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Insights into an unusual Auxiliary Activity 9 family member lacking the histidine brace motif of lytic polysaccharide monooxygenases
- Frandsen, Kristian EH;
- Tovborg, Morten;
- Jørgensen, Christian I;
- Spodsberg, Nikolaj;
- Rosso, Marie-Noëlle;
- Hemsworth, Glyn R;
- Garman, Elspeth F;
- Grime, Geoffrey W;
- Poulsen, Jens-Christian N;
- Batth, Tanveer S;
- Miyauchi, Shingo;
- Lipzen, Anna;
- Daum, Chris;
- Grigoriev, Igor V;
- Johansen, Katja S;
- Henrissat, Bernard;
- Berrin, Jean-Guy;
- Lo Leggio, Leila
- et al.
Published Web Location
https://doi.org/10.1074/jbc.ra119.009223Abstract
Lytic polysaccharide monooxygenases (LPMOs) are redox-enzymes involved in biomass degradation. All characterized LPMOs possess an active site of two highly conserved histidine residues coordinating a copper ion (the histidine brace), which are essential for LPMO activity. However, some protein sequences that belong to the AA9 LPMO family display a natural N-terminal His to Arg substitution (Arg-AA9). These are found almost entirely in the phylogenetic fungal class Agaricomycetes, associated with wood decay, but no function has been demonstrated for any Arg-AA9. Through bioinformatics, transcriptomic, and proteomic analyses we present data, which suggest that Arg-AA9 proteins could have a hitherto unidentified role in fungal degradation of lignocellulosic biomass in conjunction with other secreted fungal enzymes. We present the first structure of an Arg-AA9, LsAA9B, a naturally occurring protein from Lentinus similis The LsAA9B structure reveals gross changes in the region equivalent to the canonical LPMO copper-binding site, whereas features implicated in carbohydrate binding in AA9 LPMOs have been maintained. We obtained a structure of LsAA9B with xylotetraose bound on the surface of the protein although with a considerably different binding mode compared with other AA9 complex structures. In addition, we have found indications of protein phosphorylation near the N-terminal Arg and the carbohydrate-binding site, for which the potential function is currently unknown. Our results are strong evidence that Arg-AA9s function markedly different from canonical AA9 LPMO, but nonetheless, may play a role in fungal conversion of lignocellulosic biomass.
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