Your search keyword '"nodal root"' showing total 39 results

1. Transcription factor EoBBR interacts with EoPROG1 and represses EoSINAT5 expression to regulate the nodal root development in Eremochloa ophiuroides (Munro) Hack

Author

Chen, Rongrong, Zhang, Ling, Wang, Rui, Sun, Qixue, Wang, Haoran, Guo, Hailin, Chen, Jingbo, and Wang, Jingjing

Published

2025

2. Identification of genetic and environmental factors influencing aerial root traits that support biological nitrogen fixation in sorghum.

Author

Wolf, Emily S A, Vela, Saddie, Wilker, Jennifer, Davis, Alyssa, Robert, Madalen, Infante, Valentina, Venado, Rafael E, Voiniciuc, Cătălin, Ané, Jean-Michel, and Vermerris, Wilfred

Subjects

*NITROGEN fixation, *SORGHUM, *PLANT breeding, *GENOME-wide association studies, *CROPS, *PLANT genetics

Abstract

Plant breeding and genetics play a major role in the adaptation of plants to meet human needs. The current requirement to make agriculture more sustainable can be partly met by a greater reliance on biological nitrogen fixation by symbiotic diazotrophic microorganisms that provide crop plants with ammonium. Select accessions of the cereal crop sorghum (Sorghum bicolor (L.) Moench) form mucilage-producing aerial roots that harbor nitrogen-fixing bacteria. Breeding programs aimed at developing sorghum varieties that support diazotrophs will benefit from a detailed understanding of the genetic and environmental factors contributing to aerial root formation. A genome-wide association study of the sorghum minicore, a collection of 242 landraces, and 30 accessions from the sorghum association panel was conducted in Florida and Wisconsin and under 2 fertilizer treatments to identify loci associated with the number of nodes with aerial roots and aerial root diameter. Sequence variation in genes encoding transcription factors that control phytohormone signaling and root system architecture showed significant associations with these traits. In addition, the location had a significant effect on the phenotypes. Concurrently, we developed F2 populations from crosses between bioenergy sorghums and a landrace that produced extensive aerial roots to evaluate the mode of inheritance of the loci identified by the genome-wide association study. Furthermore, the mucilage collected from aerial roots contained polysaccharides rich in galactose, arabinose, and fucose, whose composition displayed minimal variation among 10 genotypes and 2 fertilizer treatments. These combined results support the development of sorghums with the ability to acquire nitrogen via biological nitrogen fixation. [ABSTRACT FROM AUTHOR]

Published

2024

3. Four-dimensional measurement of root system development using time-series three-dimensional volumetric data analysis by backward prediction

Author

Shota Teramoto and Yusaku Uga

Subjects

Back prediction, Crown root, Image analysis, Image processing, Nodal root, Radicle, Plant culture, SB1-1110, Biology (General), QH301-705.5

Abstract

Abstract Background Root system architecture (RSA) is an essential characteristic for efficient water and nutrient absorption in terrestrial plants; its plasticity enables plants to respond to different soil environments. Better understanding of root plasticity is important in developing stress-tolerant crops. Non-invasive techniques that can measure roots in soils nondestructively, such as X-ray computed tomography (CT), are useful to evaluate RSA plasticity. However, although RSA plasticity can be measured by tracking individual root growth, only a few methods are available for tracking individual roots from time-series three-dimensional (3D) images. Results We developed a semi-automatic workflow that tracks individual root growth by vectorizing RSA from time-series 3D images via two major steps. The first step involves 3D alignment of the time-series RSA images by iterative closest point registration with point clouds generated by high-intensity particles in potted soils. This alignment ensures that the time-series RSA images overlap. The second step consists of backward prediction of vectorization, which is based on the phenomenon that the root length of the RSA vector at the earlier time point is shorter than that at the last time point. In other words, when CT scanning is performed at time point A and again at time point B for the same pot, the CT data and RSA vectors at time points A and B will almost overlap, but not where the roots have grown. We assumed that given a manually created RSA vector at the last time point of the time series, all RSA vectors except those at the last time point could be automatically predicted by referring to the corresponding RSA images. Using 21 time-series CT volumes of a potted plant of upland rice (Oryza sativa), this workflow revealed that the root elongation speed increased with age. Compared with a workflow that does not use backward prediction, the workflow with backward prediction reduced the manual labor time by 95%. Conclusions We developed a workflow to efficiently generate time-series RSA vectors from time-series X-ray CT volumes. We named this workflow 'RSAtrace4D' and are confident that it can be applied to the time-series analysis of RSA development and plasticity.

Published

2022

4. Four-dimensional measurement of root system development using time-series three-dimensional volumetric data analysis by backward prediction.

Author

Teramoto, Shota and Uga, Yusaku

Subjects

*VOLUMETRIC analysis, *ROOT development, *COMPUTED tomography, *SYSTEMS development, *UPLAND rice

Abstract

Background: Root system architecture (RSA) is an essential characteristic for efficient water and nutrient absorption in terrestrial plants; its plasticity enables plants to respond to different soil environments. Better understanding of root plasticity is important in developing stress-tolerant crops. Non-invasive techniques that can measure roots in soils nondestructively, such as X-ray computed tomography (CT), are useful to evaluate RSA plasticity. However, although RSA plasticity can be measured by tracking individual root growth, only a few methods are available for tracking individual roots from time-series three-dimensional (3D) images. Results: We developed a semi-automatic workflow that tracks individual root growth by vectorizing RSA from time-series 3D images via two major steps. The first step involves 3D alignment of the time-series RSA images by iterative closest point registration with point clouds generated by high-intensity particles in potted soils. This alignment ensures that the time-series RSA images overlap. The second step consists of backward prediction of vectorization, which is based on the phenomenon that the root length of the RSA vector at the earlier time point is shorter than that at the last time point. In other words, when CT scanning is performed at time point A and again at time point B for the same pot, the CT data and RSA vectors at time points A and B will almost overlap, but not where the roots have grown. We assumed that given a manually created RSA vector at the last time point of the time series, all RSA vectors except those at the last time point could be automatically predicted by referring to the corresponding RSA images. Using 21 time-series CT volumes of a potted plant of upland rice (Oryza sativa), this workflow revealed that the root elongation speed increased with age. Compared with a workflow that does not use backward prediction, the workflow with backward prediction reduced the manual labor time by 95%. Conclusions: We developed a workflow to efficiently generate time-series RSA vectors from time-series X-ray CT volumes. We named this workflow 'RSAtrace4D' and are confident that it can be applied to the time-series analysis of RSA development and plasticity. [ABSTRACT FROM AUTHOR]

Published

2022

5. Identification of a unique allele in the quantitative trait locus for crown root number in japonica rice from Japan using genome-wide association studies.

