Abstract
Xylan is tightly associated with cellulose and lignin in secondary plant cell walls, contributing to its rigidity and structural integrity in vascular plants. However, the molecular features and the nanoscale forces that control the interactions among cellulose microfibrils, hemicelluloses, and lignin are still not well understood. Here, we combine comprehensive mass spectrometric glycan sequencing and molecular dynamics simulations to elucidate the substitution pattern in softwood xylans and to investigate the effect of distinct intramolecular motifs on xylan conformation and on the interaction with cellulose surfaces in Norway spruce (Picea abies). We confirm the presence of motifs with evenly spaced glycosyl decorations on the xylan backbone, together with minor motifs with consecutive glucuronation. These domains are differently enriched in xylan fractions extracted by alkali and subcritical water, which indicates their preferential positioning in the secondary plant cell wall ultrastructure. The flexibility of the 3-fold screw conformation of xylan in solution is enhanced by the presence of arabinofuranosyl decorations. Additionally, molecular dynamic simulations suggest that the glycosyl substitutions in xylan are not only sterically tolerated by the cellulose surfaces but that they increase the affinity for cellulose and favor the stabilization of the 2-fold screw conformation. This effect is more significant for the hydrophobic surface compared with the hydrophilic ones, which demonstrates the importance of nonpolar driving forces on the structural integrity of secondary plant cell walls. These novel molecular insights contribute to an improved understanding of the supramolecular architecture of plant secondary cell walls and have fundamental implications for overcoming lignocellulose recalcitrance and for the design of advanced wood-based materials.
Highlights
Xylan is tightly associated with cellulose and lignin in secondary plant cell walls, contributing to its rigidity and structural integrity in vascular plants
The presence of glycosyl substitutions has no strong influence on the flexible 31-fold screw of the xylan backbone in solution; they may act as local moieties prone to hydration
Xylan oligosaccharides adopt a flat, relatively rigid, 21-fold screw conformation when they are docked onto hydrophilic and hydrophobic cellulose surfaces. This conformation is stabilized by the presence of glycosyl substituents and is not hindered by the consecutive placement of mGlcA substitutions, as demonstrated by the simulations
Summary
Xylan is tightly associated with cellulose and lignin in secondary plant cell walls, contributing to its rigidity and structural integrity in vascular plants. Molecular dynamic simulations suggest that the glycosyl substitutions in xylan are sterically tolerated by the cellulose surfaces but that they increase the affinity for cellulose and favor the stabilization of the 2-fold screw conformation This effect is more significant for the hydrophobic surface compared with the hydrophilic ones, which demonstrates the importance of nonpolar driving forces on the structural integrity of secondary plant cell walls. MD simulations suggest that these substitution motifs in xylan modulate the affinity for cellulose hydrophilic and hydrophobic surfaces and stabilize the conformational transition of xylan from a 3-fold screw in solution to a 2-fold screw onto the cellulose microfibrils This offers new molecular insights on the structural integrity and the supramolecular architecture of plant secondary cell walls, with fundamental implications to overcome plant biomass recalcitrance and an optimized utilization of wood-derived materials
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