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• W45380802 abstract "One of the key challenges in material sciences is the technological utilization of self-assembly systems, wherein molecules spontaneously associate under equilibrium conditions into supramolecular structures joined by noncovalent bonds. Although molecular self-assembly is the governing principle in morphogenesis of biological systems, so far only a few molecular species have been exploited for controlled self-assembly into defined nanostructures. Crystalline bacterial cell surface layer (S-layer) proteins represent a first-order self-assembly system that has been optimized in the course of evolution. S-layers are composed of single protein or glycoprotein species which self-assemble into lattices with oblique, square, or hexagonal symmetry. Self-assembly into highly ordered monomolecular protein lattices occurs not only on the bacterial cell surface but also on artificial supports, such as polymers, silicon wafers, noble metals, lipid films, liposomes, lipid-plasmid particles, or on hollow polyelectrolyte nanoparticles. For recrystallization in an oriented manner, S-layerspecific polysaccharides as the natural anchoring molecules for S-layer proteins in the bacterial cell wall have been exploited as biomimetic linkers. To generate oriented functional monomolecular protein lattices, S-layer fusion proteins have been constructed, which incorporated either IgG-binding sequences, streptavidin, hypervariable regions of heavy chain camel antibodies, allergens, green fluorescent protein, metal-binding sequences, or a single cysteine residue. The fusion sites were selected such that after recrystallization on artificial supports precoated with S-layer-specific polysaccharides, the functional sequence remains exposed on the outermost surface of the protein lattice." @default.
• W45380802 created "2016-06-24" @default.
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• W45380802 creator A5083902250 @default.
• W45380802 date "2008-02-06" @default.
• W45380802 modified "2023-10-10" @default.
• W45380802 title "Genetically Engineered S-Layer Proteins and S-Layer-Specific Heteropolysaccharides as Components of a Versatile Molecular Construction Kit for Applications in Nanobiotechnology" @default.
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• W45380802 doi "https://doi.org/10.1007/978-1-59745-218-2_4" @default.
• W45380802 hasPublicationYear "2008" @default.
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