Tyrisonase enzymes aid crosslinking: organisms
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Blue mussels / Travis S. / License
Tyrosinase enzymes serve a wide variety of crosslinking functions in organisms by catalyzing the oxidation of phenols and converting them into reactive quinones.
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"Prof. [Herb] Waite’s work on mussel adhesion has demonstrated that biology offers many important lessons for materials scientists. Biology’s crosslinking enzymes may enable us to apply two such lessons. The first lesson is sustainability. Enzymes enable renewable, bio-based raw materials to be accessed to generate functional materials. We are using various natural phenols, proteins, and polysaccharides to create functional polymers and crosslinked networks. In addition to the renewable raw materials, the enzymecatalyzed processes are expected to be inherently safe and the products environmentally-friendly (e.g., biodegradable). The second lesson is bottom-up precision assembly. A current challenge in nanotechnology is the hierarchical assembly of pre-formed nanoparticles into precise assemblies for either drug delivery or nanoelectronics. Nature is well known for its ability to employ non-covalent mechanisms (e.g., hydrogen bonds and hydrophobic interactions), molecular recognition, and self-assembly to precisely construct macromolecular assemblies from their component parts. Enzymes are capable of selectively adding covalent bonds which could stabilize macromolecular assemblies and, thus, complement self-assembly methods based on reversible physical mechanisms. As we learn these lessons, we expect a growth in the list of examples in which biology’s crosslinking enzymes are explored for technological applications." (Yang et al. 2009:584)
"In summary, tyrosinase catalyzes the oxidation of low molecular weight phenols and accessible phenolic moieties of macromolecules and converts these phenols into reactive quinones. The broad substrate range of tyrosinase enables this enzyme to access the diverse array of phenols that are present in nature (e.g., plant phenols) as well as the tyrosine residues of peptides and proteins. The quinones generated by tyrosinase readily react with the nucleophilic amines of chitosan to yield grafted polymers or crosslinked networks. Importantly, quinone-chitosan reactions are facilitated by the relatively low pKa (6–6.5) of chitosan’s amines [74,75]. Also, protein-chitosan conjugates can be generated that possess chitosan’s pH-responsive solubility [61]." (Yang et al. 2009:577-80)
Application Ideas: 'Green' catalysts for polymer synthesis and modification. Immobilization of cells. Sealing wounds. Adhesive applications. Removing polluting or specific phenols from chemical solutions. Grafting phenols onto compounds to create antimicrobials or antioxidants.
Industrial Sector(s) interested in this strategy: Biotechnology, chemistry, medical
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