Sequence-Optimized Peptide Nanofibers as Growth Stimulators for Regeneration of Peripheral Neurons

Corinna Schilling; Thomas Mack; Selene Lickfett; Stefanie Sieste; Francesco S. Ruggeri; Tomas Sneideris; Arghya Dutta; Tristan Bereau; Ramin Naraghi; Daniela Sinske; Tuomas P.J. Knowles; Christopher V. Synatschke; Tanja Weil; Bernd Knöll

doi:10.1002/adfm.201809112

Sequence-Optimized Peptide Nanofibers as Growth Stimulators for Regeneration of Peripheral Neurons

Corinna Schilling, Thomas Mack, Selene Lickfett, Stefanie Sieste, Francesco S. Ruggeri, Tomas Sneideris, Arghya Dutta, Tristan Bereau, Ramin Naraghi, Daniela Sinske, Tuomas P.J. Knowles, Christopher V. Synatschke, Tanja Weil^*, Bernd Knöll

^*Corresponding author for this work

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

25 Citations (Scopus)

Abstract

There is an urgent need for biomaterials that support tissue healing, particularly neuronal regeneration. In a medium throughput screen novel self-assembling peptide (SAP) sequences that form fibrils and stimulated nerve fiber growth of peripheral nervous system (PNS)-derived neurons are identified. Based on the peptide sequences and fibril morphologies and by applying rational data-mining, important structural parameters stimulating neuronal activity are elucidated. Three SAPs (SAP^1e, SAP^2e, and SAP^5c) enhance adhesion and growth of PNS neurons. These SAPs form 2D and 3D matrices that serve as bioactive scaffolds stimulating cell adhesion and growth. The newly discovered SAPs also support the growth of CNS neurons and glia cells. Subsequently, the potential of SAPs to enhance PNS regeneration in vivo is analyzed. For this, the facial nerve driving whisker movement in mice is injured. Notably, SAPs persist for up to 3 weeks in the injury site indicating highly adhesive properties and stability. After SAP administration, more motor neurons incorporating markers for successive regeneration are observed. Recovery of whisker movement is elevated in SAP-injected mice. In summary, short peptides that form fibrils are identified and the adhesion, growth, and regeneration of neurons have been efficiently enhanced without the necessity to attach hormones or growth factors.

Original language	English
Article number	1809112
Journal	Advanced Functional Materials
Volume	29
Issue number	24
DOIs	https://doi.org/10.1002/adfm.201809112
Publication status	Published - 13 Jun 2019
Externally published	Yes

Keywords

facial nerve
naofiber
neuron growth
regeneration
self-assembling peptide

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Schilling, C., Mack, T., Lickfett, S., Sieste, S., Ruggeri, F. S., Sneideris, T., Dutta, A., Bereau, T., Naraghi, R., Sinske, D., Knowles, T. P. J., Synatschke, C. V., Weil, T., & Knöll, B. (2019). Sequence-Optimized Peptide Nanofibers as Growth Stimulators for Regeneration of Peripheral Neurons. Advanced Functional Materials, 29(24), Article 1809112. https://doi.org/10.1002/adfm.201809112

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title = "Sequence-Optimized Peptide Nanofibers as Growth Stimulators for Regeneration of Peripheral Neurons",

abstract = "There is an urgent need for biomaterials that support tissue healing, particularly neuronal regeneration. In a medium throughput screen novel self-assembling peptide (SAP) sequences that form fibrils and stimulated nerve fiber growth of peripheral nervous system (PNS)-derived neurons are identified. Based on the peptide sequences and fibril morphologies and by applying rational data-mining, important structural parameters stimulating neuronal activity are elucidated. Three SAPs (SAP1e, SAP2e, and SAP5c) enhance adhesion and growth of PNS neurons. These SAPs form 2D and 3D matrices that serve as bioactive scaffolds stimulating cell adhesion and growth. The newly discovered SAPs also support the growth of CNS neurons and glia cells. Subsequently, the potential of SAPs to enhance PNS regeneration in vivo is analyzed. For this, the facial nerve driving whisker movement in mice is injured. Notably, SAPs persist for up to 3 weeks in the injury site indicating highly adhesive properties and stability. After SAP administration, more motor neurons incorporating markers for successive regeneration are observed. Recovery of whisker movement is elevated in SAP-injected mice. In summary, short peptides that form fibrils are identified and the adhesion, growth, and regeneration of neurons have been efficiently enhanced without the necessity to attach hormones or growth factors.",

keywords = "facial nerve, naofiber, neuron growth, regeneration, self-assembling peptide",

