# Importance of the actual plant height in modulating the within-community spectrum of plant form and function

**Authors:** Dong He, En-Rong Yan, Li-Ting Zheng, Yan-Jun Song, Xiao-Dong Yang, Wen-Hui You, J. Hans C. Cornelissen

PMC · DOI: 10.3389/fpls.2025.1616656 · 2025-07-24

## TL;DR

This study shows that actual plant height, not maximum height, better explains variations in plant traits within local communities.

## Contribution

The paper introduces actual plant height as a key factor in modulating plant functional traits at the community level.

## Key findings

- Leaf traits correlate more strongly with actual height than maximum height at the community level.
- Intraspecific variation in traits is greater than interspecific variation.
- Actual height influences trade-offs in biomass allocation and hydraulic limitations.

## Abstract

Maximum height (Hmax) is a principal driver or correlate of interspecific variation in many plant functional traits. Still, it remains unclear why leaf resource economic traits are invariant with Hmax at global scale and why broad-scale interspecific trait correlations are not retained at local scale. Here we proposed that the actual plant height (Hact), which is tightly linked with highly localized abiotic and biotic interactions, is more important than Hmax in determining plant morpho-physiological traits among locally co-occurring plants. We tested the idea across community, regional, and global scales. We also examined correlations among 22 traits, including leaf physiology, hydraulics, and crown architecture, within a subtropical forest in Eastern China. Additionally, we explored how Hact-driven trait variations align with vertical patterns of microclimates. Results showed stronger correlations between leaf traits and Hact at the community level, except for leaf area. Intraspecific variation exceeded interspecific variation, and trait correlations were stronger at the individual level than at the species level. Hact positively correlated with traits like crown area, leaf mass per area, stomatal density, and hydraulic conductivity but negatively with stem hydraulic safety margin and leaf coverage. Vertical changes in photosynthetically active radiation explained most Hact-driven trait variations. Our findings suggest that Hact influences plant trade-offs in biomass allocation and photosynthetic-hydraulic limitations, shaping functional diversity within communities. This highlights Hact as a key factor in balancing resource use, support, and water transport among coexisting plants.

## Full-text entities

- **Chemicals:** phosphorus (MESH:D010758), nitrogen (MESH:D009584), water (MESH:D014867), carbon (MESH:D002244), Ca (-)
- **Species:** Quercus myrsinifolia (shira-kashi, species) [taxon 57648], Schima superba (species) [taxon 59677], Salinicoccus sp. M (species) [taxon 1545528], Eurya loquaiana (species) [taxon 184572], Camellia fraterna (species) [taxon 542725], Symplocos sumuntia (species) [taxon 251602], Castanopsis fargesii (species) [taxon 167386], Rhododendron ovatum (species) [taxon 49169], Lithocarpus glaber (Japanese oak, species) [taxon 157794]

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12328304/full.md

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Source: https://tomesphere.com/paper/PMC12328304