Spider wrapping silk fibre architecture arising from its modular soluble protein precursor

Tremblay, Marie-Laurence; Xu, Liang; Lefèvre, Thierry; Sarker, Muzaddid; Orrell, Kathleen E.; Leclerc, Jérémie; Meng, Qing; Pézolet, Michel; Auger, Michèle; Liu, Xiang-Qin; Rainey, Jan K.

doi:10.1038/srep11502

Cited by 40 publications

(156 citation statements)

References 73 publications

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“…During fibre formation, AcSp1 undergoes a partial conversion from α-helical to β-sheet structuring [21], putatively seeded at helix 5 in the W unit [19,22]. This transition is recapitulated in recombinant W 2 between the soluble and fibrous forms [19].…”

Section: Introductionmentioning

confidence: 99%

“…In our previous structural studies [19], we performed segmental-labelling using split intein trans -splicing [49,50], whereby either the first (W 2-1 ) or second (W 2-2 ) W unit in W 2 was enriched with NMR-active 13 C and/or 15 N nuclei while the other W unit was at natural abundance. Although we demonstrated differential dynamics between the globular core and linker/tail regions through variation in the observed heteronuclear [ 1 H]- 15 N NOE, a more in-depth analysis of backbone dynamics is necessary to compare and contrast the behaviour of isolated W units vs. concatemers and to provide insight into more subtle variations in dynamics within the W unit.…”

Section: Introductionmentioning

confidence: 99%

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Characterizing Aciniform Silk Repetitive Domain Backbone Dynamics and Hydrodynamic Modularity

Tremblay

Sarker

et al. 2016

IJMS

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Spider aciniform (wrapping) silk is a remarkable fibrillar biomaterial with outstanding mechanical properties. It is a modular protein consisting, in Argiope trifasciata, of a core repetitive domain of 200 amino acid units (W units). In solution, the W units comprise a globular folded core, with five α-helices, and disordered tails that are linked to form a ~63-residue intrinsically disordered linker in concatemers. Herein, we present nuclear magnetic resonance (NMR) spectroscopy-based 15N spin relaxation analysis, allowing characterization of backbone dynamics as a function of residue on the ps–ns timescale in the context of the single W unit (W1) and the two unit concatemer (W2). Unambiguous mapping of backbone dynamics throughout W2 was made possible by segmental NMR active isotope-enrichment through split intein-mediated trans-splicing. Spectral density mapping for W1 and W2 reveals a striking disparity in dynamics between the folded core and the disordered linker and tail regions. These data are also consistent with rotational diffusion behaviour where each globular domain tumbles almost independently of its neighbour. At a localized level, helix 5 exhibits elevated high frequency dynamics relative to the proximal helix 4, supporting a model of fibrillogenesis where this helix unfolds as part of the transition to a mixed α-helix/β-sheet fibre.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Characterizing Aciniform Silk Repetitive Domain Backbone Dynamics and Hydrodynamic Modularity

Tremblay

Sarker

et al. 2016

IJMS

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“…We have previously expressed recombinant AcSp1-derived constructs with varying numbers of W units (nomenclature: W n , n= number of repeats) in Escherichia coli 36 and demonstrated that W 2 , W 3 , and W 4 constructs can be hand-pulled from low-concentration buffered aqueous solutions to form multi-centimeter fibers 32,36 . However, lowconcentration solutions are inefficient for high-yield fiber production and we have found that increasing W n concentration in aqueous solution promotes non-productive aggregation (results not shown).…”

Section: Introductionmentioning

confidence: 99%

“…AcSp1 undergoes a conceptually similar structural transition, but this results in a highly distinct fibrous structuring. In solution, AcSp1 from A. trifasciata is composed of compactly structured ~138 residue globular helical/turn containing domains connected together by 62 residue intrinsically disordered linkers 32 . Upon fiber formation, the protein retains a similar proportion of disorder and turn content alongside a mixture of moderately oriented β-sheet (~30%) and α-helical (~24%) domains 33,34 .…”

Section: Introductionmentioning

confidence: 99%

Identification of Wet-Spinning and Post-Spin Stretching Methods Amenable to Recombinant Spider Aciniform Silk

Weatherbee-Martin¹,

Xu²,

Hupe

et al. 2016

Biomacromolecules

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Spider silks are outstanding biomaterials with mechanical properties that outperform synthetic materials. Of the six fibrillar spider silks, aciniform (or wrapping) silk is the toughest through a unique combination of strength and extensibility. In this study, a wet-spinning method for recombinant Argiope trifasciata aciniform spidroin (AcSp1) is introduced. Recombinant AcSp1 comprising three 200 amino acid repeat units was solubilized in a 1,1,1,3,3,3-hexafluoro-2-propanol (HFIP)/water mixture, forming a viscous α-helix-enriched spinning dope, and wet-spun into an ethanol/water coagulation bath allowing continuous fiber production. Post-spin stretching of the resulting wet-spun fibers in water significantly improved fiber strength, enriched β-sheet conformation without complete α-helix depletion, and enhanced birefringence. These methods allow reproducible aciniform silk fiber formation, albeit with lower extensibility than native silk, requiring conditions and methods distinct from those previously reported for other silk proteins. This provides an essential starting point for tailoring wet-spinning of aciniform silk to achieve desired properties. Graphical Abstract*

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“…Acriniform silk is also used to form the soft inner layer of egg case. Tremblay et al (2015) found that the high toughness of aciniform silk is related to the primary sequence of spidroin and the distinctive mixture of α-helical, β-sheet, and non-canonical secondary structures. We expect that well understanding of the hierarchical architecture about these silks will inspire to the designs and development of advanced materials.…”

Section: Non-web Spider Silk Materialsmentioning

confidence: 99%

Development of New Smart Materials and Spinning Systems Inspired by Natural Silks and Their Applications

Cheng

Lee

2016

Front. Mater.

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Silks produced by spiders and silkworms are charming natural biological materials with highly optimized hierarchical structures and outstanding physicomechanical properties. The superior performance of silks relies on the integration of a unique protein sequence, a distinctive spinning process, and complex hierarchical structures. Silks have been prepared to form a variety of morphologies and are widely used in diverse applications, for example, in the textile industry, as drug delivery vehicles, and as tissue engineering scaffolds. This review presents an overview of the organization of natural silks, in which chemical and physical functions are optimized, as well as a range of new materials inspired by the desire to mimic natural silk structure and synthesis.

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Spider wrapping silk fibre architecture arising from its modular soluble protein precursor

Cited by 40 publications

References 73 publications

Characterizing Aciniform Silk Repetitive Domain Backbone Dynamics and Hydrodynamic Modularity

Characterizing Aciniform Silk Repetitive Domain Backbone Dynamics and Hydrodynamic Modularity

Identification of Wet-Spinning and Post-Spin Stretching Methods Amenable to Recombinant Spider Aciniform Silk

Development of New Smart Materials and Spinning Systems Inspired by Natural Silks and Their Applications

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