Your search keyword '"Acid soil"' showing total 48 results

1. Comparative quantitative phosphoproteomic and parallel reaction monitoring analysis of soybean roots under aluminum stress identify candidate phosphoproteins involved in aluminum resistance capacity.

Author

He Y, Wang Z, Cui W, Zhang Q, Zheng M, Li W, Gao J, Yang Z, and You J

Subjects

Stress, Physiological, Phosphorylation, Glycine max drug effects, Glycine max metabolism, Glycine max genetics, Glycine max growth & development, Plant Roots metabolism, Plant Roots drug effects, Phosphoproteins metabolism, Phosphoproteins genetics, Aluminum toxicity, Plant Proteins metabolism, Plant Proteins genetics, Proteomics

Abstract

Aluminum (Al) toxicity adversely impacts soybean (Glycine max) growth in acidic soil. Reversible protein phosphorylation plays an important role in adapting to adverse environmental conditions by regulating multiple physiological processes including signal transduction, energy coupling and metabolism adjustment in higher plant. This study aimed to reveal the Al-responsive phosphoproteins to understand their putative function and involvement in the regulation of Al resistance in soybean root. We used immobilized metal affinity chromatography to enrich the key phosphoproteins from soybean root apices at 0, 4, or 24 h Al exposure. These phosphoproteins were detected using liquid chromatography-tandem mass spectrometry measurement, verified by parallel reaction monitoring (PRM), and functionally characterized via overexpression in soybean hairy roots. A total of 638 and 686 phosphoproteins were identified as differentially enriched between the 4-h and 0-h, and the 24-h and 0-h Al treatment comparison groups, respectively. Typically, the phosphoproteins involved in biological processes including cell wall modification, and RNA and protein metabolic regulation displayed patterns of decreasing enrichment (clusters 3, 5 and 6), however, the phosphoproteins involved in the transport and metabolic processes of various substrates, and signal transduction pathways showed increased enrichment after 24 h of Al treatment. The enrichment of phosphoproteins in organelle organization bottomed after 4 h of Al treatment (cluster 1). Next, we selected 26 phosphoproteins from the phosphoproteomic profiles, assessed their enrichment status using PRM, and detected enrichment patterns similar to those observed via phosphoproteomic analysis. Among them, 15 phosphoproteins were found to reduce the accumulation of Al and callose in Al-stressed soybean root apices when their corresponding genes were individually overexpressed in soybean hairy roots. In summary, the findings of this study facilitated a comprehensive understanding of the protein phosphorylation events involved in Al resistance responses and revealed some critical phosphoproteins that enhance Al resistance in soybean roots., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published

2024

2. Cadmium Minimization in Grains of Maize and Wheat Grown on Smelting-Impacted Land Ameliorated by Limestone.

Author

Sui F, Yang Y, Wu Y, Yan J, Fu H, Li C, Qin S, Wang L, Zhang W, Gao W, Liu H, and Zhao P

Abstract

Cadmium (Cd) contamination in agricultural soils has emerged as a significant concern, particularly due to its potential impact on plant-based food. Soil pH reductions can exacerbate Cd mobility, leading to excessive accumulation in crops. While liming has been demonstrated as an effective method to mitigate Cd accumulation in rice grains in acid soils of southern China, its efficacy in remediating acid soils in northern China remains unclear. In this study, a multi-year field experiment was conducted on farmland impacted by zinc ore smelting at coordinates of 33.92° N 112.46° E to investigate the use of limestone for controlling Cd accumulation in wheat and maize grains. The results indicated that applying 7.5 t ha -1 of limestone significantly raised the soil pH from 4.5 to 6.8 as anticipated. Different rates of limestone application (2.25, 4.45, and 7.50 t ha -1 ) reduced Cd bioavailability in the soil by 20-54%, and Cd accumulation in wheat grains by 5-38% and maize grains by 21-63%, without yield penalty. The remediation effects were sustained for at least 27 months, highlighting limestone as a promising ameliorant for smelting-affected farmland in northern China.

Published

2024

3. Comparative stress physiological analysis of aluminium stress tolerance of indigenous maize ( Zea mays L.) cultivars of eastern Himalaya.

Author

Bhukya N, Hazarika S, Rangappa K, Thakuria D, Narzari R, and Debnath S

Abstract

Yield potential of maize having distinct genetic diversity in Eastern Himalayan Region (EHR) hill ecologies is often limited by Al toxicity caused due to soil acidity. Stress physiological analysis of local check exposed to 0-300 μM Al under sand culture revealed that 150 μM Al as critical and 200 μM Al as tolerable limit. Increase in Al from 0 to 300 μM reduced total chlorophyll, carotenoids by 74.8 % and 44.7 % respectively and enhanced anthocyanin by 35.3 % whereas LA, SLW and SL have reduced by 81.3%, 21.3 % and 47.8 % respectively. R/S ratio was 51.0 and 13.7 % higher at lower Al levels (50 μM and 100 μM) and photosynthetic, transpiration rate and TDM were 62.5 %, 42.9 % and 78.6 % lower at higher Al (300 μM) as compared to control. TRL, RSA, RDW and RV at higher Al (300 μM) were 92.6 %, 98.7 %, 78.7 and 97.5 % lower over control respectively. Root and shoot Al and PUpE at higher Al (300 μM) was 194.0, 69.2 and 830 % higher whereas PUE decreased to 88.5 % over control. Evaluation of 31 indigenous maize cultivars at 0, 150, and 250 μM Al in sand culture, alongside tolerance scoring and assessment, revealed that Megha-9, Megha-10, and MZM-19 exhibits high Al tolerance, Megha-1, MZM-22, and MZM-42 demonstrated moderate tolerance, whereas Uruapara, Sublgarh, and BRL Para were identified as Al-sensitive. Stress physiological parameters like SDW, TDM, TRL, SL and LA contributed 46.02 % of variability to PC1, whereas A, RV, RSA, anthocyanin and Chlorophyll_b, contributed 13.56 % of variability to PC2. Highest values of CMS, SL, LP, LA, TRL and anthocyanin were recorded in cluster I having sensitive cultivars while highest CMS, SL, LA, LP, TRL and RSA were found in cluster II having moderately tolerant cultivars and highest mean values for TRL, RSA, LP, LA, CMS and SL were recorded in cluster III having highly Al stress tolerant cultivars. The traits viz., A, RV, RSA, anthocyanin and Chlorophyll_b, total chlorophyll and TDM were emanated as physio-morphological for assessing Al toxicity stress tolerance in Maize with high divergence values. Tolerant cultivars showing 63.4 % and 22.4 % higher anthocyanin at 150 μM Al and 250 μM Al than moderately tolerant one in acid soil experiment with increased root Al, shoot Al, root P and shoot P by 42.6 %, 11 %, 95.1 % and 34 % respectively were emerged as promising for novel maize improvement under acid soils of EHR., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2024 Published by Elsevier Ltd.)

Published

2024

4. Novel α-amino acid-like structure decorated biochar for heavy metal remediation in acid soil.

Author

Li S, Wen Y, Wang Y, Liu M, Su L, Peng Z, Zhou Z, and Zhou N

Subjects

Cadmium chemistry, Copper chemistry, Soil chemistry, Charcoal chemistry, Zinc, Amino Acids, Metals, Heavy analysis, Soil Pollutants analysis

Abstract

Neither chemical nor physical adsorption play well in heavy metals remediation in acid soil due to the competing behavior of abundant protons, where stable chelators that can be reused are of significant demand. Herein, biochar with abundant nitro and carboxyl groups is prepared, which can be assembled into self-supporting electrode. Under the catalyzation of electricity, the surface decorated -NO 2 on the biochar can be in situ transformed into -NH 2 . Combined with the carboxyl group that attached on the same carbon atom, a special α-amino acid-like structure modified biochar (α-AC@BC) can be successfully constructed. Due to the strong affinity between the α-amino acid-like ligand and heavy metals, this α-AC@BC exhibits high removal efficiencies of 83.41%, 80.94%, 92.54% and 77.05% for available copper, cadmium, lead and zinc respectively, even in a strong acid soil with low pH of 4. After four adsorption-desorption cycles, the α-AC@BC could still eliminate 83.88% of copper. The high adsorption energy among -NH 2 , -COOH and heavy metals (-2.99 eV for copper, -1.90 eV for lead, -1.30 eV for zinc and -0.91 eV for cadmium) could form steady coordination structure to guarantee a highly practical application potential of α-AC@BC in strong acid soil. This study provides a novel concept for the decontamination of multiple heavy metal polluted acid soil., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier B.V. All rights reserved.)

Published

2024

5. Nitrogen-enriched biochar co-compost for the amelioration of degraded tropical soil.

Author

Nain P, Purakayastha TJ, Sarkar B, Bhowmik A, Biswas S, Kumar S, Shukla L, Biswas DR, Bandyopadhyay KK, Agarwal BK, and Saha ND

Subjects

Nitrogen analysis, Charcoal chemistry, Soil chemistry, Composting

Abstract

Tropical soils are often deeply weathered and vulnerable to degradation having low pH and unfavorable Al/Fe levels, which can constrain crop production. This study aims to examine nitrogen-enriched novel biochar co-composts prepared from rice straw, maize stover, and gram residue in various mixing ratios of the biochar and their feedstock materials for the amelioration of acidic tropical soil. Three pristine biochar and six co-composts were prepared, characterized, and evaluated for improving the chemical and biological quality of the soil against a conventional lime treatment. The pH, cation exchange capacity (CEC), calcium carbonate equivalence (CCE) and nitrogen content of co-composts varied between 7.78-8.86, 25.3-30.5 cmol (p + ) kg -1 , 25.5-30.5%, and 0.81-1.05%, respectively. The co-compost prepared from gram residue biochar mixed with maize stover at a 1:7 dry-weight ratio showed the highest rise in soil pH and CEC, giving an identical performance with the lime treatment and significantly better effect ( p  < .05) than the unamended control. Agglomerates of calcite and dolomite in biochar co-composts, and surface functional groups contributed to pH neutralization and increased CEC of the amended soil. The co-composts also significantly ( p  < .05) increased the dehydrogenase (1.87 µg TPF g -1 soil h -1 ), β-glucosidase (90 µg PNP g -1 soil h -1 ), and leucine amino peptidase (3.22 µmol MUC g -1 soil h -1 ) enzyme activities in the soil, thereby improving the soil's biological quality. The results of this study are encouraging for small-scale farmers in tropical developing countries to sustainably reutilize crop residues via biochar-based co-composting technology.

