Evidence for Anaerobic CH₄ Oxidation in Freshwater Peatlands

REFERENCES

• Alperin , M J and Reeburgh , W S . 1984 . “ Geochemical evidence supporting anaerobic methane oxidation ” . In Microbial Growth on C1 Compounds , Edited by: Crawford , R and Hanson , R . 282 – 289 . Washington , DC : American Society for Microbiology .
   Google Scholar
• Alperin , M J and Reeburgh , W S . 1985 . Inhibition experiments on anaerobic methane oxidation. Appl Environ Microb 50:940–945. Alperin MJ, Reeburgh WS, Whiticar MJ. 1988. Carbon and hydrogen isotope fractionation resulting from anaerobic methane oxidation . Global Biogeochem Cy , 2 : 279 – 288 .
   Web of Science ®Google Scholar
• Basiliko , N and Yavitt , J B . 2001 . Influence of Ni, Co, Fe, and Na additions on methane production in Sphagnum-dominated Northern American peatlands . Biogeochemistry , 52 : 133 – 153 .
   Web of Science ®Google Scholar
• Bernard , J M and Macdonald , J G . 1974 . Primary production and life history of Carex lacustris . Can J Botany , 52 : 117 – 123 .
   Google Scholar
• Boetius , A , Ravenschlag , K , Schubert , C J , Rickert , D , Widdel , F , Gieseke , A , Amann , R , Jorgensen , B B , Witte , U and Pfannkuche , O . 2000 . A marine microbial consortium appartently mediating anaerobic oxidation of methane . Nature , 407 : 623 – 626 .
   PubMed Web of Science ®Google Scholar
• Bridgham , S D , Updegraff , K and Pastor , J . 1998 . Carbon, nitrogen, and phosphorous mineralization in nothern wetlands . Ecology , 79 : 1545 – 1561 .
   Web of Science ®Google Scholar
• Brock , T D . 1978 . “ The poisoned control in biogeochemical investigations ” . In Environmental Biogeochemistry and Microbiology , Edited by: Krunben , W E . 717 – 725 . Ann Arbor , MI : Ann Arbor Science .
   Google Scholar
• Bubier , J L , Moore , T R and Juggins , S . 1995 . Predicting methane emission from bryophyte distribution in northern Canadian peatlands . Ecology , 76 : 677 – 693 .
   Web of Science ®Google Scholar
• Chanton , J P , Chasar , L C , Glaser , P and Siegel , D . 2005 . “ Carbon and hydrogen isotopic effects in microbial methane from terrestrial environments ” . In Stable isotopes and biosphere-atmosphere interactions , Edited by: Flanagan , L B . 85 – 105 . Amsterdam : Elsevier-Academic Press .
   Google Scholar
• Chidthaisong , A , Chin , K , Valentine , D L and Tyler , S C . 2002 . A comparison of isotope fractionation of carbon and hydrogen from paddy field rice roots and soil bacterial enrichments during CO2/H2 methanogenesis . Geochim Cosmochim Acta , 66 : 983 – 995 .
   Web of Science ®Google Scholar
• Coleman , D D , Risatte , J B and Schoell , M . 1981 . Fractionation of carbon and hydrogen isotopes by methane oxidizing bacteria . Geochim Cosmochim Ac , 45 : 1033 – 1037 .
   Web of Science ®Google Scholar
• Crill , P , Bartlett , K and Roulet , N . 1993 . Methane flux from boreal peatlands . Suo , 43 : 173 – 182 .
   Google Scholar
• Daniel , R , Warnecke , F , Potekhina , J S and Gottschalk , G . 1999 . Identification of the syntrophic partners in a coculture coupling anaerobic methanol oxidation to Fe(III) reduction . FEMS Microbiol Lett , 180 : 197 – 203 .
   PubMed Web of Science ®Google Scholar
• Dettling , M D , Yavitt , J B and Zinder , S H . 2006 . Control of organic carbon mineralization by alternative electron acceptors in four peatlands, Central New York State, USA . Wetlands , 26 : 917 – 927 .
