Project description:Electron and Proton Flux for Carbon Dioxide Reduction in Methanosarcina barkeri During Direct Interspecies Electron Transfer

Project description:TRANSCRIPTOMIC AND GENETIC ANALYSIS OF DIRECT INTERSPECIES ELECTRON TRANSFER

Project description:Development of Direct Interspecies Electron Transfer as a sole electron transfer mechanism in a syntrophic co-culture

Project description:different conductive materials-mediated direct interspecies electron transfer during anaerobic digestion

Project description:Understanding the ecophysiology of the key partners participating in direct interspecies electron transfer

Project description:Transcriptome of Methanosarcina acetivorans grown via direct interspecies electron transfer with Geobacter metallireducens

Project description:A new model for electron flow during anaerobic digestion: direct interspecies electron transfer to Methanosaeta for the reduction of carbon dioxide to methane

Project description:Biochar accelerates methane production efficiency from wastewater: some viewpoints considering direct interspecies electron transfer

Project description:To explore the interspecies electron transfer and substrate co-metabolism mechanism between denitrifiers and electroactive microorganisms

Project description:Geobacter species are of great interest for environmental and biotechnology applications as they can carry out direct electron transfer to insoluble metals or other microorganisms and have the ability to assimilate inorganic carbon. Here, we report on the capability and key enabling metabolic machinery of Geobacter metallireducens GS-15 to carry out CO2 fixation and direct electron transfer to iron. An updated metabolic reconstruction was generated, growth screens on targeted conditions of interest were performed, and constraint-based analysis was utilized to characterize and evaluate critical pathways and reactions in G. metallireducens. The novel capability of G. metallireducens to grow autotrophically with formate and Fe(III) was predicted and subsequently validated in vivo. Additionally, the energetic cost of transferring electrons to an external electron acceptor was determined through analysis of growth experiments carried out using three different electron acceptors (Fe(III), nitrate, and fumarate) by systematically isolating and examining different parts of the electron transport chain. The updated reconstruction will serve as a knowledgebase for understanding and engineering Geobacter and similar species.