Published

2024

6. GmRj2/Rfg1 control of soybean-rhizobium-soil compatibility.

Author

Wang Z, Han Q, and Ji H

Subjects

Soil, Symbiosis genetics, Soil Microbiology, Glycine max genetics, Rhizobium

Abstract

Coordinated evolution and mutual adaptation of soybean-rhizobium-soil (SRS) are crucial for soybean distribution, but the genetic mechanism involved had remained unclear. In a recent study, Li et al. identified a natural variant of the GmRj2/Rfg1 gene that affected the ability of soybean to adapt to distinct soil types by controlling soybean-rhizobium interaction, thus unravelling the mystery of SRS compatibility., Competing Interests: Declaration of interests No interests are declared., (Copyright © 2023 Elsevier Ltd. All rights reserved.)

Published

2024

7. The biomineralization of silica induced stress tolerance in plants: a case study for aluminum toxicity.

Author

Feng Y, Han H, Nong W, Tang J, Chen X, Li X, Shi L, Kreslavski VD, Allakhverdiev SI, Shabala S, Shi W, and Yu M

Subjects

Aluminum toxicity, Biomineralization, Cell Cycle, Soil, Silicon Dioxide, Silicon pharmacology

Abstract

Biomineralization in plant roots refers to the process of cell-induced self-assembly to form nanostructures on the root surface. Silicon (Si) is the second most abundant element in soils, and beneficial to plant growth. Meanwhile, silicon is shown to participate in the process of biomineralization, which is useful for improving mechanical strength and alleviating biotic and abiotic stress, for example silicic acid polymerizes to form amorphous silica (SiO 2 -nH 2 O) in the process of growing to resist fungi and environmental stress. This process alters physical and chemical properties of cell wall. However, the mechanistic basis of this process remains unclear. Aluminum toxicity is a major constraint affecting plant performance in acid soil. This paper summarizes recent research advances in the field of plant biomineralization and describes the effects of silicon biomineralization on plant aluminum tolerance and its adaptive significance, using aluminum toxicity as a case study.

Published

2023

8. Involvement of the 4-coumarate:coenzyme A ligase 4CL4 in rice phosphorus acquisition and rhizosphere microbe recruitment via root growth enlargement.

Author

Xiao X, Hu AY, Dong XY, Shen RF, and Zhao XQ

Subjects

Fertilizers, Plant Breeding, Soil, Coenzyme A Ligases genetics, Oryza genetics, Phosphorus, Rhizosphere

Abstract

Main Conclusion: The 4-coumarate:coenzyme A ligase 4CL4 is involved in enhancing rice P acquisition and use in acid soil by enlarging root growth and boosting functional rhizosphere microbe recruitment. Rice (Oryza sativa L.) cannot easily acquire phosphorus (P) from acid soil, where root growth is inhibited and soil P is fixed. The combination of roots and rhizosphere microbiota is critical for plant P acquisition and soil P mobilization, but the associated molecular mechanism in rice is unclear. 4CL4/RAL1 encodes a 4-coumarate:coenzyme A ligase related to lignin biosynthesis in rice, and its dysfunction results in a small rice root system. In this study, soil culture and hydroponic experiments were conducted to examine the role of RAL1 in regulating rice P acquisition, fertilizer P use, and rhizosphere microbes in acid soil. Disruption of RAL1 markedly decreased root growth. Mutant rice plants exhibited decreased shoot growth, shoot P accumulation, and fertilizer P use efficiency when grown in soil-but not under hydroponic conditions, where all P is soluble and available for plants. Mutant ral1 and wild-type rice rhizospheres had distinct bacterial and fungal community structures, and wild-type rice recruited some genotype-specific microbial taxa associated with P solubilization. Our results highlight the function of 4CL4/RAL1 in enhancing rice P acquisition and use in acid soil, namely by enlarging root growth and boosting functional rhizosphere microbe recruitment. These findings can inform breeding strategies to improve P use efficiency through host genetic manipulation of root growth and rhizosphere microbiota., (© 2023. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2023

9. Estimating lime requirements for tropical soils: Model comparison and development.

Author

Aramburu Merlos F, Silva JV, Baudron F, and Hijmans RJ

Abstract

Acid tropical soils may become more productive when treated with agricultural lime, but optimal lime rates have yet to be determined in many tropical regions. In these regions, lime rates can be estimated with lime requirement models based on widely available soil data. We reviewed seven of these models and introduced a new model (LiTAS). We evaluated the models' ability to predict the amount of lime needed to reach a target change in soil chemical properties with data from four soil incubation studies covering 31 soil types. Two foundational models, one targeting acidity saturation and the other targeting base saturation, were more accurate than the five models that were derived from them, while the LiTAS model was the most accurate. The models were used to estimate lime requirements for 303 African soil samples. We found large differences in the estimated lime rates depending on the target soil chemical property of the model. Therefore, an important first step in formulating liming recommendations is to clearly identify the soil property of interest and the target value that needs to be reached. While the LiTAS model can be useful for strategic research, more information on acidity-related problems other than aluminum toxicity is needed to comprehensively assess the benefits of liming., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2023 The Author(s).)

Published

2023

10. Biochar application can mitigate NH 3 volatilization in acidic forest and upland soils but stimulates gaseous N losses in flooded acidic paddy soil.

Author

Chu C, Dai S, Meng L, Cai Z, Zhang J, and Müller C

Subjects

Gases, Volatilization, Charcoal, Nitrogen, Forests, Fertilizers, Soil, Oryza

Abstract

Biochar (BC) has attracted attention for carbon sequestration, a strategy to mitigate climate change and alleviate soil acidification. Most meta-analyses have insufficiently elaborated the effects of BC on soil N transformation so the practical importance of BC could not be assessed. In this study, a 15 N tracing study was conducted to investigate the effects of BC amendment on soil gross N transformations in acidic soils with different land-use types. The results show that the BC amendment accelerated the soil gross mineralization rate of labile organic N to NH 4 + (M Nlab ) (3 %-128 %) which was associated with an increase in total nitrogen. BC mitigated NH 3 volatilization (V NH3 ) (52 %-99 %) in upland and forest soils due to NH 4 + /NH 3 adsorption, while it caused higher gaseous N losses (NH 3 and N 2 O) in flooded paddy soils. An important function was the effect of BC addition on NH 4 + oxidation (O NH4 ). While O NH4 increased (4 %-19 %) in upland soils, it was inhibited (34 %-71 %) in paddy soils and did not show a response in forest soils. Overall, the BC amendment reduced the potential risk of N loss (P RL ), especially in forest soils (82 %-98 %). This study also shows that the BC effect on soil N cycling is land-use specific. The suitability of practices including BC hinges on the effects on gaseous N losses., Competing Interests: Declaration of competing interest The authors declare that the paper is being submitted for consideration for publication in Science of the Total Environment and that the content has not been published or submitted for publication elsewhere, in whole or in part, in any language. All authors have contributed significantly, and all authors are in agreement with the content of the manuscript. The authors have no relevant financial or non-financial interests to disclose., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published

2023

11. Deciphering Interactions between Phosphorus Status and Toxic Metal Exposure in Plants and Rhizospheres to Improve Crops Reared on Acid Soil.

Author

Wang X, Ai S, and Liao H

Subjects

Cadmium toxicity, Cadmium metabolism, Rhizosphere, Crops, Agricultural, Manganese metabolism, Aluminum toxicity, Soil, Phosphorus metabolism

Abstract

Acid soils are characterized by deficiencies in essential nutrient elements, oftentimes phosphorus (P), along with toxicities of metal elements, such as aluminum (Al), manganese (Mn), and cadmium (Cd), each of which significantly limits crop production. In recent years, impressive progress has been made in revealing mechanisms underlying tolerance to high concentrations of Al, Mn, and Cd. Phosphorus is an essential nutrient element that can alleviate exposure to potentially toxic levels of Al, Mn, and Cd. In this review, recent advances in elucidating the genes responsible for the uptake, translocation, and redistribution of Al, Mn, and Cd in plants are first summarized, as are descriptions of the mechanisms conferring resistance to these toxicities. Then, literature highlights information on interactions of P nutrition with Al, Mn, and Cd toxicities, particularly possible mechanisms driving P alleviation of these toxicities, along with potential applications for crop improvement on acid soils. The roles of plant phosphate (Pi) signaling and associated gene regulatory networks relevant for coping with Al, Mn, and Cd toxicities, are also discussed. To develop varieties adapted to acid soils, future work needs to further decipher involved signaling pathways and key regulatory elements, including roles fulfilled by intracellular Pi signaling. The development of new strategies for remediation of acid soils should integrate the mechanisms of these interactions between limiting factors in acid soils.

Published

2023

12. Combined de novo transcriptomic and physiological analyses reveal RyALS3-mediated aluminum tolerance in Rhododendron yunnanense Franch.

Author

Xu YX, Lei YS, Huang SX, Zhang J, Wan ZY, Zhu XT, and Jin SH

Abstract

Rhododendron (Ericaceae) not only has ornamental value, but also has great medicinal and edible values. Many Rhododendron species are native to acid soils where aluminum (Al) toxicity limits plant productivity and species distribution. However, it remains unknown how Rhododendron adapts to acid soils. Here, we investigated the physiological and molecular mechanisms of Al tolerance in Rhododendron yunnanense Franch. We found that the shoots of R. yunnanense Franch did not accumulate Al after exposure of seedlings to 50 μM Al for 7 days but predominantly accumulated in roots, suggesting that root Al immobilization contributes to its high Al tolerance. Whole-genome de novo transcriptome analysis was carried out for R. yunnanense Franch root apex in response to 6 h of 50 μM Al stress. A total of 443,639 unigenes were identified, among which 1,354 and 3,413 were up- and down-regulated, respectively, by 6 h of 50 μM Al treatment. Both Gene Ontology (GO) enrichment and the Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analyses revealed that genes involved in "ribosome" and "cytoskeleton" are overrepresented. Additionally, we identified Al-tolerance homologous genes including a tonoplast-localized ABC transporter RyALS3; 1. Overexpression of RyALS3; 1 in tobacco plants confers transgenic plants higher Al tolerance. However, root Al content was not different between wild-type plants and transgenic plants, suggesting that RyALS3; 1 is responsible for Al compartmentalization within vacuoles. Taken together, integrative transcriptome, physiological, and molecular analyses revealed that high Al tolerance in R. yunnanense Franch is associated with ALS3; 1-mediated Al immobilization in roots., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Xu, Lei, Huang, Zhang, Wan, Zhu and Jin.)

Published

2022

13. Chlorophyll Fluorescence Imaging as a Tool for Evaluating Disease Resistance of Common Bean Lines in the Western Amazon Region of Colombia.