   Web of Science ®Google Scholar
• Dise , N B and Verry , E S . 2001 . Suppression of peatland methane emission by cumulative sulfate deposition in simulated acid rain . Biogeochemistry , 53 : 143 – 160 .
   Web of Science ®Google Scholar
• Flett , R J , Hamilton , R D and Cambell , N ER . 1976 . Aquatic acetylene-reduction techniques: solutions to several problems . Can J Microbiol , 22 : 43 – 51 .
   PubMed Web of Science ®Google Scholar
• Fung , I , John , J , Lerner , J , Matthews , E , Prather , M , Steele , M P and Fraser , P J . 1991 . Three dimensional model synthesis of the global methane cycle . J Geophys Res , 96 : 13033 – 13065 .
   Web of Science ®Google Scholar
• Gauci , V , Dise , N and Fowler , D . 2002 . Controls on suppression of methane flux from a peat bog subjected to simulated acid rain sulfate depostion . Global Biogeochem Cy , 16 : 1 – 12 .
   Web of Science ®Google Scholar
• Gorham , E . 1991 . Northern Peatlands: Role in the carbon cycle and probable responses to climatic warming . Ecol Appl , 1 : 182 – 195 .
   PubMed Web of Science ®Google Scholar
• Granberg , G , Sundh , I , Svensson , B H and Nilsson , M . 2001 . Effects of temperature, and nitrogen and sulfur deposition, on methane emission from a boreal mire . Ecology , 82 : 1982 – 1998 .
   Web of Science ®Google Scholar
• Grossman , E L , Cifuentes , L A and Cozzarelli , I M . 2002 . Anaerobic methane oxidation in a landfill-leachate plume . Environ Sci Technol , 36 : 2436 – 2442 .
   PubMed Web of Science ®Google Scholar
• Hallam , S J , Putnam , N , Preston , C M , Detter , J C , Rokhsar , D S , Richardson , P M and De Long , E F . 2004 . Reverse methanogenesis: Testing the hypothesis with environmental genomics . Science , 305 : 1457 – 1462 .
   PubMed Web of Science ®Google Scholar
• Hanson , R S and Hanson , T E . 1996 . Methanotrophic bacteria . Microbiol Rev , 60 : 439 – 471 .
   PubMedGoogle Scholar
• Hinrichs , K-U and Boetius , A . 2002 . “ The anaerobic oxidation of methane: New insights in microbial ecology and biogeochemistry ” . In Ocean Margin Systems , Edited by: Wefer , G . 457 – 477 . Heidelberg : Springer Verlag .
   Google Scholar
• Hoehler , T M , Alperin , M J , Albert , D B and Martens , C S . 1994 . Field and laboratory studies of methane oxidation in an anoxic marine sediment-evidence for a methanogen-sulfate reducer consortium . Global Biogeochem Cy , 8 : 451 – 463 .
   Web of Science ®Google Scholar
• Islas-Lima , S , Thalasso , F and Gómez-Hernandez , J . 2004 . Evidence of anoxic methane oxidation coupled to denitrification . Water Res , 38 : 13 – 16 .
   PubMed Web of Science ®Google Scholar
• Iversen , N , Oremland , R S and Klug , M J . 1987 . Big Soda Lake (Nevada). 3. Pelagic methanogenesis and anaerobic methane oxidation . Limnol Oceanogr , 32 : 804 – 814 .
   Web of Science ®Google Scholar
• Jarrell , K F and Kalmokoff , M L . 1988 . Nutritional requirements of the methanogenic archaebacteria . Can J Microbiol , 34 : 557 – 576 . Kiene RP. 1991. Production and consumption of methane in aquatic systems. In: Rogers JE, Whitman WB, editors. Microbial production and consumption of greenhouse gases: methane, nitrogen oxides, and halomethanes. Washington, DC: American Society for Microbiology. P 111–146
   Web of Science ®Google Scholar
• Kluber , H D and 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 : 301 – 318 .
   Web of Science ®Google Scholar
• Kruger , M , Meyerdierks , A , Glockner , F O , Amann , R , Widdel , F , Kube , M , Reinhardt , R , Kahnt , R , Bocher , R , Thauer , R K and Shima , S . 2003 . A conspicuous nickel protein in microbial mats that oxidize methane anaerobically . Nature , 426 : 878 – 881 .
