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Light-driven CO2 reduction for acetate production by coupling photocatalyst CdS with acetogenic bacteria Clostridium aceticum: An insight into the electron transfer pathway

Bo Fu, Wei Lin, Hui Zhao, Shijian Yang, Jingyi Han, Qihao Cao, He Liu, He Liu, Hongbo Liu, Hongbo Liu, Jieshu Qian

2025Journal of environmental chemical engineering8 citationsDOIOpen Access PDF

Abstract

Light-driven CO 2 reduction for acetate production by coupling photocatalyst with acetogenic bacteria has risen great interests due to the solar-to-chemical production and carbon neutrality. Although several acetogens have been employed to semi-artificial photosynthesis for acetate production, challenges remain in enhancing electron transfer efficiency and system stability. In this work, a novel hybrid of acetogenic bacteria Clostridium aceticum and photocatalyst CdS was constructed for CO 2 reduction to acetate, in which biosynthesized CdS nanoparticles on the cell surface of Clostridium aceticum served as the light harvester to provide electrons for bacterial metabolism. The CdS- C. aceticum hybrid system continuously produced acetate of 120 mg/L under irradiation of white light and summer natural light over several days of light-dark cycles. To elucidate the interfacial electron transfer and energy metabolism in this hybrid, the determination of cytochrome C and electron carriers as well as transcriptional analysis were performed. The content of cytochrome C and riboflavin in the hybrid system increased under light-exposure conditions, and H 2 was detected in the sterilized hybrid system. The genes associated with the Wood-ljungdahl pathway and energy conservation system were highly up-regulated under CdS-light irradiation along with the activation of genes encoding cytochrome C, riboflavin transporter and hydrogenase. The results indicated the CdS- C. aceticum hybrid possessed direct extracellular electron transfer via cytochrome C and indirect extracellular electron transfer via riboflavin and H 2 . This study provides a novel CdS- C. aceticum hybrid system for CO 2 reduction and insights into the electron transfer in the abiotic-biotic system for boosting the development of semi-artificial photosynthesis.

Topics & Concepts

PhotocatalysisElectron transferReduction (mathematics)BacteriaCoupling (piping)Production (economics)ClostridiumPhotochemistryChemistryMicrobiologyMaterials scienceCatalysisBiologyOrganic chemistryMacroeconomicsEconomicsGeneticsGeometryMetallurgyMathematicsAdvanced Photocatalysis TechniquesMicrobial Fuel Cells and BioremediationCO2 Reduction Techniques and Catalysts
Light-driven CO2 reduction for acetate production by coupling photocatalyst CdS with acetogenic bacteria Clostridium aceticum: An insight into the electron transfer pathway | Litcius