Author

Suárez JC, Vanegas JI, Contreras AT, Anzola JA, Urban MO, Beebe SE, and Rao IM

Abstract

The evaluation of disease resistance is considered an important aspect of phenotyping for crop improvement. Identification of advanced lines of the common bean with disease resistance contributes to improved grain yields. This study aimed to determine the response of the photosynthetic apparatus to natural pathogen infection by using chlorophyll (Chl a ) fluorescence parameters and their relationship to the agronomic performance of 59 common bean lines and comparing the photosynthetic responses of naturally infected vs. healthy leaves. The study was conducted over two seasons under acid soil and high temperature conditions in the western Amazon region of Colombia. A disease susceptibility index (DSI) was developed and validated using chlorophyll a (Chl a ) fluorescence as a tool to identify Mesoamerican and Andean lines of common bean ( Phaseolus vulgaris L.) that are resistant to pathogens. A negative effect on the functional status of the photosynthetic apparatus was found with the presence of pathogen infection, a situation that allowed the identification of four typologies based on the DSI values ((i) moderately resistant; (ii) moderately susceptible; (iii) susceptible; and (iv) highly susceptible). Moderately resistant lines, five of them from the Mesoamerican gene pool (ALB 350, SMC 200, BFS 10, SER 16, SMN 27) and one from the Andean gene pool (DAB 295), allocated a higher proportion of energy to photochemical processes, which increased the rate of electron transfer resulting in a lower sensitivity to disease stress. This photosynthetic response was associated with lower values of DSI, which translated into an increase in the accumulation of dry matter accumulation in different plant organs (leaves, stem, pods and roots). Thus, DSI values based on chlorophyll fluorescence response to pathogen infection could serve as a phenotyping tool for evaluating advanced common bean lines. Six common bean lines (ALB 350, BFS 10, DAB 295, SER 16, SMC 200 and SMN 27) were identified as less sensitive to disease stress under field conditions in the western Amazon region of Colombia, and these could serve as useful parents for improving the common bean for multiple stress resistance.

Published

2022

14. pH-Dependent mitigation of aluminum toxicity in pea (Pisum sativum) roots by boron.

Author

Yang G, Qu M, Xu G, Li Y, Li X, Feng Y, Xiao H, He Y, Shabala S, Demidchik V, Liu J, and Yu M

Subjects

Hydrogen-Ion Concentration, Pisum sativum, Plant Roots physiology, Aluminum toxicity, Boron toxicity

Abstract

Boron (B) deficiency and aluminum (Al) toxicity are two major constraints on plants grown in acidic soils. B supply mitigates Al toxicity; however, the underlying mechanisms of this process remain elusive. In this work, Pisum sativum plants were used to address this issue. In the absence of pH buffers, B supply had a better mitigation effect on Al-induced root inhibition at pH 4.0 than pH 4.8. However, in MES buffered solution, mitigating effects of B on Al-induced root inhibition were more pronounced at pH 4.8, indicating a strong pH dependency of this process. Quantification of pH-dependent accumulation of Al in various root zones, modification of root pH by an exogenous addition of rapid alkalization factor (RALF), and measuring changes in the rhizosphere pH by fluorescent dyes have revealed operation of two concurrent mechanisms to explain alleviation of the inhibition of root elongation induced by Al toxicity by boron: (1) via enhancing rhizosphere pH under strong acidic stress (pH4.0), and (2) via stabilizing of cell wall by cross-linking with RGII at relatively higher pH (4.8). These findings provide scientific basis and support for the application of B fertilizers in the regions with inherited soil acidity., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published

2022

15. Microbial keystone taxa drive crop productivity through shifting aboveground-belowground mineral element flows.

Author

Wang JL, Liu KL, Zhao XQ, Gao GF, Wu YH, and Shen RF

Subjects

Agriculture, Minerals, Soil, Fertilizers analysis, Soil Microbiology

Abstract

Unbalanced fertilization of nutritional elements is a potential threat to environmental quality and agricultural productivity in acid soil. Harnessing keystone taxa in soil microbiome represents a promising strategy to enhance crop productivity as well as reducing the adverse environmental effects of fertilizers, with the goal of agricultural sustainability. However, there is a lack of information on which and how soil microbial keystone taxa contribute to sustainable crop productivity in acid soil. Here, we examined soil microbial communities (including bacteria, fungi, and archaea) and soil nutrients, and the mineral nutrition and yield of maize subjected to different inorganic and organic fertilization treatments over 35 years in acid soil. The application of organic fertilizer alone or in combination with inorganic fertilizers sustained high maize yield when compared with the other fertilization treatments. Microbial abundances and community structures rather than their alpha diversities explained the main variation in maize yield among different treatments. Sixteen soil keystone taxa (a fungal operational taxonomic unit and 15 bacterial operational taxonomic units) were identified from the microbial co-occurrence network. Among them, five keystone taxa (in Hypocreales, Bryobacter, Solirubrobacterales, Thermomicrobiales, and Roseiflexaceae) contributed to high maize yield through increasing phosphorus flow and inhibiting toxic aluminum and manganese flow from soils to plants. However, the remaining eleven keystone taxa (in Conexibacter, Acidothermus, Ktedonobacteraceae, Deltaproteobacteria, Actinobacteria, Elsterales, Ktedonobacterales, and WPS-2) exerted the opposite effects. As a result, maize productivity varied among different fertilization treatments because of the altered maize mineral element flows by microbial keystone taxa. We conclude that microbial keystone taxa drive crop productivity through shifting aboveground-belowground mineral element flows in acid soil. This study highlights the importance of microbial keystone taxa for sustainable crop productivity in acid soil and provides deep insights into the relationships between soil microbial keystone taxa, crop mineral nutrition, and productivity., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2022

16. Diversity of Native Arbuscular Mycorrhiza Extraradical Mycelium Influences Antioxidant Enzyme Activity in Wheat Grown Under Mn Toxicity.

Author

Faria JMS, Pinto AP, Teixeira D, Brito I, and Carvalho M

Subjects

Ascorbate Peroxidases metabolism, Mycelium metabolism, Triticum metabolism, Antioxidants metabolism, Mycorrhizae metabolism

Abstract

Sustainable agricultural practices based on the development of native arbuscular mycorrhizal fungi (AMF) can improve crop growth and stress tolerance in acidic soils with manganese toxicity. The beneficial effects are stronger when crops are colonized early in development by an intact extraradical mycelium (ERM), but are dependent on AMF assemblage. In wheat colonized by AMF associated to Lolium rigidum L. (LOL) or Ornithopus compressus (ORN), growth and stress tolerance are differently influenced. In the present study, this functional diversity was studied by evaluating the activity of ascorbate peroxidase (APX), catalase (CAT), glutathione reductase (GR), guaiacol peroxidase (GPX), superoxide dismutase (SOD) and Mn-SOD. ORN treatment promoted higher wheat shoot and root dry weights, a higher root protein content, decreased root APX, GR and SOD activities but a higher proportion of MnSOD activity. ORN associated microbiota differently manage antioxidant enzyme activity of succeeding wheat to improve growth., (© 2021. The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2022

17. Water Use, Leaf Cooling and Carbon Assimilation Efficiency of Heat Resistant Common Beans Evaluated in Western Amazonia.

Author

Suárez JC, Urban MO, Contreras AT, Noriega JE, Deva C, Beebe SE, Polanía JA, Casanoves F, and Rao IM

Abstract

In our study, we analyzed 30years of climatological data revealing the bean production risks for Western Amazonia. Climatological profiling showed high daytime and nighttime temperatures combined with high relative humidity and low vapor pressure deficit. Our understanding of the target environment allows us to select trait combinations for reaching higher yields in Amazonian acid soils. Our research was conducted using 64 bean lines with different genetic backgrounds. In high temperatures, we identified three water use efficiency typologies in beans based on detailed data analysis on gasometric exchange. Profligate water spenders and not water conservative accessions showed leaf cooling, and effective photosynthate partitioning to seeds, and these attributes were found to be related to higher photosynthetic efficiency. Thus, water spenders and not savers were recognized as heat resistant in acid soil conditions in Western Amazonia. Genotypes such as BFS 10, SEN 52, SER 323, different SEFs (SEF 73, SEF 10, SEF 40, SEF 70), SCR 56, SMR 173, and SMN 99 presented less negative effects of heat stress on yield. These genotypes could be suitable as parental lines for improving dry seed production. The improved knowledge on water-use efficiency typologies can be used for bean crop improvement efforts as well as further studies aimed at a better understanding of the intrinsic mechanisms of heat resistance in legumes., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Suárez, Urban, Contreras, Noriega, Deva, Beebe, Polanía, Casanoves and Rao.)

Published

2021

18. Application of measuring electrochemical characteristics on plant root surfaces in screening Al-tolerant wheat.

Author

Dong G, Lu HL, Pan XY, He X, Jiang J, Li JY, and Xu RK

Subjects

Aluminum toxicity, Plant Roots, Soil, Soil Pollutants, Triticum

Abstract

To explore the relationship between Al phytotoxicity and the electrochemical characteristics of wheat root surfaces, a new chemical mechanism for tolerance of wheat to Al toxicity was initially proposed by conducting acute root elongation experiment, adsorption/desorption experiment, streaming potential determination, and infrared spectroscopy (ATR-FTIR) analysis respectively to classify the grade of Al tolerance of 92 wheat cultivars and quantitatively characterize the electrochemical properties of their root surfaces. Then a pot experiment was conducted with the screened wheat cultivars with different Al resistance grown on acid soils to verify their tolerance to Al toxicity. Results show that zeta potentials of the roots of 67 wheat cultivars at pH4.46 were significantly negatively correlated with Al(Ⅲ) adsorbed on the roots and their relative root elongation (P < 0.05), indicating that wheat roots with less negative charges is more tolerant to Al toxicity. Based on the mechanism, 14 Al-tolerant, 23 medium Al-tolerant and 30 Al-sensitive wheat cultivars were classified. The pot experiment reveals that the relative dry weight of Al-tolerant wheat cultivars was generally greater than that of medium Al-tolerant and Al-sensitive wheat cultivars and Al-tolerant wheat cultivars accumulate less Al in their shoots, which further verifies the relationship among charge characteristics, tolerance of wheat to Al toxicity, and Al uptake by wheat. The negative charges derived from organic functional groups on root surfaces could influence the exchangeable and complexed Al(Ⅲ) adsorbed on wheat roots and thereby affect Al tolerance of wheat cultivars. This finding not only provides a new perspective to screen Al-tolerant wheat cultivars and explain the mechanism of tolerance of wheat to Al toxicity, but is also useful for the prediction of differences in the uptake of Al in the shoots between Al-tolerant and Al-sensitive wheat cultivars, and finally contributes to the prevention of food security risk caused by Al in acid soils., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021

