Your search keyword '"acid soil"' showing total 6 results

1. High affinity promoter binding of STOP1 is essential for early expression of novel aluminum-induced resistance genes GDH1 and GDH2 in Arabidopsis.

Author

Tokizawa, Mutsutomo, Enomoto, Takuo, Ito, Hiroki, Wu, Liujie, Kobayashi, Yuriko, Mora-Macías, Javier, Armenta-Medina, Dagoberto, Iuchi, Satoshi, Kobayashi, Masatomo, Nomoto, Mika, Tada, Yasuomi, Fujita, Miki, Shinozaki, Kazuo, Yamamoto, Yoshiharu Y, Kochian, Leon V, and Koyama, Hiroyuki

Subjects

*GENES, *TOXICOLOGY of aluminum, *ARABIDOPSIS, *ARABIDOPSIS thaliana, *PROTEIN synthesis, *CELLULAR signal transduction, *ALUMINUM

Abstract

Malate efflux from roots, which is regulated by the transcription factor STOP1 (SENSITIVE-TO-PROTON-RHIZOTOXICITY1) and mediates aluminum-induced expression of ALUMINUM-ACTIVATED-MALATE-TRANSPORTER1 (AtALMT1), is critical for aluminum resistance in Arabidopsis thaliana. Several studies showed that AtALMT1 expression in roots is rapidly observed in response to aluminum; this early induction is an important mechanism to immediately protect roots from aluminum toxicity. Identifying the molecular mechanisms that underlie rapid aluminum resistance responses should lead to a better understanding of plant aluminum sensing and signal transduction mechanisms. In this study, we observed that GFP-tagged STOP1 proteins accumulated in the nucleus soon after aluminum treatment. The rapid aluminum-induced STOP1-nuclear localization and AtALMT1 induction were detected in the presence of a protein synthesis inhibitor, suggesting that post-translational regulation is involved in these events. STOP1 also regulated rapid aluminum-induced expression for other genes that carry a functional/high-affinity STOP1-binding site in their promoter, including STOP2 , GLUTAMATE-DEHYDROGENASE1 and 2 (GDH1 and 2). However STOP1 did not regulate Al resistance genes which have no functional STOP1-binding site such as ALUMINUM-SENSITIVE3 , suggesting that the binding of STOP1 in the promoter is essential for early induction. Finally, we report that GDH1 and 2 which are targets of STOP1, are novel aluminum-resistance genes in Arabidopsis. [ABSTRACT FROM AUTHOR]

Published

2021

2. HvHOX9, a novel homeobox leucine zipper transcription factor, positively regulates aluminum tolerance in Tibetan wild barley.

Author

Feng, Xue, Liu, Wenxing, Dai, Huaxin, Qiu, Yue, Zhang, Guoping, Chen, Zhong-Hua, and Wu, Feibo

Subjects

*LEUCINE zippers, *TRANSCRIPTION factors, *BARLEY, *ACID soils, *AGRICULTURAL productivity, *ZINC, *MOSAIC viruses

Abstract

Aluminum (Al) toxicity is the primary limiting factor of crop production on acid soils. Tibetan wild barley germplasm is a valuable source of potential genes for breeding barley with acid and Al tolerance. We performed microRNA and RNA sequencing using wild (XZ16, Al-tolerant; XZ61, Al-sensitive) and cultivated (Dayton, Al-tolerant) barley. A novel homeobox-leucine zipper transcription factor, HvHOX9 , was identified as a target gene of miR166b and functionally characterized. HvHOX9 was up-regulated by Al stress in XZ16 (but unchanged in XZ61 and Dayton) and was significantly induced only in root tip. Phylogenetic analysis showed that HvHOX9 is most closely related to wheat TaHOX9 and orthologues of HvHOX9 are present in the closest algal relatives of Zygnematophyceae. Barley stripe mosaic virus-induced gene silencing of HvHOX9 in XZ16 led to significantly increased Al sensitivity but did not affect its sensitivity to other metals and low pH. Disruption of HvHOX9 did not change Al concentration in the root cell sap, but led to more Al accumulation in root cell wall after Al exposure. Silencing of HvHOX 9 decreased H+ influx after Al exposure. Our findings suggest that miR166b /HvHOX9 play a critical role in Al tolerance by decreasing root cell wall Al binding and increasing apoplastic pH for Al detoxification in the root. [ABSTRACT FROM AUTHOR]

