,et al. The fate of intertidal microphytobenthos carbon: An in situ 13C‐labeling study , 2000 .
[32] E. Kristensen,et al. Organic matter diagenesis in sediments on the continental shelf and slope of the Eastern Tropical and temperate North Pacific , 1999 .
[33] F. Tabita. Microbial ribulose 1,5-bisphosphate carboxylase/oxygenase: A different perspective , 1999, Photosynthesis Research.
[34] D. Kelly. Thermodynamic aspects of energy conservation by chemolithotrophic sulfur bacteria in relation to the sulfur oxidation pathways , 1999, Archives of Microbiology.
[35] J. Cole,et al. BACTERIAL GROWTH EFFICIENCY IN NATURAL AQUATIC SYSTEMS , 1998 .
[36] C. Martens,et al. Thermodynamic control on hydrogen concentrations in anoxic sediments , 1998 .
[37] R. Parkes,et al. Direct linking of microbial populations to specific biogeochemical processes by 13C-labelling of biomarkers , 1998, Nature.
[38] W. Liesack,et al. Elemental Sulfur and Thiosulfate Disproportionation by Desulfocapsa sulfoexigens sp. nov., a New Anaerobic Bacterium Isolated from Marine Surface Sediment , 1998, Applied and Environmental Microbiology.
[39] E. Kristensen,et al. Dynamics of sigmaCO2 in a surficial sandy marine sediment: the role of chemoautotrophy , 1997 .
[40] D. Nelson,et al. Organic carbon utilization by obligately and facultatively autotrophic beggiatoa strains in homogeneous and gradient cultures , 1996, Applied and environmental microbiology.
[41] Karline Soetaert,et al. A model of early diagenetic processes from the shelf to abyssal depths , 1996 .
[42] D. Kelly,et al. Chemolithoutotrophic growth of Thiothrix ramosa , 1993, Archives of Microbiology.
[43] B. Jørgensen,et al. Pathways and Microbiology of Thiosulfate Transformations and Sulfate Reduction in a Marine Sediment (Kattegat, Denmark) , 1991, Applied and environmental microbiology.
[44] G. King,et al. Effects of substrate concentration, growth state, and oxygen availability on relationships among bacterial carbon, nitrogen and phospholipid phosphorus content , 1990 .
[45] N. Pfennig,et al. Chemolithotrophic growth of Desulfovibrio sulfodismutans sp. nov. by disproportionation of inorganic sulfur compounds , 1987, Archives of Microbiology.
[46] B. Jørgensen,et al. Growth Pattern and Yield of a Chemoautotrophic Beggiatoa sp. in Oxygen-Sulfide Microgradients , 1986, Applied and environmental microbiology.
[47] W. Sand,et al. Signature fatty acids in the polar lipids of acid-producing Thiobacillus spp.: Methoxy, cyclopropyl, alpha-hydroxy-cyclopropyl and branched and normal monoenoic fatty acids , 1986 .
[48] D. White,et al. Extractable and lipopolysaccharide fatty acid and hydroxy acid profiles from Desulfovibrio species. , 1985, Journal of lipid research.
[49] R. Aller,et al. Effects of the marine deposit-feeders Heteromastus filiformis (Polychaeta), Macoma balthica (Bivalvia), and Tellina texana (Bivalvia) on averaged sedimentary solute transport, reaction rates, and microbial distributions , 1985 .
[50] D. Nelson,et al. Chemoautotrophic growth of a marine Beggiatoa in sulfide-gradient cultures , 1983, Archives of Microbiology.
[51] R. Parkes,et al. The Cellular Fatty Acids of the Sulphate-reducing Bacteria, Desulfobacter sp., Desulfobulbus sp. and Desulfovibrio desulfuricans , 1983 .
[52] C. Cavanaugh. Symbiotic chemoautotrophic bacteria in marine invertebrates from sulphide-rich habitats , 1983, Nature.
[53] Holger W. Jannasch,et al. Chemosynthetic Primary Production at East Pacific Sea Floor Spreading Centers , 1979 .
