Sulfur BiogeochemistryâPast and Present

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Microbially mediated sulfur-redox 31Amend, J.P., Meyer-Dombard, D.R., Sheth, S.N., Zolotova, N., and Amend,A.C., 2003a, Palaeococcus helgesonii sp. nov., a facultatively anaerobic,hyperthermophilic archaeon from a geothermal well on Vulcano Island,Italy: Archives of Microbiology, v. 179, p. 394–401.Amend, J.P., Rogers, K.L., Shock, E.L., Gurrieri, S., and Inguaggiato, S.,2003b, Energetics of chemolithoautotrophy in the hydrothermal systemof Vulcano Island, southern Italy: Geobiology, v. 1, p. 37–58.Arvidson, R.E., 2004, Geology of Meridiani Planum as inferred from MarsExploration Rover Observation: Lunar and Planetary Science Conference,35th Annual Meeting, Houston, Texas, Abstract no. 2165.Baross, J.A., and Hoffman, S.E., 1985, Submarine hydrothermal vents andassociated gradient environments as sites for the origin and evolution oflife: Origins of Life, v. 15, p. 327–345.Bates, T.S., Kiene, R.P., Wolfe, G.V., Matrai, P.A., Chavez, F.P., Buck, K.R.,Blomquist, B.W., and Cuhel, R.L., 1994, The cycling of sulfur in surfaceseawater of the northeast Pacific: Journal of Geophysical Research, C,Oceans, v. 99, p. 7835–7843, doi:10.1029/93JC02782.Beeder, J., Nilsen, R.K., Rosnes, J.T., Torsvik, T., and Lien, T., 1994, Archaeoglobusfulgidus isolated from hot North Sea oil field waters: Applied andEnvironmental Microbiology, v. 60, p. 1227–1231.Blöchl, E., Rachel, R., Burggraf, S., Hafenbradl, D., Jannasch, H.W., andStetter, K.O., 1997, Pyrolobus fumarii, gen. and sp. nov., represents a novelgroup of archaea, extending the upper temperature limit for life to 113°C:Extremophiles, v. 1, p. 14–21, doi:10.1007/S007920050010.Bonch-Osmolovskaya, E.A., Miroshnichenko, M.L., Kostrikina, N.A.,Chernych, N.A., and Zavarzin, G.A., 1990, Thermoproteus uzoniensissp. nov., a new extremely thermophilic archaebacterium from Kamchatkacontinental hot springs: Archives of Microbiology, v. 154, p. 556–559.Botz, R., Winckler, G., Bayer, R., Schmitt, M., Schmidt, M., Garbe-Schonberg, D., Stoffers, P., and Kristjansson, J.K., 1999, Origin of tracegases in submarine hydrothermal vents of the Kolbeinsey Ridge, northIceland: Earth and Planetary Science Letters, v. 171, p. 83–93, doi:10.1016/S0012-821X(99)00128-4.Brakenridge, G.R., Newsom, H.E., and Baker, V.R., 1985, Ancient hot springson Mars: Origins and paleoenvironmental significance of small Martianvalleys: Geology, v. 13, p. 859–862.Brasier, M.D., Green, O.R., Jephcoat, A.P., Kleppe, A.K., Van Kranendonk, M.J.,Lindsay, J.F., Steele, A., and Grassineau, N.V., 2002, Questioning theevidence for Earth’s oldest fossils: Nature, v. 416, p. 76–81, doi:10.1038/416076A.Brinkhoff, T., Sievert, S.M., Kuever, J., and Muyzer, G., 1999, Distributionand diversity of sulfur-oxidizing Thiomicrospira spp. at a shallow-waterhydrothermal vent in the Aegean Sea, Milos, Greece: Applied and EnvironmentalMicrobiology, v. 65, p. 1127–1132.Brocks, J.J., Logan, G.A., Buick, R., and Summons, R.E., 1999, Archeanmolecular fossils and the early rise of eukaryotes: Science, v. 285,p. 1033–1036, doi:10.1126/SCIENCE.285.5430.1033Brown, G.C., and