Your search keyword '"root morphological trait"' showing total 10 results

1. The combined effect of root morphological and resistance traits alleviated the growth limitations of Pinus massoniana seedlings under low phosphorus conditions

Author

Xu, Jin, Lei, Lei, Zeng, Lixiong, Jian, Zunji, Xiao, Wenfa, and Ni, Yanyan

Published

2024

2. Enhanced phosphorus-fertilizer-use efficiency and sustainable phosphorus management with intercropping.

Author

An, Ran, Yu, Rui-Peng, Xing, Yi, Zhang, Jiu-Dong, Bao, Xing-Guo, Lambers, Hans, and Li, Long

Subjects

*CATCH crops, *MONOCULTURE agriculture, *SUSTAINABLE agriculture, *INTERCROPPING, *RAPESEED, *CROPPING systems, *FAVA bean, *GRAIN yields

Abstract

Establishing desirable cropping systems with higher fertilizer-use efficiency and lower risk of environmental pollution is a promising approach for more sustainable agriculture development. Intercropping may facilitate phosphorus (P) uptake and reduce P-fertilizer application rates. However, how root-root interactions mediate enhanced P-fertilizer-use efficiency in intercropping under field conditions remains poorly understood. Using a long-term field experiment established in 2009, where there have been three P-fertilizer application rates (0, 40, and 80 kg P ha−1) and nine cropping systems (four intercropping combinations and corresponding monocultures), we calculated aboveground biomass, grain yield, aboveground P content, P-use efficiency indicators, e.g., the apparent recovery efficiency of applied P, and diversity effects. We also investigated the P-related physiological and morphological traits of crop species and linked root traits with agronomic indicators. We found that 12 years of intercropping significantly increased productivity, shoot P content, agronomic efficiency of applied P, and the apparent recovery efficiency of applied P in all combinations compared with the weighted means of corresponding monocultures; intercropping with 40 kg P ha−1 application showed relatively high productivity, P content and P-use efficiency. The P-uptake advantage in intercropping was mainly related to the positive complementarity effect. The companion crop species (i.e. faba bean, oilseed rape, chickpea, and soybean) exhibited greater P-mobilizing capacity than sole maize. Intercropped maize exhibited greater root physiological, e.g., rhizosheath phosphatase activity and carboxylates (proxied by leaf manganese concentration), and morphological traits (e.g., specific root length) than sole maize, partly related to facilitation by efficient P-mobilizing neighbors. The greater P-use efficiency was mainly contributed by morphological traits of maize rather than traits of companion crop species. We highlight that the enhanced P-use efficiency in intercropping systems is partly mediated by belowground facilitation, and desirable intercropping systems have the potential to save P-fertilizer input and improve the sustainability of P management in agroecosystems. [ABSTRACT FROM AUTHOR]

Published

2023

3. The interspecific competition of tree plants in the presence of AM fungi and litter facilitates root morphological development and nutrition when compared with intraspecific competition.

Author

Guo, Yun, Shen, Kaiping, Xia, Tingting, He, Yuejun, Ren, Wenda, Wu, Pan, Lin, Yan, Wu, Bangli, Han, Xu, Gao, Lu, Li, Jinting, Hu, Xiaorun, Wang, Li, Jiao, Min, Yan, Jiawei, Yang, Xionggui, Yu, Hangcheng, and Zhang, Jingkun

Subjects

PLANT competition, PLANT litter, COMPETITION (Biology), VESICULAR-arbuscular mycorrhizas, ROOT development, TREE planting

