無細胞代謝のためのモーター(A motor for cell-free metabolism)

2024-07-11 マックス・プランク研究所

Cell-free system composed of interdependent metabolic (Cetch cycle, pink) and genetic (Pure, blue) levels that recursively interact with one another. Pure produces the missing enzymes for CO₂ fixation (i.e. Epi and Ecm) by transcription and translation (TX-TL) of Epi and Ecm genes; Cetch utilizes such enzymes for synthesizing glycine from CO₂, thus sustaining protein production. Enzyme abbreviations Epi, Ecm, and RNAP stand for methylmalonyl-/ethylmalonyl-CoA epimerase, ethylmalonyl-CoA mutase, and RNA polymerase respectively.
© MPI f. Terrestrial Microbiology/ Giaveri

<関連情報>

• https://www.mpg.de/22163540/0703-terr-a-motor-for-cell-free-metabolism-153410-x
• https://www.science.org/doi/10.1126/science.adn3856

部分的に自己合成する生化学ネットワークにおける翻訳と代謝の統合 Integrated translation and metabolism in a partially self-synthesizing biochemical network

SIMONE GIAVERI, NITIN BOHRA, CHRISTOPH DIEHL, HAO YUAN YANG, […], AND TOBIAS J. ERB
Science  Published:11 Jul 2024
DOI:https://doi.org/10.1126/science.adn3856

Editor’s summary

All life must transform metabolites through enzyme-catalyzed reactions and transmit the information necessary to produce those enzymes for future generations. Synthetic biology systems are often limited to either a metabolic or genetic focus. Giaveri et al. combined two existing artificial systems, a carbon dioxide–fixing metabolic cycle and an in vitro transcription and translation platform, to create a complex hybrid system that can incorporate carbon dioxide–derived glycine into DNA-encoded protein products. When provided with the appropriate starting conditions, a droplet-confined system can self-regenerate by producing missing enzymes. This integrated metabolic and genetic biosynthetic system may be a useful system in which to study metabolic networks and could serve as a platform for additional metabolic modules. —Michael A. Funk

Abstract

One of the hallmarks of living organisms is their capacity for self-organization and regeneration, which requires a tight integration of metabolic and genetic networks. We sought to construct a linked metabolic and genetic network in vitro that shows such lifelike behavior outside of a cellular context and generates its own building blocks from nonliving matter. We integrated the metabolism of the crotonyl-CoA/ethyl-malonyl-CoA/hydroxybutyryl-CoA cycle with cell-free protein synthesis using recombinant elements. Our network produces the amino acid glycine from CO₂ and incorporates it into target proteins following DNA-encoded instructions. By orchestrating ~50 enzymes we established a basic cell-free operating system in which genetically encoded inputs into a metabolic network are programmed to activate feedback loops allowing for self-integration and (partial) self-regeneration of the complete system.