Author

Shota Teramoto, Masanori Yamasaki, and Yusaku Uga

Subjects

*LOCUS (Genetics), *GENOME-wide association studies, *CYCLIC nucleotide-gated ion channels, *ALLELES, *ALLELES in plants, *ION channels, *GERMPLASM, *PHENOTYPES

Abstract

To explore the genetic resources that could be utilized to help improve root system architecture phenotypes in rice (Oryza sativa), we have conducted genome-wide association studies to investigate maximum root length and crown root number in 135 10-day-old Japanese rice accessions grown hydroponically. We identified a quantitative trait locus for crown root number at approximately 32.7 Mbp on chromosome 4 and designated it qNCR1 (quantitative trait locus for Number of Crown Root 1). A linkage disequilibrium map around qNCR1 suggested that three candidate genes are involved in crown root number: a cullin (LOC_Os04g55030), a gibberellin 20 oxidase 8 (LOC_Os04g55070), and a cyclic nucleotide-gated ion channel (LOC_Os04g55080). The combination of haplotypes for each gene was designated as a haploblock, and haploblocks 1, 2, and 3 were defined. Compared to haploblock 1, the accessions with haploblocks 2 and 3 had fewer crown roots; approximately 5% and 10% reductions in 10-day-old plants and 15% and 25% reductions in 42-day-old plants, respectively. A Japanese leading variety Koshihikari and its progenies harbored haploblock 3. Their crown root number could potentially be improved using haploblocks 1 and 2. [ABSTRACT FROM AUTHOR]

Published

2022

6. Deep rooting development and growth in upland rice NERICA induced by subsurface irrigation

Author

Akira Miyazaki and Naoya Arita

Subjects

branching, deep rooting, nodal root, root diameter, subsurface irrigation, upland rice, Plant culture, SB1-1110

Abstract

Changes in root development and growth in upland rice receiving subsurface irrigation were evaluated using root box experiments. Irrigated water was independently applied every day to depths of 0, 5, 10 and 20 cm from the ground surface, and root morphology and aboveground growth were determined after 2 weeks of treatment. Plant length, stem number and leaf age significantly increased along with the irrigation depth, and the aboveground dry weights of rice grown at 5-, 10- and 20-cm depths were significantly greater than those grown at 0 cm. Root surface area significantly increased along with the irrigation depth, which was attributed to the increasing lengths and branch numbers of roots. Subsurface irrigation significantly increased root lengths in deep layers (below 15 cm) and increased the deep layers’ distribution ratios by 1.2 to 5.7 times as the surface layer ratio decreased. This was accompanied with a decrease in the root diameter. This may be associated with the increase in the numbers of branches and the decrease in the numbers of thick nodal roots. These results indicate that subsurface irrigation increases root length and branching in the deep soil layers, inducing deep rooting, even with same amount of irrigation.

Published

2020

7. Characterization of root traits for phosphorus deficiency tolerance using chromosome segment substitution lines.

Author

Yuki Akamatsu, Ryosuke Tajima, Toru Uno, Toyoaki Ito, Mizuhiko Nishida, and Masanori Saito

Subjects

*CHROMOSOMES, *SURFACE area, *PHOSPHORUS, *ROOT growth, *GENOTYPES, *RICE

Abstract

Phosphorus (P) acquisition, a key factor in rice productivity, is related to morphological and anatomical root traits. In this study, we examined the root traits of rice that contribute to P acquisition under low P conditions using chromosomal segment substitution lines (CSSLs) grown under nonflooded conditions. Rice plants were grown under low- and high-P conditions in a growth chamber. We tested 39 CSSLs and the parent varieties 'Sasanishiki' and 'Habataki.' Four out of the five selected genotypes from 39 CSSLs had larger root surface areas than that of Sasanishiki due to long fine root and/or coarse roots. The root surface area and shoot P uptake were significantly and positively correlated. Two of the genotypes had higher P use efficiency and shoot dry weight compared to that of Sasanishiki under low P conditions, and nodal root cross-sectional areas were larger in the two genotypes than in Sasanishiki under low P conditions. The root cortical aerenchyma in the nodal roots was well developed in all observed genotypes, which may have reduced the metabolic cost. These results suggest that the thick nodal roots with aerenchyma in contribution to the increase in root surface area are the advantage for growth under low P levels in non-flooded conditions. [ABSTRACT FROM AUTHOR]

Published

2022

8. Use of Transcriptomic Analyses to Elucidate the Mechanism Governing Nodal Root Development in Eremochloa ophiuroides (Munro) Hack.

Author

Rui Wang, Haoyan Zhao, Hailin Guo, Junqin Zong, Jianjian Li, Haoran Wang, Jianxiu Liu, and Jingjing Wang

Subjects

centipedegrass, nodal root, plant hormone, E3 ubiquitin-protein ligase, SINAT5, Plant culture, SB1-1110

Abstract

Centipedegrass [Eremochloa ophiuroides (Munro) Hack.] is a perennial warm-season grass that originated in China, and its speed of nodal rooting is important for lawn establishment. In our study, centipedegrass nodal rooting ability was limited by node aging. Transcriptome sequencing of nodal roots after 0, 2, 4, and 8 days of water culture was performed to investigate the molecular mechanisms of root development. GO enrichment and KEGG pathway analyses of DEGs indicated that plant hormone signal transduction and transcription factors might play important roles in centipedegrass nodal root growth. Among them, E3 ubiquitin-protein ligases participated in multiple hormone signal transduction pathways and interacted with transcription factors. Furthermore, an E3 ubiquitin protein ligase EoSINAT5 overexpressed in rice resulted in longer roots and more numerous root tips, while knockout of LOC_Os07g46560 (the homologous gene of EoSINAT5 in rice) resulted in shorter roots and fewer root tips. These results indicated that EoSINAT5 and its homologous gene are able to promote nodal root development. This research presents the transcriptomic analyses of centipedegrass nodal roots, and may contribute to elucidating the mechanism governing the development of nodal roots and facilitates the use of molecular breeding in improving rooting ability.

Published

2021

9. Use of Transcriptomic Analyses to Elucidate the Mechanism Governing Nodal Root Development in Eremochloa ophiuroides (Munro) Hack.

Author

Wang, Rui, Zhao, Haoyan, Guo, Hailin, Zong, Junqin, Li, Jianjian, Wang, Haoran, Liu, Jianxiu, and Wang, Jingjing

Subjects

ROOT development, UBIQUITIN ligases, UBIQUITINATION, PLANT hormones, TRANSCRIPTION factors, CELLULAR signal transduction

Abstract

Centipedegrass [ Eremochloa ophiuroides (Munro) Hack.] is a perennial warm-season grass that originated in China, and its speed of nodal rooting is important for lawn establishment. In our study, centipedegrass nodal rooting ability was limited by node aging. Transcriptome sequencing of nodal roots after 0, 2, 4, and 8 days of water culture was performed to investigate the molecular mechanisms of root development. GO enrichment and KEGG pathway analyses of DEGs indicated that plant hormone signal transduction and transcription factors might play important roles in centipedegrass nodal root growth. Among them, E3 ubiquitin-protein ligases participated in multiple hormone signal transduction pathways and interacted with transcription factors. Furthermore, an E3 ubiquitin protein ligase EoSINAT5 overexpressed in rice resulted in longer roots and more numerous root tips, while knockout of LOC_Os07g46560 (the homologous gene of EoSINAT5 in rice) resulted in shorter roots and fewer root tips. These results indicated that EoSINAT5 and its homologous gene are able to promote nodal root development. This research presents the transcriptomic analyses of centipedegrass nodal roots, and may contribute to elucidating the mechanism governing the development of nodal roots and facilitates the use of molecular breeding in improving rooting ability. [ABSTRACT FROM AUTHOR]

