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A molecular atlas reveals the tri-sectional spinning mechanism of spider dragline silk

Author

Listed:
  • Wenbo Hu

    (Southwest University)

  • Anqiang Jia

    (Southwest University)

  • Sanyuan Ma

    (Southwest University)

  • Guoqing Zhang

    (Southwest University)

  • Zhaoyuan Wei

    (Southwest University)

  • Fang Lu

    (Southwest University)

  • Yongjiang Luo

    (Southwest University)

  • Zhisheng Zhang

    (Southwest University)

  • Jiahe Sun

    (Southwest University)

  • Tianfang Yang

    (Southwest University)

  • TingTing Xia

    (Southwest University)

  • Qinhui Li

    (Southwest University)

  • Ting Yao

    (Southwest University)

  • Jiangyu Zheng

    (Southwest University)

  • Zijie Jiang

    (Southwest University)

  • Zehui Xu

    (Southwest University)

  • Qingyou Xia

    (Southwest University)

  • Yi Wang

    (Southwest University)

Abstract

The process of natural silk production in the spider major ampullate (Ma) gland endows dragline silk with extraordinary mechanical properties and the potential for biomimetic applications. However, the precise genetic roles of the Ma gland during this process remain unknown. Here, we performed a systematic molecular atlas of dragline silk production through a high-quality genome assembly for the golden orb-weaving spider Trichonephila clavata and a multiomics approach to defining the Ma gland tri-sectional architecture: Tail, Sac, and Duct. We uncovered a hierarchical biosynthesis of spidroins, organic acids, lipids, and chitin in the sectionalized Ma gland dedicated to fine silk constitution. The ordered secretion of spidroins was achieved by the synergetic regulation of epigenetic and ceRNA signatures for genomic group-distributed spidroin genes. Single-cellular and spatial RNA profiling identified ten cell types with partitioned functional division determining the tri-sectional organization of the Ma gland. Convergence analysis and genetic manipulation further validated that this tri-sectional architecture of the silk gland was analogous across Arthropoda and inextricably linked with silk formation. Collectively, our study provides multidimensional data that significantly expand the knowledge of spider dragline silk generation and ultimately benefit innovation in spider-inspired fibers.

Suggested Citation

  • Wenbo Hu & Anqiang Jia & Sanyuan Ma & Guoqing Zhang & Zhaoyuan Wei & Fang Lu & Yongjiang Luo & Zhisheng Zhang & Jiahe Sun & Tianfang Yang & TingTing Xia & Qinhui Li & Ting Yao & Jiangyu Zheng & Zijie , 2023. "A molecular atlas reveals the tri-sectional spinning mechanism of spider dragline silk," Nature Communications, Nature, vol. 14(1), pages 1-16, December.
  • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-36545-6
    DOI: 10.1038/s41467-023-36545-6
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    References listed on IDEAS

    as
    1. Fritz Vollrath & David P. Knight, 2001. "Liquid crystalline spinning of spider silk," Nature, Nature, vol. 410(6828), pages 541-548, March.
    2. Yan Ma & Wenhui Zeng & Yongbing Ba & Qin Luo & Yao Ou & Rongpeng Liu & Jingwen Ma & Yiyun Tang & Jie Hu & Haomiao Wang & Xuan Tang & Yuanyuan Mu & Qingjun Li & Yuqin Chen & Yiting Ran & Zhonghuai Xian, 2022. "A single-cell transcriptomic atlas characterizes the silk-producing organ in the silkworm," Nature Communications, Nature, vol. 13(1), pages 1-16, December.
    3. Hyoung-Joon Jin & David L. Kaplan, 2003. "Mechanism of silk processing in insects and spiders," Nature, Nature, vol. 424(6952), pages 1057-1061, August.
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