Engineering CO2-fixing modules in E. coli via efficient assembly of cyanobacterial Rubisco and carboxysomes

Rubisco (ribulose 1,5-bisphosphate carboxylase/oxygenase) is the central enzyme for converting atmospheric CO2 into organic molecules, playing a crucial role in the global carbon cycle. In cyanobacteria and some chemoautotrophs, Rubisco complexes, along with carbonic anhydrase, are enclosed within s...

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Bibliographic Details
Published in:Plant communications 2024-12, p.101217, Article 101217
Main Authors: Sun, Yaqi, Chen, Taiyu, Ge, Xingwu, Ni, Tao, Dykes, Gregory F., Zhang, Peijun, Huang, Fang, Liu, Lu-Ning
Format: Article
Language:English
Subjects:
carbon fixation
carboxysome
chaperone
Raf1
Rubisco
synthetic engineering
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Summary:Rubisco (ribulose 1,5-bisphosphate carboxylase/oxygenase) is the central enzyme for converting atmospheric CO2 into organic molecules, playing a crucial role in the global carbon cycle. In cyanobacteria and some chemoautotrophs, Rubisco complexes, along with carbonic anhydrase, are enclosed within specific proteinaceous microcompartments, known as carboxysomes. The polyhedral carboxysome shell ensures a dense packaging of Rubisco and creates a high-CO2 internal environment to facilitate the fixation of CO2. Rubisco and carboxysomes have been popular targets for bioengineering, with the intent of enhancing plant photosynthesis, crop yields, and biofuel production. However, efficient generation of Form 1B Rubisco and cyanobacterial β-carboxysomes in heterologous systems remains challenging. Here, we developed genetic systems to efficiently engineer functional cyanobacterial Form 1B Rubisco in E. coli, by incorporating Rubisco assembly factor Raf1 and modulating the RbcL/S stoichiometry. We further accomplished effective reconstitution of catalytically active β-carboxysomes in E. coli with cognate Form 1B Rubisco by fine-tuning the expression levels of individual β-carboxysome components. In addition, we investigated the encapsulation mechanism of Rubisco into carboxysomes via constructing hybrid carboxysomes; this was achieved by creating a chimeric encapsulation peptide incorporating SSLDs that permits the encapsulation of Form 1B Rubisco into α-carboxysome shells. Our study provides insights into the assembly mechanisms of plant-like Form 1B Rubisco and its encapsulation principles in both β-carboxysomes and hybrid carboxysomes, and highlights the inherent modularity of carboxysome structures. The findings lay the framework for rational design and repurposing of CO2-fixing modules in bioengineering applications, e.g. crop engineering, biocatalyst production, and molecule delivery. Short Summary: With the intent of improving the efficiency of Rubisco carboxylation, our research established efficient production of active Form 1B Rubisco in E. coli, engineering of β-carboxysome structures, and construction of hybrid carboxysomes. These findings provide valuable insights into the assembly mechanisms of Rubisco and carboxysomes and will underpin their bioengineering applications in crop engineering, biocatalyst production, and molecule delivery.
ISSN:2590-3462
2590-3462
DOI:10.1016/j.xplc.2024.101217