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A cysteine-less and ultra-fast split intein rationally engineered from being aggregation-prone to highly efficient in protein trans-splicing

Author

Listed:
  • Christoph Humberg

    (University of Münster)

  • Zahide Yilmaz

    (University of Münster)

  • Katharina Fitzian

    (University of Münster)

  • Wolfgang Dörner

    (University of Münster)

  • Daniel Kümmel

    (University of Münster)

  • Henning D. Mootz

    (University of Münster)

Abstract

Split inteins catalyze protein trans-splicing by ligating their extein sequences while undergoing self-excision, enabling diverse protein modification applications. However, many purified split intein precursors exhibit partial or no splicing activity for unknown reasons. The Aes123 PolB1 intein, a representative of the rare cysteine-less split inteins, is of particular interest due to its resistance to oxidative conditions and orthogonality to thiol chemistries. In this work, we identify β-sheet-dominated aggregation of its N-terminal intein fragment as the origin of its low (~30%) splicing efficiency. Using computational, biochemical, and biophysical analyses, we characterize the fully active monomeric fraction and pinpoint aggregation-prone regions. Supported by a crystal structure, we design stably monomeric mutants with nearly complete splicing activity. The optimized CLm intein (Cysteine-Less and monomeric) retains the wild-type’s ultra-fast reaction rate and serves as an efficient, thiol-independent protein modification tool. We find that other benchmark split inteins show similar precursor aggregation, suggesting that this general phenomenon arises from the intrinsic challenge to maintain the precursor in a partially disordered state while promoting stable folding upon fragment association.

Suggested Citation

  • Christoph Humberg & Zahide Yilmaz & Katharina Fitzian & Wolfgang Dörner & Daniel Kümmel & Henning D. Mootz, 2025. "A cysteine-less and ultra-fast split intein rationally engineered from being aggregation-prone to highly efficient in protein trans-splicing," Nature Communications, Nature, vol. 16(1), pages 1-17, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-57596-x
    DOI: 10.1038/s41467-025-57596-x
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    References listed on IDEAS

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