Abstract

Arbuscular mycorrhizal (AM) fungi can affect plant growth by regulating competition. Nutrient-deficient karst habitats contain abundant plants that compete for nutrients through interspecific or intraspecific competition, involving the nutritional transformation of litter decomposition. However, how plant competition in the presence of AM fungi and litter affects root development and nutrition remains unclear. A potted experiment was conducted, including AM fungus treatment with or without Glomus etunicatum, the competition treatment concerning intraspecific or interspecific competition through planting Broussonetia papyrifera and Carpinus pubescens seedlings, and the litter treatment with or without the mixture of B. papyrifera and C. pubescens litter leaves. The root morphological traits were analyzed, and nitrogen (N), phosphorus (P), and potassium (K) were measured. The results showed that AM fungus differently affected the root morphological development and nutrition of both competitive plants, significantly promoting B. papyrifera roots in the increase of dry weight, length, volume, surface area, tips, and branches as well as N, P, and K acquisitions regardless of litter addition. However, there was no apparent influence for C. pubescens roots, except for the diameter in the interspecific competition with litter. The root dry weight, length, volume, surface area, and tips of B. papyrifera under two competitive styles were significantly greater than C. pubescens regulated by AM fungus, presenting significant species differences. The responses of the relative competition intensity (RCI) on root morphological and nutritional traits indicated that AM fungus and litter both asymmetrically alleviated more competitive pressure for B. papyrifera than C. pubescens, and the interspecific competition facilitated more root morphological development and nutrition utilization by endowing B. papyrifera root superiority relative to C. pubescens compared with the intraspecific competition. In conclusion, interspecific competition is more beneficial for plant root development and nutrition than intraspecific competition in the presence of AM fungus and litter via asymmetrically alleviating competitive pressure for different plants. [ABSTRACT FROM AUTHOR]

Published

2023

4. Root Features Determine the Increasing Proportion of Forbs in Response to Degradation in Alpine Steppe, Tibetan Plateau

Author

Zhenchao Zhang and Jian Sun

Subjects

forbs, species richness, plant community structure, root morphological trait, degradation, alpine steppe, Environmental sciences, GE1-350

Abstract

Understanding the response of plant community to degradation is fundamentally important for grassland conservation and management. The objective of this study is to examine the changes in soil properties and plant characteristics along a degradation gradient in alpine steppe, and explore the potential mechanisms that biotic and abiotic controls regulate plant community variations. We chose seven sequent degrees of degradation, and conducted a field survey as well as soil and plant samplings in an alpine steppe in Northern Tibet. The results showed that soil water content (SWC), soil compaction (SCOM), soil total carbon (STC), and total nitrogen (STN) dramatically decreased along the degradation gradient. The species richness, overall aboveground biomass (AGB), and AGB of graminoids were apparently reduced with increasing degradation, while AGB of forbs slightly increased. The increasing degradation levels induced a significant increase in the trade-off value of AGB of forbs, which was negatively associated with SWC, SCOM, STC, STN, and soil available nitrogen. The mean root length of forbs was significantly longer than that of graminoids (P < 0.05). Moreover, the mean root diameter of the top 1/3 part of forbs was remarkably thicker than that of graminoids (P < 0.05). These findings indicate that the degradation-induced cohesionless soils with insufficient water and nutrients together with the divergent root morphological traits of graminoids and forbs determine the plant community structure shift with grassland degradation. This study can improve the understanding of community succession of grassland degradation, and provide guidance for the management of degraded alpine steppe on the Tibetan Plateau.

Published

2020

5. High-Throughput Root Imaging Analysis Reveals Wide Variation in Root Morphology of Wild Adzuki bean (Vigna angularis) Accessions

Author

Rupesh Tayade, Seong-Hoon Kim, Pooja Tripathi, Yi-Dam Choi, Jung-Beom Yoon, and Yoon-Ha Kim

Subjects

cluster analysis, image analysis, legume, root architectural trait, root morphological trait, Botany, QK1-989

