Design and implementation of aerobic and ambient CO2-reduction as an entry-point for enhanced carbon fixation.

Ari Satanowski; Daniel G Marchal; Alain Perret; Jean-Louis Petit; Madeleine Bouzon; Volker Döring; Ivan Dubois; Hai He; Edward N Smith; Virginie Pellouin; Henrik M Petri; Vittorio Rainaldi; Maren Nattermann; Simon Burgener; Nicole Paczia; Jan Zarzycki; Matthias Heinemann; Arren Bar-Even; Tobias J Erb

doi:10.1038/s41467-025-57549-4

Design and implementation of aerobic and ambient CO2-reduction as an entry-point for enhanced carbon fixation.

Ari Satanowski^*, Daniel G Marchal, Alain Perret, Jean-Louis Petit, Madeleine Bouzon, Volker Döring, Ivan Dubois, Hai He, Edward N Smith, Virginie Pellouin, Henrik M Petri, Vittorio Rainaldi, Maren Nattermann, Simon Burgener, Nicole Paczia, Jan Zarzycki, Matthias Heinemann, Arren Bar-Even, Tobias J Erb^*

^*Corresponding author for this work

Molecular Systems Biology

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

The direct reduction of CO 2 into one-carbon molecules is key to highly efficient biological CO 2-fixation. However, this strategy is currently restricted to anaerobic organisms and low redox potentials. In this study, we introduce the CORE cycle, a synthetic metabolic pathway that converts CO 2 to formate at aerobic conditions and ambient CO 2 levels, using only NADPH as a reductant. Combining theoretical pathway design and analysis, enzyme bioprospecting and high-throughput screening, modular assembly and adaptive laboratory evolution, we realize the CORE cycle in vivo and demonstrate that the cycle supports growth of E. coli by supplementing C1-metabolism and serine biosynthesis from CO 2. We further analyze the theoretical potential of the CORE cycle as a new entry-point for carbon in photorespiration and autotrophy. Overall, our work expands the solution space for biological carbon reduction, offering a promising approach to enhance CO 2 fixation processes such as photosynthesis, and opening avenues for synthetic autotrophy.

Original language	English
Article number	3134
Number of pages	18
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-57549-4
Publication status	Published - 1-Apr-2025

Keywords

Carbon Dioxide/metabolism
Oxidation-Reduction
Carbon Cycle
Escherichia coli/metabolism
Photosynthesis
Aerobiosis
Formates/metabolism
NADP/metabolism
Metabolic Networks and Pathways
Carbon/metabolism
Metabolic Engineering/methods
Autotrophic Processes

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Satanowski, A., Marchal, D. G., Perret, A., Petit, J.-L., Bouzon, M., Döring, V., Dubois, I., He, H., Smith, E. N., Pellouin, V., Petri, H. M., Rainaldi, V., Nattermann, M., Burgener, S., Paczia, N., Zarzycki, J., Heinemann, M., Bar-Even, A., & Erb, T. J. (2025). Design and implementation of aerobic and ambient CO2-reduction as an entry-point for enhanced carbon fixation. Nature Communications, 16(1), Article 3134. https://doi.org/10.1038/s41467-025-57549-4

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title = "Design and implementation of aerobic and ambient CO2-reduction as an entry-point for enhanced carbon fixation.",

abstract = "The direct reduction of CO 2 into one-carbon molecules is key to highly efficient biological CO 2-fixation. However, this strategy is currently restricted to anaerobic organisms and low redox potentials. In this study, we introduce the CORE cycle, a synthetic metabolic pathway that converts CO 2 to formate at aerobic conditions and ambient CO 2 levels, using only NADPH as a reductant. Combining theoretical pathway design and analysis, enzyme bioprospecting and high-throughput screening, modular assembly and adaptive laboratory evolution, we realize the CORE cycle in vivo and demonstrate that the cycle supports growth of E. coli by supplementing C1-metabolism and serine biosynthesis from CO 2. We further analyze the theoretical potential of the CORE cycle as a new entry-point for carbon in photorespiration and autotrophy. Overall, our work expands the solution space for biological carbon reduction, offering a promising approach to enhance CO 2 fixation processes such as photosynthesis, and opening avenues for synthetic autotrophy. ",

keywords = "Carbon Dioxide/metabolism, Oxidation-Reduction, Carbon Cycle, Escherichia coli/metabolism, Photosynthesis, Aerobiosis, Formates/metabolism, NADP/metabolism, Metabolic Networks and Pathways, Carbon/metabolism, Metabolic Engineering/methods, Autotrophic Processes",

author = "Ari Satanowski and Marchal, {Daniel G} and Alain Perret and Jean-Louis Petit and Madeleine Bouzon and Volker D{\"o}ring and Ivan Dubois and Hai He and Smith, {Edward N} and Virginie Pellouin and Petri, {Henrik M} and Vittorio Rainaldi and Maren Nattermann and Simon Burgener and Nicole Paczia and Jan Zarzycki and Matthias Heinemann and Arren Bar-Even and Erb, {Tobias J}",