19. Physiological, nutritional, and molecular responses of Brazilian sugarcane cultivars under stress by aluminum.

Author

Oliveira MS, Rocha SV, Schneider VK, Henrique-Silva F, Soares MR, and Soares-Costa A

Abstract

Background: Sugarcane is a crop of global importance and has been expanding to areas with soils containing high levels of exchangeable aluminum (Al), which is a limiting factor for crop development in acidic soils. The study of the sugarcane physiological and nutritional behavior together with patterns of gene expression in response to Al stress may provide a basis for effective strategies to increase crop productivity in acidic soils., Methods: Sugarcane cultivars were evaluated for physiological parameters (photosynthesis, stomatal conductance, and transpiration), nutrient (N, P, K, Ca, Mg, and S) and Al contents in leaves and roots and gene expression, of the genes MDH , SDH by qPCR, both related to the production of organic acids, and SOD , related to oxidative stress., Results: Brazilian sugarcane RB867515, RB928064, and RB935744 cultivars exhibited very different responses to induced stress by Al. Exposure to Al caused up-regulation ( SOD and MDH ) or down-regulation ( SDH , MDH , and SOD ), depending on the cultivar, Al level, and plant tissue. The RB867515 cultivar was the most Al-tolerant, showing no decline of nutrient content in plant tissue, photosynthesis, transpiration, and stomatal conductance after exposure to Al; it exhibited the highest Al content in the roots, and showed important MDH and SOD gene expression in the roots. RB928064 only showed low expression of SOD in roots and leaves, while RB935744 showed important expression of the SOD gene only in the leaves. Sugarcane cultivars were classified in the following descending Al-tolerance order: RB867515 > RB928064 = RB935744. These results may contribute to the obtention of Al-tolerant cultivars that can play their genetic potential in soils of low fertility and with low demand for agricultural inputs; the selection of potential plants for breeding programs; the elucidation of Al detoxification mechanisms employed by sugarcane cultivars., Competing Interests: The authors declare that they have no competing interests., (© 2021 Oliveira et al.)

Published

2021

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

Author

Tokizawa M, Enomoto T, Ito H, Wu L, Kobayashi Y, Mora-Macías J, Armenta-Medina D, Iuchi S, Kobayashi M, Nomoto M, Tada Y, Fujita M, Shinozaki K, Yamamoto YY, Kochian LV, and Koyama H

Subjects

Aluminum metabolism, Gene Expression Regulation, Plant, Glutamate Dehydrogenase, Plant Roots genetics, Plant Roots metabolism, Promoter Regions, Genetic, Transcription Factors metabolism, Aluminum toxicity, Arabidopsis genetics, Arabidopsis metabolism, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism

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., (© The Author(s) 2021. Published by Oxford University Press on behalf of the Society for Experimental Biology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2021

21. Tease out the future: How tea research might enable crop breeding for acid soil tolerance.

Author

Ding ZJ, Shi YZ, Li GX, Harberd NP, and Zheng SJ

Subjects

Camellia sinensis genetics, Aluminum metabolism, Camellia sinensis physiology, Plant Breeding, Soil chemistry

Abstract

Unlike most crops, in which soil acidity severely limits productivity, tea ( Camellia sinensis ) actually prefers acid soils (pH 4.0-5.5). Specifically, tea is very tolerant of acidity-promoted aluminum (Al) toxicity, a major factor that limits the yield of most other crops, and it even requires Al for optimum growth. Understanding tea Al tolerance and Al-stimulatory mechanisms could therefore be fundamental for the future development of crops adapted to acid soils. Here, we summarize the Al-tolerance mechanisms of tea plants, propose possible mechanistic explanations for the stimulation of tea growth by Al based on recent research, and put forward ideas for future crop breeding for acid soils., (© 2021 The Authors.)

Published

2021

22. Plants alter surface charge and functional groups of their roots to adapt to acidic soil conditions.

Author

Lu HL, Nkoh JN, Abdulaha-Al Baquy M, Dong G, Li JY, and Xu RK

Subjects

Acclimatization, Agriculture, Biological Transport, Hydroponics, Plant Roots, Soil, Soil Pollutants

Abstract

The rapid increase in soil acidification rate has led to a decrease in global agricultural productivity owing to the debilitating effects of Al and Mn toxicities. In this study, we investigated the adaptation of plants to acidic conditions by examining the behavior of plant roots grown in hydroponic solution and pot experiments at different pHs. The Mn(II) sorption by the roots was investigated and the mechanisms involved were deduced by analyzing the changes in the zeta potential and functional groups on the root surface. The exchangeable, complexed, and precipitated Mn(II) on plant roots were extracted sequentially with 1 M KNO 3 , 0.05 M EDTA-2Na, and 0.01 M HCl. The results of hydroponic experiment indicated that plant roots subjected to NH 4 + treatment carried lower negative charge and fewer functional groups owing to acidic pH condition induced by NH 4 + uptake of roots, when compared with plant roots treated with NO 3 - . Similarly, in pot experiments, the surface negative charge and functional groups of plant roots cultured in soils with lower pH were fewer than those on plant roots cultured in soils with higher pH, with the former presenting less exchangeable and complexed Mn(II) sorption than the latter. Thus, alterations in the charge properties and number of functional groups on the surface of plant roots are some of the mechanisms used by plants to adapt to acidic soil condition., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020

23. Comprehensive characterization of the ALMT and MATE families on Populus trichocarpa and gene co-expression network analysis of its members during aluminium toxicity and phosphate starvation stresses.

Author

Cardoso TB, Pinto RT, and Paiva LV

Abstract

Aluminium (Al) toxicity and phosphate deficit on soils are some of the main problems of modern agriculture and are usually associated. Some plants are able to overcome these stresses through exuding organic acids on the rhizosphere, such as citrate and malate, which are exported by MATE (Multi drug and toxin extrusion) and ALMT (Aluminium-activated malate transporter) transporters, respectively. Despite its co-action on acidic soils, few studies explore these two families' correlation, especially on tree crops, therefore we performed a comprehensive description of MATE and ALMT families on Populus trichocarpa as a model species for arboreal plants. We found 20 and 56 putative members of ALMT and MATE families, respectively. Then, a gene co-expression network analysis was performed using broad transcriptomic data to analyze which members of each family were transcriptionally associated. Four independent networks were generated, one of which is composed of members putatively related to phosphate starvation and aluminum toxicity stresses. The PoptrALMT10 and PoptrMATE54 genes were selected from this network for a deeper analysis, which revealed that in roots under phosphate starvation stress the two genes have independent transcriptional profiles, however, on the aluminum toxicity stress they share some common correlations with other genes. The data presented here help on the description of these gene families, of which some members are potentially involved in plant responses to acid soil-related stresses and its exploration is an important step towards using this knowledge on breeding programs for P. trichocarpa and other tree crops., Competing Interests: Conflict of interest The authors declare that they have no conflict of interest., (© King Abdulaziz City for Science and Technology 2020.)

Published

2020

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

Author

Feng X, Liu W, Dai H, Qiu Y, Zhang G, Chen ZH, and Wu F

Subjects

Aluminum toxicity, Genes, Homeobox, Leucine Zippers, Phylogeny, Plant Breeding, Plant Roots genetics, Stress, Physiological, Tibet, Transcription Factors genetics, Hordeum genetics

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 HvHOX9 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., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Society for Experimental Biology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2020

25. Dissection of Root Transcriptional Responses to Low pH, Aluminum Toxicity and Iron Excess Under Pi-Limiting Conditions in Arabidopsis Wild-Type and stop1 Seedlings.

Author

Ojeda-Rivera JO, Oropeza-Aburto A, and Herrera-Estrella L

Abstract

Acidic soils constrain plant growth and development in natural and agricultural ecosystems because of the combination of multiple stress factors including high levels of Fe 3+ , toxic levels of Al 3+ , low phosphate (Pi) availability and proton rhizotoxicity. The transcription factor SENSITIVE TO PROTON RHIZOTOXICITY (STOP1) has been reported to underlie root adaptation to low pH, Al 3+ toxicity and low Pi availability by activating the expression of genes involved in organic acid exudation, regulation of pH homeostasis, Al 3+ detoxification and root architecture remodeling in Arabidopsis thaliana . However, the mechanisms by which STOP1 integrates these environmental signals to trigger adaptive responses to variable conditions in acidic soils remain to be unraveled. It is unknown whether STOP1 activates the expression of a single set of genes that enables root adaptation to acidic soils or multiple gene sets depending on the combination of different types of stress present in acidic soils. Previous transcriptomic studies of stop1 mutants and wild-type plants analyzed the effect of individual types of stress prevalent in acidic soils. An integrative study of the transcriptional regulation pathways that are activated by STOP1 under the combination of major stresses common in acidic soils is lacking. Using RNA-seq, we performed a transcriptional dissection of wild-type and stop1 root responses, individually or in combination, to toxic levels of Al 3+ , low Pi availability, low pH and Fe excess. We show that the level of STOP1 is post-transcriptionally and coordinately upregulated in the roots of seedlings exposed to single or combined stress factors. The accumulation of STOP1 correlates with the transcriptional activation of stress-specific and common gene sets that are activated in the roots of wild-type seedlings but not in stop1 . Our data indicate that perception of low Pi availability, low pH, Fe excess and Al toxicity converges at two levels via STOP1 signaling: post-translationally through the regulation of STOP1 turnover, and transcriptionally, via the activation of STOP1-dependent gene expression that enables the root to better adapt to abiotic stress factors present in acidic soils., (Copyright © 2020 Ojeda-Rivera, Oropeza-Aburto and Herrera-Estrella.)

Published

2020

26. Root architecture, rooting profiles and physiological responses of potential slope plants grown on acidic soil.

Author

Dorairaj D, Suradi MF, Mansor NS, and Osman N

Abstract

Globally, there has been an increase in the frequency of landslides which is the result of slope failures. The combination of high intensity rainfall and high temperature resulted in the formation of acidic soil which is detrimental to the healthy growth of plants. Proper plant coverage on slopes is a prerequisite to mitigate and rehabilitate the soil. However, not all plant species are able to grow in marginal land. Thus, this study was undertaken to find a suitable slope plant species. We aimed to evaluate the effect of different soil pH on root profiles and growth of three different potential slope plant species namely, Melastoma malabathricum , Hibiscus rosa-sinensis and Syzygium campanulatum . M. malabathricum showed the highest tolerance to acidic soil as it recorded the highest plant height and photosynthetic rate. The root systems of M. malabathricum , H. rosa-sinensis and S. campanulatum were identified as M, VH- and R-types, respectively. The study proposed M. malabathricum which possessed dense and shallow roots to be planted at the toe or top of the slope while H. rosa-sinensis and S. campanulatum to be planted in the middle of a slope. S. campanulatum consistently recorded high root length and root length density across all three types of soil pH while M. malabathricum showed progressive increase in length as the soil pH increased. The root average diameter and root volume of M. malabathricum outperformed the other two plant species irrespective of soil pH. In terms of biomass, M. malabathricum exhibited the highest root and shoot dry weights followed by S. campanulatum . Thus, we propose M. malabathricum to be planted on slopes as a form of soil rehabilitation. The plant species displayed denser rooting, hence a stronger root anchorage that can hold the soil particles together which will be beneficial for slope stabilization., Competing Interests: The authors declare there are no competing interests., (©2020 Dorairaj et al.)