Mussett, A.E., 1993, The inaccessible Earth: An integratedview to its structure and composition: London, Chapman & Hall, 276 p.Brüchert, V., Knoblauch, C., and Jørgensen, B.B., 2001, Controls on stablesulfur isotope fractionation during bacterial sulfate reduction in Arcticsediments: Geochimica et Cosmochimica Acta, v. 65, p. 763–776, doi:10.1016/S0016-7037(00)00557-3.Burggraf, S., Fricke, H., Neuner, A., Kristjansson, J., Rouvier, P., Mandelco, L.,Woese, C.R., and Stetter, K.O., 1990a, Methanococcus igneus sp. nov., anovel hyperthermophilic methanogen from a shallow submarine hydrothermalvent: Systematic and Applied Microbiology, v. 13, p. 263–269.Burggraf, S., Jannasch, H.W., Nicolaus, B., and Stetter, K.O., 1990b, Archaeoglobusprofundus sp. nov. represents a new species within the sulfate- reducing archaebacteria:Systematic and Applied Microbiology, v. 13, p. 24–28.Canfield, D.E., and Raiswell, R., 1999, The evolution of the sulfur cycle:American Journal of Science, v. 299, p. 697–723.Canfield, D.E., Habicht, K.S., and Thamdrup, B., 2000, The Archean sulfur cycleand the early history of atmospheric oxygen: Science, v. 288, p. 658–661.Carr, M.H., and Chuang, F.C., 1997, Martian drainage densities: Journal ofGeophysical Research, v. 102, p. 9145–9152, doi:10.1029/97JE00113.Christensen, P.R., Bandfield, J.L., Clark, R.N., Edgett, K.S., Hamilton, V.E.,Hoefen, T., Kieffer, H.H., Kuzmin, R.O., Lane, M.D., Malin, M.C., Morris,R.V., Pearl, J.C., Pearson, R., Roush, T.L., Ruff, S.W., and Smith, M.D.,2000, Detection of crystalline hematite mineralization on Mars by the ThermalEmission Spectrometer: Evidence for near-surface water: Journal ofGeophysical Research, v. 105, p. 9623–9642, doi:10.1029/1999JE001093.Chyba, C.F., 2000, Energy for microbial life on Europa: Nature, v. 403, p. 381–382, doi:10.1038/35000281.Cutter, G.A., and Kluckhohn, R.S., 1999, The cycling of particulate carbon,nitrogen, sulfur, and sulfur species (iron monosulfide, greigite, pyrite,and organic sulfur) in the water columns of Framvaren Fjord and theBlack Sea: Marine Chemistry, v. 67, p. 149–160, doi:10.1016/S0304-4203(99)00056-0.Deckert, G., Warren, P.V., Gaasterland, T., Young, W.G., Lenox, A.L.,Graham, D.E., Overbeek, R., Snead, M.A., Keller, M., Aujay, M.,Huber, R., Feldman, R.A., Short, J.M., Olsen, G.J., and Swanson, R.V.,1998, The complete genome of the hyperthermophilic bacterium Aquifexaeolicus: Nature, v. 392, p. 353–358, doi:10.1038/32831.Durand, P., Reysenbach, A.-L., Prieur, D., and Pace, N., 1993, Isolation andcharacterization of Thiobacillus hydrothermalis sp. nov., a mesophilicobligately chemolithotrophic bacterium isolated from a deep-sea hydrothermalvent in Fiji Basin: Archives of Microbiology, v. 159, p. 39–44.Edgett, K.S., and Parker, T.J., 1997, Water on early Mars: Possible subaqueoussedimentary deposits covering ancient cratered terrain in western Arabiaand Sinus Meridiani: Geophysical Research Letters, v. 24, p. 2897–2900,doi:10.1029/97GL02840.Elsgaard, L., Guezennec, J., Benbouzid-Rollet, N., and Prieur, D., 1995, Mesophilicsulfate reducing bacteria from three deep-sea hydrothermal ventsites: Oceanologica Acta, v. 18, p. 95–104.Elsgaard, L., Isaksen, M.F., Jørgensen, B.B., Alayse, A.