Emergence of Lignin-Carbohydrate Interactions During Plant Stem Maturation Visualized by Solid-State NMR

Lignification waterproofs and strengthens the secondary plant cell wall, while increasing the energy cost associated with releasing sugars for biofuel production. The physical association between lignin and the carbohydrate scaffold that accommodates lignin polymerization, as well as the temporally distinct roles of different lignin units and carbohydrate partners during lignification, remain largely unclear. Here we map the lignin-carbohydrate interactions by solid-state NMR in ¹³ C-labeled Arabidopsi s inflorescence stems as secondary cell walls are formed. Analysis includes wild-type and two mutants that either selectively or globally disrupt lignin biosynthesis. Mature cell walls in the basal regions of older stems are enriched in S-lignin and carbohydrate-lignin interactions. Acetylated xylan is the dominant mediator of interactions with S-lignin, while methylated pectin unexpectedly interacts with G-lignin during early-stage lignification. The critical role of S-lignin in stabilizing carbohydrate-lignin interface is emphasized by the weak lignin-carbohydrate interactions and compromised mechanical properties of a low-S fah1 mutant, whereas the ref3 mutant, with low overall lignin content but a higher S/G ratio, remained unaffected. These findings demonstrate that the molecular mixing pattern, rather than lignin content, is a key determinant of the structure and properties of lignocellulosic materials.