Resumen de Prion inspired assemblies to build up bionanomaterials
Despite amyloid scaffolds have been traditionally related to disease, in the last two decades, it has been highlighted their involvement in important biological functions. These findings raised the interest in the development of amyloid based nanomaterials in multiple areas like biomedicine, nanoelectronics, environmental sciences and nanotechnology. The complexity of the production and manipulation of amyloidogenic full-length proteins evidenced the need for alternative building-blocks that mimic their properties to assemble amyloid-based nanomaterials. The use of natural and artificial short peptides has emerged as one of the most appealing solutions, their synthesis and purification resulting easier, faster and cheaper compared to complete protein sequences. Prion and prion-like proteins present a slow aggregation rate compared to classical amyloids and, under certain conditions, the assembly process can be reverted, two properties that make them attractive for the development of nanomaterials. Despite this potentiality, the de novo design and synthesis of short prion-inspired peptides for nanotechnological purposes has been scarcely explored until recent time.
In this thesis, we collect a series of studies regarding the design and characterization of synthetic prion-inspired nanomaterials. We addressed the capacity of designed short peptides to polymerize into amyloid assemblies and studied the molecular interactions behind their supramolecular organization. Furthermore, we illustrated some of their potential applications exploring their biocatalytic properties, their coupling with the biotin-streptavidin system and their decoration with divalent metallic cations. We also explored how the assembly of this kind of peptides can be controlled in a reversible manner by manipulating the environmental pH. Finally, the last part of this thesis focused on the study of the cytotoxic properties of the early soluble assemblies that populate the fibrillation reaction of functional prion-inspired nanostructures.
Overall, this thesis highlights the potentiality of prion-like peptidic sequences to generate bionanomaterials, emphasizing their functional versatility and adaptability for multiple nanotechnological applications. It also proposes that biosafety studies should be routinely implemented during the development of amyloid-based nanomaterials.