Abstract

Root system architecture and morphological diversification in wild accessions are important for crop improvement and productivity in adzuki beans. In this study, via analysis using 2-dimensional (2D) root imaging and WinRHIZO Pro software, we described the root traits of 61 adzuki bean accessions in their early vegetative growth stage. These accessions were chosen for study because they are used in Korea’s crop improvement programs; however, their root traits have not been sufficiently investigated. Analysis of variance revealed a significant difference between the accessions of all measured root traits. Distribution analysis demonstrated that most of the root traits followed normal distribution. The accessions showed up to a 17-fold increase in the values in contrasting accessions for the root traits. For total root length (TRL), the values ranged from 82.43 to 1435 cm, and for surface area (SA), they ranged from 12.30 to 208.39 cm2. The values for average diameter (AD) ranged from 0.23 to 0.56 mm. Significant differences were observed for other traits. Overall, the results showed that the accession IT 305544 had the highest TRL, SA, and number of tips (NT), whereas IT 262477 and IT 262492 showed the lowest values for TRL, SA, and AD. Principal component analysis showed an 89% variance for PC1 and PC2. K-mean clustering explained 77.4% of the variance in the data and grouped the accessions into three clusters. All six root traits had greater coefficients of variation (≥15%) among the tested accessions. Furthermore, to determine which root traits best distinguished different accessions, the correlation within our set of accessions provided trait-based ranking depending on their contribution. The identified accessions may be advantageous for the development of new crossing combinations to improve root features in adzuki beans during the early growth stage. The root traits assessed in this study could be attributes for future adzuki bean crop selection and improvement.

Published

2022

6. Simulating the anchorage behaviour of plant roots of different morphological traits

Author

Zhu, Jun, Leung, Kwan Anthony, Wang, Yu, Zhu, Jun, Leung, Kwan Anthony, and Wang, Yu

Abstract

Slope greening is a nature-based solution that brings multiple environmental and societal benefits to urban built environments. The selection of plant species for this purpose is often based on their landscape values. However, the potential engineering functions of vegetation, such as pull-out resistance to soil sliding, have generally been ignored. Previous studies have attempted to use different root morphological traits to empirically explain the variations in pull-out resistance Pul, but the underlying root–soil load transfer mechanisms have rarely been investigated. This study used a validated three-dimensional (3-D) embedded beam element model in a finite element platform to parametrically investigate the effects of various root morphological traits on the pull-out behaviour of 3-D root systems. Simulation results showed that root systems whose morphology and branching pattern could gain more interfacial shear resistance (oblique second-order laterals in contrast to the horizontal case) and mobilise more root internal stresses (deeper branching point between first- and second-order roots) had higher Pul values. The third-order sinkers were effective in mobilising their tensile strength to resist pull-out only when they were within a certain distance away from the first-order taproot. A new integrated morphological trait was proposed to implicitly capture the different aspects of root–soil interaction mechanisms, and it contributed to approximately 85% of the Pul variability. Our study suggests that among the root systems that have the same volumes, those with either (1) more branch roots (BRs) but shorter lengths or (2) less BR but longer lengths have greater pull-out resistance and are thus more effective to soil stabilisation. © 2023 Elsevier GmbH

Published

2023

7. Root Response to Drought Stress in Rice (

Author

Yoonha, Kim, Yong Suk, Chung, Eungyeong, Lee, Pooja, Tripathi, Seong, Heo, and Kyung-Hwan, Kim

Subjects

root morphological trait, fungi, food and beverages, Water, Oryza, phenomics, Review, root architecture, physiological response to drought, Adaptation, Physiological, Plant Roots, Droughts, Plant Breeding, Soil, Gene Expression Regulation, Plant, Stress, Physiological, parasitic diseases, screening methods for drought stress, Plant Proteins

Abstract

The current unpredictable climate changes are causing frequent and severe droughts. Such circumstances emphasize the need to understand the response of plants to drought stress, especially in rice, one of the most important grain crops. Knowledge of the drought stress response components is especially important in plant roots, the major organ for the absorption of water and nutrients from the soil. Thus, this article reviews the root response to drought stress in rice. It is presented to provide readers with information of use for their own research and breeding program for tolerance to drought stress in rice.

Published

2020

8. High-Throughput Root Imaging Analysis Reveals Wide Variation in Root Morphology of Wild Adzuki bean (Vigna angularis) Accessions.

