Evidence of Differences in Covariation Among Root Traits Across Plant Growth Forms, Mycorrhizal Types, and Biomes

An, Nannan; Lü, Nan; Fu, Bojie; Chen, Wei‐Liang; Keyimu, Maierdang; Wang, Mengyu

doi:10.3389/fpls.2021.785589

Cited by 4 publications

(5 citation statements)

References 99 publications

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“…Since WUE was not correlated with water use but was positively correlated with shoot weight, it could be that root traits that improve nutrient absorption to synthesize more shoot dry matter might be positively correlated with WUE. Our results are supported by previous reports on the multifaceted role of fine roots in plant resource acquisition, net primary production, and adaptation to environmental changes (An et al., 2022; Diaz et al., 2004; McCormack et al., 2014, 2015). According to the root economics spectrum (RES) hypothesis, roots with an acquisitive strategy are characterized by a thin diameter (i.e., fine roots) (An et al., 2022).…”

Section: Discussionsupporting

confidence: 92%

“…Our results are supported by previous reports on the multifaceted role of fine roots in plant resource acquisition, net primary production, and adaptation to environmental changes (An et al., 2022; Diaz et al., 2004; McCormack et al., 2014, 2015). According to the root economics spectrum (RES) hypothesis, roots with an acquisitive strategy are characterized by a thin diameter (i.e., fine roots) (An et al., 2022). Taken together, our results emphasize the importance of fine roots in enhancing the WUE of cotton.…”

Section: Discussionsupporting

confidence: 92%

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Phenotypic variability in the US upland cotton core set for root traits and water use efficiency at the late reproductive stage

Ghimire,

Spivey,

Kuraparthy

et al. 2024

Crop Science

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To incorporate root traits that improve water use efficiency (WUE) in cotton (Gossypium hirsutum L.) variety development, harnessing the genetic variability for root traits is essential. The objectives of this study were to characterize the US upland cotton core set for root traits and WUE and determine the traits associated with WUE. The core set includes 23 of the 381 accessions of the cotton diversity panel and represents 74% of the allelic diversity in US upland cotton. Plants were grown in polyvinyl chloride columns (125‐cm height, 15‐cm diameter) in a greenhouse in 2021–2022 and 2022–2023. Half of the columns contained a synthetic hardpan (1 cm thickness, 300 PSI penetration resistance) at a depth of 25 cm. Plants were harvested when >50% of the population opened bolls. Based on 16 root‐ and shoot‐traits, water use, and WUE, Deltapine 14, Station Miller, and Southland M1 were the best performers, and Toole, Paymaster HS200, Western Stormproof, CD3HCABCUH‐1‐89, and PD 2164 were the poor performers irrespective of the presence or absence of hardpan stress to root growth. The WUE of the core set genotypes was positively correlated with very fine root (diameter <0.25 mm) length, surface area, and volume and total root weight (correlation coefficient ≥0.45). These traits serve as beneficial root traits for developing new varieties with enhanced WUE. The identified genotypes and traits will be valuable for developing the next generation of water‐use‐efficient cotton varieties with a broad genetic base through advanced breeding techniques involving genomic tools and genetic diversity.

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Section: Discussionsupporting

confidence: 92%

Section: Discussionsupporting

confidence: 92%

Phenotypic variability in the US upland cotton core set for root traits and water use efficiency at the late reproductive stage

Ghimire,

Spivey,

Kuraparthy

et al. 2024

Crop Science

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“…More details of these traits can be seen in Table S2. Previous studies have found that RCN was closely related to root tissue density (RTD) at both the species and community level (Wang et al ., 2018; An et al ., 2022). Therefore, to analogize with leaf traits, we considered RCN here instead of RTD, even which is the more commonly used RES trait.…”

Section: Methodsmentioning

confidence: 99%

Are absorptive root traits good predictors of ecosystem functioning? A test in a natural temperate forest

