Roberta Flamia scite author profile

In this paper, we report an AFM study on the supramolecular structures adopted by the synthetic polypentapeptide poly(ValGlyGlyValGly), whose monomeric sequence is an abundant, simple building block of elastin. The polypeptide was analyzed by deposition from both methanolic and aqueous suspensions, showing different behaviors. In methanol, the polypeptide is able to evolve, in a time-dependent way, from layers to ribbons to beaded filaments. When the equilibrium is reached, the formation of well-defined dendritic structures is also observed. This restructuring of the polypentapeptide seems to be reminiscent of a sort of Rayleigh instability. When deposited from aqueous suspensions, the polypeptide self-assembles either in fibrillar networks or in amyloid-like patterns, both of them being found in elastin or elastin-related polypeptides. As a general finding, poly(ValGlyGlyValGly) seems to constitute an excellent mimetic of the supramolecular properties of native elastin.

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Conformational Study and Hydrogen Bonds Detection on Elastin-Related Polypeptides Using X-ray Photoelectron Spectroscopy

Flamia

Lanza

Salvi

et al. 2005

Biomacromolecules

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The chemical bonds of the pentapeptide sequence of elastin ValGlyGlyValGly (VGGVG), both in its monomer and polymer forms, were correlated with their XPS spectra through a well-established curve-fitting procedure. To aid in this correlation, the C1s, O1s, and N1s chemical shifts of the Boc-VGGVG-OEt, were validated by theoretical calculations, performed in the framework of the Koopman approximation of HF/6-31G molecular orbitals, leading to the "preferred" conformation of the protected monomer. Then the same curve-fitting procedure was adopted for interpreting the XPS spectra of the polypentapeptide as a powder, and the XPS results obtained both for monomer and polymer compounds were compared with those obtained by FT-IR. The polymer was then analyzed after deposition onto a silicon substrate, Si(100), either from methanol or water suspensions and the presence of hydrogen bonds was detected at the polymer/substrate interface and between the polymer chains. The "surface rearrangement" that could be inferred from XPS results strongly confirms that derived from AFM images previously obtained under the same experimental conditions. In particular, the observed amyloid conformation is stabilized by hydrogen bonds to water molecules included in the structure while the formation of the beaded string structure observed in deposits from methanolic suspension is probably mediated by hydrogen bonds to the hydrated silicon surface.

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Transformation of Amyloid-like Fibers, Formed from an Elastin-Based Biopolymer, into a Hydrogel: An X-ray Photoelectron Spectroscopy and Atomic Force Microscopy Study

et al. 2006

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Previous studies have revealed the propensity of elastin-based biopolymers to form amyloid-like fibers when dissolved in water. These are of interest when considered as "ancestral units" of elastin in which they represent the simplest sequences in the hydrophobic regions of the general type XxxGlyGlyZzzGly (Xxx, Zzz = Val, Leu). We normally refer to these biopolymers based on elastin or related to elastin units as "elastin-like polypeptides". The requirement of water for the formation of amyloids seems quite interesting and deserves investigation, the water representing the natural transport medium in human cells. As a matter of fact, the "natural" supramolecular organization of elastin is in the form of beaded-string-like filaments and not in the form of amyloids whose "in vivo" deposition is associated with some important human diseases. Our work is directed, therefore, to understanding the mechanism by which such hydrophobic sequences form amyloids and any conditions by which they might regress to a non-amyloid filament. The elastin-like sequence here under investigation is the ValGlyGlyValGly pentapeptide that has been previously analyzed both in its monomer and polymer form. In particular, we have focused our investigation on the apparent stability of amyloids formed from poly(ValGlyGlyValGly), and we have observed these fibers evolving to a hydrogel after prolonged aging in water. We will show how atomic force microscopy can be combined with X-ray photoelectron spectroscopy to gain an insight into the spontaneous organization of an elastin-like polypeptide driven by interfacial interactions. The results are discussed also in light of fractal-like assembly and their implications from a biomedical point of view.

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Investigating the Amyloidogenic Nanostructured Sequences of Elastin: Sequence Encoded by Exon 28 of Human Tropoelastin Gene

et al. 2007

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In this paper we demonstrate that the sequence encoded by exon 28 (EX28) of human tropoelastin gene is able to give amyloid-like fibrils. CD (circular dichroism) in solution and solid-state FTIR (Fourier transform infrared spectroscopy) spectroscopies have shown the presence of beta-sheet conformation. At the supramolecular level the fibers formed by EX28 peptide were investigated by AFM (atomic force microscopy) and ESEM (environmental scanning electron microscopy). A very big left-handed helix, 100 mum long, is visible together with aggregates of different sizes, some of them being constituted by helically interwoven fibers. Furthermore, an additional AFM image of EX28 is shown where the ultrastructure found is somewhat reminiscent of a more or less retiform film. These findings should be useful for designing proper elastin-inspired biomaterials.

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Roberta Flamia

AFM Study of the Elastin-like Biopolymer Poly(ValGlyGlyValGly)

Conformational Study and Hydrogen Bonds Detection on Elastin-Related Polypeptides Using X-ray Photoelectron Spectroscopy

Transformation of Amyloid-like Fibers, Formed from an Elastin-Based Biopolymer, into a Hydrogel: An X-ray Photoelectron Spectroscopy and Atomic Force Microscopy Study

Investigating the Amyloidogenic Nanostructured Sequences of Elastin: Sequence Encoded by Exon 28 of Human Tropoelastin Gene

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