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Membrane-anchored HDCR nanowires drive hydrogen-powered CO2 fixation

Author

Listed:
  • Helge M. Dietrich

    (Johann Wolfgang Goethe University)

  • Ricardo D. Righetto

    (Helmholtz Munich
    University of Basel)

  • Anuj Kumar

    (Johann Wolfgang Goethe University
    Philipps-University)

  • Wojciech Wietrzynski

    (Helmholtz Munich
    University of Basel)

  • Raphael Trischler

    (Johann Wolfgang Goethe University)

  • Sandra K. Schuller

    (Philipps-University)

  • Jonathan Wagner

    (Max Planck Institute of Biochemistry)

  • Fabian M. Schwarz

    (Johann Wolfgang Goethe University)

  • Benjamin D. Engel

    (Helmholtz Munich
    University of Basel)

  • Volker Müller

    (Johann Wolfgang Goethe University)

  • Jan M. Schuller

    (Philipps-University)

Abstract

Filamentous enzymes have been found in all domains of life, but the advantage of filamentation is often elusive1. Some anaerobic, autotrophic bacteria have an unusual filamentous enzyme for CO2 fixation—hydrogen-dependent CO2 reductase (HDCR)2,3—which directly converts H2 and CO2 into formic acid. HDCR reduces CO2 with a higher activity than any other known biological or chemical catalyst4,5, and it has therefore gained considerable interest in two areas of global relevance: hydrogen storage and combating climate change by capturing atmospheric CO2. However, the mechanistic basis of the high catalytic turnover rate of HDCR has remained unknown. Here we use cryo-electron microscopy to reveal the structure of a short HDCR filament from the acetogenic bacterium Thermoanaerobacter kivui. The minimum repeating unit is a hexamer that consists of a formate dehydrogenase (FdhF) and two hydrogenases (HydA2) bound around a central core of hydrogenase Fe-S subunits, one HycB3 and two HycB4. These small bacterial polyferredoxin-like proteins oligomerize through their C-terminal helices to form the backbone of the filament. By combining structure-directed mutagenesis with enzymatic analysis, we show that filamentation and rapid electron transfer through the filament enhance the activity of HDCR. To investigate the structure of HDCR in situ, we imaged T. kivui cells with cryo-electron tomography and found that HDCR filaments bundle into large ring-shaped superstructures attached to the plasma membrane. This supramolecular organization may further enhance the stability and connectivity of HDCR to form a specialized metabolic subcompartment within the cell.

Suggested Citation

  • Helge M. Dietrich & Ricardo D. Righetto & Anuj Kumar & Wojciech Wietrzynski & Raphael Trischler & Sandra K. Schuller & Jonathan Wagner & Fabian M. Schwarz & Benjamin D. Engel & Volker Müller & Jan M. , 2022. "Membrane-anchored HDCR nanowires drive hydrogen-powered CO2 fixation," Nature, Nature, vol. 607(7920), pages 823-830, July.
  • Handle: RePEc:nat:nature:v:607:y:2022:i:7920:d:10.1038_s41586-022-04971-z
    DOI: 10.1038/s41586-022-04971-z
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    Cited by:

    1. Jimyung Moon & Anja Poehlein & Rolf Daniel & Volker Müller, 2024. "Redirecting electron flow in Acetobacterium woodii enables growth on CO and improves growth on formate," Nature Communications, Nature, vol. 15(1), pages 1-11, December.
    2. Chen, Han & Huang, Yu & Sha, Chong & Moradian, Jamile Mohammadi & Yong, Yang-Chun & Fang, Zhen, 2023. "Enzymatic carbon dioxide to formate: Mechanisms, challenges and opportunities," Renewable and Sustainable Energy Reviews, Elsevier, vol. 178(C).

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