author = "Corinna Schilling and Thomas Mack and Selene Lickfett and Stefanie Sieste and Ruggeri, {Francesco S.} and Tomas Sneideris and Arghya Dutta and Tristan Bereau and Ramin Naraghi and Daniela Sinske and Knowles, {Tuomas P.J.} and Synatschke, {Christopher V.} and Tanja Weil and Bernd Kn{\"o}ll",

year = "2019",

month = jun,

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doi = "10.1002/adfm.201809112",

language = "English",

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Schilling, C, Mack, T, Lickfett, S, Sieste, S, Ruggeri, FS, Sneideris, T, Dutta, A, Bereau, T, Naraghi, R, Sinske, D, Knowles, TPJ, Synatschke, CV, Weil, T & Knöll, B 2019, 'Sequence-Optimized Peptide Nanofibers as Growth Stimulators for Regeneration of Peripheral Neurons', Advanced Functional Materials, vol. 29, no. 24, 1809112. https://doi.org/10.1002/adfm.201809112

TY - JOUR

T1 - Sequence-Optimized Peptide Nanofibers as Growth Stimulators for Regeneration of Peripheral Neurons

AU - Schilling, Corinna

AU - Mack, Thomas

AU - Lickfett, Selene

AU - Sieste, Stefanie

AU - Ruggeri, Francesco S.

AU - Sneideris, Tomas

AU - Dutta, Arghya

AU - Bereau, Tristan

AU - Naraghi, Ramin

AU - Sinske, Daniela

AU - Knowles, Tuomas P.J.

AU - Synatschke, Christopher V.

AU - Weil, Tanja

AU - Knöll, Bernd

PY - 2019/6/13

Y1 - 2019/6/13

N2 - There is an urgent need for biomaterials that support tissue healing, particularly neuronal regeneration. In a medium throughput screen novel self-assembling peptide (SAP) sequences that form fibrils and stimulated nerve fiber growth of peripheral nervous system (PNS)-derived neurons are identified. Based on the peptide sequences and fibril morphologies and by applying rational data-mining, important structural parameters stimulating neuronal activity are elucidated. Three SAPs (SAP1e, SAP2e, and SAP5c) enhance adhesion and growth of PNS neurons. These SAPs form 2D and 3D matrices that serve as bioactive scaffolds stimulating cell adhesion and growth. The newly discovered SAPs also support the growth of CNS neurons and glia cells. Subsequently, the potential of SAPs to enhance PNS regeneration in vivo is analyzed. For this, the facial nerve driving whisker movement in mice is injured. Notably, SAPs persist for up to 3 weeks in the injury site indicating highly adhesive properties and stability. After SAP administration, more motor neurons incorporating markers for successive regeneration are observed. Recovery of whisker movement is elevated in SAP-injected mice. In summary, short peptides that form fibrils are identified and the adhesion, growth, and regeneration of neurons have been efficiently enhanced without the necessity to attach hormones or growth factors.

AB - There is an urgent need for biomaterials that support tissue healing, particularly neuronal regeneration. In a medium throughput screen novel self-assembling peptide (SAP) sequences that form fibrils and stimulated nerve fiber growth of peripheral nervous system (PNS)-derived neurons are identified. Based on the peptide sequences and fibril morphologies and by applying rational data-mining, important structural parameters stimulating neuronal activity are elucidated. Three SAPs (SAP1e, SAP2e, and SAP5c) enhance adhesion and growth of PNS neurons. These SAPs form 2D and 3D matrices that serve as bioactive scaffolds stimulating cell adhesion and growth. The newly discovered SAPs also support the growth of CNS neurons and glia cells. Subsequently, the potential of SAPs to enhance PNS regeneration in vivo is analyzed. For this, the facial nerve driving whisker movement in mice is injured. Notably, SAPs persist for up to 3 weeks in the injury site indicating highly adhesive properties and stability. After SAP administration, more motor neurons incorporating markers for successive regeneration are observed. Recovery of whisker movement is elevated in SAP-injected mice. In summary, short peptides that form fibrils are identified and the adhesion, growth, and regeneration of neurons have been efficiently enhanced without the necessity to attach hormones or growth factors.

KW - facial nerve

KW - naofiber

KW - neuron growth

KW - regeneration

KW - self-assembling peptide

U2 - 10.1002/adfm.201809112

DO - 10.1002/adfm.201809112

M3 - Article

AN - SCOPUS:85064499804

SN - 1616-301X

VL - 29

JO - Advanced Functional Materials

JF - Advanced Functional Materials

IS - 24

M1 - 1809112

ER -

Sequence-Optimized Peptide Nanofibers as Growth Stimulators for Regeneration of Peripheral Neurons

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Keywords

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