Published

2020

3. Rhizosheaths on wheat grown in acid soils: phosphorus acquisition efficiency and genetic control.

Author

James, Richard A., Weligama, Chandrakumara, Verbyla, Klara, Ryan, Peter R., Rebetzke, Gregory J., Rattey, Allan, Richardson, Alan E., and Delhaize, Emmanuel

Subjects

*WHEAT quality, *ROOT formation, *RHIZOSPHERE microbiology, *COMPOSITION of wheat, *ROOT hairs (Botany), *ACID soils

Abstract

Rhizosheaths comprise soil bound to roots, and in wheat (Triticum aestivum L.) rhizosheath size correlates with root hair length. The aims of this study were to determine the effect that a large rhizosheath has on the phosphorus (P) acquisition by wheat and to investigate the genetic control of rhizosheath size in wheat grown on acid soil. Near-isogenic wheat lines differing in rhizosheath size were evaluated on two acid soils. The soils were fertilized with mineral nutrients and included treatments with either low or high P. The same soils were treated with CaCO3 to raise the pH and detoxify Al3+. Genotypic differences in rhizosheath size were apparent only when soil pH was low and Al3+ was present. On acid soils, a large rhizosheath increased shoot biomass compared with a small rhizosheath regardless of P supply. At low P supply, increased shoot biomass could be attributed to a greater uptake of soil P, but at high P supply the increased biomass was due to some other factor. Generation means analysis indicated that rhizosheath size on acid soil was controlled by multiple, additive loci. Subsequently, a quantitative trait loci (QTL) analysis of an F6 population of recombinant inbred lines identified five major loci contributing to the phenotype together accounting for over 60% of the total genetic variance. One locus on chromosome 1D accounted for 34% of the genotypic variation. Genetic control of rhizosheath size appears to be relatively simple and markers based on the QTL provide valuable tools for marker assisted breeding. [ABSTRACT FROM AUTHOR]

Published

2016

4. Enhancing the aluminium tolerance of barley by expressing the citrate transporter genes SbMATE and FRD3.

Author

Gaofeng Zhou, Pereira, Jorge F., Delhaize, Emmanuel, Meixue Zhou, Magalhaes, Jurandir V., and Ryan, Peter R.

Subjects

*EFFECT of aluminum on plants, *AGRICULTURAL productivity, *GENE expression in plants, *CITRATES, *ACID soils, BARLEY genetics

Abstract

Malate and citrate efflux from root apices is a mechanism of Al3+ tolerance in many plant species. Citrate efflux is facilitated by members of the MATE (multidrug and toxic compound exudation) family localized to the plasma membrane of root cells. Barley (Hordeum vulgare) is among the most Al3+-sensitive cereal species but the small genotypic variation in tolerance that is present is correlated with citrate efflux via a MATE transporter named HvAACT1. This study used a biotechnological approach to increase the Al3+ tolerance of barley by transforming it with two MATE genes that encode citrate transporters: SbMATE is the major Al3+-tolerance gene from sorghum whereas FRD3 is involved with Fe nutrition in Arabidopsis. Independent transgenic and null T3 lines were generated for both transgenes. Lines expressing SbMATE showed Al3+-activated citrate efflux from root apices and greater tolerance to Al3+ toxicity than nulls in hydroponic and short-term soil trials. Transgenic lines expressing FRD3 exhibited similar phenotypes except citrate release from roots occurred constitutively. The Al3+ tolerance of these lines was compared with previously generated transgenic barley lines overexpressing the endogenous HvAACT1 gene and the TaALMT1 gene from wheat. Barley lines expressing TaALMT1 showed significantly greater Al3+ tolerance than all lines expressing MATE genes. This study highlights the relative efficacy of different organic anion transport proteins for increasing the Al3+ tolerance of an important crop species. [ABSTRACT FROM AUTHOR]