Published

2021

10. Genome-Wide Association Study on Seminal and Nodal Roots of Wheat Under Different Growth Environments

Author

Fengdan Xu, Shulin Chen, Xiwen Yang, Sumei Zhou, Xu Chen, Jie Li, Kehui Zhan, and Dexian He

Subjects

GWAS, grain yield, seminal root, wheat, nodal root, Plant culture, SB1-1110

Abstract

The root of wheat consists of seminal and nodal roots. Comparatively speaking, fewer studies have been carried out on the nodal root system because of its disappearance at the early seedling stage under indoor environments. In this study, 196 accessions from the Huanghuai Wheat Region (HWR) were used to identify the characteristics of seminal and nodal root traits under different growth environments, including indoor hydroponic culture (IHC), outdoor hydroponic culture (OHC), and outdoor pot culture (OPC), for three growing seasons. The results indicated that the variation range of root traits in pot environment was larger than that in hydroponic environment, and canonical coefficients were the greatest between OHC and OPC (0.86) than those in other two groups, namely, IHC vs. OPC (0.48) and IHC vs. OHC (0.46). Most root traits were negatively correlated with spikes per area (SPA), grains per spike (GPS), and grain yield (GY), while all the seminal root traits were positively correlated with thousand-kernel weight (TKW). Genome-wide association study (GWAS) was carried out on root traits by using a wheat 660K SNP array. A total of 35 quantitative trait loci (QTLs)/chromosomal segments associated with root traits were identified under OPC and OHC. In detail, 11 and 24 QTLs were significantly associated with seminal root and nodal root traits, respectively. Moreover, 13 QTLs for number of nodal roots per plant (NRP) containing 14 stable SNPs, were distributed on chromosomes 1B, 2B, 3A, 4B, 5D, 6D, 7A, 7B, and Un. Based on LD and bioinformatics analysis, these QTLs may contain 17 genes closely related to NRP. Among them, TraesCS2B02G552500 and TraesCS7A02G428300 were highly expressed in root tissues. Moreover, the frequencies of favorable alleles of these 14 SNPs were confirmed to be less than 70% in the natural population, suggesting that the utilization of these superior genes in wheat root is still improving.

Published

2021

11. Genome-Wide Association Study on Seminal and Nodal Roots of Wheat Under Different Growth Environments.

Author

Xu, Fengdan, Chen, Shulin, Yang, Xiwen, Zhou, Sumei, Chen, Xu, Li, Jie, Zhan, Kehui, and He, Dexian

Subjects

WHEAT, GRAIN yields, GROWING season, PLANT roots, CHROMOSOMES

Abstract

The root of wheat consists of seminal and nodal roots. Comparatively speaking, fewer studies have been carried out on the nodal root system because of its disappearance at the early seedling stage under indoor environments. In this study, 196 accessions from the Huanghuai Wheat Region (HWR) were used to identify the characteristics of seminal and nodal root traits under different growth environments, including indoor hydroponic culture (IHC), outdoor hydroponic culture (OHC), and outdoor pot culture (OPC), for three growing seasons. The results indicated that the variation range of root traits in pot environment was larger than that in hydroponic environment, and canonical coefficients were the greatest between OHC and OPC (0.86) than those in other two groups, namely, IHC vs. OPC (0.48) and IHC vs. OHC (0.46). Most root traits were negatively correlated with spikes per area (SPA), grains per spike (GPS), and grain yield (GY), while all the seminal root traits were positively correlated with thousand-kernel weight (TKW). Genome-wide association study (GWAS) was carried out on root traits by using a wheat 660K SNP array. A total of 35 quantitative trait loci (QTLs)/chromosomal segments associated with root traits were identified under OPC and OHC. In detail, 11 and 24 QTLs were significantly associated with seminal root and nodal root traits, respectively. Moreover, 13 QTLs for number of nodal roots per plant (NRP) containing 14 stable SNPs, were distributed on chromosomes 1B, 2B, 3A, 4B, 5D, 6D, 7A, 7B, and Un. Based on LD and bioinformatics analysis, these QTLs may contain 17 genes closely related to NRP. Among them, TraesCS2B02G552500 and TraesCS7A02G428300 were highly expressed in root tissues. Moreover, the frequencies of favorable alleles of these 14 SNPs were confirmed to be less than 70% in the natural population, suggesting that the utilization of these superior genes in wheat root is still improving. [ABSTRACT FROM AUTHOR]

Published

2021

12. Deep rooting development and growth in upland rice NERICA induced by subsurface irrigation.

Author

Miyazaki, Akira and Arita, Naoya

Subjects

SUBIRRIGATION, UPLAND rice, ROOT development, ROOT growth, IRRIGATION

Abstract

Changes in root development and growth in upland rice receiving subsurface irrigation were evaluated using root box experiments. Irrigated water was independently applied every day to depths of 0, 5, 10 and 20 cm from the ground surface, and root morphology and aboveground growth were determined after 2 weeks of treatment. Plant length, stem number and leaf age significantly increased along with the irrigation depth, and the aboveground dry weights of rice grown at 5-, 10- and 20-cm depths were significantly greater than those grown at 0 cm. Root surface area significantly increased along with the irrigation depth, which was attributed to the increasing lengths and branch numbers of roots. Subsurface irrigation significantly increased root lengths in deep layers (below 15 cm) and increased the deep layers' distribution ratios by 1.2 to 5.7 times as the surface layer ratio decreased. This was accompanied with a decrease in the root diameter. This may be associated with the increase in the numbers of branches and the decrease in the numbers of thick nodal roots. These results indicate that subsurface irrigation increases root length and branching in the deep soil layers, inducing deep rooting, even with same amount of irrigation. [ABSTRACT FROM AUTHOR]

Published

2020

13. Ectopic expression of ARGOS8 reveals a role for ethylene in root‐lodging resistance in maize.

Author

Shi, Jinrui, Drummond, Bruce J., Habben, Jeffrey E., Brugire, Norbert, Weers, Ben P., Hakimi, Salim M., Lafitte, H. Renee, Schussler, Jeffrey R., Mo, Hua, Beatty, Mary, Zastrow‐Hayes, Gina, and O'Neill, Dennis

Subjects

*CORN, *ETHYLENE, *PLANT development, *AMINOCYCLOPROPANECARBOXYLATE synthase, *GRAIN yields

