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Xylan Structure and Dynamics in Native <i>Brachypodium</i> Grass Cell Walls Investigated by Solid-State NMR Spectroscopy

Pu Duan, Samuel J. Kaser, Jan J. Łyczakowski, Pyae Phyo, Theodora Tryfona, Paul Dupree, Mei Hong

2021ACS Omega50 citationsDOIOpen Access PDF

Abstract

The polysaccharide composition and dynamics of the intact stem and leaf cell walls of the model grass Brachypodium distachyon are investigated to understand how developmental stage affects the polysaccharide structure of grass cell walls. 13C enrichment of the entire plant allowed detailed analysis of the xylan structure, side-chain functionalization, dynamics, and interaction with cellulose using magic-angle-spinning solid-state NMR spectroscopy. Quantitative one-dimensional 13C NMR spectra and two-dimensional 13C–13C correlation spectra indicate that stem and leaf cell walls contain less pectic polysaccharides compared to previously studied seedling primary cell walls. Between the stem and the leaf, the secondary cell wall-rich stem contains more xylan and more cellulose compared to the leaf. Moreover, the xylan chains are about twofold more acetylated and about 60% more ferulated in the stem. These highly acetylated and ferulated xylan chains adopt a twofold conformation more prevalently and interact more extensively with cellulose. These results support the notion that acetylated xylan is found more in the twofold screw conformation, which preferentially binds cellulose. This in turn promotes cellulose–lignin interactions that are essential for the formation of the secondary cell wall.

Topics & Concepts

CelluloseCell wallLigninBrachypodium distachyonXylanSecondary cell wallPolysaccharideNuclear magnetic resonance spectroscopyChemistryBrachypodiumCarbon-13 NMRMicrofibrilBotanyStereochemistryOrganic chemistryBiochemistryBiologyGeneGenomePolysaccharides and Plant Cell WallsAdvanced Cellulose Research StudiesPlant nutrient uptake and metabolism