-M., and Jannasch, H.W.,1994, Microbial sulfate reduction in deep-sea sediments at the Guaymasbasin hydrothermal vent area: Influence of temperature and substrates:Geochimica et Cosmochimica Acta, v. 58, p. 3335–3343, doi:10.1016/0016-7037(94)90089-2.Erauso, G., Reysenbach, A.-L., Godfroy, A., Meunier, J.-R., Crump, B.,Partensky, F., Baross, J.A., Marteinsson, V., Barbier, G., Pace, N.R., andPrieur, D., 1993, Pyrococcus abyssii sp. nov., a new hyperthermophilicarchaeon isolated from a deep-sea hydrothermal vent: Archives of Microbiology,v. 160, p. 338–349.Farmer, J.D., 1996, Hydrothermal systems on Mars: An assessment of presentevidence, in Bock, G. R., and Goode, J. A., eds., Evolution of hydrothermalsystems on Earth (and Mars?): Chichester, Wiley, p. 273–299.Fiala, G., and Stetter, K.O., 1986, Pyrococcus furiosus sp. nov. represents anovel genus of marine heterotrophic archaebacteria growing optimally at100 °C: Archives of Microbiology, v. 145, p. 56–61.Fischer, F., Zillig, W., Stetter, K.O., and Schreiber, G., 1983, Chemolithoautotrophicmetabolism of anaerobic extremely thermophilic archaebacteria:Nature, v. 301, p. 511–513.Fossing, H., and Jørgensen, B.B., 1990, Oxidation and reduction of radiolabeledinorganic sulfur compounds in an estuarine sediment, Kysing Fjord,Denmark: Geochimica et Cosmochimica Acta, v. 54, p. 2731–2742, doi:10.1016/0016-7037(90)90008-9.Gaidos, E.J., Nealson, K.H., and Kirschvink, J.L., 1999, Life in ice-covered oceans:Science, v. 284, p. 1631–1633, doi:10.1126/SCIENCE.284.5420.1631.Gonzalez, J.M., Masuchi, Y., Robb, F.T., Ammerman, J.W., Maeder, D.L.,Yanagibayashi, M., Tamaoka, J., and Kato, C., 1998, Pyrococcus horikoshiisp. nov., a hyperthermophilic archaeon isolated from a hydrothermal ventat the Okinawa Trough: Extremophiles, v. 2, p. 123–130, doi:10.1007/S007920050051.Götz, D., Banta, A., Beveridge, T.J., Rushdi, A.I., Simoneit, B.R.T., andReysenbach, A.-L., 2002, Persephonella marina gen. nov., sp. nov.and Persephonella guaymasensis sp. nov., two novel, thermophilic,hydrogen-oxidizing microaerophiles from deep-sea hydrothermal vents:International Journal of Systematic and Evolutionary Microbiology, v. 52,p. 1349–1359, doi:10.1099/IJS.0.02126-0.Grant, J.A., 2000, Valley formation in Margaritifer Sinus, Mars, by precipitation-rechargedground-water sapping: Geology, v. 28, p. 223–226, doi:10.1130/0091-7613(2000)0282.3.CO;2.Grant, J. A. and Parker, T. J., 2002, Drainage evolution in the Margaritifer Sinusregion, Mars: Journal of Geophysical Research, v. 107, p. 4–1 to 4–19.Greenberg, R., and Geissler, P., 2002, Europa’s dynamic icy crust: Meteoritics& Planetary Science, v. 37, p. 1685–1710.Grossman, E.L., and Desrocher, S., 2001, Microbial sulfur cycling in terrestrialsubsurface environments, in Fredrickson, J.K., and Fletcher, M., eds., Subsurfacemicrobiology and biogeochemistry: Wiley-Liss, Inc., p. 219–248.Gugliandolo, C., and Maugeri, T.L., 1993, Chemolithotrophic sulfur-oxidizingbacteria from a marine shallow hydrothermal vent of Vulcano (Italy):Geomicrobiology Journal, v. 11, p. 109–120.
