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Arrest Peptide Profiling resolves co-translational folding pathways and chaperone interactions in vivo

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  • Xiuqi Chen

    (Johns Hopkins University
    Johns Hopkins University
    Delft University of Technology)

  • Vincent J. Hilser

    (Johns Hopkins University)

  • Christian M. Kaiser

    (Johns Hopkins University
    Utrecht University)

Abstract

Cytosolic proteins begin to fold co-translationally as soon as they emerge from the ribosome during translation. These early co-translational steps are crucial for overall folding and are guided by an intricate network of interactions with molecular chaperones. Because cellular co-translational folding is challenging to detect, its timing and progression remain largely elusive. To quantitatively define co-translational folding in live cells, we developed a high-throughput method that we term “Arrest Peptide Profiling” (AP Profiling). Combining AP Profiling with single-molecule experiments, we delineate co-translational folding for a set of GTPase domains with similar structures, defining how topology shapes folding pathways. Genetic ablation of nascent chain-binding chaperones results in discrete and localized folding changes, highlighting how functional redundancy among chaperones is achieved by distinct engagement with the nascent protein. Our work provides a window into cellular folding pathways of structurally intricate proteins and paves the way for systematic studies of nascent protein folding at exceptional resolution and throughput.

Suggested Citation

  • Xiuqi Chen & Vincent J. Hilser & Christian M. Kaiser, 2025. "Arrest Peptide Profiling resolves co-translational folding pathways and chaperone interactions in vivo," Nature Communications, Nature, vol. 16(1), pages 1-12, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-61398-6
    DOI: 10.1038/s41467-025-61398-6
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    References listed on IDEAS

    as
    1. Xiuqi Chen & Nandakumar Rajasekaran & Kaixian Liu & Christian M. Kaiser, 2020. "Synthesis runs counter to directional folding of a nascent protein domain," Nature Communications, Nature, vol. 11(1), pages 1-9, December.
    2. Julian O. Streit & Ivana V. Bukvin & Sammy H. S. Chan & Shahzad Bashir & Lauren F. Woodburn & Tomasz Włodarski & Angelo Miguel Figueiredo & Gabija Jurkeviciute & Haneesh K. Sidhu & Charity R. Hornby &, 2024. "The ribosome lowers the entropic penalty of protein folding," Nature, Nature, vol. 633(8028), pages 232-239, September.
    3. Hao-Hsuan Hsieh & Jae Ho Lee & Sowmya Chandrasekar & Shu-ou Shan, 2020. "A ribosome-associated chaperone enables substrate triage in a cotranslational protein targeting complex," Nature Communications, Nature, vol. 11(1), pages 1-20, December.
    4. Kazuki Saito & Hanna Kratzat & Annabelle Campbell & Robert Buschauer & A. Maxwell Burroughs & Otto Berninghausen & L. Aravind & Rachel Green & Roland Beckmann & Allen R. Buskirk, 2022. "Ribosome collisions induce mRNA cleavage and ribosome rescue in bacteria," Nature, Nature, vol. 603(7901), pages 503-508, March.
    5. Lars Ferbitz & Timm Maier & Holger Patzelt & Bernd Bukau & Elke Deuerling & Nenad Ban, 2004. "Trigger factor in complex with the ribosome forms a molecular cradle for nascent proteins," Nature, Nature, vol. 431(7008), pages 590-596, September.
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