Precursor-Dependent Routing of Aromatic Amino Acids Determines Lignin Structure in Grasses by Sensitivity-Enhanced Solid-State NMR

Lignin biosynthesis in grasses exhibits unique metabolic flexibility, yet the precursor-specific routing of carbon into lignin polymers remains poorly resolved in planta. Here, we combine 13C-isotope labeling with solid-state NMR under sensitivity-enhancement by dynamic nuclear polarization (DNP), to directly track phenylalanine- and tyrosine-derived carbon incorporation into the lignin polymer in Brachypodium distachyon. Precursor-specific 13C labeling reveals that phenylalanine is the dominant contributor to canonical guaiacyl and syringyl lignins, whereas tyrosine preferentially enriches hydroxyphenyl lignin and hydroxycinnamates, including ferulates characteristic of grass cell walls. Two-dimensional 13C-13C correlation NMR resolves distinct lignin moieties arising from each precursor. Disruption of p-coumarate 3-hydroxylase (C3H) selectively impairs phenylalanine-derived lignification, while tyrosine-derived lignin remains comparatively unchanged, maintaining polymer assembly through alternative metabolic routes. These findings show precursor-dependent control of lignin composition and reveal tyrosine-mediated lignification as a compensatory pathway in grasses. This work also establishes precursor-resolved solid-state NMR and DNP as a powerful framework for dissecting lignin biosynthesis and metabolic plasticity in plant cell walls. SIGNIFICANCE STATEMENTLignin is a complex plant polymer that strengthens cell walls but also limits the efficiency of biomass processing for agriculture and bioenergy. Grasses possess a unique lignin biosynthetic flexibility that is not well understood. By combining stable isotope labeling with solid-state NMR spectroscopy, we directly traced how the aromatic amino acids, phenylalanine and tyrosine, contribute differently to lignin formation in intact grass cell walls. We show that phenylalanine primarily builds conventional lignin structures, whereas tyrosine supplies alternative phenolic components and maintains lignin synthesis even when a key biosynthetic enzyme is disrupted. This metabolic flexibility helps explain the unique structural aspects of grass cell walls and identifies precursor-level control as a promising strategy for engineering lignin composition to improve biomass utilization.