Cédric Vogt scite author profile

Fibronectin, like other proteins involved in mechanotransduction, has the ability to exhibit recognition sites under mechanical stretch. Such cryptic sites are buried inside the protein structure in the native fold and become exposed under an applied force, thereby activating specific signalling pathways. Here, we report the design of new active polymeric nanoassembled surfaces that show some similarities to these cryptic sites. These nanoassemblies consist of a first polyelectrolyte multilayer stratum loaded with enzymes and capped with a second polyelectrolyte multilayer acting as a mechanically sensitive nanobarrier. The biocatalytic activity of the film is switched on/off reversibly by mechanical stretching, which exposes enzymes through the capping barrier, similarly to mechanisms involved in proteins during mechanotransduction. This first example of a new class of biologically inspired surfaces should have great potential in the design of various devices aimed to trigger and modulate chemical reactions by mechanical action with applications in the field of microfluidic devices or mechanically controlled biopatches for example.

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Mobility of Proteins in Highly Hydrated Polyelectrolyte Multilayer Films

Vogt

Ball

Mutterer

et al. 2012

J. Phys. Chem. B

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The lateral diffusion of a protein (human serum albumin labeled with fluorescein isothiocyanate) within a highly hydrated polyelectrolyte film is studied. The film is built up with poly(L-lysine) as polycation and hyaluronate as polyanion. Fluorescence recovery after photobleaching is used to evaluate the mobility of the labeled protein. Spatial Fourier transformation is applied to the fluorescence intensity recorded at various times after bleaching of a narrow rectangular area within an image representative of the film. This approach necessitates no hypothesis on the intensity distribution at the end of the bleaching provided that the bleach has not appreciably changed the concentration ratios of the different diffusing species. Furthermore, under the hypothesis that molecules move according to Fick's law, we represent the Fourier transform by a weighted sum of exponentials each containing another diffusion coefficient and evaluate the proportion attached to each term of this sequence using the simulated annealing method. A criterion, combining goodness-of-fit and the entropy characterizing the diffusion coefficient spectrum, is proposed to avoid overinterpretation of the experimental data. The optimum spectrum of the diffusion coefficient is then extracted from the time evolution of the light intensity at various albumin concentrations within the films. It appears that the mobility, quantified by the amount of tracer molecules having a diffusion coefficient smaller than, e.g., 0.1 μm(2)/s, undergoes a transition between 20 and 2000 μg/mL of internal concentration. This suggests that the mutual interactions of the albumin molecules and the interactions between fluorescently labeled albumin and the film network become increasingly important in the reduction of the albumin mobility as the albumin concentration increases.

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Cédric Vogt

Mechanotransductive surfaces for reversible biocatalysis activation

Mobility of Proteins in Highly Hydrated Polyelectrolyte Multilayer Films

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