Your search keyword '"nodal root"' showing total 5 results

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

Author

Akira Miyazaki and Naoya Arita

Subjects

0106 biological sciences, 04 agricultural and veterinary sciences, lcsh:Plant culture, Upland rice, 01 natural sciences, subsurface irrigation, deep rooting, nodal root, upland rice, Agronomy, root diameter, branching, 040103 agronomy & agriculture, Subsurface irrigation, 0401 agriculture, forestry, and fisheries, Environmental science, lcsh:SB1-1110, Agronomy and Crop Science, 010606 plant biology & botany

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

2. 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

3. 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

4. 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

5. 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