Hierarchical spidroin micellar nanoparticles as the fundamental precursors of spider silks

Parent, Lucas R.; Onofrei, David; Xu, Dian; Stengel, Dillan; Roehling, John D.; Addison, J. Bennett; Forman, Christopher; Amin, Samrat A.; Cherry, Brian R.; Yarger, Jeffery L.; Gianneschi, Nathan C.; Holland, Gregory P.

doi:10.1073/pnas.1810203115

Cited by 50 publications

(70 citation statements)

References 48 publications

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“…This phenomenon was more frequently seen in HFIP dope, implying that nanoparticles in HFIP solvent are more dynamic and less stable, consistent with the broader size distribution observed in HFIP dope. The observed morphologies, including the potential for nanoparticle fusion, are also consistent with the recent cryo‐EM report of nanoparticle‐like assemblies comprising multiple micellar species in the MA gland of L. hesperus …”

Section: Resultssupporting

confidence: 88%

“…Of particular importance, two primary and perhaps not mutually exclusive mechanisms for spidroin structural transition during passage through the gland and duct have been advanced: a liquid crystalline hypothesis and a micellar hypothesis . Recently, cryoelectron microscopy and diffusion NMR experiments have provided evidence for nanoparticle self‐assembly of spidroins in the gland setting, comprising micellar subdomains . In light of the requirement for self‐assembly, phase transition, and anisotropic orientation inherent in these fibrillogenesis mechanisms, favoring of such a process in mimicking the natural silk assembly process is likely to be beneficial.…”

Section: Introductionmentioning

confidence: 99%

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Recombinant Silk Fiber Properties Correlate to Prefibrillar Self‐Assembly

Weatherbee-Martin

Liu

et al. 2019

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Spider silks are desirable materials with mechanical properties superior to most synthetic materials coupled with biodegradability and biocompatibility. In order to replicate natural silk properties using recombinant spider silk proteins (spidroins) and wet‐spinning methods, the focus to date has typically been on modifying protein sequence, protein size, and spinning conditions. Here, an alternative approach is demonstrated. Namely, using the same ≈57 kDa recombinant aciniform silk protein with a consistent wet‐spinning protocol, fiber mechanical properties are shown to significantly differ as a function of the solvent used to dissolve the protein at high concentration (the “spinning dope” solution). A fluorinated acid/alcohol/water dope leads to drastic improvement in fibrillar extensibility and, correspondingly, toughness compared to fibers produced using a previously developed fluorinated alcohol/water dope. To understand the underlying cause for these mechanical differences, morphology and structure of the two classes of silk fiber are compared, with features tracing back to dope‐state protein structuring and preassembly. Specifically, distinct classes of spidroin nanoparticles appear to form in each dope prior to fiber spinning and these preassembled states are, in turn, linked to fiber morphology, structure, and mechanical properties. Tailoring of dope‐state spidroin nanoparticle assembly, thus, appears a promising strategy to modulate fibrillar silk properties.

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Section: Resultssupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Recombinant Silk Fiber Properties Correlate to Prefibrillar Self‐Assembly

Weatherbee-Martin

Liu

et al. 2019

Small

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“…The overall effect of these factors is to promote rapid β-sheet assembly and supramolecular aggregation. Several competing hypotheses exist for the specific mechanisms of silk fibroin structural transition in vivo, on which the reader is referred to relevant literature for further discussion [2,[71][72][73][74][75]. Importantly, the non-repetitive N and C-terminus domains have been implicated in controlling silk fibroin self-assembly [48][49][50].…”

Section: The Supramolecular Nature Of Silkmentioning

confidence: 99%

Chemical Synthesis of Silk-Mimetic Polymers

et al. 2019

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Silk is a naturally occurring high-performance material that can surpass man-made polymers in toughness and strength. The remarkable mechanical properties of silk result from the primary sequence of silk fibroin, which bears semblance to a linear segmented copolymer with alternating rigid (“crystalline”) and flexible (“amorphous”) blocks. Silk-mimetic polymers are therefore of great emerging interest, as they can potentially exhibit the advantageous features of natural silk while possessing synthetic flexibility as well as non-natural compositions. This review describes the relationships between primary sequence and material properties in natural silk fibroin and furthermore discusses chemical approaches towards the synthesis of silk-mimetic polymers. In particular, step-growth polymerization, controlled radical polymerization, and copolymerization with naturally derived silk fibroin are presented as strategies for synthesizing silk-mimetic polymers with varying molecular weights and degrees of sequence control. Strategies for improving macromolecular solubility during polymerization are also highlighted. Lastly, the relationships between synthetic approach, supramolecular structure, and bulk material properties are explored in this review, with the aim of providing an informative perspective on the challenges facing chemical synthesis of silk-mimetic polymers with desirable properties.

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“…Those hierarchically supra-molecular silk structures are greatly controlled by the sophisticated spinning process occurring in the spinning ducts of the spiders. Currently, two common hypotheses describe the hierarchical structures responsible for the spinning process that transforms silk protein solutions into solid filaments at the submicron and micron levels, namely the liquid crystalline model [9] and the micelles model [10][11][12]. The liquid crystalline model describes the transformation of liquid silk protein into fibers formed within the spinning duct of spiders, which in turn is accompanied by increasing shear forces that lead to the formation of intermolecular secondary structures.…”

Section: Introductionmentioning

confidence: 99%

Hydrothermal Effect on Mechanical Properties of Nephila pilipes Spidroin

Pandey

Chang

et al. 2020

Polymers

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The superlative mechanical properties of spider silk and its conspicuous variations have instigated significant interest over the past few years. However, current attempts to synthetically spin spider silk fibers often yield an inferior physical performance, owing to the improper molecular interactions of silk proteins. Considering this, herein, a post-treatment process to reorganize molecular structures and improve the physical strength of spider silk is reported. The major ampullate dragline silk from Nephila pilipes with a high β-sheet content and an adequate tensile strength was utilized as the study material, while that from Cyrtophora moluccensis was regarded as a reference. Our results indicated that the hydrothermal post-treatment (50–70 °C) of natural spider silk could effectively induce the alternation of secondary structures (random coil to β-sheet) and increase the overall tensile strength of the silk. Such advantageous post-treatment strategy when applied to regenerated spider silk also leads to an increment in the strength by ~2.5–3.0 folds, recapitulating ~90% of the strength of native spider silk. Overall, this study provides a facile and effective post-spinning means for enhancing the molecular structures and mechanical properties of as-spun silk threads, both natural and regenerated.

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Hierarchical spidroin micellar nanoparticles as the fundamental precursors of spider silks

Cited by 50 publications

References 48 publications

Recombinant Silk Fiber Properties Correlate to Prefibrillar Self‐Assembly

Recombinant Silk Fiber Properties Correlate to Prefibrillar Self‐Assembly

Chemical Synthesis of Silk-Mimetic Polymers

Hydrothermal Effect on Mechanical Properties of Nephila pilipes Spidroin

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