Chen

Zhang

et al. 2023

New Phytologist

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Trait-based approaches provide a useful framework to predict ecosystem functions under intensifying global change. However, our current understanding of trait-functioning relationships mainly relies on aboveground traits. Belowground traits (e.g. absorptive root traits) are rarely studied although these traits are related to important plant functions.We analyzed four pairs of analogous leaf and absorptive root traits of woody plants in a temperate forest and examined how these traits are coordinated at the community-level, and to what extent the trait covariation depends on local-scale environmental conditions. We then quantified the contributions of leaf and absorptive root traits and the environmental conditions in determining two important forest ecosystem functions, aboveground carbon storage, and woody biomass productivity.The results showed that both morphological trait pairs and chemical trait pairs exhibited positive correlations at the community level. Absorptive root traits show a strong response to environmental conditions compared to leaf traits. We also found that absorptive root traits were better predictors of the two forest ecosystem functions than leaf traits and environmental conditions.Our study confirms the important role of belowground traits in modulating ecosystem functions and deepens our understanding of belowground responses to changing environmental conditions.

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“…Notably, only plants with arbuscular mycorrhizal associations were examined in this study due to the tropical woody plants are dominated by arbuscular mycorrhizal species [54,55]. However, root resource acquisition strategies are also influenced by mycorrhizal type [23,56]. Mycorrhizal type can impact the relationships between fine root chemical (e.g., RNC) or morphological (e.g., SRL) traits and root respiration [57].…”

Section: Tropical Plant Root Traits Followed a Multidimensional Patte...mentioning

confidence: 99%

“…How root systems impact plant growth and ecosystem processes is closely tied to the interplay among fine root chemical, morphological, and physiological traits [3]. Although root respiration shapes nutrient acquisition and plays a vital role in the RES [18,19], previous studies testing the RES hypothesis predominantly focused only on chemical and morphological traits, given the relative difficulty of measuring respiration [20][21][22][23]. But there are also several studies in grassland, temperate forest, and subtropical forest ecosystems that incorporate root respiration into the RES.…”

Section: Introductionmentioning

confidence: 99%

Root Respiration–Trait Relationships Are Influenced by Leaf Habit in Tropical Plants

Deng,

Sun,

Yang

2024

Forests

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Root respiration is a critical physiological trait that significantly influences root system activity. Recent studies have associated root respiration with the economic functioning of roots; however, research on root respiration in tropical plants remains limited. This study examined the fine root respiration and the relationship between root respiration and root chemical and morphological traits in 16 tropical plant species, including both evergreen and deciduous species. Findings revealed that deciduous species exhibited higher root respiration compared to evergreen species. Root respiration positively correlated with root nitrogen concentration and specific root length and correlated negatively with root diameter and root tissue density across all species. The root respiration patterns in evergreen species aligned with those seen in all tree species, while deciduous species showed a distinct negative correlation with root tissue density and no significant correlations with other root traits. Principal component analysis revealed that the patterns of root variation in both evergreen and deciduous trees were multidimensional, with deciduous trees exhibiting acquisitive traits and evergreen trees displaying conservative traits. Random forest and multiple regression analysis showed that specific root length exerted the most significant influence on root respiration in both evergreen and deciduous trees. These findings are ecologically significant, enhancing our understanding of root respiration in tropical plants and its impact on ecosystem functions. They contribute valuable insights and support the conservation and management of tropical vegetation.

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Evidence of Differences in Covariation Among Root Traits Across Plant Growth Forms, Mycorrhizal Types, and Biomes

Cited by 4 publications

References 99 publications

Phenotypic variability in the US upland cotton core set for root traits and water use efficiency at the late reproductive stage

Phenotypic variability in the US upland cotton core set for root traits and water use efficiency at the late reproductive stage

Are absorptive root traits good predictors of ecosystem functioning? A test in a natural temperate forest

Root Respiration–Trait Relationships Are Influenced by Leaf Habit in Tropical Plants

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