Corner's Rules and Their Linkages With Twig Functions and Tree Productivity in Simple- and Compound-Leaved Tree Species

Corner's rules are well known in describing inter-specific scaling relationships for plant organ size-related traits, from species with thick terminal stems, large leaves, and sparsely branched twigs to species with opposite traits; however, the implications of organ size on physiological functions and growth performance of trees remain unclear. Moreover, whether Corner's rules spectra differ between tree species with simple and compound leaves is not known. Here, we measured key twig morphological traits, physiological characteristics, and radial growth rates of 27 simple- and 6 compound-leaved tree species in a common garden in Northeast China. The size scaling relationships between leaf lamina and supporting structures were mostly allometric (slope < 1) in simple-leaved species. In contrast, such relationships were predominantly isometric (slope = 1) in compound-leaved species. Consistently, twig hydraulic conductance and photosynthetic rate increased significantly faster as twig size increased across the compound-leaved species. Consequently, compound-leaved species equipped with twigs of fewer but larger leaves have the potential to achieve remarkably high growth rates. Our study revealed divergent investment-return strategies between the two functional groups, that is, 'diminishing returns' in simple-leaved species and 'stable returns' in compound-leaved species, and identified mechanistic associations among twig architecture, physiological characteristics and tree growth rate.