Abstract

Summary: Ethylene plays a critical role in many diverse processes in plant development. Recent studies have demonstrated that overexpression of the maize ARGOS8 gene reduces the plant's response to ethylene by decreasing ethylene signaling and enhances grain yield in transgenic maize plants. The objective of this study was to determine the effects of ethylene on the development of nodal roots, which are primarily responsible for root‐lodging resistance in maize. Exogenous application of the ethylene precursor 1‐aminocyclopropane‐1‐carboxylic acid (ACC) was found to promote the emergence of nodal roots. Transcriptome analysis of nodal tissues revealed that the expression of genes involved in metabolic processes and cell wall biogenesis was upregulated in response to ACC treatment, supporting the notion that ethylene is a positive regulator for the outgrowth of young root primordia. In BSV::ARGOS8 transgenic plants with reduced ethylene sensitivity due to constitutive overexpression of ARGOS8, nodal root emergence was delayed and the promotional effect of ACC on nodal root emergence decreased. Field tests showed that the BSV::ARGOS8 plants had higher root lodging relative to non‐transgenic controls. When ARGOS8 expression was controlled by the developmentally regulated promoter FTM1, which conferred ARGOS8 overexpression in adult plants but not in the nodal roots and nodes in juvenile plants, the FTM1::ARGOS8 plants had no significant difference in root lodging compared with the wild type but produced a higher grain yield. These results suggest that ethylene has a role in promoting nodal root emergence and that a delay in nodal root development has a negative effect on root‐lodging resistance in maize. Significance Statement: Root‐lodging resistance is a critically important trait for high‐yield maize hybrids and has been selected in maize breeding programs over the past 100 years. In maize, the stem‐borne nodal roots are formed in the normal developmental process and play a major role in root‐lodging resistance. Using the ethylene precursor 1‐aminocyclopropane‐1‐carboxylic acid (ACC) and ARGOS8 transgenic plants which have reduced ethylene sensitivity, we found that ACC promotes nodal root emergence and that ARGOS8 transgenic plants have delayed nodal root development and increased root lodging. These results suggest a positive role for ethylene in root‐lodging resistance. These findings have applications in maize breeding for improved agronomic traits. [ABSTRACT FROM AUTHOR]

Published

2019

14. 冬小麦初生根与次生根形态、生理性状差异分析.

Author

臧贺藏, 王言景, 张 均, 李 丰, 卢红芳, and 贺德先

Abstract

Copyright of Journal of Henan Agricultural Sciences is the property of Editorial Board of Journal of Henan Agricultural Sciences and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2018

15. Root type is not an important driver of mycorrhizal colonisation in Brachypodium distachyon.

Author

Donn, Suzanne, Kawasaki, Akitomo, Delroy, Brendan, Chochois, Vincent, Watt, Michelle, and Powell, Jeff R.

Subjects

*MYCORRHIZAL plants, *BRACHYPODIUM, *PLANT breeding, *ENERGY crops, *PLANT roots, *SOIL microbiology

Abstract

Breeding for favourable root traits in food and energy crops should be considered in the context of interactions with soil biota, notably those that can increase the nutrient use efficiency of crops. Arbuscular mycorrhizal (AM) fungi can provide services to plants but a better understanding of the interactions between root traits and AM fungi is required to maximise these benefits. One source of intraspecific variation in root architecture is the allocation of resources to different root types. We hypothesized that different root types would have different traits and be colonised differently by AM fungi, either in the amount of colonisation or identity of colonisers. We studied communities colonising the seminal, coleoptile nodal and leaf nodal roots of seven Brachypodium distachyon accessions grown in three crop or pasture soils. Leaf nodal roots had low specific root length compared to coleoptile nodal and seminal roots, yet all three root types harboured similar AM fungal communities and levels of colonisation. Most of the variation in the AM fungal communities was explained by soil; significant proportions were explained by plant accession and root type but these effects were weak. Differential allocation of resources between root types is not a trait that could be selected to maximise beneficial interactions with AM fungi and we found no link between a root phenotypic trait (specific root length) and AM fungal colonisation. Accessions did vary in extent of colonisation by arbuscules, meaning B. distachyon may be a useful model to study mechanisms underlying the symbiotic interface and mycorrhizal growth response of cereals. [ABSTRACT FROM AUTHOR]

Published

2017

16. Developmental models to describe the relationships between shoot and root growth in rice

Author

Abe, J., Morita, S., Hagisawa, Y., and Box, James E., Jr., editor

Published

1998

17. Shootborne Roots — An Adaptive Organ for Plants of Sand Dunes

Author

Danin, Avinoam, Chu, Ernest H. Y., editor, Altman, Arie, editor, and Waisel, Yoav, editor

Published

1997

18. Commercial Importance of Adventitious Rooting to Agronomy

Author

Kovar, John L., Kuchenbuch, Rolf O., Chu, Ernest H. Y., editor, Davis, Tim D., editor, and Haissig, Bruce E., editor

Published

1994

19. Deep Rooting in Winter Wheat: Rooting Nodes of Deep Roots in Two Cultivars with Deep and Shallow Root Systems

Author

Hideki Araki and Morio Iijima

Subjects

Compacted soil layer, Deep root, Direction of root elongation, Nodal root, Root Depth Index, Seminal root, Triticum aestivum L, Vertical distribution of roots, Plant culture, SB1-1110

Abstract

Deep rooting of wheat has been suggested that it influences the tolerance to various environmental stresses. In this study, the nodes from which the deepest penetrated roots had emerged were examined in winter wheat. The wheat was grown in long tubes with or without mechanical stress and in large root boxes. The length and growth angle of each axile root were examined to analyze the difference in the vertical distribution of the roots between the two wheat cultivars, one with a deep and one with a shallow root system. In Shiroganekomugi, a Japanese winter wheat cultivar with a shallow root system, the rooting depths of the seminal and nodal roots decreased as the rooting nodes advanced acropetally. Six out of nine deepest roots were seminal root in the non-mechanical stress conditions. In Mutsubenkei, a Japanese winter wheat cultivar with a deep root system, grown in root boxes, not only the seminal roots but also the coleoptilar and the first nodal roots penetrated to a depth of more than 1.3 m in the root box, and became the deepest roots. In both cultivars, the seminal roots became the deepest roots under the mechanical stress conditions. There were no clear tendencies in the root growth angles among the rooting nodes in the wheat root system. This indicates that the length of the axile roots can explain the differences in the rooting depths among axile roots in a wheat root system. On the other hand, the axile roots of Mutsubenkei elongated significantly more vertically than those of Shiroganekomugi. This suggests that not only seminal but also nodal roots exhibit strong positive gravitropism and penetrate deeply in a cultivar with a deep root system. In wheat cultivars, it is likely that the extent of its Root Depth Index results partly from the gravitropic responses of both seminal and nodal roots.

Published

2001

20. Anatomy of Nodal Roots in Tropical Upland and Lowland Rice Varieties

Author

Motohiko Kondo, Albert Aguilar, Jun Abe, and Shigenori Morita

Subjects

Nodal root, Sclerenchyma, Upland rice, Xylem vessel, Plant culture, SB1-1110

Abstract

Nodal root anatomy was compared among twelve upland and lowland rice (Oryza sative L.) varieties with tropical origin which were grown in hydroponic culture and under field conditions. The traditional upland japonica varieties showed the largest diameter of root, stele, and xylem vessel followed by modern upland varieties. There was a clear varietal difference in the ratio of stele to root diameter, which was associated with the genetic group rather than with the ecosystems. The japonica varieties had a significantly larger stele diameter relative to the root diameter than indica and aus varieties. The indica and aus varieties displayed more xylem vessels per unit area of stele than the japonica varieties, but the diameter of xylem vessel was smaller. Equivalent xylem vessel diameter (De) was more dependent on the number of xylem in the indica varieties than in the japonica varieties. Distinctly different types of sclerenchyma anatomy were identified among the varieties. The development of sclerenchyma was classified into four different types based on thickening of cell wall in the outer cortical parenchyma and the number of sclerenchymatous cell layers. Like the xylem anatomy, the varietal differences in sclerenchyma development were more associated with genetic group rather than the ecotype. The japonica varieties had higher frequency of the types which have a doubled cell layer in sclerenchyma with thick cell wall than indica and aus. The difference among the genetic groups was nearly consistent across growing conditions, aerobic and submerged soils. These results indicated that sclerenchyma development is controlled by a genetic factor.

