A fibronectin mimetic motif improves integrin mediated cell biding to recombinant spider silk matrices

Abstract The cell binding motif RGD is the most widely used peptide to improve cell binding properties of various biomaterials, including recombinant spider silk. In this paper we use genetic engineering to further enhance the cell supportive capacity of spider silk by presenting the RGD motif as a...

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Bibliographic Details
Published in:Biomaterials 2016-01, Vol.74, p.256-266
Main Authors: Widhe, Mona, Shalaly, Nancy Dekki, Hedhammar, My
Format: Article
Language:English
Subjects:
Advanced Basic Science
Animals
Araneae
Binding
Bio Materials
Biomaterial
Biomaterials
Biomedical materials
Cell Adhesion
Cells, Cultured
Dentistry
Disulphide bridged loop
Fibronectin
Fibronectins - chemistry
Humans
Integrins - metabolism
Molecular Mimicry
Protein Binding
Recombinant
RGD
Silk
Silk - metabolism
Spiders
Surgical implants
Wound healing
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Summary:Abstract The cell binding motif RGD is the most widely used peptide to improve cell binding properties of various biomaterials, including recombinant spider silk. In this paper we use genetic engineering to further enhance the cell supportive capacity of spider silk by presenting the RGD motif as a turn loop, similar to the one found in fibronectin (FN), but in the silk stabilized by cysteines, and therefore denoted FNCC . Human primary cells cultured on FNCC -silk showed increased attachment, spreading, stress fiber formation and focal adhesions, not only compared to RGD-silk, but also to silk fused with linear controls of the RGD containing motif from fibronectin. Cell binding to FNCC -silk was shown to involve the α5β1 integrin, and to support proliferation and migration of keratinocytes. The FNCC -silk protein allowed efficient assembly, and could even be transformed into free standing films, on which keratinocytes could readily form a monolayer culture. The results hold promise for future applications within tissue engineering.
ISSN:0142-9612
1878-5905
1878-5905
DOI:10.1016/j.biomaterials.2015.10.013