Genes, enzymes, and regulation of para-cresol metabolism in Geobacter metallireducensPETERS, Franziska; HEINTZ, Dimitri; JOHANNES, Jörg et al.Journal of bacteriology. 2007, Vol 189, Num 13, pp 4729-4738, issn 0021-9193, 10 p.Article

Geobacter metallireducens accesses insoluble Fe(III) oxide by chemotaxisCHILDERS, Susan E; CIUFO, Stacy; LOVLEY, Derek R et al.Nature (London). 2002, Vol 416, Num 6882, pp 767-769, issn 0028-0836Article

Occurrence of hopanoid lipids in anaerobic Geobacter speciesHÄRTNER, Thomas; STRAUB, Kristina L; KANNENBERG, Elmar et al.FEMS microbiology letters. 2005, Vol 243, Num 1, pp 59-64, issn 0378-1097, 6 p.Article

Abiotic reduction of 4-chloronitrobenzene to 4-chloroaniline in a dissimilatory iron-reducing enrichment cultureHEIJMAN, C. G; HOLLIGER, C; GLAUS, M. A et al.Applied and environmental microbiology (Print). 1993, Vol 59, Num 12, pp 4350-4353, issn 0099-2240Article

Evidence for iron-dependent nitrate respiration in the dissimilatory iron-reducing bacterium Geobacter metallireducensSENKOT, John M; STOLZ, John F.Applied and environmental microbiology (Print). 2001, Vol 67, Num 8, pp 3750-3752, issn 0099-2240Article

Purification and characterization of triheme cytochrome c₇ from the metal-reducing bacterium, Geobacter metallireducensAFKAR, E; FUKUMORI, Y.FEMS microbiology letters. 1999, Vol 175, Num 2, pp 205-210, issn 0378-1097Article

Evidence for a novel nitrate reductase in the dissimilatory iron-reducing bacterium Geobacter metallireducensNAIK, R. R; MURILLO, F. M; STOLZ, J. F et al.FEMS microbiology letters. 1993, Vol 106, Num 1, pp 53-58, issn 0378-1097Article

Lack of production of electron-shuttling compounds or solubilization of Fe(III) during reduction of insoluble Fe(III) oxide by Geobacter metallireducensNEVIN, K. P; LOVLEY, D. R.Applied and environmental microbiology (Print). 2000, Vol 66, Num 5, pp 2248-2251, issn 0099-2240Article

Quinone moieties act as electron acceptors in the reduction of humic substances by humics-reducing microorganismsSCOTT, D. T; MCKNIGHT, D. M; BLUNT-HARRIS, E. L et al.Environmental science & technology. 1998, Vol 32, Num 19, pp 2984-2989, issn 0013-936XArticle

Direct Exchange of Electrons Within Aggregates of an Evolved Syntrophic Coculture of Anaerobic BacteriaSUMMERS, Zarath M; FOGARTY, Heather E; LEANG, Ching et al.Science (Washington, D.C.). 2010, Vol 330, Num 6009, pp 1413-1415, issn 0036-8075, 3 p.Article

Reduction kinetics of Fe(III), Co(III), U(VI), Cr(VI), and Tc(VII) in cultures of dissimilatory metal-reducing bacteriaCHONGXUAN LIU; GORBY, Yuri A; ZACHARA, John M et al.Biotechnology and bioengineering. 2002, Vol 80, Num 6, pp 637-649, issn 0006-3592, 13 p.Article

Geobacter metallireducens gen. nov. sp. nov., a microorganism capable of coupling the complete oxidation of organic compounds to the reduction of iron and other metalsLOVLEY, D. R; GIOVANNONI, S. J; WHITE, D. C et al.Archives of microbiology. 1993, Vol 159, Num 4, pp 336-344, issn 0302-8933Article

Humic substances as electron acceptors for microbial respirationLOVLEY, D. R; COATES, J. D; BLUNT-HARRIS, E. L et al.Nature (London). 1996, Vol 382, Num 6590, pp 445-448, issn 0028-0836Article

A novel phosphorImager-based technique for monitoring the microbial reduction of technetiumLLOYD, J. R; MACASKIE, L. E.Applied and environmental microbiology (Print). 1996, Vol 62, Num 2, pp 578-582, issn 0099-2240Article

Degradation of monochlorinated and nonchlorinated aromatic compounds under iron-reducing conditionsKAZUMI, J; HÄGGBLOM, M. M; YOUNG, L. Y et al.Applied and environmental microbiology (Print). 1995, Vol 61, Num 11, pp 4069-4073, issn 0099-2240Article

Electricity generation using membrane and salt bridge microbial fuel cellsMIN, Booki; SHAOAN CHENG; LOGAN, Bruce E et al.Water research (Oxford). 2005, Vol 39, Num 9, pp 1675-1686, issn 0043-1354, 12 p.Article

A heme-C-containing enzyme complex that exhibits nitrate and nitrite reductase activity from the dissimilatory iron-reducing bacterium Geobacter metallireducensMARTINEZ MURILLO, F; GUGLIUZZA, T; SENKO, J et al.Archives of microbiology. 1999, Vol 172, Num 5, pp 313-320, issn 0302-8933Article

Role of humic-bound iron as an electron transfer agent in dissimilatory Fe(III) reductionLOVLEY, D. R; BLUNT-HARRIS, E. L.Applied and environmental microbiology (Print). 1999, Vol 65, Num 9, pp 4252-4254, issn 0099-2240Article

Humic substances as a mediator for microbially catalyzed metal reductionLOVLEY, D. R; FRAGA, J. L; BLUNT-HARRIS, E. L et al.Acta hydrochimica et hydrobiologica. 1998, Vol 26, Num 3, pp 152-157, issn 0323-4320Article

Anodic electron shuttle mechanism based on 1-hydroxy-4-aminoanthraquinone in microbial fuel cellsXINHUA TANG; ZHUWEI DU; HAORAN LI et al.Electrochemistry communications. 2010, Vol 12, Num 8, pp 1140-1143, issn 1388-2481, 4 p.Article

Potential for nonenzymatic reduction of Fe(III) via electron shuttling in subsurface sedimentsNEVIN, K. P; LOVLEY, D. R.Environmental science & technology. 2000, Vol 34, Num 12, pp 2472-2478, issn 0013-936XArticle

Carbon tetrachloride transformation on the surface of nanoscale biogenic magnetite particlesMCCORMICK, Michael L; ADRIAENS, Peter.Environmental science & technology. 2004, Vol 38, Num 4, pp 1045-1053, issn 0013-936X, 9 p.Article

Arsenic mobilization through microbially mediated deflocculation of ferrihydriteTADANIER, Christopher J; SCHREIBER, Madeline E; ROLLER, Jonathan W et al.Environmental science & technology. 2005, Vol 39, Num 9, pp 3061-3068, issn 0013-936X, 8 p.Article

Hexahydro-1,3,5-trinitro-1,3,5-triazine transformation by biologically reduced ferrihydrite : Evolution of Fe mineralogy, surface area, and reaction ratesWILLIAMS, Aaron G. B; GREGORY, Kelvin B; PARKIN, Gene F et al.Environmental science & technology. 2005, Vol 39, Num 14, pp 5183-5189, issn 0013-936X, 7 p.Article

Carbon tetrachloride transformation in a model iron-reducing culture: Relative kinetics of biotic and abiotic reactionsMCCORMICK, Michael L; BOUWER, Edward J; ADRIAENS, Peter et al.Environmental science & technology. 2002, Vol 36, Num 3, pp 403-410, issn 0013-936XArticle