   PubMed Web of Science ®Google Scholar
• Lovley , D R and Phillips , E JP . 1986 . Organic matter mineralization with reduction of ferric iron in anaerobic sediments . Appl Environ Microb , 51 : 683 – 689 .
   PubMed Web of Science ®Google Scholar
• Lovley , D R and Phillips , E JP . 1988 . Novel mode of microbial energy metabolism: organic carbon oxidation coupled to dissimilatory reduction of iron or manganese . Appl Environ Microb , 54 : 1472 – 1480 .
   PubMed Web of Science ®Google Scholar
• Lovley , D R , Coates , J D , Blunt , H EL , Phillips , E JP and Woodward , J C . 1996 . Humic substances as electron acceptors for microbial respiration . Nature , 382 : 445 – 448 .
   Web of Science ®Google Scholar
• Malek , R E and Weismann , T J . 1988 . Cyclic behavior in anaerobic methane production and oxidation . J Penn Ac Sci , 62 : 155 – 159 .
   Google Scholar
• Malmer , N and Wallén , B . 1996 . “ Peat formation and mass balance in subarctic ombrotrophic peatlands around Abisko, northern Scandinavia ” . In Plant ecology of the subarctic Swedish Lapland Edited by: Karlsson , P S and Callaghan , T V . 79 – 92 .
   Google Scholar
• Michaelis , W , Seifert , R , Nauhaus , K , Treude , T , Thiel , V , Blumenberg , M , Knittel , K , Gieseke , A , Peterknecht , K , Pape , T , Boetius , A , Amann , R , Jørgensen , B B , Widdel , F , Peckmann , J , Pimenov , N V and Gulin , M B . 2002 . Microbial reefs in the Black Sea fueled by anaerobic oxidation of methane . Science , 297 : 1013 – 1015 .
   PubMed Web of Science ®Google Scholar
• Moore , T R and Knowles , R . 1989 . The influence of water table levels on methane and carbon dioxide emissions from peatland soils . Can J Soil Sci , 69 : 33 – 38 .
   Web of Science ®Google Scholar
• Moore , T R and Roulet , N T . 1993 . Methane flux: water table relations in northern wetlands . Geophys Res Lett , 20 : 587 – 590 .
   Web of Science ®Google Scholar
• Moore , T R , Roulet , N T and Waddington , J M . 1998 . Uncertainty in predicting the effect of climatic change on the carbon cycling of canadian peatlands . Climatic Change , 40 : 229 – 245 .
   Web of Science ®Google Scholar
• Müller , V , Blaut , M and Gottschalk , G . 1993 . “ Bioenergetics of methanogenesis ” . In Methanogenesis: Ecology, Physiology, Biochemistry, and Genetics , Edited by: Ferry , J G . 360 – 406 . New York : Chapman & Hall .
   Google Scholar
• Murase , J and Kimura , M . 1994a . Methane production and its fate in paddy fields: VII. Electron acceptors responsible for anaerobic methane oxidation . Soil Sci Plant Nutr , 40 : 647 – 654 .
   Web of Science ®Google Scholar
• Murase , J and Kimura , M . 1994b . Methane production and its fate in patty fields IV. Sources of microorganisms and substrates responsible for anaerobic methane oxidation . Soil Sci Plant Nutr , 40 : 57 – 61 . Murase J, Kimura M. 1994c. Methane production and its fate in paddy fields: VI. Anaerobic oxidation of methane in plow layer soil. Soil Sci Plant Nutr 40:505–514. Boston: McGraw-Hill
   Web of Science ®Google Scholar
• Neter , J , Kutner , M H , Nachtsheim , C J and Wasserman , W . 1996 . Applied Linear Statistical Models , 1408 Boston , Massachusetts : McGraw-Hill .
   Google Scholar
• Panganiban , A TJ , Patt , T E , Hart , W and Hanson , R S . 1979 . Oxidation of methane in the absence of oxygen in lake water samples . Appl Environ Microb , 37 : 303 – 309 .