Author

Tayade, Rupesh, Kim, Seong-Hoon, Tripathi, Pooja, Choi, Yi-Dam, Yoon, Jung-Beom, and Kim, Yoon-Ha

Subjects

IMAGE analysis, BEANS, VIGNA, CROP improvement, PRINCIPAL components analysis

Abstract

Root system architecture and morphological diversification in wild accessions are important for crop improvement and productivity in adzuki beans. In this study, via analysis using 2-dimensional (2D) root imaging and WinRHIZO Pro software, we described the root traits of 61 adzuki bean accessions in their early vegetative growth stage. These accessions were chosen for study because they are used in Korea's crop improvement programs; however, their root traits have not been sufficiently investigated. Analysis of variance revealed a significant difference between the accessions of all measured root traits. Distribution analysis demonstrated that most of the root traits followed normal distribution. The accessions showed up to a 17-fold increase in the values in contrasting accessions for the root traits. For total root length (TRL), the values ranged from 82.43 to 1435 cm, and for surface area (SA), they ranged from 12.30 to 208.39 cm2. The values for average diameter (AD) ranged from 0.23 to 0.56 mm. Significant differences were observed for other traits. Overall, the results showed that the accession IT 305544 had the highest TRL, SA, and number of tips (NT), whereas IT 262477 and IT 262492 showed the lowest values for TRL, SA, and AD. Principal component analysis showed an 89% variance for PC1 and PC2. K-mean clustering explained 77.4% of the variance in the data and grouped the accessions into three clusters. All six root traits had greater coefficients of variation (≥15%) among the tested accessions. Furthermore, to determine which root traits best distinguished different accessions, the correlation within our set of accessions provided trait-based ranking depending on their contribution. The identified accessions may be advantageous for the development of new crossing combinations to improve root features in adzuki beans during the early growth stage. The root traits assessed in this study could be attributes for future adzuki bean crop selection and improvement. [ABSTRACT FROM AUTHOR]

Published

2022

9. Root Response to Drought Stress in Rice (Oryza sativa L.)

Author

Eungyeong Lee, Yoon Ha Kim, Seong Heo, Kyung-Hwan Kim, Pooja Tripathi, and Yong Suk Chung

Subjects

0106 biological sciences, 0301 basic medicine, Drought stress, Breeding program, Climate change, root architecture, Biology, physiological response to drought, 01 natural sciences, Catalysis, Drought stress response, lcsh:Chemistry, Inorganic Chemistry, 03 medical and health sciences, Phenomics, Nutrient, parasitic diseases, screening methods for drought stress, Physical and Theoretical Chemistry, lcsh:QH301-705.5, Molecular Biology, Spectroscopy, root morphological trait, Oryza sativa, Plant roots, fungi, Organic Chemistry, food and beverages, phenomics, General Medicine, Computer Science Applications, 030104 developmental biology, lcsh:Biology (General), lcsh:QD1-999, Agronomy, 010606 plant biology & botany

Abstract

The current unpredictable climate changes are causing frequent and severe droughts. Such circumstances emphasize the need to understand the response of plants to drought stress, especially in rice, one of the most important grain crops. Knowledge of the drought stress response components is especially important in plant roots, the major organ for the absorption of water and nutrients from the soil. Thus, this article reviews the root response to drought stress in rice. It is presented to provide readers with information of use for their own research and breeding program for tolerance to drought stress in rice.

Published

2020

10. Root Response to Drought Stress in Rice (Oryza sativa L.).

Author

Kim, Yoonha, Chung, Yong Suk, Lee, Eungyeong, Tripathi, Pooja, Heo, Seong, and Kim, Kyung-Hwan

Subjects

*DROUGHTS, *DROUGHT tolerance, *CLIMATE change, *PLANT roots, *RICE, *GRAIN

Abstract

The current unpredictable climate changes are causing frequent and severe droughts. Such circumstances emphasize the need to understand the response of plants to drought stress, especially in rice, one of the most important grain crops. Knowledge of the drought stress response components is especially important in plant roots, the major organ for the absorption of water and nutrients from the soil. Thus, this article reviews the root response to drought stress in rice. It is presented to provide readers with information of use for their own research and breeding program for tolerance to drought stress in rice. [ABSTRACT FROM AUTHOR]

Published

2020