Multicomponent nature underlies the extraordinary mechanical properties of spider dragline silk

N. Kono, Hiroyuki Nakamura, Masaru Mori, Yuki Yoshida, Rintaro Ohtoshi, A. Malay, Daniel A Pedrazzoli Moran, M. Tomita, K. Numata, K. Arakawa
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引用次数: 41

Abstract

Significance Artificial synthesis of spider silk has been actively pursued. However, until now, the natural mechanical properties of spider silk have been largely unreproducible. We thoroughly investigated the genomes and transcripts of four related species of orb-weaver spiders as well as the proteins in their silk threads. Then, in addition to spidroin, we found several low-molecular-weight proteins in common. Interestingly, the low-molecular-weight protein component of spider dragline silk doubled the tensile strength of artificial silk–based material. This discovery will greatly advance the industry and research on the use of protein-based materials. Dragline silk of golden orb-weaver spiders (Nephilinae) is noted for its unsurpassed toughness, combining extraordinary extensibility and tensile strength, suggesting industrial application as a sustainable biopolymer material. To pinpoint the molecular composition of dragline silk and the roles of its constituents in achieving its mechanical properties, we report a multiomics approach, combining high-quality genome sequencing and assembly, silk gland transcriptomics, and dragline silk proteomics of four Nephilinae spiders. We observed the consistent presence of the MaSp3B spidroin unique to this subfamily as well as several nonspidroin SpiCE proteins. Artificial synthesis and the combination of these components in vitro showed that the multicomponent nature of dragline silk, including MaSp3B and SpiCE, along with MaSp1 and MaSp2, is essential to realize the mechanical properties of spider dragline silk.
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多组分性质是蜘蛛拖丝非凡机械性能的基础
意义蜘蛛丝的人工合成得到了积极的研究。然而,到目前为止,蜘蛛丝的天然机械性能在很大程度上是不可复制的。我们深入研究了四种相关的圆织蜘蛛的基因组和转录本,以及它们丝线中的蛋白质。然后,除了蜘蛛蛋白,我们还发现了几种共同的低分子量蛋白质。有趣的是,蜘蛛拖丝的低分子量蛋白质成分使人造丝基材料的抗拉强度增加了一倍。这一发现将极大地推动蛋白质基材料的工业和研究。金球编织蜘蛛(Nephilinae)的拖丝以其无与伦比的韧性而闻名,结合了非凡的延展性和拉伸强度,建议作为可持续生物聚合物材料的工业应用。为了确定拖丝的分子组成及其成分在实现其机械性能中的作用,我们报告了一种多组学方法,结合高质量的基因组测序和组装,丝腺转录组学和四种Nephilinae蜘蛛的拖丝蛋白质组学。我们观察到该亚家族特有的MaSp3B蜘蛛蛋白以及几种非蜘蛛蛋白SpiCE蛋白的一致存在。这些成分的人工合成和体外组合表明,拖丝的多组分性质,包括MaSp3B和SpiCE,以及MaSp1和MaSp2,是实现蜘蛛拖丝力学性能所必需的。
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