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4. Duplicate and Conquer: Multiple Homologs of PHOSPHORUS-STARVATION TOLERANCE1 Enhance Phosphorus Acquisition and Sorghum Performance on Low-Phosphorus Soils

Author

Hufnagel, Barbara, de Sousa, Sylvia M., Assis, Lidianne, Guimaraes, Claudia T., Leiser, Willmar, Azevedo, Gabriel C., Negri, Barbara, Larson, Brandon G., Shaff, Jon E., Pastina, Maria Marta, Barros, Beatriz A., Weltzien, Eva, Rattunde, Henry Frederick W., Viana, Joao H., Clark, Randy T., Falcão, Alexandre, Gazaffi, Rodrigo, Garcia, Antonio Augusto F., Schaffert, Robert E., Kochian, Leon V., and Magalhaes, Jurandir V.

Published
2014
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13. Identification and characterization of Aluminum tolerance loci in Arabidopsis (Landsberg erecta x Columbia) by quantitative trait locus mapping. A physiologically simple but genetically complex trait (1)

Author

Hoekenga, Owen A., Vision, Todd J., Shaff, Jon E., Monforte, Antonio J., Lee, Gung Pyo, Howell, Stephen H., and Kochian, Leon V.

Subjects
Aluminum -- Physiological aspects, Arabidopsis -- Physiological aspects, Arabidopsis -- Genetic aspects, Arabidopsis -- Research, Phytochemistry -- Research, Phytochemistry -- Genetic aspects, Biological sciences, Science and technology
Published
2003

18. Adaption of Roots to Nitrogen Deficiency Revealed by 3D Quantification and Proteomic Analysis1[OPEN]

Author

Qin, Lu, Walk, Thomas C., Han, Peipei, Chen, Liyu, Zhang, Sheng, Li, Yinshui, Hu, Xiaojia, Xie, Lihua, Yang, Yong, Liu, Jiping, Lu, Xing, Yu, Changbing, Tian, Jiang, Shaff, Jon E, Kochian, Leon V., Liao, Xing, and Liao, Hong

Subjects
Proteomics, Cell Wall, Nitrogen, Stress, Physiological, Brassica napus, sense organs, skin and connective tissue diseases, Adaptation, Physiological, Plant Roots, Research Articles, Peroxidase, Plant Proteins
Abstract

Proteomics analysis reveals the mechanisms underlying root architectural changes in response to N deficiency.

Published
2018

20. Evolving technologies for growing, imaging and analyzing 3D root system architecture of crop plants

Author

Piñeros, Miguel A., Larson, Brandon G., Shaff, Jon E., Schneider, David J., Falcão, Alexandre Xavier, Yuan, Lixing, Clark, Randy T., Craft, Eric J., Davis, Tyler W., Pradier, Pierre-Luc, Shaw, Nathanael M., Assaranurak, Ithipong, McCouch, Susan R., Sturrock, Craig, Bennett, Malcolm, and Kochian, Leon V.

Abstract

A plant's ability to maintain or improve its yield under limiting conditions, such as nutrient deficiency or drought, can be strongly influenced by root system architecture (RSA), the three-dimensional distribution of the different root types in the soil. The ability to image, track and quantify these root system attributes in a dynamic fashion is a useful tool in assessing desirable genetic and physiological root traits. Recent advances in imaging technology and phenotyping software have resulted in substantive progress in describing and quantifying RSA. We have designed a hydroponic growth system which retains the three-dimensional RSA of the plant root system, while allowing for aeration, solution replenishment and the imposition of nutrient treatments, as well as high-quality imaging of the root system. The simplicity and flexibility of the system allows for modifications tailored to the RSA of different crop species and improved throughput. This paper details the recent improvements and innovations in our root growth and imaging system which allows for greater image sensitivity (detection of fine roots and other root details), higher efficiency, and a broad array of growing conditions for plants that more closely mimic those found under field conditions.