Published

2000

21. Dry Matter Production and Root System Development of Rice Cultivars under Fluctuating Soil Moisture

Author

Dionisio M. Bañoc, Akira Yamauchi, Akihiko Kamoshita, Len J. Wade, and Jose R. Pardales

Subjects

Drought, Lateral root, Nodal root, Oryza sativa L., Phenotypic plasticity, Root system, Soil moisture, Plant culture, SB1-1110

Abstract

Rice plants in the rainfed areas are mostly grown under fluctuating soil moisture. We examined responses in dry matter production, root development and water use to changing soil moisture in diverse rice cultivars. Rice plants were grown in polyvinyl chloride tubes under glasshouse conditions. Progressive drought right after planting greatly inhibited the shoot dry matter production, tiller development, nodal root development and water uptake in all cultivars tested. When the plants experienced soil submergence before being exposed to drought, all the cultivars exhibited higher dry matter production than their well-watered counterparts. Cultivar differences were clearly noted in the growth responses to rewatering after these plants were droughted. With well–watered control as basis, IRAT 109 and KDML 105 plants increased efficiency in converting available dry matter to increase their total root length by means of enhanced lateral root development. In the latter, however, the dry weight of roots also increased and so did root water uptake. In Dular, droughted plants did not show a clear response in terms of root development and water uptake to rewatering while its shoot growth was much more severely inhibited than the other cultivars. These findings suggest that phenotypic plasticity in the root system structure exhibited by promoted lateral root development and new nodal root production play a key role in the growth of rice under changing moisture level in the soil.

Published

2000

22. Use of Transcriptomic Analyses to Elucidate the Mechanism Governing Nodal Root Development in Eremochloa ophiuroides (Munro) Hack

Author

Jingjing Wang, Haoran Wang, Jianxiu Liu, Hailin Guo, Zong Junqin, Rui Wang, Haoyan Zhao, and Jianjian Li

Subjects

Molecular breeding, biology, centipedegrass, Plant culture, Plant Science, plant hormone, Eremochloa ophiuroides, biology.organism_classification, SB1-1110, Cell biology, Ubiquitin ligase, Transcriptome, nodal root, SINAT5, E3 ubiquitin-protein ligase, biology.protein, Plant hormone, Signal transduction, NODAL, Transcription factor, Original Research

Abstract

Centipedegrass [Eremochloa ophiuroides (Munro) Hack.] is a perennial warm-season grass that originated in China, and its speed of nodal rooting is important for lawn establishment. In our study, centipedegrass nodal rooting ability was limited by node aging. Transcriptome sequencing of nodal roots after 0, 2, 4, and 8 days of water culture was performed to investigate the molecular mechanisms of root development. GO enrichment and KEGG pathway analyses of DEGs indicated that plant hormone signal transduction and transcription factors might play important roles in centipedegrass nodal root growth. Among them, E3 ubiquitin-protein ligases participated in multiple hormone signal transduction pathways and interacted with transcription factors. Furthermore, an E3 ubiquitin protein ligase EoSINAT5 overexpressed in rice resulted in longer roots and more numerous root tips, while knockout of LOC_Os07g46560 (the homologous gene of EoSINAT5 in rice) resulted in shorter roots and fewer root tips. These results indicated that EoSINAT5 and its homologous gene are able to promote nodal root development. This research presents the transcriptomic analyses of centipedegrass nodal roots, and may contribute to elucidating the mechanism governing the development of nodal roots and facilitates the use of molecular breeding in improving rooting ability.

Published

2021

23. Genome-Wide Association Study on Seminal and Nodal Roots of Wheat Under Different Growth Environments

Author

Xiwen Yang, Fengdan Xu, Xu Chen, Sumei Zhou, Jie Li, Kehui Zhan, Shulin Chen, and Dexian He

Subjects

0106 biological sciences, 0301 basic medicine, Single-nucleotide polymorphism, Plant Science, Root system, lcsh:Plant culture, Quantitative trait locus, Biology, 01 natural sciences, 03 medical and health sciences, wheat, GWAS, lcsh:SB1-1110, Allele, Gene, Original Research, grain yield, food and beverages, biology.organism_classification, nodal root, Horticulture, seminal root, 030104 developmental biology, Natural population growth, Seedling, 010606 plant biology & botany, SNP array

Abstract

The root of wheat consists of seminal and nodal roots. Comparatively speaking, fewer studies have been carried out on the nodal root system because of its disappearance at the early seedling stage under indoor environments. In this study, 196 accessions from the Huanghuai Wheat Region (HWR) were used to identify the characteristics of seminal and nodal root traits under different growth environments, including indoor hydroponic culture (IHC), outdoor hydroponic culture (OHC), and outdoor pot culture (OPC), for three growing seasons. The results indicated that the variation range of root traits in pot environment was larger than that in hydroponic environment, and canonical coefficients were the greatest between OHC and OPC (0.86) than those in other two groups, namely, IHC vs. OPC (0.48) and IHC vs. OHC (0.46). Most root traits were negatively correlated with spikes per area (SPA), grains per spike (GPS), and grain yield (GY), while all the seminal root traits were positively correlated with thousand-kernel weight (TKW). Genome-wide association study (GWAS) was carried out on root traits by using a wheat 660K SNP array. A total of 35 quantitative trait loci (QTLs)/chromosomal segments associated with root traits were identified under OPC and OHC. In detail, 11 and 24 QTLs were significantly associated with seminal root and nodal root traits, respectively. Moreover, 13 QTLs for number of nodal roots per plant (NRP) containing 14 stable SNPs, were distributed on chromosomes 1B, 2B, 3A, 4B, 5D, 6D, 7A, 7B, and Un. Based on LD and bioinformatics analysis, these QTLs may contain 17 genes closely related to NRP. Among them, TraesCS2B02G552500 and TraesCS7A02G428300 were highly expressed in root tissues. Moreover, the frequencies of favorable alleles of these 14 SNPs were confirmed to be less than 70% in the natural population, suggesting that the utilization of these superior genes in wheat root is still improving.

