posted on 2016-11-09, 00:00authored byGraziano Deidda, Sai Vamshi R. Jonnalagadda, Jacob W. Spies, Anthi Ranella, Estelle Mossou, V. Trevor Forsyth, Edward P. Mitchell, Matthew W. Bowler, Phanourios Tamamis, Anna Mitraki
Self-assembled
peptides gain increasing interest as biocompatible
and biodegradable scaffolds for tissue engineering. Rationally designed
self-assembling building blocks that carry cell adhesion motifs such
as Arg-Gly–Asp (RGD) are especially attractive. We have used
a combination of theoretical and experimental approaches toward such
rational designs, especially focusing on modular designs that consist
of a central ultrashort amphiphilic motif derived from the adenovirus
fiber shaft. In this study, we rationally designed RGDSGAITIGC, a
bifunctional self-assembling amyloid peptide which encompasses cell
adhesion and potential cysteine-mediated functionalization properties
through the incorporation of an RGD sequence motif and a cysteine
residue at the N- and C- terminal end, respectively. We performed
replica exchange MD simulations that suggested that the key factor
determining cell adhesion is the total solvent accessibility of the
RGD motif and also that the C-terminal cysteine is adequately exposed.
The designer peptides self-assembled into fibers that are structurally
characterized with Transmission Electron Microscopy, Scanning Electron
Microscopy and X-ray fiber diffraction. Furthermore, they supported
cell adhesion and proliferation of a model cell line. We consider
that the current bifunctional properties of the RGDSGAITIGC fibril-forming
peptide can be exploited to fabricate novel biomaterials with promising
biomedical applications. Such short self-assembling peptides that
are amenable to computational design offer open-ended possibilities
toward multifunctional tissue engineering scaffolds of the future.