Intraspecific variability rivals interspecific differences in root traits of temperate tree seedlings

Dendoncker, Morgane; Maheu, Audrey; Weemstra, Monique; Villemaire-Côté, Olivier; Darquié, Léa; Lobet, Guillaume

doi:10.64898/2025.12.15.694302

Intraspecific variability rivals interspecific differences in root traits of temperate tree seedlings

Dendoncker, Morgane

;

Maheu, Audrey

;

Weemstra, Monique

;

Villemaire-Côté, Olivier

;

Lobet, Guillaume

;et.al.

(2025) bioRxiv — p. 26 (2025)

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Authors

Dendoncker, MorganeUCLouvain
Author
Maheu, Audrey
Author
Weemstra, MoniqueWageningen
Author
Villemaire-Côté, OlivierDépartement des Sciences du Bois et de la Forêt, Université Laval, 2405 de la Terrasse, Québec City, G1S 0A6, Canada
Author
Lobet, GuillaumeUCLouvain
Author
et. al.

Abstract

Global change and associated disturbances are increasing the risk of regeneration failure for tree species in temperate forests. Seedlings are particularly vulnerable to water stress due to their shallow root systems, making belowground plasticity a potentially key component of species adaptive capacity. Quantifying root trait variability and its drivers can improve our understanding of regeneration success under increasingly warm and dry conditions. We quantified between species variation (BTV) and intraspecific variation (ITV) in seven root traits linked to water uptake—root-to-shoot ratio, maximum rooting depth, proportion of absorptive roots, specific root length, root tissue density, average absorptive root diameter, and root branching density—for seedlings of seven common, co-occurring tree species in forests of northeastern North America. We sampled seedlings under contrasting climate and light conditions, and assessed the influence of abiotic (climate, light conditions, soil properties) and biotic drivers (neighboring vegetation) as well as seedling characteristics (species identity, age, spermatophyte type) on root ITV at local and regional scales. Species differed significantly for some traits but differed even more strongly in multivariate trait syndromes, suggesting distinct belowground strategies. ITV was substantial but trait-dependent, with maximum rooting depth and root to shoot ratio being the most variable (coefficient of variation > 45%) and branching density the least variable. BTV was the primary driver of overall trait variation for three traits, explaining more than 60% of variation, whereas within-plot ITV accounted for more than 50% of variation in the remaining four traits. Local drivers did not outweigh regional factors, and the overall explanatory power of measured drivers was limited, suggesting that fine-scale heterogeneity, not captured in our study, may strongly influence root ITV. High ITV in most traits suggests substantial plasticity in roots, which may contribute to the adaptive capacity of seedlings facing climate change. Integrating this plasticity into mechanistic models is critical for predicting regeneration dynamics or root-mediated ecosystem processes. We propose a set of guidelines for integrating root traits into comparative studies and models based on trait measurability and extent of ITV. We further highlight the need to account for the scale- and gradient-intensity dependence of ITV-environment relationships.

Affiliations

UCLouvainSST/ELI/ELIA - Agronomy

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Dendoncker, M., Maheu, A., Weemstra, M., Villemaire-Côté, O., Darquié, L., Lobet, G., & et al. (2025). Intraspecific variability rivals interspecific differences in root traits of temperate tree seedlings. bioRxiv, 26. https://doi.org/10.64898/2025.12.15.694302 (Original work published 2025)