Published

2021

24. Ectopic expression ofARGOS8reveals a role for ethylene in root-lodging resistance in maize

Author

Bruce J. Drummond, Norbert Brugire, Hua Mo, Jeffrey R. Schussler, Jinrui Shi, Mary Beatty, Ben P. Weers, Salim M. Hakimi, Jeffrey E. Habben, H. Renee Lafitte, Dennis O'Neill, and Gina Zastrow-Hayes

Subjects

ARGOS8, 0106 biological sciences, 0301 basic medicine, Ethylene, Plant Science, Genetically modified crops, Biology, maize, 01 natural sciences, Transcriptome, 03 medical and health sciences, chemistry.chemical_compound, ethylene, Genetics, Primordium, Genetically modified maize, grain yield, Wild type, food and beverages, Original Articles, Cell Biology, Cell biology, nodal root, 030104 developmental biology, root lodging, chemistry, Original Article, Ectopic expression, NODAL, 010606 plant biology & botany

Abstract

Summary Ethylene plays a critical role in many diverse processes in plant development. Recent studies have demonstrated that overexpression of the maize ARGOS8 gene reduces the plant's response to ethylene by decreasing ethylene signaling and enhances grain yield in transgenic maize plants. The objective of this study was to determine the effects of ethylene on the development of nodal roots, which are primarily responsible for root‐lodging resistance in maize. Exogenous application of the ethylene precursor 1‐aminocyclopropane‐1‐carboxylic acid (ACC) was found to promote the emergence of nodal roots. Transcriptome analysis of nodal tissues revealed that the expression of genes involved in metabolic processes and cell wall biogenesis was upregulated in response to ACC treatment, supporting the notion that ethylene is a positive regulator for the outgrowth of young root primordia. In BSV::ARGOS8 transgenic plants with reduced ethylene sensitivity due to constitutive overexpression of ARGOS8, nodal root emergence was delayed and the promotional effect of ACC on nodal root emergence decreased. Field tests showed that the BSV::ARGOS8 plants had higher root lodging relative to non‐transgenic controls. When ARGOS8 expression was controlled by the developmentally regulated promoter FTM1, which conferred ARGOS8 overexpression in adult plants but not in the nodal roots and nodes in juvenile plants, the FTM1::ARGOS8 plants had no significant difference in root lodging compared with the wild type but produced a higher grain yield. These results suggest that ethylene has a role in promoting nodal root emergence and that a delay in nodal root development has a negative effect on root‐lodging resistance in maize., Significance Statement Root‐lodging resistance is a critically important trait for high‐yield maize hybrids and has been selected in maize breeding programs over the past 100 years. In maize, the stem‐borne nodal roots are formed in the normal developmental process and play a major role in root‐lodging resistance. Using the ethylene precursor 1‐aminocyclopropane‐1‐carboxylic acid (ACC) and ARGOS8 transgenic plants which have reduced ethylene sensitivity, we found that ACC promotes nodal root emergence and that ARGOS8 transgenic plants have delayed nodal root development and increased root lodging. These results suggest a positive role for ethylene in root‐lodging resistance. These findings have applications in maize breeding for improved agronomic traits.

Published

2018

25. A flood-free period combined with early planting is required to sustain yield of pre-rice sweet sorghum (Sorghum bicolor L. Moench).

Author

Promkhambut, A., Polthanee, A., Akkasaeng, C., and Younger, A.

Subjects

*PLANTING, *SORGHUM, *CROP yields, *EFFECT of floods on plants, *HARVESTING, *SUCROSE, *PLANT stems, *WATERLOGGING (Soils)

Abstract

Understanding the responses of sweet sorghum to flooding and the characters associated with flooding tolerance may be a useful strategy for pre-rice production and help meet demand for biofuel feedstock. Three sweet sorghum genotypes (Bailey, Keller and Wray) and five flooding treatments including non-flooding control, continuous flooding extended from 30, 45, 60 and 75 days after emergence to harvest were conducted under greenhouse conditions. Flooding decreased leaf dry weight (22-60%), leaf area (10-70%), number of node per stalk (1-5%), shoot dry weight (5-20%) and stalk yield (2-22%) with highest reduction in 30 days after emergence flooding treatment. Flooding later than 30 days after emergence did not significantly affect shoot growth, yield and yield components. Brix value, sucrose content and total sugar content were not significantly affected. All studied cultivars had similar shoot growth response. Flooding induced development of roots in water; root length, root dry weight, nodal root and lateral root number and interconnection of aerenchyma spaces from roots in flooded soil to stalk base above water level but suppressed root growth in flooded soil. The acclimation traits were highest in Keller, flooding from 30 days after emergence but there was a lack of root development in 75 days after emergence flooding treatments. These findings indicate the effect of waterlogging on sweet sorghum growth and yield strongly depends on the growth stage at which it occurs. There were genetic variations in root morphological and anatomical responses to flooding of sweet sorghum. The development of nodal and lateral roots and aerenchyma formation from flooded plant parts to stalk bases above water level may distribute to flooding tolerance in sweet sorghum. Based on the results, a flood-free period of at least 30 days after emergence is required to sustain yield of pre-rice sweet sorghum and early planting is highly recommended. [ABSTRACT FROM AUTHOR]

Published

2011

26. Morphological and architectural development of root systems in sorghum and maize.

Author

Singh, Vijaya, van Oosterom, Erik J., Jordan, David R., Messina, Carlos D., Cooper, Mark, and Hammer, Graeme L.

Subjects

*PLANT-soil relationships, *PLANT-water relationships, *SOIL moisture, *SORGHUM, *CORN, *GERMINATION, *PLANT breeding, *PLANT roots, *DEVELOPMENTAL biology

Abstract

Root systems determine the capacity of a plant to access soil water and their architecture can influence adaptation to water-limited conditions. It may be possible to associate that architecture with root attributes of young plants as a basis for rapid phenotypic screening. This requires improved understanding of root system development. This study aimed to characterise the morphological and architectural development of sorghum and maize root systems by (i) clarifying the initiation and origin of roots at germination, and (ii) monitoring and quantifying the development of root systems in young plants. Three experiments were conducted with two maize and four sorghum hybrids. Sorghum produced a sole seminal (primary) root and coleoptile nodal roots emerged at the 4th–5th leaf stage, whereas maize produced 3–7 seminal (primary and scutellum) roots and coleoptile nodal roots emerged at the 2nd leaf stage. Genotypic variation in the flush angle and mean diameter of nodal roots was observed and could be considered a suitable target for large scale screening for root architecture in breeding populations. Because of the relatively late appearance of nodal roots in sorghum, such screening would require a small chamber system to grow plants until at least 6 leaves had fully expanded. [ABSTRACT FROM AUTHOR]

Published

2010

27. Identification of a unique allele in the quantitative trait locus for crown root number in japonica rice from Japan using genome-wide association studies.

Author

Teramoto S, Yamasaki M, and Uga Y

Abstract

To explore the genetic resources that could be utilized to help improve root system architecture phenotypes in rice ( Oryza sativa ), we have conducted genome-wide association studies to investigate maximum root length and crown root number in 135 10-day-old Japanese rice accessions grown hydroponically. We identified a quantitative trait locus for crown root number at approximately 32.7 Mbp on chromosome 4 and designated it qNCR1 ( quantitative trait locus for Number of Crown Root 1 ). A linkage disequilibrium map around qNCR1 suggested that three candidate genes are involved in crown root number: a cullin ( LOC_Os04g55030 ), a gibberellin 20 oxidase 8 ( LOC_Os04g55070 ), and a cyclic nucleotide-gated ion channel ( LOC_Os04g55080 ). The combination of haplotypes for each gene was designated as a haploblock, and haploblocks 1, 2, and 3 were defined. Compared to haploblock 1, the accessions with haploblocks 2 and 3 had fewer crown roots; approximately 5% and 10% reductions in 10-day-old plants and 15% and 25% reductions in 42-day-old plants, respectively. A Japanese leading variety Koshihikari and its progenies harbored haploblock 3. Their crown root number could potentially be improved using haploblocks 1 and 2., (Copyright © 2022 by JAPANESE SOCIETY OF BREEDING.)

