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A map of the rubisco biochemical landscape

Author

Listed:
  • Noam Prywes

    (University of California Berkeley
    University of California Berkeley)

  • Naiya R. Phillips

    (University of California Berkeley)

  • Luke M. Oltrogge

    (University of California Berkeley
    University of California Berkeley)

  • Sebastian Lindner

    (University of Heidelberg)

  • Leah J. Taylor-Kearney

    (University of California Berkeley)

  • Yi-Chin Candace Tsai

    (Nanyang Technological University)

  • Benoit Pins

    (University of Naples Federico II)

  • Aidan E. Cowan

    (University of California Berkeley
    Lawrence Berkeley National Laboratory)

  • Hana A. Chang

    (University of California Berkeley)

  • Renée Z. Wang

    (University of California Berkeley)

  • Laina N. Hall

    (University of California Berkeley)

  • Daniel Bellieny-Rabelo

    (University of California Berkeley
    University of California Berkeley)

  • Hunter M. Nisonoff

    (University of California Berkeley)

  • Rachel F. Weissman

    (University of California Berkeley)

  • Avi I. Flamholz

    (California Institute of Technology)

  • David Ding

    (University of California Berkeley
    University of California Berkeley)

  • Abhishek Y. Bhatt

    (University of California Berkeley
    University of California San Diego)

  • Oliver Mueller-Cajar

    (Nanyang Technological University)

  • Patrick M. Shih

    (University of California Berkeley
    University of California Berkeley
    Lawrence Berkeley National Laboratory
    Joint BioEnergy Institute)

  • Ron Milo

    (Weizmann Institute of Science)

  • David F. Savage

    (University of California Berkeley
    University of California Berkeley
    University of California Berkeley)

Abstract

Rubisco is the primary CO2-fixing enzyme of the biosphere1, yet it has slow kinetics2. The roles of evolution and chemical mechanism in constraining its biochemical function remain debated3,4. Engineering efforts aimed at adjusting the biochemical parameters of rubisco have largely failed5, although recent results indicate that the functional potential of rubisco has a wider scope than previously known6. Here we developed a massively parallel assay, using an engineered Escherichia coli7 in which enzyme activity is coupled to growth, to systematically map the sequence–function landscape of rubisco. Composite assay of more than 99% of single-amino acid mutants versus CO2 concentration enabled inference of enzyme velocity and apparent CO2 affinity parameters for thousands of substitutions. This approach identified many highly conserved positions that tolerate mutation and rare mutations that improve CO2 affinity. These data indicate that non-trivial biochemical changes are readily accessible and that the functional distance between rubiscos from diverse organisms can be traversed, laying the groundwork for further enzyme engineering efforts.

Suggested Citation

  • Noam Prywes & Naiya R. Phillips & Luke M. Oltrogge & Sebastian Lindner & Leah J. Taylor-Kearney & Yi-Chin Candace Tsai & Benoit Pins & Aidan E. Cowan & Hana A. Chang & Renée Z. Wang & Laina N. Hall & , 2025. "A map of the rubisco biochemical landscape," Nature, Nature, vol. 638(8051), pages 823-828, February.
    • Handle: RePEc:nat:nature:v:638:y:2025:i:8051:d:10.1038_s41586-024-08455-0
    DOI: 10.1038/s41586-024-08455-0
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