Light-driven eosin Y-Ralstonia eutropha biohybrid for CO2 conversion to acetoin via specific photo-induced electron transfer and metabolic engineering

IF 7.2 2区工程技术 Q1 CHEMISTRY, MULTIDISCIPLINARY

Journal of CO2 Utilization Pub Date : 2025-03-01 DOI:10.1016/j.jcou.2025.103051

Yao Tian , Zhiqi Guo , Jiaping He , Dake Xu , Wen-Wei Li , Shaoan Cheng , Hao Song

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引用次数: 0

Abstract

Whole-cell photosynthetic biohybrid systems offer a promising route for CO₂ conversion into value-added chemicals. However, many existing systems suffer from inefficient electron transfer to intracellular catalytic CO₂ center, which arises from non-specific charge transfer between photosensitizer and microbe. Herein, we developed an efficient eosin Y-Ralstonia eutropha biohybrid system that achieved targeted electron transfer for powering CO₂ reduction into acetoin, a valuable platform chemical with broad applications. By spontaneously attaching eosin Y to the membrane-bound hydrogenase (MBH) of R. eutropha, we enabled direct and specific electron flow. The biohybrid system demonstrated sustainable and efficient light-energized CO₂ conversion to acetoin, even surpassing the yields from H₂-supplied autotrophic fermentation, which is considered the optimal source of reducing equivalents and energy for CO₂ fixation by R. eutropha. Mechanistic investigations indicated that the photo-induced electrons from eosin Y were transferred to MBH, resulting in the formation of H₂ intermediate in periplasm, which was subsequently oxidized by cytosolic soluble hydrogenase to generate NADH for energizing CO₂ fixation. To further enhance efficiency, metabolic engineering was applied to boost ATP synthesis by introducing a non-oxygen-dependent proton pump (Gloeobacter rhodopsin), while blocking L-lactate and acetate biosynthesis pathways to divert carbon flux toward acetoin production. The engineered eosin Y-R. eutropha biohybrid system achieved an acetoin yield of 1.41 ± 0.06 mM, representing 2.07 times greater than that of H₂-supplied autotrophic fermentation. This system exemplifies a sustainable, light-driven CO₂ conversion process, contributing significantly to the advancement of sustainable biocatalytic processes in the realms of green chemistry and CO₂ management.

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来源期刊

Journal of CO2 Utilization CHEMISTRY, MULTIDISCIPLINARY-ENGINEERING, CHEMICAL

CiteScore

13.90

自引率

10.40%

发文量

406

审稿时长

2.8 months

期刊介绍： The Journal of CO2 Utilization offers a single, multi-disciplinary, scholarly platform for the exchange of novel research in the field of CO2 re-use for scientists and engineers in chemicals, fuels and materials. The emphasis is on the dissemination of leading-edge research from basic science to the development of new processes, technologies and applications. The Journal of CO2 Utilization publishes original peer-reviewed research papers, reviews, and short communications, including experimental and theoretical work, and analytical models and simulations.