Published

2022

28. Distribution of mineral nutrient from nodal roots of Trifolium repens: Genotypic variation in intra‐plant allocation of 32P and 45Ca.

Author

Lötscher, M. and Hay, M. J. M.

Subjects

*CALCIUM, *PLANT nutrients, *PLANT roots, *PHOSPHORUS, *WHITE clover, *DEFOLIATION

Abstract

To assess genotypic variability in nutrient supply of shoot branches, the distribution of 32P and 45Ca exported from a source nodal root (24‐h uptake period) was measured within a genotype of a large‐leaved (Kopu) and a small‐leaved (Tahora) cultivar of Trifolium repens. Source‐sink relationships of plants were modified by root severance, defoliation, and shade treatments. In control plants of both genotypes distribution of 32P and 45Ca closely followed the pathways that could be predicted from the known phyllotactic constraints on the vascular system. As such there was little allocation of radioisotopes (3.1% and 2.5% of exported 32P and 45Ca, respectively) from the source root to branches on the apposite side of the parent axis (far‐side branches). However, genotypic differences in nutrient allocation were apparent, when treatments were imposed to alter intra‐plant source‐sink relationships. In the large‐leaved genotype, the imposed treatments had minor effects on the allocation to far‐side branches: whereas, in the small‐leaved genotype, root severance and defoliation treatments increased lateral transport to far‐side branches to 30% (32P) and 10% (45Ca) of exported radioisotopes. Genotypes with low (8–9) and high (12–13) numbers of vascular bundles were selected from within the large‐leaved cultivar. Distribution of 32P was then measured after plants had been pre‐treated by removal of all far‐side roots two days prior to labelling. Genotypes with low vascular bundle number allocated 20% and those with high vascular bundle number 3.2% of exported 32P to far‐side branches. It was concluded (1) that genotypic variation exists within T. repens for potential to alter intra‐plant allocation of mineral nutrients, in response to treatments that modify source‐sink relationships within plants; and (2) that this variation is correlated with differences among genotypes in the organisation of the vasculature of their stolons. [ABSTRACT FROM AUTHOR]

Published

1996

29. Branch and root formation in Trifolium repens is influenced by the light environment of unfolded leaves.

Author

Lötscher, M. and Nösberger, J.

Abstract

In plagiotropic plants, axillary buds on the stolon can be exposed to low red:far-red (R:FR) ratios, while the leaves may be positioned in the uppermost layer of the sward where they are exposed to a high R:FR ratio. We tested whether the light environment of unfolded leaves influences outgrowth of the axillary buds and the formation of nodal roots of Trifolium repens. Single plants were grown in a growth cabinet with high photosynthetic photon flux rate (PPFR) and a high R:FR ratio (FHRH, control), low PPFR and high R:FR (FLRH) or low PPFR and low R:FR (FLRL). In an additional treatment (SS), only stolons were shaded so that developing leaves grew into light conditions similar to the control treatment. Neutral shading (FLRH) had a minor effect on branching and did not influence root formation. A reduction in the R:FR ratio (FLRL) significantly delayed the outgrowth of axillary buds so that, compared to the control plants, the percentage of branched phytomers was reduced by 43% on the parent axis and by 75% on primary branches. Furthermore, the number of nodal roots per plant was reduced by about 30%. When only the stolons were shaded (SS), the percentage of branched and rooted phytomers was similar to that of the control plants. Extension of petioles and leaves was very variable, increasing the values in the FLRL treatment at least 2.5-fold compared with the control plants. It was concluded that the light environment of the unfolded leaves had a significant influence on the regulation of the outgrowth of axillary buds and that the high plasticity in petiole growth allows the positioning of the leaves in a light environment conducive to the stimulation of branch outgrowth. [ABSTRACT FROM AUTHOR]

Published

1997

30. Inter-organ control of photosynthesis mediated by emerging nodal roots in young maize plants

Author

Ješco, Timotej, Brouwer, R., editor, Gašparíková, O., editor, Kolek, J., editor, and Loughman, B. C., editor

Published

1981

31. Absorption and transport of anions by different roots of Zea mays L.

Author

Holobradá, M., Mistrík, I., Kolek, J., Brouwer, R., editor, Gašparíková, O., editor, Kolek, J., editor, and Loughman, B. C., editor

Published

1981

32. Deep Rooting in Winter Wheat: Rooting Nodes of Deep Roots in Two Cultivars with Deep and Shallow Root Systems

Author

Morio Iijima and Hideki Araki

Subjects

Nodal root, Triticum aestivum L, Acclimatization, Compacted soil layer, Winter wheat, Gravitropism, Root system, lcsh:Plant culture, Biology, Plant Roots, lcsh:SB1-1110, Poaceae, Cultivar, Direction of root elongation, Root Depth Index, Seminal root, Triticum, Positive gravitropism, Agriculture, Deep root, Agronomy, Vertical distribution of roots, Stress conditions, Agronomy and Crop Science

Abstract

Deep rooting of wheat has been suggested that it influences the tolerance to various environmental stresses. In this study, the nodes from which the deepest penetrated roots had emerged were examined in winter wheat. The wheat was grown in long tubes with or without mechanical stress and in large root boxes. The length and growth angle of each axile root were examined to analyze the difference in the vertical distribution of the roots between the two wheat cultivars, one with a deep and one with a shallow root system. In Shiroganekomugi, a Japanese winter wheat cultivar with a shallow root system, the rooting depths of the seminal and nodal roots decreased as the rooting nodes advanced acropetally. Six out of nine deepest roots were seminal root in the non-mechanical stress conditions. In Mutsubenkei, a Japanese winter wheat cultivar with a deep root system, grown in root boxes, not only the seminal roots but also the coleoptilar and the first nodal roots penetrated to a depth of more than 1.3 m in the root box, and became the deepest roots. In both cultivars, the seminal roots became the deepest roots under the mechanical stress conditions. There were no clear tendencies in the root growth angles among the rooting nodes in the wheat root system. This indicates that the length of the axile roots can explain the differences in the rooting depths among axile roots in a wheat root system. On the other hand, the axile roots of Mutsubenkei elongated significantly more vertically than those of Shiroganekomugi. This suggests that not only seminal but also nodal roots exhibit strong positive gravitropism and penetrate deeply in a cultivar with a deep root system. In wheat cultivars, it is likely that the extent of its Root Depth Index results partly from the gravitropic responses of both seminal and nodal roots.

