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Extensible and self-recoverable proteinaceous materials derived from scallop byssal thread

Author

Listed:
  • Xiaokang Zhang

    (Ocean University of China
    Pilot National Laboratory for Marine Science and Technology)

  • Mengkui Cui

    (ShanghaiTech University)

  • Shuoshuo Wang

    (Ocean University of China
    Pilot National Laboratory for Marine Science and Technology)

  • Fei Han

    (Chinese Academy of Sciences)

  • Pingping Xu

    (Ocean University of China
    Pilot National Laboratory for Marine Science and Technology)

  • Luyao Teng

    (Ocean University of China
    Pilot National Laboratory for Marine Science and Technology)

  • Hang Zhao

    (Chinese Academy of Sciences)

  • Ping Wang

    (Chinese Academy of Sciences)

  • Guichu Yue

    (Beihang University)

  • Yong Zhao

    (Beihang University)

  • Guangfeng Liu

    (Chinese Academy of Sciences)

  • Ke Li

    (ShanghaiTech University)

  • Jicong Zhang

    (ShanghaiTech University)

  • Xiaoping Liang

    (Tsinghua University)

  • Yingying Zhang

    (Tsinghua University)

  • Zhiyuan Liu

    (Chinese Academy of Sciences)

  • Chao Zhong

    (Chinese Academy of Sciences
    Chinese Academy of Sciences)

  • Weizhi Liu

    (Ocean University of China
    Pilot National Laboratory for Marine Science and Technology)

Abstract

Biologically derived and biologically inspired fibers with outstanding mechanical properties have found attractive technical applications across diverse fields. Despite recent advances, few fibers can simultaneously possess high-extensibility and self-recovery properties especially under wet conditions. Here, we report protein-based fibers made from recombinant scallop byssal proteins with outstanding extensibility and self-recovery properties. We initially investigated the mechanical properties of the native byssal thread taken from scallop Chlamys farreri and reveal its high extensibility (327 ± 32%) that outperforms most natural biological fibers. Combining transcriptome and proteomics, we select the most abundant scallop byssal protein type 5-2 (Sbp5-2) in the thread region, and produce a recombinant protein consisting of 7 tandem repeat motifs (rTRM7) of the Sbp5-2 protein. Applying an organic solvent-enabled drawing process, we produce bio-inspired extensible rTRM7 fiber with high-extensibility (234 ± 35%) and self-recovery capability in wet condition, recapitulating the hierarchical structure and mechanical properties of the native scallop byssal thread. We further show that the mechanical properties of rTRM7 fiber are highly regulated by hydrogen bonding and intermolecular crosslinking formed through disulfide bond and metal-carboxyl coordination. With its outstanding mechanical properties, rTRM7 fiber can also be seamlessly integrated with graphene to create motion sensors and electrophysiological signal transmission electrode.

Suggested Citation

  • Xiaokang Zhang & Mengkui Cui & Shuoshuo Wang & Fei Han & Pingping Xu & Luyao Teng & Hang Zhao & Ping Wang & Guichu Yue & Yong Zhao & Guangfeng Liu & Ke Li & Jicong Zhang & Xiaoping Liang & Yingying Zh, 2022. "Extensible and self-recoverable proteinaceous materials derived from scallop byssal thread," Nature Communications, Nature, vol. 13(1), pages 1-11, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-30415-3
    DOI: 10.1038/s41467-022-30415-3
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    References listed on IDEAS

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    1. Shanshan Lv & Daniel M. Dudek & Yi Cao & M. M. Balamurali & John Gosline & Hongbin Li, 2010. "Designed biomaterials to mimic the mechanical properties of muscles," Nature, Nature, vol. 465(7294), pages 69-73, May.
    2. Jordan J. Green & Jennifer H. Elisseeff, 2016. "Mimicking biological functionality with polymers for biomedical applications," Nature, Nature, vol. 540(7633), pages 386-394, December.
    3. Yuli Li & Xiaoqing Sun & Xiaoli Hu & Xiaogang Xun & Jinbo Zhang & Ximing Guo & Wenqian Jiao & Lingling Zhang & Weizhi Liu & Jing Wang & Ji Li & Yan Sun & Yan Miao & Xiaokang Zhang & Taoran Cheng & Guo, 2017. "Scallop genome reveals molecular adaptations to semi-sessile life and neurotoxins," Nature Communications, Nature, vol. 8(1), pages 1-11, December.
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    Cited by:

    1. Yingkun Shi & Baohu Wu & Shengtong Sun & Peiyi Wu, 2023. "Aqueous spinning of robust, self-healable, and crack-resistant hydrogel microfibers enabled by hydrogen bond nanoconfinement," Nature Communications, Nature, vol. 14(1), pages 1-13, December.

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