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Solar‐Driven Methanogenesis through Microbial Ecosystem Engineering on Carbon Nitride

Shafeer Kalathil, Motiar Rahaman, Erwin Lam, Teresa L. Augustin, Heather F. Greer, Erwin Reisner

2024Angewandte Chemie International Edition25 citationsDOIOpen Access PDF

Abstract

Abstract Semi‐biological photosynthesis combines synthetic photosensitizers with microbial catalysts to produce sustainable fuels and chemicals from CO 2 . However, the inefficient transfer of photoexcited electrons to microbes leads to limited CO 2 utilization, restricting the catalytic performance of such biohybrid assemblies. Here, we introduce a biological engineering solution to address the inherently sluggish electron uptake mechanism of a methanogen, Methanosarcina barkeri ( M. barkeri ), by coculturing it with an electron transport specialist, Geobacter sulfurreducens KN400 ( KN400 ), an adapted strain rich with multiheme c‐type cytochromes (c‐Cyts) and electrically conductive protein filaments (e‐PFs) made of polymerized c‐Cyts with enhanced capacity for extracellular electron transfer (EET). Integration of this M. barkeri ‐KN400 co‐culture with a synthetic photosensitizer, carbon nitride, demonstrates that c‐Cyts and e‐PFs, emanating from live KN400 , transport photoexcited electrons efficiently from the carbon nitride to M. barkeri for methanogenesis with remarkable long‐term stability and selectivity. The demonstrated cooperative interaction between two microbes via direct interspecies electron transfer (DIET) and the photosensitizer to assemble a semi‐biological photocatalyst introduces an ecosystem engineering strategy in solar chemistry to drive sustainable chemical reactions.

Topics & Concepts

MethanogenesisEcosystemEnvironmental scienceCarbon fibersCarbon nitrideEnvironmental chemistryEcologyMethaneChemistryMaterials scienceBiologyComposite numberPhotocatalysisBiochemistryCatalysisComposite materialMicrobial Fuel Cells and BioremediationAdvanced Photocatalysis TechniquesCO2 Reduction Techniques and Catalysts
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