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A topological refactoring design strategy yields highly stable granulopoietic proteins

Author

Listed:
  • Julia Skokowa

    (University Hospital Tübingen)

  • Birte Hernandez Alvarez

    (Max Planck Institute for Biology)

  • Murray Coles

    (Max Planck Institute for Biology)

  • Malte Ritter

    (University Hospital Tübingen)

  • Masoud Nasri

    (University Hospital Tübingen)

  • Jérémy Haaf

    (University Hospital Tübingen)

  • Narges Aghaallaei

    (University Hospital Tübingen)

  • Yun Xu

    (University Hospital Tübingen)

  • Perihan Mir

    (University Hospital Tübingen)

  • Ann-Christin Krahl

    (University Hospital Tübingen)

  • Katherine W. Rogers

    (Friedrich Miescher Laboratory of the Max Planck Society
    National Institutes of Health)

  • Kateryna Maksymenko

    (Max Planck Institute for Biology
    Friedrich Miescher Laboratory of the Max Planck Society)

  • Baubak Bajoghli

    (University Hospital Tübingen)

  • Karl Welte

    (University Hospital Tübingen)

  • Andrei N. Lupas

    (Max Planck Institute for Biology)

  • Patrick Müller

    (Friedrich Miescher Laboratory of the Max Planck Society
    University of Konstanz)

  • Mohammad ElGamacy

    (University Hospital Tübingen
    Friedrich Miescher Laboratory of the Max Planck Society
    Heliopolis Biotechnology Ltd
    Max Planck Institute for Biology)

Abstract

Protein therapeutics frequently face major challenges, including complicated production, instability, poor solubility, and aggregation. De novo protein design can readily address these challenges. Here, we demonstrate the utility of a topological refactoring strategy to design novel granulopoietic proteins starting from the granulocyte-colony stimulating factor (G-CSF) structure. We change a protein fold by rearranging the sequence and optimising it towards the new fold. Testing four designs, we obtain two that possess nanomolar activity, the most active of which is highly thermostable and protease-resistant, and matches its designed structure to atomic accuracy. While the designs possess starkly different sequence and structure from the native G-CSF, they show specific activity in differentiating primary human haematopoietic stem cells into mature neutrophils. The designs also show significant and specific activity in vivo. Our topological refactoring approach is largely independent of sequence or structural context, and is therefore applicable to a wide range of protein targets.

Suggested Citation

  • Julia Skokowa & Birte Hernandez Alvarez & Murray Coles & Malte Ritter & Masoud Nasri & Jérémy Haaf & Narges Aghaallaei & Yun Xu & Perihan Mir & Ann-Christin Krahl & Katherine W. Rogers & Kateryna Maks, 2022. "A topological refactoring design strategy yields highly stable granulopoietic proteins," Nature Communications, Nature, vol. 13(1), pages 1-17, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-30157-2
    DOI: 10.1038/s41467-022-30157-2
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    References listed on IDEAS

    as
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