[54] J. H. Tuttle,et al. Microbial dark assimilation of CO2 in the Cariaco Trench1 , 1979 .
[55] Y. Sorokin. The Bacterial Population and the Processes of Hydrogen Sulphide Oxidation in the Black Sea , 1972 .
[56] M. Blumer,et al. Fatty Acids in the Lipids of Marine and Terrestrial Nitrifying Bacteria , 1969, Journal of bacteriology.
[57] Iver W. Duedall,et al. PREPARATION OF ARTIFICIAL SEAWATER1 , 1967 .
[58] W. Hempfling,et al. Yield Coefficients of Thiobacillus neapolitanus in Continuous Culture , 1967, Journal of bacteriology.
[59] Romanenko Vi. [HETEROTROPHIC CO-2 ASSIMILATION BY WATER BACTERIAL FLORA]. , 1964 .
[60] M. Kanemori,et al. Distribution and Population of Free-Living Cells Related to Endosymbiont A Harbored in Oligobrachia mashikoi (a Siboglinid Polychaete) Inhabiting Tsukumo Bay. , 2008, Microbes and environments.
[61] T. Naganuma,et al. Composition of archaeal, bacterial, and eukaryal RuBisCO genotypes in three Western Pacific arc hydrothermal vent systems , 2006, Extremophiles.
[62] F. Widdel,et al. Dissimilatory Sulfate- and Sulfur-Reducing Prokaryotes , 2006 .
[63] E. Kristensen,et al. Dynamics of CCOz in a surficial sandy marine sediment : the role of chemoautotrophy , 2006 .
[64] B. Jørgensen,et al. Sulfide oxidation in marine sediments: Geochemistry meets microbiology , 2004 .
[65] S. D. de Vries,et al. Competition between the facultatively chemolithotrophic Thiobacillus A2, an obligately chemolithotrophic Thiobacillus and a heterotrophic spirillum for inorganic and organic substrates , 2004, Archives of Microbiology.
[66] H. Boschker. Linking microbial community structure and functioning: stable istope (13C) labeling in combination with PLFA analysis , 2004 .
[67] H. Boschker. Section 8 update: Linking microbial community structure and functioning: stable isotope (13C) labeling in combination with PLFA analysis , 2004 .
[68] A. T. Hoor. Cell yield and bioenergetics of Thiomicrospira denitrificans compared with Thiobacillus denitrificans , 2004, Antonie van Leeuwenhoek.
[69] E. Spieck,et al. Fatty acid profiles of nitrite-oxidizing bacteria reflect their phylogenetic heterogeneity. , 2001, Systematic and applied microbiology.
[70] E. Spieck,et al. Fatty Acid Profiles of Nitrite-oxidizing Bacteria Reflect theirPhylogenetic Heterogeneity , 2001 .
[71] A. Stams,et al. Identification of sulfate reducers and Syntrophobacter sp. in anaerobic granular sludge by fatty-acid biomarkers and 16S rRNA probing , 1998 .
[72] J. G. Kuenen,et al. Colorless Sulfur Bacteria , 1992 .
[73] J. Prosser. Autotrophic nitrification in bacteria. , 1989, Advances in microbial physiology.
[74] M. Samuelsson,et al. Nitrification and dissimilatory ammonium production and their effects on nitrogen flux over the sediment-water interface in bioturbated coastal sediments , 1987 .
[75] G. W. Skyring,et al. Sulfate reduction in coastal ecosystems , 1987 .
[76] A. Timer-ten Hoor. Cell yield and bioenergetics of Thiomicrospira denitrificans compared with Thiobacillus denitrificans. , 1981, Antonie van Leeuwenhoek.
[77] Bo Barker J⊘rgensen. A comparison of methods for the quantification of bacterial sulfate reduction in coastal marine sediments: III. Estimation from chemical and bacteriological field data , 1978 .
[78] A. C. Redfield. The biological control of chemical factors in the environment. , 1960, Science progress.