Published

2020

27. Impacts of Phosphogypsum, Soluble Fertilizer and Lime Amendment of Acid Soils on the Bioavailability of Phosphorus and Sulphur Under Lucerne ( Medicago sativa ).

Author

Bouray M, Moir J, Condron L, and Lehto N

Abstract

Legumes play critical dual roles in grazed grassland ecosystems; providing nitrogen inputs and high-quality feed for grazing livestock. However, many species fail to persist in acidic, low fertility soils. A glasshouse study was conducted to investigate the response of lucerne ( Medicago sativa ) to phosphogypsum (PG), lime and soluble P + S fertilizer (PS) application to two soils. Phosphorus and sulphur were applied through either PG (0, 1, 3 and 9 t ha -1 ) or P + S fertilizer at equivalent rates to PG. Both PG and PS were applied with or without lime, which was applied at 2 t ha -1 . Yield and nutrient uptake of the lucerne was measured, while the soil was analyzed for pH, Olsen P and exchangeable aluminum. Yield responses were significantly different between the two soils. Maximum yields and P and S uptakes were obtained under PG 9 t ha -1 combined with lime. Exchangeable Al decreased in both soils under 1 ha -1 of PG compared with the control. At the highest rate, Olsen P increased by 8 and 6 mg kg -1 for PG and by 6 and 11 mg kg -1 for PS compared with the control for Glenmore and Molesworth soils respectively. Phosphogypsum showed positive effects on P and S bioavailability.

Published

2020

28. Transcriptomic Revelation of Phenolic Compounds Involved in Aluminum Toxicity Responses in Roots of Cunninghamia lanceolata (Lamb.) Hook.

Author

Ma Z and Lin S

Subjects

Cunninghamia drug effects, Flavonoids biosynthesis, Genes, Plant, Plant Roots drug effects, Aluminum toxicity, Cunninghamia genetics, Drug Resistance genetics, Flavonoids genetics, Hydroxybenzoates metabolism, Transcriptome

Abstract

: Chinese fir (Cunninghamia lanceolata (Lamb.) Hook.) is one of the most important coniferous evergreen tree species in South China due to its desirable attributes of fast growth and production of strong and hardy wood. However, the yield of Chinese fir is often inhibited by aluminum (Al) toxicity in acidic soils of South China. Understanding the molecular mechanisms of Chinese fir root responses to Al toxicity might help to further increase its productivity. Here we used the Illumina Hiseq4000 platform to carry out transcriptome analysis of Chinese fir roots subjected to Al toxicity conditions. A total of 88.88 Gb of clean data was generated from 12 samples and assembled into 105,732 distinct unigenes. The average length and N50 length of these unigenes were 839 bp and 1411 bp, respectively. Among them, 58362 unigenes were annotated through searches of five public databases (Nr: NCBI non-redundant protein sequences, Swiss-Prot: A manually annotated and reviewed protein sequence database, GO: Gene Ontology, KOG/COG: Clusters of Orthologous Groups of proteins, and KEGG: the Kyoto Encyclopedia of Genes and Genomes database), which led to association of unigenes with 44 GO terms. Plus, 1615 transcription factors (TFs) were functionally classified. Then, differentially expressed genes (DEGs, |log 2 (fold change)| ≥ 1 and FDR ≤ 0.05) were identified in comparisons labelled TC1 (CK-72 h/CK-1 h) and TC2 (Al-72 h/Al-1 h). A large number of TC2 DEGs group were identified, with most being down-regulated under Al stress, while TC1 DEGs were primarily up-regulated. Combining GO, KEGG, and MapMan pathway analysis indicated that many DEGs are involved in primary metabolism, including cell wall metabolism and lipid metabolism, while other DEGs are associated with signaling pathways and secondary metabolism, including flavonoids and phenylpropanoids metabolism. Furthermore, TFs identified in TC1 and TC2 DEGs represented 21 and 40 transcription factor families, respectively. Among them, expression of bHLH, C2H2, ERF, bZIP, GRAS, and MYB TFs changed considerably under Al stress, which suggests that these TFs might play crucial roles in Chinese fir root responses to Al toxicity. These differentially expressed TFs might act in concert with flavonoid and phenylpropanoid pathway genes in fulfilling of key roles in Chinese fir roots responding to Al toxicity., Competing Interests: The authors declare no conflict of interest. The funders had no role in the design of the study.

Published

2019

29. Low pH stress responsive transcriptome of seedling roots in wheat (Triticum aestivum L.).

Author

Hu H, He J, Zhao J, Ou X, Li H, and Ru Z

Subjects

Gene Expression Profiling, Gene Expression Regulation, Plant, Hydrogen-Ion Concentration, Oligonucleotide Array Sequence Analysis, Plant Proteins chemistry, Plant Proteins genetics, Plant Proteins metabolism, Plant Roots genetics, Plant Roots growth & development, Plant Roots metabolism, Promoter Regions, Genetic, Real-Time Polymerase Chain Reaction, Seedlings genetics, Seedlings metabolism, Stress, Physiological genetics, Transcription Factors chemistry, Transcription Factors genetics, Transcription Factors metabolism, Triticum growth & development, Triticum metabolism, Transcriptome, Triticum genetics

Abstract

Soil acidification is one of major problems limiting crop growth and especially becoming increasingly serious in China owing to excessive use of nitrogen fertilizer. Only the STOP1 of Arabidopsis was identified clearly sensitive to proton rhizotoxicity and the molecular mechanism for proton toxicity tolerance of plants is still poorly understood. The main objective of this study was to investigate the transcriptomic change in plants under the low pH stress. The low pH as a single factor was employed to induce the response of the wheat seedling roots. Wheat cDNA microarray was used to identify differentially expressed genes (DEGs). A total of 1057 DEGs were identified, of which 761 genes were up-regulated and 296 were down-regulated. The greater percentage of up-regulated genes involved in developmental processes, immune system processes, multi-organism processes, positive regulation of biological processes and metabolic processes of the biological processes. The more proportion of down-regulation genes belong to the molecular function category including transporter activity, antioxidant activity and molecular transducer activity and to the extracellular region of the cellular components category. Moreover, most genes among 41 genes involved in ion binding, 17 WAKY transcription factor genes and 17 genes related to transport activity were up-regulated. KEGG analysis showed that the jasmonate signal transduction and flavonoid biosynthesis might play important roles in response to the low pH stress in wheat seedling roots. Based on the data, it is can be deduced that WRKY transcription factors might play a critical role in the transcriptional regulation, and the alkalifying of the rhizosphere might be the earliest response process to low pH stress in wheat seedling roots. These results provide a basis to reveal the molecular mechanism of proton toxicity tolerance in plants.

Published

2018

30. Assessing How the Aluminum-Resistance Traits in Wheat and Rye Transfer to Hexaploid and Octoploid Triticale.

Author

Ryan PR, Dong D, Teuber F, Wendler N, Mühling KH, Liu J, Xu M, Salvador Moreno N, You J, Maurer HP, Horst WJ, and Delhaize E

Abstract

The mechanisms of aluminum (Al) resistance in wheat and rye involve the release of citrate and malate anions from the root apices. Many of the genes controlling these processes have been identified and their responses to Al treatment described in detail. This study investigated how the major Al resistance traits of wheat and rye are transferred to triticale (x Tritosecale Wittmack) which is a hybrid between wheat and rye. We generated octoploid and hexaploid triticale lines and compared them with the parental lines for their relative resistance to Al, organic anion efflux and expression of some of the genes encoding the transporters involved. We report that the strong Al resistance of rye was incompletely transferred to octoploid and hexaploid triticale. The wheat and rye parents contributed to the Al-resistance of octoploid triticale but the phenotypes were not additive. The Al resistance genes of hexaploid wheat, TaALMT1 , and TaMATE1B , were more successfully expressed in octoploid triticale than the Al resistance genes in rye tested, ScALMT1 and ScFRDL2 . This study demonstrates that an important stress-tolerance trait derived from hexaploid wheat was expressed in octoploid triticale. Since most commercial triticale lines are largely hexaploid types it would be beneficial to develop techniques to generate genetically-stable octoploid triticale material. This would enable other useful traits that are present in hexaploid but not tetraploid wheat, to be transferred to triticale.

Published

2018

31. Effects of a natural sepiolite bearing material and lime on the immobilization and persistence of cadmium in a contaminated acid agricultural soil.

Author

Cao X, Hu P, Tan C, Wu L, Peng B, Christie P, and Luo Y

Subjects

Agriculture, Biological Availability, Brassica drug effects, Brassica growth & development, Cadmium analysis, Cadmium pharmacokinetics, Calcium Compounds chemistry, Crops, Agricultural drug effects, Crops, Agricultural growth & development, Hydrogen-Ion Concentration, Oxides chemistry, Plant Shoots drug effects, Plant Shoots metabolism, Soil chemistry, Soil Pollutants pharmacokinetics, Cadmium chemistry, Environmental Restoration and Remediation methods, Magnesium Silicates chemistry, Soil Pollutants chemistry

Abstract

Soil contamination with cadmium (Cd) represents a substantial threat to human health and environmental quality. Long-term effectiveness and persistence of remediation are two important criteria for the evaluation of amendment techniques used to remediate soils polluted with potentially toxic metals. In the current study, we investigated the remediation persistence of a natural sepiolite bearing material (NSBM, containing 15% sepiolite) and ground limestone (equivalent to > 98.0% CaO) on soil pH, Cd bioavailability, and Cd accumulation by pak choi (Brassica chinensis L.) during the growth of four consecutive crops in a Cd-contaminated acid soil with different amounts of NSBM (0, 0.2, 0.5, 1, 2, and 5%). Soil pH levels ranged from 5.21 to 7.76 during the first crop, 4.30 to 7.34 during the second, 4.23 to 7.80 during the third, and 4.33 to 6.98 during the fourth, and increased significantly with increasing the application rate of NSBM. Soil CaCl 2 -Cd and shoot Cd concentrations decreased by 8.11 to 99.2% and 6.58 to 94.5%, respectively, compared with the control throughout the four cropping seasons. A significant negative correlation was found between soil CaCl 2 -Cd and soil pH. Combined use of 0.1% lime and NSBM showed greater effects than NSBM alone, especially, when the application rate of NSBM was ˂ 2%. Moreover, pak choi tissue Cd concentrations in the treatments with NSBM addition alone at ≥ 2% or at ≥ 1% NSBM combined with 0.1% lime met the maximum permissible concentration (MPC) over the four crops, allowed by the Chinese and European regulations. Based on the present study, safe crop production in the test soil is possible at a soil pH > 6.38 and CaCl 2 -Cd < 14 μg kg -1 , and soil Cd immobilization by NSBM without or with lime is a potentially feasible method of controlling the transfer of soil Cd into the food chain.