32 J.P. Amend, K.L. Rogers, and D.R. Meyer-DombardGugliandolo, C., Italiano, F., Maugeri, T.L., Inguaggiato, S., Caccamo, D., andAmend, J.P., 1999, Submarine hydrothermal vents of the Aeolian islands:Relationship between microbial communities and thermal fluids: GeomicrobiologyJournal, v. 16, p. 105–117, doi:10.1080/014904599270794.Gulick, V.C., 1998, Magmatic intrusions and a hydrothermal origin for fluvialvalleys on Mars: Journal of Geophysical Research, v. 103, p. 19365–19387, doi:10.1029/98JE01321.Gulick, V.C., and Baker, V.R., 1990, Origin and evolution of valleys on Martianvolcanoes: Journal of Geophysical Research, v. 95, p. 14325–14344.Gundersen, J.K., Jørgensen, B.B., Larsen, E., and Jannasch, H.W., 1992, Matsof giant sulphur bacteria on deep-sea sediments due to fluctuating hydrothermalflow: Nature, v. 360, p. 454–455, doi:10.1038/360454A0.Haldane, J.B.S., 1929, The origin of life: The Rationalist Annual.Helgeson, H.C., Delany, J.M., Nesbitt, W.H., and Bird, D.K., 1978, Summaryand critique of the thermodynamic properties of rock-forming minerals:American Journal of Science, v. 278A, p. 1–229.Helgeson, H.C., Kirkham, D.H., and Flowers, G.C., 1981, Theoretical predictionof the thermodynamic behavior of aqueous electrolytes at high pressuresand temperatures: IV. Calculation of activity coefficients, osmotic coefficients,and apparent molal and standard and relative partial molal propertiesto 600 °C and 5 kb: American Journal of Science, v. 281, p. 1249–1516.Henry, E.A., Devereux, R., Maki, J.S., Gilmour, C.C., Woese, C.R.,Mandelco, L., Schauder, R., Remsen, C.C., and Mitchell, R., 1994,Characterization of a new thermophilic sulfate-reducing bacterium,Thermodesulfovibrio yellowstonii, gen. nov. and sp. nov.: Its phylogeneticrelationship to Thermodesulfobacterium commune and their origins deepwithin the bacterial domain: Archives of Microbiology, v. 161, p. 62–69,doi:10.1007/S002030050022.Hinrichs, K.-U., Hayes, J.M., Sylva, S.P., Brewer, P.G., and DeLong, E.F.,1999, Methane-consuming archaebacteria in marine sediments: Nature,v. 398, p. 802–805, doi:10.1038/19751.Huber, C., and Wächtershäuser, G., 1998, Peptides by activation of amino acidswith CO on (Ni,Fe)S surfaces: Implications for the origin of life: Science,v. 281, p. 670–672, doi:10.1126/SCIENCE.281.5377.670.Huber, C., Eisenreich, W., Hecht, S., and Wächtershäuser, G., 2003, A possibleprimordial peptide cycle: Science, v. 301, p. 938–940, doi:10.1126/SCIENCE.1086501.Huber, H., Jannasch, H., Rachel, R., Fuchs, T., and Stetter, K.O., 1997,Archaeoglobus venefi cus sp. nov., a novel facultative chemolithoautotrophichyperthermophilic sulfur reducer, isolated from abyssal black smokers:Systematic and Applied Microbiology, v. 20, p. 374–380.Huber, H., Burggraf, S., Mayer, T., Wyschkony, I., Biebl, M., Rachel, R., andStetter, K.O., 2000, Ignicococcus gen. nov., a novel genus of hyperthermophilic,chemolithoautotrophic Archaea, represented by two new speciesIgnicococcus islandicus sp. nov. and Ignicococcus pacifi cus sp. nov:International Journal of Systematic and Evolutionary Microbiology, v. 50,p. 2093–2100.Huber, R., and Stetter, K.O., 1989, Thiobacillus