Published
2016

21. Evolving technologies for growing, imaging and analyzing 3D root system architecture of crop plants: Digital phenotyping of root system architecture

Author

Larson, Brandon G., Shaff, Jon E., Schneider, David J., Yuan, Lixing, Clark, Randy T., Craft, Eric J., Davis, Tyler W., Pradier, Pierre-Luc, Shaw, Nathanael M., Assaranurak, Ithipong, McCouch, Susan R., Sturrock, Craig, Bennett, Malcolm J., and Kochian, Leon V.

Subjects
digital root phenotyping, mineral nutritionroot system architecture, Abiotic stress
Abstract

A plant's ability to maintain or improve its yield under limiting conditions, such as nutrient deficiency or drought, can be strongly influenced by root system architecture (RSA), the three-dimensional distribution of the different root types in the soil. The ability to image, track and quantify these root system attributes in a dynamic fashion is a useful tool in assessing desirable genetic and physiological root traits. Recent advances in imaging technology and phenotyping software have resulted in substantive progress in describing and quantifying RSA. We have designed a hydroponic growth system which retains the three-dimensional RSA of the plant root system, while allowing for aeration, solution replenishment and the imposition of nutrient treatments, as well as high-quality imaging of the root system. The simplicity and flexibility of the system allows for modifications tailored to the RSA of different crop species and improved throughput. This paper details the recent improvements and innovations in our root growth and imaging system which allows for greater image sensitivity (detection of fine roots and other root details), higher efficiency, and a broad array of growing conditions for plants that more closely mimic those found under field conditions.

Published
2016

23. Molecular and Physiological Analysis of Al3+ and H+ Rhizotoxicities at Moderately Acidic Conditions1[W][OPEN]

Author

Kobayashi, Yasufumi, Kobayashi, Yuriko, Watanabe, Toshihiro, Shaff, Jon E., Ohta, Hiroyuki, Kochian, Leon V., Wagatsuma, Tadao, Kinraide, Thomas B., and Koyama, Hiroyuki

Subjects
integumentary system, Models, Genetic, Arabidopsis Proteins, Cell Membrane, Arabidopsis, Hydrogen-Ion Concentration, Plant Roots, Gene Knockout Techniques, Soil, Stress, Physiological, Calcium, Ecophysiology and Sustainability, Aluminum, Hydrogen
Abstract

Al³⁺ and H⁺ toxicities predicted to occur at moderately acidic conditions (pH [water] = 5-5.5) in low-Ca soils were characterized by the combined approaches of computational modeling of electrostatic interactions of ions at the root plasma membrane (PM) surface and molecular/physiological analyses in Arabidopsis (Arabidopsis thaliana). Root growth inhibition in known hypersensitive mutants was correlated with computed {Al³⁺} at the PM surface ({Al³⁺}(PM)); inhibition was alleviated by increased Ca, which also reduced {Al³⁺}(PM) and correlated with cellular Al responses based on expression analysis of genes that are markers for Al stress. The Al-inducible Al tolerance genes ALUMINUM-ACTIVATED MALATE TRANSPORTER1 and ALUMINUM SENSITIVE3 were induced by levels of {Al³⁺}(PM) too low to inhibit root growth in tolerant genotypes, indicating that protective responses are triggered when {Al³⁺}(PM) was below levels that can initiate injury. Modeling of the H⁺ sensitivity of the SENSITIVE TO PROTON RHIZOTOXICITY1 knockout mutant identified a Ca alleviation mechanism of H⁺ rhizotoxicity, possibly involving stabilization of the cell wall. The phosphatidate phosphohydrolase1 (pah1) pah2 double mutant showed enhanced Al susceptibility under low-P conditions, where greater levels of negatively charged phospholipids in the PM occur, which increases {Al³⁺}(PM) through increased PM surface negativity compared with wild-type plants. Finally, we found that the nonalkalinizing Ca fertilizer gypsum improved the tolerance of the sensitive genotypes in moderately acidic soils. These findings fit our modeling predictions that root toxicity to Al³⁺ and H⁺ in moderately acidic soils involves interactions between both toxic ions in relation to Ca alleviation.