Published

2001

33. Anatomy of Nodal Roots in Tropical Upland and Lowland Rice Varieties

Author

Albert Aguilar, Motohiko Kondo, Jun Abe, and Shigenori Morita

Subjects

Nodal root, Oryza sativa, biology, fungi, Xylem, food and beverages, Upland rice, Anatomy, lcsh:Plant culture, Vascular bundle, Oryza, biology.organism_classification, Xylem vessel, Japonica, Sclerenchyma, Stele, Botany, parasitic diseases, lcsh:SB1-1110, Cultivar, Agronomy and Crop Science

Abstract

Nodal root anatomy was compared among twelve upland and lowland rice (Oryza sative L.) varieties with tropical origin which were grown in hydroponic culture and under field conditions. The traditional upland japonica varieties showed the largest diameter of root, stele, and xylem vessel followed by modern upland varieties. There was a clear varietal difference in the ratio of stele to root diameter, which was associated with the genetic group rather than with the ecosystems. The japonica varieties had a significantly larger stele diameter relative to the root diameter than indica and aus varieties. The indica and aus varieties displayed more xylem vessels per unit area of stele than the japonica varieties, but the diameter of xylem vessel was smaller. Equivalent xylem vessel diameter (De) was more dependent on the number of xylem in the indica varieties than in the japonica varieties. Distinctly different types of sclerenchyma anatomy were identified among the varieties. The development of sclerenchyma was classified into four different types based on thickening of cell wall in the outer cortical parenchyma and the number of sclerenchymatous cell layers. Like the xylem anatomy, the varietal differences in sclerenchyma development were more associated with genetic group rather than the ecotype. The japonica varieties had higher frequency of the types which have a doubled cell layer in sclerenchyma with thick cell wall than indica and aus. The difference among the genetic groups was nearly consistent across growing conditions, aerobic and submerged soils. These results indicated that sclerenchyma development is controlled by a genetic factor.

Published

2000

34. Dry Matter Production and Root System Development of Rice Cultivars under Fluctuating Soil Moisture

Author

Akira Yamauchi, Dionisio M. Banoc, Len J. Wade, J.R. Pardales, and Akihiko Kamoshita

Subjects

Nodal root, Drought, Root system, Lateral root, fungi, food and beverages, Tiller (botany), Phenotypic plasticity, Biology, lcsh:Plant culture, Agronomy, Dry weight, Dry matter, Oryza sativa L, lcsh:SB1-1110, Cultivar, Soil moisture, Water-use efficiency, Agronomy and Crop Science, Water content

Abstract

Rice plants in the rainfed areas are mostly grown under fluctuating soil moisture. We examined responses in dry matter production, root development and water use to changing soil moisture in diverse rice cultivars. Rice plants were grown in polyvinyl chloride tubes under glasshouse conditions. Progressive drought right after planting greatly inhibited the shoot dry matter production, tiller development, nodal root development and water uptake in all cultivars tested. When the plants experienced soil submergence before being exposed to drought, all the cultivars exhibited higher dry matter production than their well-watered counterparts. Cultivar differences were clearly noted in the growth responses to rewatering after these plants were droughted. With well–watered control as basis, IRAT 109 and KDML 105 plants increased efficiency in converting available dry matter to increase their total root length by means of enhanced lateral root development. In the latter, however, the dry weight of roots also increased and so did root water uptake. In Dular, droughted plants did not show a clear response in terms of root development and water uptake to rewatering while its shoot growth was much more severely inhibited than the other cultivars. These findings suggest that phenotypic plasticity in the root system structure exhibited by promoted lateral root development and new nodal root production play a key role in the growth of rice under changing moisture level in the soil.

Published

2000

35. トウモロコシの根数は多いほど良いのか

Author

Arima, Susumu

Subjects

Nodal root, Corn, T-R-ratio, Root pruning, Seminal root

Abstract

application/pdf, Article

Published

1998

36. Rate of differentiation and emergence of nodal maize roots

Author

Sylvain Pellerin, Station de recherches grandes cultures : Laboratoire de zoologie, and Institut National de la Recherche Agronomique (INRA)

Subjects

RACINE NODALE, NODAL ROOT, Field experiment, Soil Science, Sowing, Plant physiology, SYSTEME RACINAIRE, ROOT MORPHOLOGY, Plant Science, Root system, Biology, Horticulture, Linear relationship, Botany, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Poaceae, Primordium, Cultivar, ROOT SYSTEM

Abstract

The timing of root production is one of the parameters required for modelling the root system architecture. The objectives of this study are (1) to describe the rate of appearance of adventitious root primordia of maize and their rate of emergence out of the stem; (2) to test equations for the prediction of the rank of the phytomer on which root emergence occurs, in a wide range of field situations. Maize, cultivar Dea, was grown in controlled conditions and in the field in 1987, 1988, 1989 and 1991. Plants were regularly sampled and the following data were recorded: foliar stage, number of root primordia and number of emerged roots per phytomer. Root primordia were counted in transverse thin sections in the stem. At a single plant level, root primordia differentiation occurred sequentially on the successive phytomers, with no overlapping between two phytomers. The same was true for root emergence. Roots belonging to the same phytomer emerged at approximately the same time. At a plant population level, there was a linear relationship between the rank of the phytomer on which root primordia were differentiated and cumulated degree-days after sowing. A linear relationship was also observed between the rank of the phytomer on which roots were emerging and cumulated degree-days or foliar stage. In the range of field situations tested (several years, sowing dates and planting densities), both equations gave an accurate prediction of the timing of root emergence during the plant cycle.

Published

1993

37. Maize nodal root ramification: Absence of dormant primordia, root classification using histological parameters and consequences on sap conduction

Author

Jordan, Marie-Odile, Harada, Jiro, Bruchou, Claude, and Yamazaki, Koou

Published

1993

38. Effect of mutual shading on the emergence of nodal roots and the root/shoot ratio of maize

Author

Demotes-Mainard, Sabine and Pellerin, Sylvain

Published

1992

39. Maize nodal root ramification: Absence of dormant primordia, root classification using histological parameters and consequences on sap conduction

Author

Jiro Harada, Claude Bruchou, Koou Yamazaki, Marie-Odile Jordan, Unité de recherche Plantes et Systèmes de Culture Horticoles (PSH), and Institut National de la Recherche Agronomique (INRA)

Subjects

0106 biological sciences, Epidermis (botany), Ramification (botany), conduction abilities, Lateral root, [SDV.SA.AGRO]Life Sciences [q-bio]/Agricultural sciences/Agronomy, Soil Science, Xylem, 04 agricultural and veterinary sciences, Plant Science, Anatomy, Biology, 01 natural sciences, lateral root, nodal root, root diameter, Stele, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Primordium, Zea mays L, NODAL, [SDV.SA.HORT]Life Sciences [q-bio]/Agricultural sciences/Horticulture, 010606 plant biology & botany, Plant stem

Abstract

International audience; Maize plants grown in field conditions were used to describe the histological organisation of the nodal roots, those of their laterals, and also to test the presence of critical stages where the subsequent capability for growth and development of young laterals was determined irreversibly. The absence of undeveloped primordia, which stop their development before boring through the nodal mother-root epidermis, proved that the number of laterals could not be regulated between the differentiation and the emission stage. Cross sections performed on nodal roots beared by the internodes 2, 4 and 6 and their long (>3 cm) and short (

Published

1993