   PubMed Web of Science ®Google Scholar
• Prather , M , Derwent , R , Ehhalt , D , Fraser , P , Sanhueaza , E and Zhou , X . 1995 . “ Other trace gases and atmospheric chemistry ” . In Climate change 1994. Radiative forcing of climate change and an evaluation of the IPCC IS92 emissions scenarios , Edited by: Houghton , J T . 73 – 126 . Cambridge , UK : Cambridge University Press .
   Google Scholar
• Quay , P , King , S , Lansdown , J and Wilbur , D . 1988 . Isotopic composition of methane released from wetlands: implications for the increase in atmospheric methane . Global Biogeochem Cy , 2 : 385 – 397 .
   Web of Science ®Google Scholar
• Raghoebarsing , A A , Pol , A , van de Pas-Schoonen , K T , Smolders , A JP , Ettwig , K F , Rijpstra , W IC , Schouten , S , Sinninghe Damsté , J S , Op den Camp , H JM , Jetten , M SM and Strous , M . 2006 . A microbial consortium couples anaerobic methane oxidation to denitrification . Nature , 440 : 918 – 921 .
   PubMed Web of Science ®Google Scholar
• Reeburgh , W S . 1989 . “ Coupling of the carbon and sulphur cycles through anaerobic methane oxidation ” . In Evolution of the Global Biogeochemical Sulfur Cycle , Edited by: Brimblecombe , P and Lein , A Y . 149 – 159 . New York : Wiley .
   Google Scholar
• Rosswall , T , Flower-Ellis , J GK , Johansson , L G , Jonsson , S , Rydén , B E and Sonesson , M . 1975 . “ Stordalen (Abisko), Sweden ” . In Structure and Function of Tundra Ecosystems Edited by: Rosswall , T and Heal , O W . 265 – 294 .
   Google Scholar
• Roy , R and Conrad , R . 1999 . Effect of methanogenic precursors (acetate, hydrogen, propionate) on the suppression of methane production by nitrate in anoxic rice field soil . FEMS Microbiol Ecol , 28 : 49 – 61 .
   Web of Science ®Google Scholar
• Scott , D T , McKnight , D M , Blunt , H EL , Lovley , D R and Kolesar , S E . 1998 . Quinone groups in humic substances as electron acceptors by humic-reducing microorganisms . Environ. Sci. Technol. , 32 ( 19 ) : 2984 – 2989 .
   Web of Science ®Google Scholar
• Segers , R . 1998 . Methane production and methane consumption: A review of processes underlying wetland methane fluxes . Biogeochemistry , 41 : 23 – 51 .
   Web of Science ®Google Scholar
• Smemo , K A and Yavitt , J B . 2006 . A multi-year perspective on CH4 cycling in a shallow peat fen in Central New York State, USA . Wetlands , 26 : 9 – 18 .
   Web of Science ®Google Scholar
• Smith , R L , Howes , B L and Garabedian , S P . 1991 . In situ measurement of methane oxidation in groundwater by using natural-gradient tracer tests . Appl Environ Microb , 57 : 1997 – 2004 .
   PubMed Web of Science ®Google Scholar
• Smith , R L , Miller , L G and Howes , B L . 1993 . The geochemistry of methane in Lake Fryxell, an amictic, permanently ice-covered, Antarctic lake . Biogeochemistry , 21 : 95 – 115 .
   Web of Science ®Google Scholar
• Sørensen , K B , Finster , K and Ramsing , N B . 2001 . Thermodynamic and kinetic requirements in anaerobic methane oxidizing consortia exclude hydrogen, acetate, and methanol as possible electron shuttles . Microbial Ecol , 42 : 1 – 10 .
   PubMed Web of Science ®Google Scholar
• Sundh , I , Nilsson , M , Granberg , G and Svensson , B H . 1994 . Depth distribution of microbial production and oxidation of methane in northern boreal peatlands . Microbial Ecol , 27 : 253 – 265 .
   PubMed Web of Science ®Google Scholar
• Svensson , B H and Rosswall , T . 1984 . In situ methane production from acid peat in plant communities with different moisture regimes . Oikos , 43 : 341 – 350 .