Published
2013

24. Aluminum Resistance in Maize Cannot Be Solely Explained by Root Organic Acid Exudation. A Comparative Physiological Study1[w]

Author

Piñeros, Miguel A., Shaff, Jon E., Manslank, Holly S., Carvalho Alves, Vera M., and Kochian, Leon V.

Subjects
Soil, Time Factors, Genotype, Carboxylic Acids, Hydrogen-Ion Concentration, Plant Roots, Zea mays, Citric Acid, Research Article, Aluminum
Abstract

Root apical aluminum (Al) exclusion via Al-activated root citrate exudation is widely accepted as the main Al-resistance mechanism operating in maize (Zea mays) roots. Nonetheless, the correlation between Al resistance and this Al-exclusion mechanism has not been tested beyond a very small number of Al-resistant and Al-sensitive maize lines. In this study, we conducted a comparative study of the physiology of Al resistance using six different maize genotypes that capture the range of maize Al resistance and differ significantly in their genetic background (three Brazilian and three North American genotypes). In these maize lines, we were able to establish a clear correlation between root tip Al exclusion (based on root Al content) and Al resistance. Both Al-resistant genotypes and three of the four Al-sensitive lines exhibited a significant Al-activated citrate exudation, with no evidence for Al activation of root malate or phosphate release. There was a lack of correlation between differential Al resistance and root citrate exudation for the six maize genotypes; in fact, one of the Al-sensitive lines, Mo17, had the largest Al-activated citrate exudation of all of the maize lines. Our results indicate that although root organic acid release may play a role in maize Al resistance, it is clearly not the only or the main resistance mechanism operating in these maize roots. A number of other potential Al-resistance mechanisms were investigated, including release of other Al-chelating ligands, Al-induced alkalinization of rhizosphere pH, changes in internal levels of Al-chelating compounds in the root, and Al translocation to the shoot. However, we were unsuccessful in identifying additional Al-resistance mechanisms in maize. It is likely that a purely physiological approach may not be sufficient to identify these novel Al-resistance mechanisms in maize and this will require an interdisciplinary approach integrating genetic, molecular, and physiological investigations.

Published
2005

25. Identification and Characterization of Aluminum Tolerance Loci in Arabidopsis (Landsberg erecta × Columbia) by Quantitative Trait Locus Mapping. A Physiologically Simple But Genetically Complex Trait1

Author

Hoekenga, Owen A., Vision, Todd J., Shaff, Jon E., Monforte, Antonio J., Lee, Gung Pyo, Howell, Stephen H., and Kochian, Leon V.

Subjects
Polymorphism, Genetic, Time Factors, Species Specificity, Quantitative Trait Loci, Arabidopsis, Malates, Citrates, Drug Tolerance, Plant Roots, Research Article, Aluminum, Enzymes, Phosphates
Abstract

Aluminum (Al) toxicity, which is caused by the solubilization of Al3+ in acid soils resulting in inhibition of root growth and nutrient/water acquisition, is a serious limitation to crop production, because up to one-half of the world's potentially arable land is acidic. To date, however, no Al tolerance genes have yet been cloned. The physiological mechanisms of tolerance are somewhat better understood; the major documented mechanism involves the Al-activated release of Al-binding organic acids from the root tip, preventing uptake into the primary site of toxicity. In this study, a quantitative trait loci analysis of Al tolerance in Arabidopsis was conducted, which also correlated Al tolerance quantitative trait locus (QTL) with physiological mechanisms of tolerance. The analysis identified two major loci, which explain approximately 40% of the variance in Al tolerance observed among recombinant inbred lines derived from Landsberg erecta (sensitive) and Columbia (tolerant). We characterized the mechanism by which tolerance is achieved, and we found that the two QTL cosegregate with an Al-activated release of malate from Arabidopsis roots. Although only two of the QTL have been identified, malate release explains nearly all (95%) of the variation in Al tolerance in this population. Al tolerance in Landsberg erecta × Columbia is more complex genetically than physiologically, in that a number of genes underlie a single physiological mechanism involving root malate release. These findings have set the stage for the subsequent cloning of the genes responsible for the Al tolerance QTL, and a genomics-based cloning strategy and initial progress on this are also discussed.

