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Defining Rational Photoelectron Routing for Targeted Intracellular Energy Transfer

標的細胞内エネルギー伝達のための合理的な光電子経路の定義 (AI 翻訳)

Hao Wang, Jialu Li, Yuhua Feng, Lin Wang, Donghao He, CK Zeng, Zhonghua Cai, Kemeng Xiao, Bo Wang

Angewandte Chemie International Edition📚 査読済 / ジャーナル2026-06-16#その他Origin: CN
DOI: 10.1002/anie.2408585
原典: https://doi.org/10.1002/anie.2408585

🤖 gxceed AI 要約

日本語

微生物人工光合成の効率向上を目的とし、リボフラビンを用いた選択的NADPH再生戦略を報告。光励起RFがNADP+に特異的に結合し電子伝達する機構を解明。in vivoでNADPHレベルを上昇させ、NADPH依存代謝産物の合成を促進。多種微生物での検証により一般性を示した。

English

This paper reports a strategy using riboflavin (RF) to selectively direct photogenerated electrons toward intracellular NADPH regeneration in microbial artificial photosynthesis. Light-excited RF specifically binds NADP+ and transfers electrons, elevating NADPH levels and enhancing NADPH-dependent metabolite synthesis. The mechanism is validated across species and products, establishing a general framework for efficient artificial photosynthesis.

Unofficial AI-generated summary based on the public title and abstract. Not an official translation.

📝 gxceed 編集解説 — Why this matters

日本のGX文脈において

基礎研究であるが、光駆動型の生体触媒プロセスはカーボンニュートラルな化学品生産など日本のGX戦略に貢献する可能性がある。現時点では直接的な政策連動はない。

In the global GX context

This work advances artificial photosynthesis, a key area for global clean energy transition and carbon fixation technologies. It provides a mechanistic framework that could be applied to bioelectrochemical systems for sustainable fuel and chemical production.

👥 読者別の含意

🔬研究者:Provides a mechanistic understanding of selective photoelectron transfer for NADPH regeneration, relevant for synthetic biology and artificial photosynthesis.

📄 Abstract(原文)

ABSTRACT Microbial artificial photosynthesis offers a promising strategy for light‐driven biomanufacturing, yet its efficiency remains limited by the non‐selective conversion of photogenerated electrons into metabolically usable reducing power, causing energy dissipation and weak coupling between light capture and metabolic reactions. Here, we report a rational strategy using riboflavin (RF), a membrane‐permeable and biocompatible flavin photosensitizer, to selectively channel photonic energy into intracellular NADPH regeneration. Quantum chemical calculations and spectroscopic analyses reveal that light‐excited RF exhibits a specific binding affinity and favorable electron transfer trend toward NADP + . In vivo, RF activation markedly elevated intracellular NADPH levels and enhanced the synthesis of NADPH‐dependent metabolites through NADPH reductase‐associated pathways. Transcriptomic and inhibition analyses linked RF‐mediated NADPH regeneration to NADP + /NADPH redox enzymes rather than glucose‐6‐phosphate dehydrogenase‐mediated flux, while NADH‐related redox genes remained largely unaffected, demonstrating the selectivity of this reductive route. Cross‐species and multi‐product validations consistently reproduced these results, underscoring the generality of this mechanism across distinct NADPH‐dependent microbial chassis. This work establishes a mechanistically defined and broadly applicable framework for directing photogenerated electrons into specific cellular reducing equivalents, paving the way for efficient artificial photosynthetic and bioelectrochemical platforms.

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