Minimalist Biostructures Designed to Create Nanomaterials
- News 14 June 2018 426 hits
- Researchers from the IBB-UAB fabricate 4 molecules of only 7 amino acids with the ability to self-assemble and rapidly and inexpensively form nanomaterials for biomedical and nanotechnological purposes.
- Four peptides were used to create one of the most resistant bionanomaterials described to date, nanocables and mini enzymes to act as a catalyst for the formation of nanomaterials.
- The study, publised in ACS Nano included the collaboration of Isabel Fuentes and Francesc Teixidor from the ICMAB-CSIC.
The new molecules are formed by a chain of 7 amino acids, each of which are made up of only two different amino acids; thus, significantly speeding up and reducing the price of the process of creation of functional synthetic amyloid structures with which to generate nanomaterials to be used in biomedicine and nanotechnology.
In biotechnology, generating functional synthetic amyloid structures to form nanostructures by imitating the natural generation process is not new. The assembly of proteins into stable fibres allows creating supramolecular shapes which no isolated protein can create, and which are used as nanoconductors, photovoltaic structures, biosensors and catalysts.
“We have demonstrated that an adequate design can permit the size of synthetic prion sequences to be reduced down to only 7 amino acids, while conserving the same properties. The four peptides we have fabricated are the shortest structures of this type created until now and capable of forming stable fibril assemblies," explains Salvador Ventura, researcher at the IBB and the UAB Department of Biochemistry and Molecular Biology.
In the study, researchers verified the stability and functionality of the four fabricated peptides. They built one of the most degradation-resistant biological nanomaterials described to date, nanocables covered in silver which can act as electrical nanoconductors and fibrillar mini enzymes capable of acting as catalysts in the formation of organic nanomaterials.
The new molecules have numerous applications, but researchers aim to focus on “the generation of electrical nanoconductors, and make use of the knowledge of the amyloid structure to generate synthetic fibres capable of being catalysts for new chemical reactions. The final objective will be to generate hybrid peptide-inorganic materials capable of making complex reactions, as those created by the photosystems of plants," the IBB researcher points out.
In order to generate new peptides, IBB researchers based their work on specific sequences of prion proteins, known as prion domains (PrDs). “We studied which amino acids are more frequent and how they are distributed in these regions, demonstrating that only 4 different types of amino acids distributed in a specific manner and always combined by a fifth type of amino acid is sufficient to have the complete code needed to form synthetic prion fibres. In fact, each of the heptapeptides (mini-PrDs) designed only contains two different types of amino acids,” says Salvador Ventura.
The study demonstrates the assembling ability of mini-PrDs into highly ordered nanostructures, a process thought to be impossible given the large presence of polar amino acids. The resulting peptides are more polar than any other similarly-sized peptide used until now to form synthetic amyloids; this, for example, allows them to function in the same conditions as natural enzymes.
“We have never worked on nanotechnology, but at the same time we have always had it near, because our strength lies in the knowledge of the molecular mechanism of protein assembly into amyloid structures. For a long time we have been working to create strategies with which to avoid this phenomenon in neurodegenerative diseases. This knowledge has allowed us to design new molecules which we now propose for the fabrication of new nanomaterials,” Dr Ventura concludes.
Figure 1: The peptides assemble to form miniature enzymes capable of acting as catalysts in the formation of nanomaterials such as the conductive polymer polypyrrole.
Figure 2: With the new heptapeptides, researchers from the IBB-UAB demonstrate that only four different types of amino acids, distributed in a specific manner and combined always with another fifth type, are enough to obtain the complete code needed to form synthetic prion fibres.
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