Recombinant Silk Fiber Properties Correlate to Prefibrillar Self-Assembly

Lingling Xu; Nathan Weatherbee-Martin; Xiang Qin Liu; Jan K. Rainey

doi:10.1002/smll.201805294

Recombinant Silk Fiber Properties Correlate to Prefibrillar Self-Assembly

Lingling Xu, Nathan Weatherbee-Martin, Xiang Qin Liu, Jan K. Rainey

Medicine

Research output: Contribution to journal › Article › peer-review

35 Citations (Scopus)

Abstract

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.

Original language	English
Article number	1805294
Journal	Small
Volume	15
Issue number	12
DOIs	https://doi.org/10.1002/smll.201805294
Publication status	Published - Mar 22 2019

Bibliographical note

Funding Information:
L.X. and N.W.-M. contributed equally to this work. Thanks to Xiaoyi Ma for assistance in figure preparation; Dr. Laurent Kreplak for helpful discussions during development of the mechanical testing apparatus and for Raman spectromicroscope access; Dr. David Waisman for CD spectropolarimeter access; Dr. Michael Lee and Brandon Scott for polarized light microscope access; Ian Burton (National Research Council of Canada (NRC), Halifax NS) for NMR spectrometer support; and Bruce Stewart for technical assistance. The TCI probe for the 16.4 T NMR spectrometer at the NRC was provided by Dalhousie University through an Atlantic Canada Opportunities Agency Grant. This work was supported by Discovery Grants from the Natural Sciences and Engineering Research Council of Canada (NSERC, to X.-Q.L. and J.K.R.); a Discovery Accelerator Supplement (to J.K.R.); equipment and infrastructure Grants from NSERC (to J.K.R.), the Canadian Foundation for Innovation (to J.K.R.) and the Dalhousie Medical Research Foundation (to X.-Q.L. and J.K.R.); an NSERC Alexander Graham Bell Canada Graduate Scholarship (to N.W.-M.); and a Canadian Institutes of Health Research New Investigator Award (to J.K.R.)

Publisher Copyright:
© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

ASJC Scopus Subject Areas

Biotechnology
Biomaterials
General Chemistry
General Materials Science

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10.1002/smll.201805294

Cite this

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title = "Recombinant Silk Fiber Properties Correlate to Prefibrillar Self-Assembly",

abstract = "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.",

author = "Lingling Xu and Nathan Weatherbee-Martin and Liu, {Xiang Qin} and Rainey, {Jan K.}",

note = "Funding Information: L.X. and N.W.-M. contributed equally to this work. Thanks to Xiaoyi Ma for assistance in figure preparation; Dr. Laurent Kreplak for helpful discussions during development of the mechanical testing apparatus and for Raman spectromicroscope access; Dr. David Waisman for CD spectropolarimeter access; Dr. Michael Lee and Brandon Scott for polarized light microscope access; Ian Burton (National Research Council of Canada (NRC), Halifax NS) for NMR spectrometer support; and Bruce Stewart for technical assistance. The TCI probe for the 16.4 T NMR spectrometer at the NRC was provided by Dalhousie University through an Atlantic Canada Opportunities Agency Grant. This work was supported by Discovery Grants from the Natural Sciences and Engineering Research Council of Canada (NSERC, to X.-Q.L. and J.K.R.); a Discovery Accelerator Supplement (to J.K.R.); equipment and infrastructure Grants from NSERC (to J.K.R.), the Canadian Foundation for Innovation (to J.K.R.) and the Dalhousie Medical Research Foundation (to X.-Q.L. and J.K.R.); an NSERC Alexander Graham Bell Canada Graduate Scholarship (to N.W.-M.); and a Canadian Institutes of Health Research New Investigator Award (to J.K.R.) Publisher Copyright: {\textcopyright} 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim",

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AU - Weatherbee-Martin, Nathan

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N1 - Funding Information: L.X. and N.W.-M. contributed equally to this work. Thanks to Xiaoyi Ma for assistance in figure preparation; Dr. Laurent Kreplak for helpful discussions during development of the mechanical testing apparatus and for Raman spectromicroscope access; Dr. David Waisman for CD spectropolarimeter access; Dr. Michael Lee and Brandon Scott for polarized light microscope access; Ian Burton (National Research Council of Canada (NRC), Halifax NS) for NMR spectrometer support; and Bruce Stewart for technical assistance. The TCI probe for the 16.4 T NMR spectrometer at the NRC was provided by Dalhousie University through an Atlantic Canada Opportunities Agency Grant. This work was supported by Discovery Grants from the Natural Sciences and Engineering Research Council of Canada (NSERC, to X.-Q.L. and J.K.R.); a Discovery Accelerator Supplement (to J.K.R.); equipment and infrastructure Grants from NSERC (to J.K.R.), the Canadian Foundation for Innovation (to J.K.R.) and the Dalhousie Medical Research Foundation (to X.-Q.L. and J.K.R.); an NSERC Alexander Graham Bell Canada Graduate Scholarship (to N.W.-M.); and a Canadian Institutes of Health Research New Investigator Award (to J.K.R.) Publisher Copyright: © 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

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N2 - 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.

AB - 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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Recombinant Silk Fiber Properties Correlate to Prefibrillar Self-Assembly

Abstract

Bibliographical note

ASJC Scopus Subject Areas

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