Response of Fine-Root Traits of Populus tomentosa to Drought in Shallow and Deep Soil

Tan, Jianbiao; Yu, Weichen; Liu, Yang; Guo, Youzheng; Liu, Nan; Fu, Haiman; Di, Nan; Duan, Jie; Li, Ximeng; Xi, Benye

doi:10.3390/f14050951

Cited by 7 publications

(5 citation statements)

References 62 publications

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“…Regardless of the different environmental characteristics, the length and biomass of fine roots decreased significantly with the increasing soil depth (Figure 1). These results confirm the distribution of roots typical of poplars, mainly in the upper layers of the soil profile, which has been shown in numerous studies, mainly from plantation crops [42,43], but also in our previous work regarding natural riparian forests [27]. Simultaneously, the distribution of fine roots reflects their absorption and transport functions and is related to decreases in the nutrient pool with increasing soil depth [44].…”

Section: Discussionsupporting

confidence: 90%

“…The lack of significant differences between sites for the remaining analyzed features (FRL, SRL, FRB except for the depth of 20-30 cm) may be related to the low range of soil depths analyzed (0-30 cm). Tan et al [42] found that the characteristics of fine roots of Populus tomentosa in relation to dry conditions were only significantly different in very deep soil layers (400-600 cm).…”

Section: Discussionmentioning

confidence: 99%

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Seasonal Dynamics in Mycorrhizal Colonization and Fine Root Features of the White Poplar (Populus alba L.) in Natural Temperate Riverside Forests with Two Contrasting Soils

Frymark-Szymkowiak,

Kulczyk-Skrzeszewska,

Tyburska-Woś

2023

Forests

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Fine roots are the most dynamic and physiologically active components of belowground tree organs. However, much remains unknown regarding the changes in fine root morphological characteristics during mycorrhizal colonization, especially in natural sites. The aim of this study was to analyze seasonal heterogeneity in fine roots and the mycorrhizal colonization of mature white poplar (Populus alba L.) trees under different soil conditions. Two floodplain forests were selected in Central Europe (Poland), which differed in soil moisture and structure. Fine roots were sampled during one growing season from the upper soil layer. Poplars were characterized by dual mycorrhizal colonization on one root system. It was, therefore, possible to investigate the contribution of two mycorrhizal types (arbuscular mycorrhiza—AM; and ectomycorrhiza—ECM) in response to different habitat conditions. The season was shown to be significant for all fine root features, as well as the degree of mycorrhizal colonization. Roots were better adapted to a drier habitat with a greater proportion of sand, mainly due to a reduction in the fine root diameter (FRD), while other root characteristics did not differ significantly. The degree of mycorrhizal colonization (RLC) and the proportion of arbuscular mycorrhizal structures (AM) were significantly and negatively correlated with the soil water content. A mutual competition between arbuscular mycorrhizas and ectomycorrhizas for poplar roots was also observed, particularly with respect to the season, site, and soil moisture. Changing environmental conditions (especially soil moisture) contribute not only to the morphological and functional changes of fine roots but also to changes in the proportion of arbuscular mycorrhiza and ectomycorrhiza. Understanding the mechanisms of adaptation of tree roots to changing environmental conditions is especially important in the context of climate change.

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Section: Discussionsupporting

confidence: 90%

Section: Discussionmentioning

confidence: 99%

Seasonal Dynamics in Mycorrhizal Colonization and Fine Root Features of the White Poplar (Populus alba L.) in Natural Temperate Riverside Forests with Two Contrasting Soils

Frymark-Szymkowiak,

Kulczyk-Skrzeszewska,

Tyburska-Woś

2023

Forests

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“…The trunk is straight and the bark is grayish green to grayish white, with diamond-shaped pores and longitudinal fissures at the base of old trees. Young branches are hairy and later fall off [45].…”

Section: Study Areamentioning

confidence: 99%

Study on the Root Characteristics and Effects on Soil Reinforcement of Slope-Protection Vegetation in the Chinese Loess Plateau

