Abstract
Understanding enzymatic breakdown of plant biomass is crucial to develop nature-inspired biotechnological processes. Lytic polysaccharide monooxygenases (LPMOs) are microbial enzymes secreted by fungal saprotrophs involved in carbon recycling. LPMOs modify biomass by oxidatively cleaving polysaccharides, thereby enhancing the efficiency of glycoside hydrolases. Fungal AA9 LPMOs are active on cellulose, but some members also display activity on hemicelluloses and/or oligosaccharides. Although the active site subsites are well defined for a few model LPMOs, the molecular determinants driving broad substrate specificity are still not easily predictable. Based on bioinformatic clustering and sequence alignments, we selected seven fungal AA9 LPMOs that differ in the amino-acid residues constituting their subsites. Investigation of their substrate specificities revealed that all these LPMOs are active on cellulose and cello-oligosaccharides, as well as plant cell wall–derived hemicellulosic polysaccharides, and carry out C4 oxidative cleavage. The product profiles from cello-oligosaccharide degradation suggest that the subtle differences in amino-acid sequence within the substrate-binding loop regions lead to different preferred binding modes. Our functional analyses allowed us to probe the molecular determinants of substrate binding within two AA9 LPMO subclusters. Many wood-degrading fungal species rich in AA9 genes have at least one AA9 enzyme with structural loop features that allow recognition of short β-(1,4)–linked glucan chains. Time-course monitoring of these AA9 LPMOs on cello-oligosaccharides also provides a useful model system for mechanistic studies of LPMO catalysis. These results are valuable for the understanding of LPMO contribution to wood decaying process in nature and for the development of sustainable biorefineries.
Highlights
Efficient conversion of plant biomass for the production of biofuels and other sustainable bioproducts and materials is considered largely dependent on the key enzymes lytic polysaccharide monooxygenases (LPMOs) [1, 2]
We determined the structures of two AA9 LPMOs from Lentinus similis (LsAA9A) and Collariella virescens (CvAA9A, previously Chaetomium virescens), which both belong to the phylogenetic cluster C38 and display activity on cello-oligosaccharides and on XG, mixed-linkage β-glucans (MLGs), and GM [28, 33]
Some of the candidates chosen in this study originate from wellknown fungal species for which other AA9 LPMOs have already been characterized, for example, P. chrysosporium PcGH61D [38, 39] and A. fumigatus AfAA9B [40]
Summary
The selection of AA9 sequences was carried out bioinformatically by searching for sequences with at least 50% sequence identity to LsAA9A in the CAZy (http://www.cazy. org/) and JGI Mycocosm (https://mycocosm.jgi.doe.gov/ mycocosm/home) databases. The vast majority of these species hold around 20 or more AA9 LPMO genes Most of these fungi appeared only once in the list, whereas some appeared twice (Gyromitra esculenta, Armillaria ostoyae, Crepidotus variabilis, Botryobasidium botryosum, Schizophyllum commune, Volvariella volvacea) or even three or four times (Crucibulum laeve and Coprinellus pellucidus). It means that these fungi display at least one LsAA9A-related LPMO that may have a dedicated biological function. The five AA9 sequences belonging to subcluster C38 originate from the basidiomycetes Phanerochaete chrysosporium (PchAA9E JGI protein ID 2934397), Phanerochaete carnosa (PcaAA9A 261285), Bjerkandera adusta (BaAA9A 353490), Armillaria gallica (AgAA9A 500811), and Schizophyllum commune (ScAA9A 2617723) and share between 63 and 76% sequence identity with LsAA9A (Table 1). The sequences of AgAA9, ScAA9A, AoAA9, and AfAA9 have the N67D substitution together with other ones near the negative
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