prosperus sp. nov., representsa new group of halotolerant metal-mobilizing bacteria isolated from amarine geothermal field: Archives of Microbiology, v. 151, p. 479–485.Huber, R., Langworthy, T.A., König, H., Thomm, M., Woese, C.R., Sleytr,U.B., and Stetter, K.O., 1986, Thermotoga maritima sp. nov. representsa new genus of unique extremely thermophilic eubacteria growing up to90 °C: Archives of Microbiology, v. 144, p. 324–333.Huber, R., Kristjansson, J.K., and Stetter, K.O., 1987, Pyrobaculum gen. nov.,a new genus group of neutrophilic, rod-shaped archaebacteria from continentalsolfataras growing optimally at 100 °C: Archives of Microbiology,v. 149, p. 95–101.Huber, R., Kurr, M., Jannasch, H.W., and Stetter, K.O., 1989, A novel group ofabyssal methanogenic archaebacteria (Methanopyrus) growing at 110 °C:Nature, v. 342, p. 833–834, doi:10.1038/342833A0.Huber, R., Wilharm, T., Huber, D., Trincone, A., Burggraf, S., König, H.,Rachel, R., Rockinger, I., Fricke, H., and Stetter, K.O., 1992, Aquifexpyrophilus gen. nov. sp. nov., represents a novel group of marine hyperthermophilichydrogen-oxidizing Bacteria: Systematic and AppliedMicrobiology, v. 15, p. 340–351.Hynek, B.M., and Phillips, R.J., 2001, Evidence for extensive denudation ofthe Martian highlands: Geology, v. 29, p. 407–410, doi:10.1130/0091-7613(2001)0292.0.CO;2.Jakosky, B.M., and Shock, E.L., 1998, The biological potential of Mars,the early Earth, and Europa: Journal of Geophysical Research, v. 103,p. 19359–19364, doi:10.1029/98JE01892.Jannasch, H.W., 1985, Chemosynthetic support for life and the microbial diversityat deep-sea hydrothermal vents: Proceedings of the Royal Society ofLondon, v. 225, p. 277–297.Jannasch, H.W., and Mottl, M.J., 1985, Geomicrobiology of deep-sea hydrothermalvents: Science, v. 229, p. 717–725.Jannasch, H.W., Wirsen, C.O., Nelson, D.C., and Robertson, L.A., 1985, Thiomicrospiracrunogena sp. nov., a colorless, sulfur-oxidizing bacteriumfrom a deep-sea hydrothermal vent: International Journal of SystematicBacteriology, v. 35, p. 422–424.Jeanthon, C., L’Haridon, S., Cueff, V., Banta, A., Reysenbach, A.-L., andPrieur, D., 2002, Thermodesulfobacterium hydrogenophilum sp. nov., athermophilic, chemolithoautotrophic, sulfate-reducing bacterium isolatedfrom a deep-sea hydrothermal vent at Guaymas Basin, and emendationof the genus Thermodesulfobacterium: International Journal of Systematicand Evolutionary Microbiology, v. 52, p. 765–772, doi:10.1099/IJS.0.02025-0.Jochimsen, B., Peinemann-Simon, S., Volker, H., Stuben, D., Botz, R.,Stoffers, P., Dando, P.R., and Thomm, M., 1997, Stetteria hydrogenophilagen. nov. and sp. nov., a novel mixotrophic sulfur-dependent crenarchaeoteisolated from Milos, Greece: Extremophiles, v. 1, p. 67–73, doi:10.1007/S007920050016.Karl, D.M., 1995, Ecology of free-living, hydrothermal vent microbial communities,in Karl, D. M., ed., The microbiology of deep-sea hydrothermalvents: Boca Raton, CRC Press, p. 35–124.Karl, D.M., Wirsen, C.O., and Jannasch, H.W., 1980, Deep-sea primary productionat the Galapagos hydrothermal vents: Science, v. 207, p. 1345–1347.Kashefi, K., and Lovley, D.R., 2003, Extending