Molecular Insights into Cell Wall Architecture and Xylan-Bound Cellulose Fibrils in the Wheat Straw

The plant cell wall, a highly abundant renewable resource, remains insufficiently understood in terms of its structure, particularly the architecture of cellulose microfibrils and their interactions with hemicellulose and lignin, which impede the development of efficient downstream conversion. Here we present an alternative model of xylan-bound cellulose microfibril architecture in the cell wall of intact wheat straw, using solid-state nuclear magnetic resonance (ssNMR) coupled with X-ray scattering techniques. We show that the spectroscopic and scattering data can be fit to a simple elementary microfibril consisting of 18 glucan chains, with additional contributions from 0 to 4 tightly bound flat-ribbon xylan chains across the cellulose fibril axis. These xylan-bound cellulose microfibrils are found to serve as the secondary interaction site with lignin, following the non-flat xylan domains. The loose packing of these xylan-bound cellulose fibrils results in a heterogenous hydration landscape within the cell wall, allowing water penetration while maintaining structural integrity through numerous physical contacts between the polymers. This study provides a potential framework to reconcile the mounting biochemical evidence supporting the 18-chain elementary cellulose microfibril model and cellulose synthase complex with the oversized observations from characterization techniques, which report averaged structures influenced by microfibril coalescence and hemicellulose binding. The structural insights also offer valuable information regarding recalcitrance and the potential applications of biomass in biorefinery operations.