Zhang,

Fu,

Pei

et al. 2024

Forests

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The Loess Plateau region of China suffers from severe soil erosion, and the selection of effective slope-protection vegetation is essential to prevent soil and water loss. This study focused on individual plants of common species in the Loess Plateau, such as Caragana korshinski Kom., Hippophae rhamnoides Linn., Pinus tabuliformis Carr., Robinia Pseudoacacia Linn., Populus tomentosa Carr., Prunus armeniaca Lam. The root spatial distribution, geometric morphology, and fractal characteristics of these plants were measured using the whole-root-excavation method, and the vertical pull-out force of their root systems was quantified using the in situ whole-plant root-pulling method. The results showed that H. rhamnoides dominates in the vertical spatial distribution of its root system through a larger number of inclined roots. C. korshinskii, P. tomentosa, R. pseudoacacia, and P. armeniaca dominate in the horizontal spatial distribution of their root systems through a greater number of horizontal roots. P. tabuliformis, on the other hand, achieves a relatively balanced distribution in both horizontal and vertical spaces through its well-developed taproot and numerous lateral roots. In terms of the geometric morphology and fractal characteristics of their root systems, H. rhamnoides and C. korshinskii exhibit a larger number of fine roots and complex branching, resulting in a higher total-root length, total-root surface area, and root fractal dimension. The soil-stabilizing ability of H. rhamnoides, C. korshinskii, and R. pseudoacacia was stronger, mainly influenced by their total-root length, total-root surface area, and inclined root quantity, and these species can be prioritized as typical vegetation for soil and water conservation in the construction of Loess Plateau vegetation. From the perspective of slope stabilization and soil conservation alone, we strongly recommend planting shrub vegetation in the Chinese Loess Plateau.

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“…Therefore, distinct adjustments of fine root traits in different soil layers could be a subtle but important aspect of any coordination between potential water and nutrient capture across the soil profile. This possibility is suggested by the asynchrony in fine root growth between shallow and deep soil layers during rainy and dry seasons (Germon et al, 2020;Lambais et al, 2017) and the different responses of fine root morphology between shallow and deep soil layers to fertilization (Bordron et al, 2019) or drought (Tan et al, 2023).…”

Section: Introductionmentioning

confidence: 99%

Contrasting depth‐related fine root plastic responses to soil warming in a subtropical Chinese fir plantation

Jia,

Jiang,

Sun

et al. 2024

Journal of Ecology

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Warming‐induced soil drought, especially in topsoil, may enlarge the spatial mismatch between nutrients and water along the soil profile, which impedes the uptake of not only water but also nutrients by trees. Therefore, coordinating the acquisition of soil water and nutrients along the soil profile is an important strategy for trees to cope with global warming. This study examined soil depth‐related changes in nutrient concentrations, biomass and morphology of fine roots in a Chinese fir plantation after 3 years of large‐scale manipulative soil warming. Soil warming (ambient +4°C) increased fine root nitrogen (N) concentrations but decreased fine root phosphorus (P) concentrations across soil depths. Warming did not affect total fine root biomass and its vertical distribution. At the 0–10 cm depth, warming increased specific root length (SRL), specific root area (SRA), fine root diameter (RD) and root length density (RLD) but reduced root tissue density (RTD). In the 40–60 cm layer, warming reduced RD, SRL and RLD while increasing RTD mainly for roots of the 1–2 mm diameter class. Synthesis. We concluded that roots of Chinese fir plantations could adapt to warming‐induced moderate water stress through contrasting depth‐related root morphological adjustments, probably to optimize the acquisition of both soil water and nutrients. The results of this study are crucial for understanding the adaptation strategies of subtropical forests under future climate conditions.

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Response of Fine-Root Traits of Populus tomentosa to Drought in Shallow and Deep Soil

Cited by 7 publications

References 62 publications

Seasonal Dynamics in Mycorrhizal Colonization and Fine Root Features of the White Poplar (Populus alba L.) in Natural Temperate Riverside Forests with Two Contrasting Soils

Seasonal Dynamics in Mycorrhizal Colonization and Fine Root Features of the White Poplar (Populus alba L.) in Natural Temperate Riverside Forests with Two Contrasting Soils

Study on the Root Characteristics and Effects on Soil Reinforcement of Slope-Protection Vegetation in the Chinese Loess Plateau

Contrasting depth‐related fine root plastic responses to soil warming in a subtropical Chinese fir plantation

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