Published

2018

32. Aluminum-Nitrogen Interactions in the Soil-Plant System.

Author

Zhao XQ and Shen RF

Abstract

Aluminum (Al) is the most abundant metal in the Earth's crust and is not an essential element for plant growth. In contrast, nitrogen (N) is the most important mineral element for plant growth, but this non-metal is often present at low levels in soils, and plants are often N deficient. Aluminum toxicity is dominant in acid soils, and so plants growing in acid soils have to overcome both Al toxicity and N limitation. Because of low N-use efficiency, large amounts of N fertilizers are applied to crop fields to achieve high yields, leading to soil acidification and potential Al toxicity. Aluminum lowers plant N uptake and N-use efficiency because Al inhibits root growth. Although numerous studies have investigated the interactions between Al and N, a complete review of these studies was lacking. This review describes: (1) the link between plant Al tolerance and ammonium/nitrate (NH 4 + /NO 3 - ) preference; (2) the effects of NH 4 + /NO 3 - and pH on Al toxicity; (3) the effects of Al on soil N transformations; and (4) the effects of Al on NH 4 + /NO 3 - uptake and assimilation by plants. Acid soils are characterized chemically by a relatively high ratio of NH 4 + to NO 3 - and high concentrations of toxic Al. Aluminum-tolerant plants generally prefer NH 4 + as an N source, while Al-sensitive plants prefer NO 3 - . Compared with NO 3 - , NH 4 + increases the solubilization of toxic Al into soil solutions, but NH 4 + generally alleviates Al phytotoxicity under solution culture because the protons from NH 4 + compete with Al 3+ for adsorption sites on the root surface. Plant NO 3 - uptake and nitrate reductase activity are both inhibited by Al, while plant NH 4 + uptake is inhibited to a smaller degree than NO 3 - . Together, the results of numerous studies indicate that there is a synergistic interaction between plant Al tolerance and NH 4 + nutrition. This has important implications for the adaptation of plants to acid soils that are dominated chemically by toxic Al as well as NH 4 + . Finally, we discuss how this knowledge can be used to increase plant Al tolerance and N-use efficiency in acid soils.

Published

2018

33. [Effects of CaCO 3 Application on Soil Microbial Nitrogen Cycle in an Acid Soil].

Author

Guo AN, Duan GL, Zhao ZQ, Tang Z, Wang YY, and Wang BX

Subjects

Acids, China, Hydrogen-Ion Concentration, Nitrogen, Calcium Carbonate chemistry, Denitrification, Nitrification, Nitrogen Cycle, Soil chemistry, Soil Microbiology

Abstract

Soil nitrification and denitrification are important steps in closing the nitrogen cycle. Understanding the effects of CaCO 3 application on the physicochemical properties and nitrogen cycle in acid soil would provide some theoretical and technical information for stable and sustainable utilization of this agricultural soil. In this study, a field trial was conducted in Xiangtan city, Hunan province. In this field, the soil pH was 5.54, and CaCO 3 was applied at four levels: 0, 2.25, 4.5, and 7.5 t·hm -2 . After one season of rice cultivation, the soil was sampled to determine dissolved organic carbon (DOC), NH 4 + -N, and NO 3 - -N levels, and the potential nitrification rate (PNR) and denitrifying enzyme activity (DEA) were measured. The results showed that CaCO 3 application improved the content of soil DOC (762.10-868.58 mg·kg -1 ) and PNR [0.59-0.82 μg·(g·h) -1 ]. However, excessive application of CaCO 3 (7.5 t·hm -2 ) revealed an obvious inhibition on the activity of soil nitrification. Furthermore, the result of Pearson correlation analysis indicated that soil nitrification was positively correlated with soil DOC and negatively correlated with NH 4 + -N content, whereas denitrification had a significant positive correlation with NO 3 - -N content and soil DOC, but a negative correlation with water content.

Published

2017

34. Regulating cytoplasmic oxalate homeostasis by Acyl activating enzyme3 is critical for plant Al tolerance.

Author

Chen WW, Fan W, Lou HQ, Yang JL, and Zheng SJ

Subjects

Gene Expression Regulation, Plant drug effects, Homeostasis, Phylogeny, Plant Proteins metabolism, Plants drug effects, Plants metabolism, Aluminum toxicity, Cytoplasm metabolism, Oxalates metabolism

Abstract

Oxalic acid is the simplest of the dicarboxylic acids. In addition to its role in biological and metabolic processes, oxalate has been implicated in biotic and abiotic stresses. Being a strong chelator of Al, oxalate also has pivotal role in Al resistance mechanisms. However, we demonstrated that cytoplasmic oxalate accumulation is a critical event leading to root growth inhibition under Al stress. Transcriptome analysis from three crop plants identified Acyl Activating Enzyme3 (AAE3) genes to be upregulated by Al stress. These AAE3 proteins display high sequence identity to known AAE3 proteins, suggesting they are oxalyl-CoA synthetases specifically involved in oxalate degradation. However, phylogenetic analysis revealed divergence of AAE3 between monocots and dicots, pointing to the necessity for functional characterization of AAE3 proteins from other plant species with respect to Al stress.

Published

2017

35. Rhizobium hidalgonense sp. nov., a nodule endophytic bacterium of Phaseolus vulgaris in acid soil.

Author

Yan J, Yan H, Liu LX, Chen WF, Zhang XX, Verástegui-Valdés MM, Wang ET, and Han XZ

Subjects

Alanine metabolism, Asparagine metabolism, Bacterial Typing Techniques, Base Composition, Base Sequence, DNA, Bacterial genetics, Endophytes classification, Endophytes genetics, Endophytes metabolism, Fatty Acids chemistry, Fatty Acids metabolism, Mexico, Molecular Sequence Data, Phylogeny, RNA, Ribosomal, 16S genetics, Rhizobium classification, Rhizobium genetics, Rhizobium metabolism, Sequence Analysis, DNA, Soil chemistry, Symbiosis, Endophytes isolation & purification, Phaseolus microbiology, Rhizobium isolation & purification, Root Nodules, Plant microbiology, Soil Microbiology

Abstract

One Gram-negative, aerobic, motile, rod-shaped bacterium, designated as FH14 T , was isolated from nodules of Phaseolus vulgaris grown in Hidalgo State of Mexico. Results based upon 16S rRNA gene (≥99.8 % similarities to known species), concatenated sequence (recA, atpD and glnII) analysis of three housekeeping genes (≤93.4 % similarities to known species) and average nucleotide identity (ANI) values of genome sequence (ranged from 87.6 to 90.0 % to related species) indicated the distinct position of strain FH14 T within the genus Rhizobium. In analyses of symbiotic genes, only nitrogen fixation gene nifH was amplified that had nucleotide sequence identical to those of the bean-nodulating strains in R. phaseoli and R. vallis, while nodulation gene nodC gene was not amplified. The failure of nodulation to its original host P. vulgaris and other legumes evidenced the loss of its nodulation capability. Strain FH14 T contained summed feature 8 (C 18:1 ω6c/C 18:1 ω7c, 59.96 %), C 16:0 (10.6 %) and summed feature 2 (C 12:0 aldehyde/unknown 10.928, 10.24 %) as the major components of cellular fatty acids. Failure to utilize alaninamide, and utilizing L-alanine, L-asparagine and γ-amino butyric acid as carbon source, distinguished the strain FH14 T from the type strains for the related species. The genome size and DNA G+C content of FH14 T were 6.94 Mbp and 60.8 mol %, respectively. Based on those results, a novel specie in Rhizobium, named Rhizobium hidalgonense sp. nov., was proposed, with FH14 T (=HAMBI 3636 T  = LMG 29288 T ) as the type strain.

Published

2017

36. Glutathione S-transferases and UDP-glycosyltransferases Are Involved in Response to Aluminum Stress in Flax.

Author

Dmitriev AA, Krasnov GS, Rozhmina TA, Kishlyan NV, Zyablitsin AV, Sadritdinova AF, Snezhkina AV, Fedorova MS, Yurkevich OY, Muravenko OV, Bolsheva NL, Kudryavtseva AV, and Melnikova NV

Abstract

About 30% of the world's ice-free land area is occupied by acid soils. In soils with pH below 5, aluminum (Al) releases to the soil solution, and becomes highly toxic for plants. Therefore, breeding of varieties that are resistant to Al is needed. Flax ( Linum usitatissimum L.) is grown worldwide for fiber and seed production. Al toxicity in acid soils is a serious problem for flax cultivation. However, very little is known about mechanisms of flax resistance to Al and the genetics of this resistance. In the present work, we sequenced 16 transcriptomes of flax cultivars resistant (Hermes and TMP1919) and sensitive (Lira and Orshanskiy) to Al, which were exposed to control conditions and aluminum treatment for 4, 12, and 24 h. In total, 44.9-63.3 million paired-end 100-nucleotide reads were generated for each sequencing library. Based on the obtained high-throughput sequencing data, genes with differential expression under aluminum exposure were revealed in flax. The majority of the top 50 up-regulated genes were involved in transmembrane transport and transporter activity in both the Al-resistant and Al-sensitive cultivars. However, genes encoding proteins with glutathione transferase and UDP-glycosyltransferase activity were in the top 50 up-regulated genes only in the flax cultivars resistant to aluminum. For qPCR analysis in extended sampling, two UDP-glycosyltransferases (UGTs), and three glutathione S-transferases (GSTs) were selected. The general trend of alterations in the expression of the examined genes was the up-regulation under Al stress, especially after 4 h of Al exposure. Moreover, in the flax cultivars resistant to aluminum, the increase in expression was more pronounced than that in the sensitive cultivars. We speculate that the defense against the Al toxicity via GST antioxidant activity is the probable mechanism of the response of flax plants to aluminum stress. We also suggest that UGTs could be involved in cell wall modification and protection from reactive oxygen species (ROS) in response to Al stress in L. usitatissimum . Thus, GSTs and UGTs, probably, play an important role in the response of flax to Al via detoxification of ROS and cell wall modification.

