Abstract
Despite the diversity of branching architectures in plants, the impact of this morphological variation on hydraulic efficiency has been poorly studied. Branch junctions are commonly thought to be points of high hydraulic resistance, but adjustments in leaf area or xylem conduit abundance or dimensions could compensate for the additional hydraulic resistance of nodal junctions at the level of the entire shoot. Here we used the sexually dimorphic genus Leucadendron (Proteaceae) to test whether variation in branch ramification impacts shoot hydraulic efficiency. We found that branch ramification was related to leaf traits via Corner’s rules such that more highly ramified shoots had smaller leaves, but that branch ramification had little consistent impact on shoot hydraulic efficiency, whether measured on a leaf area or stem cross-sectional area basis. These results suggest that the presumed increase in resistance associated with branching nodes can be compensated by other adjustments at the shoot level (e.g. leaf area adjustments, increased ramification to add additional branches in parallel rather than in series) that maintain hydraulic efficiency at the level of the entire shoot. Despite large morphological differences between males and females in the genus Leucadendron, which are due to differences in pollination and reproduction between the sexes, the physiological differences between males and females are minimal.
Highlights
Plants are remarkably diverse in gross morphology
Species exhibited different elevations in their relationships, there was no significant difference in the slopes among groups (LRT = 2.74, df = 3, P = 0.43; L. rubrum: slope = −0.39, R2 = 0.87, P < 0.001; L. daphnoides: slope = −0.45, R2 = 0.46, P < 0.001)
We found no compelling evidence that hydraulic efficiency differs between conspecific males and females or even between the co-occurring species we studied here, which differ dramatically in their degrees of sexual dimorphism
Summary
Plants are remarkably diverse in gross morphology. Theoretical studies have shown that the number of optimal plant architectures increases with the number of functions that must be performed (Niklas, 1994). One notable trait that varies both within and among species is the degree of branch ramification. Because branches and stems serve both hydraulic and biomechanical functions, larger leaves and leaf areas are correlated with thicker branches (Corner, 1949; Ackerly & Donoghue, 1998; Olson, Aguirre-Hernández & Rosell, 2009). According to Corner’s rules, branch size is inversely related to how highly ramified shoots are; that is, given a constant allocation of biomass, the stems of more highly branched shoots should, on average, be smaller.
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