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doi = "10.1038/s41467-025-57549-4",

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Satanowski, A, Marchal, DG, Perret, A, Petit, J-L, Bouzon, M, Döring, V, Dubois, I, He, H, Smith, EN, Pellouin, V, Petri, HM, Rainaldi, V, Nattermann, M, Burgener, S, Paczia, N, Zarzycki, J, Heinemann, M, Bar-Even, A & Erb, TJ 2025, 'Design and implementation of aerobic and ambient CO2-reduction as an entry-point for enhanced carbon fixation.', Nature Communications, vol. 16, no. 1, 3134. https://doi.org/10.1038/s41467-025-57549-4

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T1 - Design and implementation of aerobic and ambient CO2-reduction as an entry-point for enhanced carbon fixation.

AU - Satanowski, Ari

AU - Marchal, Daniel G

AU - Perret, Alain

AU - Petit, Jean-Louis

AU - Bouzon, Madeleine

AU - Döring, Volker

AU - Dubois, Ivan

AU - He, Hai

AU - Smith, Edward N

AU - Pellouin, Virginie

AU - Petri, Henrik M

AU - Rainaldi, Vittorio

AU - Nattermann, Maren

AU - Burgener, Simon

AU - Paczia, Nicole

AU - Zarzycki, Jan

AU - Heinemann, Matthias

AU - Bar-Even, Arren

AU - Erb, Tobias J

PY - 2025/4/1

Y1 - 2025/4/1

N2 - The direct reduction of CO 2 into one-carbon molecules is key to highly efficient biological CO 2-fixation. However, this strategy is currently restricted to anaerobic organisms and low redox potentials. In this study, we introduce the CORE cycle, a synthetic metabolic pathway that converts CO 2 to formate at aerobic conditions and ambient CO 2 levels, using only NADPH as a reductant. Combining theoretical pathway design and analysis, enzyme bioprospecting and high-throughput screening, modular assembly and adaptive laboratory evolution, we realize the CORE cycle in vivo and demonstrate that the cycle supports growth of E. coli by supplementing C1-metabolism and serine biosynthesis from CO 2. We further analyze the theoretical potential of the CORE cycle as a new entry-point for carbon in photorespiration and autotrophy. Overall, our work expands the solution space for biological carbon reduction, offering a promising approach to enhance CO 2 fixation processes such as photosynthesis, and opening avenues for synthetic autotrophy.

AB - The direct reduction of CO 2 into one-carbon molecules is key to highly efficient biological CO 2-fixation. However, this strategy is currently restricted to anaerobic organisms and low redox potentials. In this study, we introduce the CORE cycle, a synthetic metabolic pathway that converts CO 2 to formate at aerobic conditions and ambient CO 2 levels, using only NADPH as a reductant. Combining theoretical pathway design and analysis, enzyme bioprospecting and high-throughput screening, modular assembly and adaptive laboratory evolution, we realize the CORE cycle in vivo and demonstrate that the cycle supports growth of E. coli by supplementing C1-metabolism and serine biosynthesis from CO 2. We further analyze the theoretical potential of the CORE cycle as a new entry-point for carbon in photorespiration and autotrophy. Overall, our work expands the solution space for biological carbon reduction, offering a promising approach to enhance CO 2 fixation processes such as photosynthesis, and opening avenues for synthetic autotrophy.

KW - Carbon Dioxide/metabolism

KW - Oxidation-Reduction

KW - Carbon Cycle

KW - Escherichia coli/metabolism

KW - Photosynthesis

KW - Aerobiosis

KW - Formates/metabolism

KW - NADP/metabolism

KW - Metabolic Networks and Pathways

KW - Carbon/metabolism

KW - Metabolic Engineering/methods

KW - Autotrophic Processes

U2 - 10.1038/s41467-025-57549-4

DO - 10.1038/s41467-025-57549-4

M3 - Article

C2 - 40169551

SN - 2041-1723

VL - 16

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 3134

ER -

Design and implementation of aerobic and ambient CO2-reduction as an entry-point for enhanced carbon fixation.

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