   Web of Science ®Google Scholar
• Svensson , B H and Sundh , I . 1992 . Factors affecting methane production in peat soils . Suo , 43 : 183 – 190 .
   Google Scholar
• Svensson , B H , Christensen , T R , Johansson , E and Oquist , M . 1999 . Interdecadal changes in CO2 and CH4 fluxes of a subarctic mire: Stordalen revisited after 20 years . Oikos , 85 : 22 – 30 .
   Web of Science ®Google Scholar
• Thomsen , T R , Finster , K and Ramsing , N B . 2001 . Biogeochemical and molecular signatures of anaerobic methane oxidation in a marine sediment . Appl Environ Microb , 67 : 1646 – 1656 .
   PubMed Web of Science ®Google Scholar
• Topp , E and Pattey , E . 1997 . Soils as sources and sinks for atmospheric methane . Can J Soil Sci , 77 : 167 – 178 .
   Web of Science ®Google Scholar
• Valentine , D L and Reeburgh , W S . 2000 . New perspectives on anaerobic methane oxidation . Environ Microbiol , 2 : 477 – 484 .
   PubMed Web of Science ®Google Scholar
• Valentine , D L . 2002 . Biogeochemistry and microbial ecology of methane oxidation in anoxic environments: A review . A Van Leeuw J Microb , 81 : 271 – 282 .
   PubMed Web of Science ®Google Scholar
• Valentine , D L , Chidthaisong , A , Rice , A , Reeburgh , W S and Tyler , S C . 2004 . Carbon and hydrogen isotope fractionation by moderately thermophilic methanogens . Geochim Cosmochim Acta , 68 : 1571 – 1590 .
   Web of Science ®Google Scholar
• von Fischer , J C and Hedin , L O . 2002 . Separating methane production and consumption with a field-based isotope pool dilution technique . Global Biogeochem Cy , 16 ( 3 ) : 1 – 13 .
   Web of Science ®Google Scholar
• Whalen , S C and Reeburgh , W S . 2000 . Methane oxidation, production, and emission at contrasting sites in a boreal bog . Geomicrobiol J , 17 : 237 – 251 .
   Web of Science ®Google Scholar
• Wheeler , B D and Proctor , M CF . 2000 . Ecological gradients, subdivisions and terminology of north-west European mires . J Ecol , 88 : 187 – 203 .
   Web of Science ®Google Scholar
• Whiticar , M J and Faber , E . 1986 . Methane oxidation in sediment and water column environments—Isotope evidence. Adv. Org . Geochem. , 10 : 759 – 768 .
   Web of Science ®Google Scholar
• Whiting , G J and Chanton , J P . 1993 . Primary production control of methane emission from wetlands . Nature , 364 : 794 – 795 .
   Web of Science ®Google Scholar
• Wuebbles , D J and Hayhoe , K . 2002 . Atmospheric methane and global change . Earth-Sci Rev , 57 : 177 – 210 .
   Web of Science ®Google Scholar
• Yamamoto , S , Alcauskas , J B and Crozier , T E . 1976 . Solubility of methane in distilled water and seawater . J Chem Eng Data , 21 : 78 – 80 .
   Web of Science ®Google Scholar
• Yavitt , J B , Lang , G E and Downey , D M . 1988 . Potential methane production and methane oxidation rates in peatland ecosystems of the Appalachian mountains, United States . Global Biogeochem Cy , 2 : 253 – 268 .
   Web of Science ®Google Scholar
• Yavitt , J B , Williams , C J and Wieder , R K . 2000 . Controls on microbial production of methane and carbon dioxide in three spaghnum-dominated peatland ecosystems as revealed by a reciprocal filed peat transplant study. Geomicrobiol J 17:61–88. Zehnder AJ, Brock TD. 1980. Anaerobic methane oxidation: Occurence and ecology . Appl Environ Microb , 39 : 194 – 204 .
   Google Scholar
• Zehnder , A JB and Brock , T D . 1979 . Methane formation and methane oxidation by methanogenic bacteria . J Bacteriol , 137 : 420 – 432 .
   PubMed Web of Science ®Google Scholar