Published

2016

37. Genetic diversity and distribution of bradyrhizobia nodulating peanut in acid-neutral soils in Guangdong Province.

Author

Chen J, Hu M, Ma H, Wang Y, Wang ET, Zhou Z, and Gu J

Subjects

Acyltransferases genetics, Bacterial Proteins genetics, Base Sequence, Bradyrhizobium isolation & purification, China, DNA, Bacterial genetics, DNA, Ribosomal Spacer genetics, Genes, Essential genetics, Genetic Variation genetics, Geography, Phylogeny, RNA, Ribosomal, 16S genetics, Rec A Recombinases genetics, Sequence Analysis, DNA, Soil chemistry, Soil Microbiology, Symbiosis, Transcription Factors genetics, Arachis microbiology, Bacterial Typing Techniques, Bradyrhizobium classification, Bradyrhizobium genetics, Rhizobium classification, Rhizobium isolation & purification, Root Nodules, Plant microbiology

Abstract

To reveal the genetic diversity and geographic distribution of peanut (Arachis hypogaea L.) rhizobia in Guangdong Province, one of the main peanut producing regions in China, 216 bradyrhizobial isolates were trapped by peanut plants inoculated with soil samples (pH 4.7-7.4) collected from ten sites in Guangdong. Based on BOX-PCR fingerprinting analysis, 71 representative isolates were selected for sequence analyses of ribosomal IGS, recA, atpD and symbiotic gene nodA. As a result, 22 genospecies were detected in the peanut rhizobia, including eight minor groups or single strains corresponding to Bradyrhizobium diazoefficiens, B. japonicum, B. yuanmingense, B. arachidis, B. guangdongense, B. guangxiense, B. iriomotense and B. liaoningense, as well as 14 novel Bradyrhizobium genospecies covering the majority of isolates. Five symbiotic clusters were obtained based on the phylogenetic relationships of nodA genes, related to the soybean-nodulating or peanut-nodulating reference strains. Biogeographic patterns, which were mainly correlated with potassium content and pH, were detected in the peanut bradyrhizobial community in Guangdong Province. These findings enriched the diversity of peanut rhizobia, and added the K content as a special determinant for peanut rhizobial distribution in acid soils., (Copyright © 2016. Published by Elsevier GmbH.)

Published

2016

38. Alleviation of proton toxicity by nitrate uptake specifically depends on nitrate transporter 1.1 in Arabidopsis.

Author

Fang XZ, Tian WH, Liu XX, Lin XY, Jin CW, and Zheng SJ

Subjects

Anion Transport Proteins genetics, Arabidopsis genetics, Calcium metabolism, Gene Knockout Techniques, Hydrogen-Ion Concentration, Magnesium metabolism, Plant Proteins genetics, Plants, Genetically Modified, Protons, Rhizosphere, Anion Transport Proteins metabolism, Arabidopsis metabolism, Nitrates metabolism, Plant Proteins metabolism

Abstract

Protons in acid soil are highly rhizotoxic to plants, but the mechanism of tolerance of plants to protons is largely unknown. Nitrate uptake by root cells is accompanied by the uptake of protons. Therefore, nitrate uptake transporters (NRTs) may be involved in plant tolerance to proton toxicity. We investigated the root nitrate uptake response to proton stress in Arabidopsis and its association with proton tolerance using NRT-related mutants and pharmacological methods. Lack of NRT1.1 in knockout nrt1.1 mutants led to impaired proton tolerance in nitrate-sufficient growth medium, whereas no difference was seen between wild-type plants and NRT1.2-, NRT2.1-, NRT2.2-, and NRT2.4-null mutants. Another nrt1.1 point mutant, which is defective in nitrate uptake but has a normal nitrate-sensing function, also had impaired proton tolerance compared with the wild-type plant. Furthermore, proton stress induced NRT1.1-mediated nitrate uptake. These results indicate that NRT1.1-conferred proton tolerance depends on nitrate uptake activity. In addition, the rooting medium was alkalified by wild-type plants, but not by knockout nrt1.1 mutants, and in pH-buffered medium, there were no differences in proton tolerance between wild-type plants and knockout nrt1.1 mutants. We conclude that NRT1.1-mediated nitrate uptake plays a crucial role in plant proton tolerance by alkalifying the rhizosphere., (© 2016 The Authors. New Phytologist © 2016 New Phytologist Trust.)

Published

2016

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

Author

James RA, Weligama C, Verbyla K, Ryan PR, Rebetzke GJ, Rattey A, Richardson AE, and Delhaize E

Subjects

Hydrogen-Ion Concentration, Plant Roots genetics, Plant Roots growth & development, Soil chemistry, Phosphorus metabolism, Quantitative Trait Loci, Triticum genetics, Triticum growth & development

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 Al(3+) Genotypic differences in rhizosheath size were apparent only when soil pH was low and Al(3+) 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., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2016

40. Characterization of VuMATE1 Expression in Response to Iron Nutrition and Aluminum Stress Reveals Adaptation of Rice Bean (Vigna umbellata) to Acid Soils through Cis Regulation.

Author

Liu M, Xu J, Lou H, Fan W, Yang J, and Zheng S

Abstract

Rice bean (Vigna umbellata) VuMATE1 appears to be constitutively expressed at vascular system but root apex, and Al stress extends its expression to root apex. Whether VuMATE1 participates in both Al tolerance and Fe nutrition, and how VuMATE1 expression is regulated is of great interest. In this study, the role of VuMATE1 in Fe nutrition was characterized through in planta complementation assays. The transcriptional regulation of VuMATE1 was investigated through promoter analysis and promoter-GUS reporter assays. The results showed that the expression of VuMATE1 was regulated by Al stress but not Fe status. Complementation of frd3-1 with VuMATE1 under VuMATE1 promoter could not restore phenotype, but restored with 35SCaMV promoter. Immunostaining of VuMATE1 revealed abnormal localization of VuMATE1 in vasculature. In planta GUS reporter assay identified Al-responsive cis-acting elements resided between -1228 and -574 bp. Promoter analysis revealed several cis-acting elements, but transcription is not simply regulated by one of these elements. We demonstrated that cis regulation of VuMATE1 expression is involved in Al tolerance mechanism, while not involved in Fe nutrition. These results reveal the evolution of VuMATE1 expression for better adaptation of rice bean to acid soils where Al stress imposed but Fe deficiency pressure released.

Published

2016

41. The influence of biochar type on long-term stabilization for Cd and Cu in contaminated paddy soils.

Author

Li H, Ye X, Geng Z, Zhou H, Guo X, Zhang Y, Zhao H, and Wang G

Subjects

Biological Availability, Cadmium pharmacokinetics, Copper pharmacokinetics, Hydrogen-Ion Concentration, Oryza metabolism, Quercus, Soil chemistry, Soil Pollutants pharmacokinetics, Surface Properties, Zea mays, Cadmium chemistry, Charcoal chemistry, Copper chemistry, Soil Pollutants chemistry

Abstract

Long-term effect of biochar on PTEs (potential toxic elements) immobilization depends upon biochar own property and its aging process in soil. To understand the role of biachar type on PTEs stabilization, two types of biochar, corn-straw-derived biochar (CB) and hardwood-derived biochar (HB), were compared for their efficacy in achieving a stable decrease in the bio-availability of Cd and Cu in soils. The 3-year pot-culture experiment showed that HB reduced the concentration of CaCl2-extractable Cd and Cu by 57.9 and 63.8% in soil, and Cd and Cu uptake by 63.6 and 56.3% in rice tissue respectively, in the first year, whereas these values increased in the next two years. On the other hand, CB decreased these values steadily year by year. At the end of the 3 years, CB at 5% level had lowered the levels of CaCl2-extractable Cd and Cu by 53.6 and 66.8%, respectively. These variations between CB and HB were due to the differences in the way the two types of biochar age in the soil. The aging process was simulated in the laboratory, and the XPS results showed that the oxidization of the biochars introduced more oxygen-containing groups (especially carboxyl) on the surface of CB than HB, leading to a correspondingly greater number of oxygenated binding sites for Cd and Cu in the case of CB. The content of lignin was the major factor resulting in the variation of oxidation degree in two biochars. These results suggest that it is important to select the right kind of biochar to stably decrease the bio-availability of potential toxic elements (Cd and Cu) in contaminated soils., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2016

42. Wild peanut Arachis duranensis are nodulated by diverse and novel Bradyrhizobium species in acid soils.

Author

Chen JY, Gu J, Wang ET, Ma XX, Kang ST, Huang LZ, Cao XP, Li LB, and Wu YL

Subjects

Bacterial Proteins genetics, Bradyrhizobium genetics, Bradyrhizobium physiology, Cluster Analysis, DNA, Bacterial chemistry, DNA, Bacterial genetics, DNA, Ribosomal chemistry, DNA, Ribosomal genetics, Molecular Sequence Data, Phylogeny, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Symbiosis, Arachis microbiology, Biodiversity, Bradyrhizobium classification, Bradyrhizobium isolation & purification, Root Nodules, Plant microbiology, Soil chemistry

Abstract

Aiming at learning the microsymbionts of Arachis duranensis, a diploid ancestor of cultivated peanut, genetic and symbiotic characterization of 32 isolates from root nodules of this plant grown in its new habitat Guangzhou was performed. Based upon the phylogeny of 16S rRNA, atpD and recA genes, diverse bacteria belonging to Bradyrhizobium yuanmingense, Bradyrhizobium elkanii, Bradyrhizobium iriomotense and four new lineages of Bradyrhizobium (19 isolates), Rhizobium/Agrobacterium (9 isolates), Herbaspirillum (2 isolates) and Burkholderia (2 isolates) were defined. In the nodulation test on peanut, only the bradyrhizobial strains were able to induce effective nodules. Phylogeny of nodC divided the Bradyrhizobium isolates into four lineages corresponding to the grouping results in phylogenetic analysis of housekeeping genes, suggesting that this symbiosis gene was mainly maintained by vertical gene transfer. These results demonstrate that A. duranensis is a promiscuous host preferred the Bradyrhizobium species with different symbiotic gene background as microsymbionts, and that it might have selected some native rhizobia, especially the novel lineages Bradyrhizobium sp. I and sp. II, in its new habitat Guangzhou. These findings formed a basis for further study on adaptation and evolution of symbiosis between the introduced legumes and the indigenous rhizobia., (Copyright © 2014 Elsevier GmbH. All rights reserved.)

