A number of strategies exist to design molecular materials based on self-assembled peptides and their derivatives. [1] These include soft materials based on a variety of structural motifs including coiled-coils, [2,3] b-sheets, [4,5] b-hairpins, [6] and peptide amphiphiles. [7][8][9] In these systems, the peptide chains usually contain at least ten amino acids. It has been known for some time that using aromatic components in conjunction with peptides allows the use of much smaller peptides by taking advantage of p-stacking interactions. [10][11][12][13][14][15] One system that has been illustrated is that of N-fluorenylmethoxycarbonyl diphenylalanine (Fmoc-FF) which forms a hydrogel under physiological conditions. This example and other closely related aromatic short peptide derivatives are known to form fibrous hydrogels that have found applications in biological sensing [16] and cell culture. [13,17] Understanding of the supramolecular structures formed by these molecules will aid the rational design of new architectures tailored to the needs of specific biological and non-biological applications. However, to date a complete structure has not been proposed for any member of this class of self-assembly systems. Here we apply a number of spectroscopic techniques to Fmoc-FF and construct a model based on the data obtained comprising a new nanocylindrical molecular architecture based on p-p interlocked b-sheets. Transmission electron microscopy (TEM) and wide angle X-ray scattering (WAXS) was used to confirm the proposed model. Hydrogels of Fmoc-FF were prepared as described previously utilizing a sequential change in pH.[13] As shown in Figure 1a self-supporting gels were formed. The viscoelastic properties of the gels were assessed using oscillatory rheology. Figure 1b shows the mechanical spectrum obtained at room temperature for a Fmoc-FF (20 mmol L -1 ) gel. The storage modulus (G') is found to be approximately an order of magnitude larger than the loss modulus (G''), indicative of an elastic rather than viscous material. Both G' and G'' were found to be essentially independent of frequency over four decades (Fig. 1b). Such rheological behavior is characteristic of solid like gel materials. Light microscopy ( Fig. 1c) revealed a network of fine fibers with microscopic widths. Cryo Scanning Electron Microscopy (cryoSEM) revealed a dense network of flat ribbons with dimensions in the order of tens of nanometers (Fig. 1d). Circular dichroism (CD) was used to investigate the backbone orientation of the dipeptide within the hydrogel. CD analysis of peptide-based supramolecular materials is prone to artifacts. Usually only a narrow concentration range, where the hydrogel forms, can be used reliably to present a detectable CD signal, while showing no or little light scattering ef-
This tutorial review looks at the design rules that allow peptides to be exploited as building blocks for the assembly of nanomaterials. These design rules are either derived by copying nature (alpha-helix, beta-sheet) or may exploit entirely new designs based on peptide derivatives (peptide amphiphiles, pi-stacking systems). We will examine the features that can be introduced to allow self-assembly to be controlled and directed by application of an externally applied stimulus, such as pH, light or enzyme action. Lastly the applications of designed self-assembly peptide systems in biotechnology (3D cell culture, biosensing) and technology (nanoelectronics, templating) will be examined.
We report the effect of pH on the self-assembly process of Fmoc-diphenylalanine (Fmoc-FF) into fibrils consisting of antiparallel beta-sheets, and show that it results in two apparent pKa shifts of approximately 6.4 and approximately 2.2 pH units above the theoretical pKa (3.5). Using Fourier transform infrared (FTIR) spectroscopy, transmission electron microscopy (TEM), wide angle X-ray scattering (WAXS), and oscillatory rheology, these two transitions were shown to coincide with significant structural changes. An entangled network of flexible fibrils forming a weak hydrogel dominates at high pH, while nongelling flat rigid ribbons form at intermediate pH values. Overall, this study provides further understanding of the self-assembly mechanism of aromatic short peptide derivatives.
The production of functional molecular architectures through self-assembly is commonplace in biology, but despite advances, it is still a major challenge to achieve similar complexity in the laboratory. Self-assembled structures that are reproducible and virtually defect free are of interest for applications in three-dimensional cell culture, templating, biosensing and supramolecular electronics. Here, we report the use of reversible enzyme-catalysed reactions to drive self-assembly. In this approach, the self-assembly of aromatic short peptide derivatives provides a driving force that enables a protease enzyme to produce building blocks in a reversible and spatially confined manner. We demonstrate that this system combines three features: (i) self-correction--fully reversible self-assembly under thermodynamic control; (ii) component-selection--the ability to amplify the most stable molecular self-assembly structures in dynamic combinatorial libraries; and (iii) spatiotemporal confinement of nucleation and structure growth. Enzyme-assisted self-assembly therefore provides control in bottom-up fabrication of nanomaterials that could ultimately lead to functional nanostructures with enhanced complexities and fewer defects.
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