Published
2003

26. Aluminum Effects on Calcium Fluxes at the Root Apex of Aluminum-Tolerant and Aluminum-Sensitive Wheat Cultivars 1

Author

Huang, Jianwei W., Shaff, Jon E., Grunes, David L., and Kochian, Leon V.

Subjects
food and beverages, Environmental and Stress Physiology
Abstract

The role of Ca(2+) transport in the mechanism of Al toxicity was investigated, using a Ca(2+)-selective microelectrode system to study Al effects on root apical Ca(2+) fluxes in two wheat (Triticum aestivum L.) cultivars: Al-tolerant Atlas 66 and Al-sensitive Scout 66. Intact 3-day-old low-salt-grown (100 micromolar CaCl(2), pH 4.5) wheat seedlings were used, and it was found that both cultivars maintained similar rates of net Ca(2+) uptake in the absence of Al. Addition of Al concentrations that were toxic to Scout (5-20 micromolar AlCl(3)) immediately and dramatically inhibited Ca(2+) uptake in Scout, whereas Ca(2+) transport in Atlas was relatively unaffected. The Al-induced inhibition of Ca(2+) uptake in Scout 66 was rapidly reversed following removal of Al from the solution bathing the roots. Similar studies with morphologically intact root cell wall preparations indicated that the Al effects did not involve Al-Ca interactions in the cell wall. These results suggest that Al inhibits Ca(2+) influx across the root plasmalemma, possibly via blockage of calcium channels. The differential effect of Al on Ca(2+) transport in Al-sensitive Scout and Al-tolerant Atlas suggests that Al blockage of Ca(2+) channels could play a role in the cellular mechanism of Al toxicity in higher plants.

Published
1992

27. Molecular and Physiological Analysis of Al3+ and H+ Rhizotoxicities at Moderately Acidic Conditions.

Author

Yasufumi Kobayashi, Yuriko Kobayashi, Toshihiro Watanabe, Shaff, Jon E., Hiroyuki Ohta, Leon V. Kochian, Tadao Wagatsuma, Kinraide, Thomas B., and Hiroyuki Koyama

Subjects
TOXICOLOGY of aluminum, HYDROGEN ions, SOIL acidity, ELECTROSTATIC interaction, PLANT roots, ARABIDOPSIS thaliana, CALCIUM in soils, PHOSPHATIDATE phosphatase
Abstract

Al3+ and H+ toxicities predicted to occur at moderately acidic conditions (pH [water] = 5-5.5) in low-Ca soils were characterized by the combined approaches of computational modeling of electrostatic interactions of ions at the root plasma membrane (PM) surface and molecular/physiological analyses in Arabidopsis (Arabidopsis thaliana). Root growth inhibition in known hypersensitive mutants was correlated with computed {Al3+} at the PM surface ({Al3+}PM); inhibition was alleviated by increased Ca, which also reduced {A13+}PM and correlated with cellular Al responses based on expression analysis of genes that are markers for Al stress. The Al-inducible Al tolerance+ genes ALUMINUM-ACTIVATED MALATE TRANSPORTER1 and ALUMINUM SENSITIVE3 were induced by levels of {A13+ }PM too low to inhibit root growth in tolerant genotypes, indicating that protective responses are triggered when {A13+}PM was below levels that can initiate injury. Modeling of the H+ sensitivity of the SENSITIVE TO PROTON RHIZOTOXICITY1 knockout mutant identified a Ca alleviation mechanism of H+ rhizotoxicity, possibly involving stabilization of the cell wall. The phosphatidate phosphohydrolasel (pah1) pah2 double mutant showed enhanced Al susceptibility under low-P conditions, where greater levels of negatively charged phospholipids in the PM occur, which increases {Al3+}PM through increased PM surface negativity compared with wild-type plants. Finally, we found that the nonalkalinizing Ca fertilizer gypsum improved the tolerance of the sensitive genotypes in moderately acidic soils. These findings fit our modeling predictions that root toxicity to Al3+ and H+ in moderately acidic soils involves interactions between both toxic ions in relation to Ca alleviation. [ABSTRACT FROM AUTHOR]

