Cell wall thickness has phylogenetically consistent effects on the photosynthetic nitrogen-use efficiency of terrestrial plants

Leaf photosynthetic nitrogen-use efficiency (PNUE) diversified significantly among C₃ species. To date, the morpho-physiological mechanisms and interrelationships shaping PNUE on an evolutionary time scale remain unclear. In this study, we assembled a comprehensive matrix of leaf morpho-anatomical and physiological traits for 679 C₃ species, ranging from bryophytes to angiosperms, to comprehend the complexity of interrelationships underpinning PNUE variations. We discovered that leaf mass per area (LMA), mesophyll cell wall thickness (T_cwm ), Rubisco N allocation fraction (P_R ), and mesophyll conductance (g_m ) together explained 83% of PNUE variations, with P_R and g_m accounting for 65% of those variations. However, the P_R effects were species-dependent on g_m , meaning the contribution of P_R on PNUE was substantially significant in high-g_m species compared to low-g_m species. Standard major axis (SMA) and path analyses revealed a weak correlation between PNUE and LMA (r²  = 0.1), while the SMA correlation for PNUE-T_cwm was robust (r²  = 0.61). P_R was inversely related to T_cwm , paralleling the relationship between g_m and T_cwm , resulting in the internal CO₂ drawdown being only weakly proportional to T_cwm . The coordination of P_R and g_m in relation to T_cwm constrains PNUE during the course of evolution.