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Fysik & material 5.4 🇪🇬 🇫🇷 🇳🇴 🇸🇪 🇺🇦 🇺🇸

Scientists crack the code on enzymes that could transform waste into biofuels

Researchers have mapped how a powerful enzyme binds to chitin—an abundant polymer in shellfish waste—unlocking a critical step toward converting industrial byproducts into sustainable biofuels and plastics. The breakthrough could reshape how companies process biomass, turning disposal costs into feedstock value.

Originaltitel: Tangled Up in Fibers: How a Multidomain Lytic Polysaccharide Monooxygenase Binds Its Chitin Substrate

Abstrakt

Lytic polysaccharide monooxygenases (LPMOs) are redox enzymes that bind to and oxidize insoluble carbohydrate substrates such as chitin or cellulose. This class of enzymes has attracted considerable attention due to their ability to convert biomaterials of high abundance into oligosaccharides that can be useful for producing biofuels and bioplastics. However, processes at the interface between solution and insoluble substrates represent a major challenge to biochemical and structural characterization. Here, we investigated the four-domain LPMO from Vibrio cholerae, N-acetyl glucosamine binding protein A (GbpA), to elucidate how it docks onto its insoluble substrate with its two terminal domains. First, we developed a protocol that allowed GbpA and chitin to form a stable complex in suspension, overcoming incompatibilities of the two binding partners with respect to pH. After determining the small-angle neutron scattering (SANS) contrast match point for chitin (47% D2O), we characterized the mesoscale structure of GbpA in complex with chitin by SANS and complemented the results with negative-stain electron microscopy. We found that GbpA binds rapidly to chitin, where it coats the chitin fibers and smooths their surface. In some locations, GbpA binding induces the formation of protein–chitin clumps containing a large number of GbpA molecules. Together, this suggests how the secretion of GbpA efficiently prepares the ground for microcolony formation by the bacteria.

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