Published
2013
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28. High-throughput two-dimensional root system phenotyping platform facilitates genetic analysis of root growth and development.

Author

CLARK, RANDY T., FAMOSO, ADAM N., ZHAO, KEYAN, SHAFF, JON E., CRAFT, ERIC J., BUSTAMANTE, CARLOS D., MCCOUCH, SUSAN R., ANESHANSLEY, DANIEL J., and KOCHIAN, LEON V.

Subjects
ROOT growth, ROOT development, PHENOTYPES, PLANT genetics, CORN, RICE, EFFECT of aluminum on plants
Abstract

ABSTRACT High-throughput phenotyping of root systems requires a combination of specialized techniques and adaptable plant growth, root imaging and software tools. A custom phenotyping platform was designed to capture images of whole root systems, and novel software tools were developed to process and analyse these images. The platform and its components are adaptable to a wide range root phenotyping studies using diverse growth systems (hydroponics, paper pouches, gel and soil) involving several plant species, including, but not limited to, rice, maize, sorghum, tomato and Arabidopsis. The RootReader2D software tool is free and publicly available and was designed with both user-guided and automated features that increase flexibility and enhance efficiency when measuring root growth traits from specific roots or entire root systems during large-scale phenotyping studies. To demonstrate the unique capabilities and high-throughput capacity of this phenotyping platform for studying root systems, genome-wide association studies on rice ( Oryza sativa) and maize ( Zea mays) root growth were performed and root traits related to aluminium (Al) tolerance were analysed on the parents of the maize nested association mapping (NAM) population. [ABSTRACT FROM AUTHOR]

Published
2013
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29. A gene in the multidrug and toxic compound extrusion (MATE) family confers aluminum tolerance in sorghum.

Author

Magalhaes, Jurandir V., Jiping Liu, Guimarães, Claudia T., Lana, Ubiraci G. P., Alves, Vera M. C., Yi-Hong Wang, Schaffert, Robert E., Hoekenga, Owen A., Piñeros, Miguel A., Shaff, Jon E., Klein, Patricia E., Carneiro, Newton P., Coelho, Cintia M., Trick, Harold N., and Kochian, Leon V.

Subjects
GENETIC polymorphisms, SORGHUM, GENE expression, FORAGE plants, ORGANIC acids, GENETIC engineering
Abstract

Crop yields are significantly reduced by aluminum toxicity on highly acidic soils, which comprise up to 50% of the world's arable land. Candidate aluminum tolerance proteins include organic acid efflux transporters, with the organic acids forming non-toxic complexes with rhizosphere aluminum. In this study, we used positional cloning to identify the gene encoding a member of the multidrug and toxic compound extrusion (MATE) family, an aluminum-activated citrate transporter, as responsible for the major sorghum (Sorghum bicolor) aluminum tolerance locus, AltSB. Polymorphisms in regulatory regions of AltSB are likely to contribute to large allelic effects, acting to increase AltSB expression in the root apex of tolerant genotypes. Furthermore, aluminum-inducible AltSB expression is associated with induction of aluminum tolerance via enhanced root citrate exudation. These findings will allow us to identify superior AltSB haplotypes that can be incorporated via molecular breeding and biotechnology into acid soil breeding programs, thus helping to increase crop yields in developing countries where acidic soils predominate. [ABSTRACT FROM AUTHOR]

Published
2007
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