Published

2014

43. Introgression of a 4D chromosomal fragment into durum wheat confers aluminium tolerance.

Author

Han C, Ryan PR, Yan Z, and Delhaize E

Subjects

DNA, Plant genetics, Hydroponics, Inbreeding, Malates metabolism, Plant Leaves drug effects, Plant Leaves genetics, Plant Leaves physiology, Plant Proteins metabolism, Plant Roots drug effects, Plant Roots genetics, Plant Roots physiology, Seedlings drug effects, Seedlings genetics, Seedlings physiology, Sodium toxicity, Soil, Triticum drug effects, Triticum genetics, Aluminum toxicity, Chromosomes, Plant genetics, Plant Proteins genetics, Triticum physiology

Abstract

Background and Aim: Aluminium (Al(3+)) inhibits root growth of sensitive plant species and is a key factor that limits durum wheat (Triticum turgidum) production on acid soils. The aim of this study was to enhance the Al(3+) tolerance of an elite durum cultivar by introgression of a chromosomal fragment from hexaploid wheat (Triticum aestivum) that possesses an Al(3+) tolerance gene., Methods: A 4D(4B) substitution line of durum wheat 'Langdon' was backcrossed to 'Jandaroi', a current semi-dwarf Australian durum. In the second backcross, using 'Jandaroi' as the recurrent parent, a seedling was identified where TaALMT1 on chromosome 4D was recombined with the Rht-B1b locus on chromosome 4B to yield an Al(3+)-tolerant seedling with a semi-dwarf habit. This seedling was used in a third backcross to generate homozygous sister lines with contrasting Al(3+) tolerances. The backcrossed lines were characterized and compared with selected cultivars of hexaploid wheat for their Al(3+) and Na(+) tolerances in hydroponic culture as well as in short-term experiments to assess their growth on acid soil., Key Results: Analysis of sister lines derived from the third backcross showed that the 4D chromosomal fragment substantially enhanced Al(3+) tolerance. The ability to exclude Na(+) from leaves was also enhanced, indicating that the chromosomal fragment possessed the Kna1 salt tolerance locus. Although Al(3+) tolerance of seminal roots was enhanced in acid soil, the development of fine roots was not as robust as found in Al(3+)-tolerant lines of hexaploid wheat. Analysis of plant characteristics in the absence of Al(3+) toxicity showed that the introgressed fragment did not affect total grain yield but reduced the weight of individual grains., Conclusions: The results show that it is possible to increase substantially the Al(3+) tolerance of an elite durum wheat cultivar by introgression of a 4D chromosomal fragment. Further improvements are possible, such as introducing additional genes to enhance the Al(3+) tolerance of fine roots and by eliminating the locus on the chromosomal fragment responsible for smaller grain weights., (© The Author 2014. Published by Oxford University Press on behalf of the Annals of Botany Company. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2014

44. Identification of a STOP1-like protein in Eucalyptus that regulates transcription of Al tolerance genes.

Author

Sawaki Y, Kobayashi Y, Kihara-Doi T, Nishikubo N, Kawazu T, Kobayashi M, Kobayashi Y, Iuchi S, Koyama H, and Sato S

Subjects

Adaptation, Physiological drug effects, Agrobacterium metabolism, Amino Acid Sequence, Arabidopsis drug effects, Arabidopsis genetics, Arabidopsis physiology, Citrates metabolism, Eucalyptus drug effects, Gene Expression Regulation, Plant, Genetic Complementation Test, Genetic Vectors metabolism, Green Fluorescent Proteins metabolism, Molecular Sequence Data, Mutation, Phylogeny, Plant Proteins chemistry, Plant Proteins genetics, Plant Roots drug effects, Plant Roots growth & development, Plants, Genetically Modified, RNA Interference drug effects, RNA, Messenger genetics, RNA, Messenger metabolism, Sequence Alignment, Sequence Homology, Nucleic Acid, Adaptation, Physiological genetics, Aluminum toxicity, Eucalyptus genetics, Eucalyptus physiology, Genes, Plant, Plant Proteins metabolism, Transcription, Genetic drug effects

Abstract

Tolerance to soil acidity is an important trait for eucalyptus clones that are introduced to commercial forestry plantations in pacific Asian countries, where acidic soil is dominant in many locations. A conserved transcription factor regulating aluminum (Al) and proton (H⁺) tolerance in land-plant species, STOP1 (SENSITIVE TOPROTON RHIZOTOXICITY 1)-like protein, was isolated by polymerase chain reaction-based cloning, and then suppressed by RNA interference in hairy roots produced by Agrobacterium rhizogenes-mediated transformation. Eucalyptus STOP1-like protein complemented proton tolerance in an Arabidopsis thaliana stop1-mutant, and localized to the nucleus in a transient assay of a green fluorescent protein fusion protein expressed in tobacco leaves by Agrobacterium tumefaciens-mediated transformation. Genes encoding a citrate transporting MULTIDRUGS AND TOXIC COMPOUND EXTRUSION protein and an orthologue of ALUMINUM SENSITIVE 3 were suppressed in transgenic hairy roots in which the STOP1 orthologue was knocked down. In summary, we identified a series of genes for Al-tolerance in eucalyptus, including a gene for STOP1-like protein and the Al-tolerance genes it regulates. These genes may be useful for molecular breeding and genomic selection of elite clones to introduce into acid soil regions., (Copyright © 2014 Elsevier Ireland Ltd. All rights reserved.)

Published

2014

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

Author

Zhou G, Pereira JF, Delhaize E, Zhou M, Magalhaes JV, and Ryan PR

Subjects

Arabidopsis Proteins metabolism, Carrier Proteins metabolism, Hordeum genetics, Membrane Transport Proteins metabolism, Plant Proteins metabolism, Plants, Genetically Modified genetics, Up-Regulation, Aluminum metabolism, Arabidopsis Proteins genetics, Carrier Proteins genetics, Gene Expression, Hordeum metabolism, Membrane Transport Proteins genetics, Plant Proteins genetics, Plants, Genetically Modified metabolism, Sorghum genetics

Abstract

Malate and citrate efflux from root apices is a mechanism of Al(3+) 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 Al(3+)-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 Al(3+) tolerance of barley by transforming it with two MATE genes that encode citrate transporters: SbMATE is the major Al(3+)-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 Al(3+)-activated citrate efflux from root apices and greater tolerance to Al(3+) 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 Al(3+) 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 Al(3+) tolerance than all lines expressing MATE genes. This study highlights the relative efficacy of different organic anion transport proteins for increasing the Al(3+) tolerance of an important crop species., (© The Author 2014. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2014

46. Amelioration of iron toxicity: A mechanism for aluminum-induced growth stimulation in tea plants.

Author

Hajiboland R, Barceló J, Poschenrieder C, and Tolrà R

Subjects

Adaptation, Physiological drug effects, Aluminum pharmacology, Biological Transport drug effects, Camellia sinensis drug effects, Camellia sinensis growth & development, Dose-Response Relationship, Drug, Hydroponics, Oxidative Stress drug effects, Plant Leaves drug effects, Plant Leaves growth & development, Plant Roots drug effects, Plant Roots growth & development, Plant Roots metabolism, Aluminum metabolism, Camellia sinensis metabolism, Iron metabolism, Plant Leaves metabolism

Abstract

Tea plants (Camellia sinensis) are well adapted to acid soils with high Al availability. These plants not only accumulate high leaf Al concentrations, but also respond to Al with growth stimulation. Decreased oxidative stress has been associated with this effect. Why tea plants not exposed to Al suffer from oxidative stress has not been clarified. In this study, hydroponically grown tea plants treated with 0 to 300 μM Al were analyzed for growth, Al and Fe accumulation, and Al distribution by means of morin and hematoxylin staining. Roots of control plants stained black with hematoxylin. This indicates the formation of a Fe-hematoxylin complex. Young leaves of controls accumulated more than 1000 mg Fe kg(-1) dry weight. This concentration is above the Fe-toxicity threshold in most species. Supply of Al stimulated growth and reduced Fe uptake and transport. These results indicate that Al-induced growth stimulation might be due to alleviation of a latent Fe toxicity occurring in tea plants without Al supply., (© 2013.)

Published

2013

47. The barley MATE gene, HvAACT1, increases citrate efflux and Al(3+) tolerance when expressed in wheat and barley.

Author

Zhou G, Delhaize E, Zhou M, and Ryan PR

Subjects

Carrier Proteins genetics, Carrier Proteins metabolism, Hordeum metabolism, Plant Proteins genetics, Plant Proteins metabolism, Plants, Genetically Modified metabolism, Aluminum metabolism, Carrier Proteins physiology, Citric Acid metabolism, Hordeum genetics, Plant Proteins physiology, Triticum genetics

Abstract

Background and Aims: Aluminium is toxic in acid soils because the soluble Al(3+) inhibits root growth. A mechanism of Al(3+) tolerance discovered in many plant species involves the release of organic anions from root apices. The Al(3+)-activated release of citrate from the root apices of Al(3+)-tolerant genotypes of barley is controlled by a MATE gene named HvAACT1 that encodes a citrate transport protein located on the plasma membrane. The aim of this study was to investigate whether expressing HvAACT1 with a constitutive promoter in barley and wheat can increase citrate efflux and Al(3+) tolerance of these important cereal species., Methods: HvAACT1 was over-expressed in wheat (Triticum aestivum) and barley (Hordeum vulgare) using the maize ubiquitin promoter. Root apices of transgenic and control lines were analysed for HvAACT1 expression and organic acid efflux. The Al(3+) tolerance of transgenic and control lines was assessed in both hydroponic solution and acid soil., Key Results and Conclusions: Increased HvAACT1 expression in both cereal species was associated with increased citrate efflux from root apices and enhanced Al(3+) tolerance, thus demonstrating that biotechnology can complement traditional breeding practices to increase the Al(3+) tolerance of important crop plants.

Published

2013

48. The role of the plasma membrane in the response of plant roots to aluminum toxicity.

Author

Ahn SJ and Matsumoto H

Abstract

Al(3+), the predominant form of solubilized aluminum at pH values below 5.0, has been shown to exert a profound inhibitory effect on root elongation. Al is known to accumulate at the root apex. The plasma membrane represents the first potential target for Al toxicity, due to its pronounced binding to phospholipids. Al appears to alter both the structure and functions of the plasma membrane, and a great deal of research has been conducted concerning the interactions between Al and the plasma membrane. In this review, recent findings regarding the interactions between Al and the plasma membrane are described, specifically findings involving Al-induced alterations in the structure and function of the plasma membrane.

Published

2006