the upper temperature limit forlife: Science, v. 301, p. 934, doi:10.1126/SCIENCE.1086823.Kasten, S., and Jørgensen, B.B., 2000, Sulfate reduction in marine sediments, inSchulz, H.D., and Zabel, M., eds., Marine geochemistry: Berlin, Springer-Verlag, p. 263–281.Kelly, R.M., and Adams, M.W.W., 1994, Metabolism in hyperthermophilicmicroorganisms: Antonie van Leeuwenhoek, v. 66, p. 247–270.Kühl, M., Steuckert, C., Eickert, G., and Jeroschewski, P., 1998, A H 2S microsensorfor profiling biofilms and sediments—application in an acidic lakesediment: Aquatic Microbial Ecology, v. 15, p. 201–209.Kurr, M., Huber, R., König, H., Jannasch, H.W., Fricke, H., Trincone, A.,Krisjansson, J.K., and Stetter, K.O., 1991, Methanopyrus kandleri, gen.and sp. nov. represents a novel group of hyperthermophilic methanogens,growing to 110 °C: Archives of Microbiology, v. 156, p. 239–247.Küsel, K., Roth, U., Trinkwalter, T., and Pfeiffer, S., 2001, Effect of pH onthe anaerobic microbial cycling of sulfur in mining-impacted freshwaterlake sediments: Environmental and Experimental Microbiology, v. 46,p. 213–223.Lazcano, A., and Miller, S.L., 1996, The origin and early evolution of life: prebioticchemistry, the pre-RNA world, and time: Cell, v. 85, p. 793–798.Lazcano, A., and Miller, S.L., 1999, On the origin of metabolic pathways: Journalof Molecular Evolution, v. 49, p. 424–431.L’Haridon, S., Cilia, V., Messner, P., Raguenes, G., Gambacorta, A., Sleytr,U.B., Prieur, D., and Jeanthon, C., 1998, Desulfobacterium thermolithotrophumgen. nov. sp. nov., a novel autotrophic, sulfur-reducing bacteriumisolated from a deep-sea hydrothermal vent: International Journal ofSystematic Bacteriology, v. 48, p. 701–711.Loy, A., Lehner, A., Lee, N., Adamczyk, J., Meier, H., Ernst, J., Schleifer, K.-H.,and Wagner, M., 2002, Oligonucleotide microarray for 16S rRNA genebaseddetection of all recognized lineages of sulfate-reducing prokaryotesin the environment: Applied and Environmental Microbiology, v. 68,p. 5064–5081, doi:10.1128/AEM.68.10.5064-5081.2002.Lyons, T.W., Kah, L.C., and Gellatly, A.M., 2004, The Precambrian sulfurisotope record of evolving atmospheric oxygen, in Eriksson, P.G., et al.,eds., The Precambrian Earth: Tempos and events: Developments in Precambriangeology: Amsterdam, Elsevier, p. 421–439.Martin, W., and Russell, M.J., 2003, On the origins of cells: A hypothesis forthe evolutionary transitions from abiotic geochemistry to chemoautotrophicprokaryotes, and from prokaryotes to nucleated cells: PhilosophicalTransactions of the Royal Society of London, v. 358, p. 59–85.McCollom, T.M., 1999, Methanogenesis as a potential source of chemicalenergy for primary biomass production by autotrophic organisms inhydrothermal systems on Europa: Journal of Geophysical Research,v. 104, p. 30729–30742, doi:10.1029/1999JE001126.McCollom, T.M., 2000, Geochemical constraints on primary productivity in submarinehydrothermal vent plumes: Deep-Sea Research I, v. 47, p. 85–101.
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Formation and degradation of seafl
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Sulfur BiogeochemistryâPast and Present