Published

2014

5. Rhizosheaths on wheat grown in acid soils: phosphorus acquisition efficiency and genetic control

Author

Alan Richardson, Chandrakumara Weligama, Richard A. James, Emmanuel Delhaize, Klara L. Verbyla, Peter R. Ryan, Gregory J. Rebetzke, and Allan R. Rattey

Subjects

0106 biological sciences, 0301 basic medicine, aluminum toxicity, Physiology, Population, Quantitative Trait Loci, Plant Science, Acid soil, Biology, Root hair, Quantitative trait locus, heritability, complex mixtures, 01 natural sciences, Plant Roots, 03 medical and health sciences, Soil, Nutrient, Soil pH, Genetic variation, genetics, rhizosheath, education, Triticum, education.field_of_study, food and beverages, Phosphorus, Heritability, Hydrogen-Ion Concentration, phosphorus acquisition efficiency, root hairs, 030104 developmental biology, Agronomy, Soil water, 010606 plant biology & botany, Research Paper

Abstract

Highlight Large rhizosheaths on wheat genotypes grown on acid soils improved the phosphorus acquisition efficiency compared with genotypes with small rhizosheaths. The rhizosheath trait was mapped to five major quantitative trait loci with largely additive genetic effect., Rhizosheaths comprise soil bound to roots, and in wheat (Triticum aestivum L.) rhizosheath size correlates with root hair length. The aims of this study were to determine the effect that a large rhizosheath has on the phosphorus (P) acquisition by wheat and to investigate the genetic control of rhizosheath size in wheat grown on acid soil. Near-isogenic wheat lines differing in rhizosheath size were evaluated on two acid soils. The soils were fertilized with mineral nutrients and included treatments with either low or high P. The same soils were treated with CaCO3 to raise the pH and detoxify Al3+. Genotypic differences in rhizosheath size were apparent only when soil pH was low and Al3+ was present. On acid soils, a large rhizosheath increased shoot biomass compared with a small rhizosheath regardless of P supply. At low P supply, increased shoot biomass could be attributed to a greater uptake of soil P, but at high P supply the increased biomass was due to some other factor. Generation means analysis indicated that rhizosheath size on acid soil was controlled by multiple, additive loci. Subsequently, a quantitative trait loci (QTL) analysis of an F6 population of recombinant inbred lines identified five major loci contributing to the phenotype together accounting for over 60% of the total genetic variance. One locus on chromosome 1D accounted for 34% of the genotypic variation. Genetic control of rhizosheath size appears to be relatively simple and markers based on the QTL provide valuable tools for marker assisted breeding.

Published

2016

6. Enhancing the aluminium tolerance of barley by expressing the citrate transporter genes SbMATE and FRD3.

Author

Zhou, Gaofeng, Pereira, Jorge F., Delhaize, Emmanuel, Zhou, Meixue, Magalhaes, Jurandir V., and Ryan, Peter R.

Subjects

*CELL membranes, *ALUMINUM in soils, *TRANSGENIC plants, *ACID soils, *ION transport (Biology), *PLANTS, BARLEY genetics

Abstract

The article discusses a research on enhancing Aluminum iron tolerance of Barley through expression of SbMATE (Sb-multidrug and toxic compound exudation) and FRD3 genes. The topics discussed include facilitation of citrate efflux in plant root cells, genetic aspects of aluminum sensitivity in Barley, and role of organic anion transport for increasing Aluminum ion transport. Also discussed is presence of Aluminum ions in acid soils and plasma membrane proteins of root cells.

Published

2014