Your search keyword '"Dhankher, Om Parkash"' showing total 212 results

201. Nanoscale Sulfur Improves Plant Growth and Reduces Arsenic Toxicity and Accumulation in Rice ( Oryza sativa L.).

Author

G Meselhy A, Sharma S, Guo Z, Singh G, Yuan H, Tripathi RD, Xing B, Musante C, White JC, and Dhankher OP

Subjects

Humans, Plant Roots chemistry, Seedlings, Sulfur, Arsenic toxicity, Oryza, Soil Pollutants analysis, Soil Pollutants toxicity

Abstract

Rice is known to accumulate arsenic (As) in its grains, posing serious health concerns for billions of people globally. We studied the effect of nanoscale sulfur (NS) on rice seedlings and mature plants under As stress. NS application caused a 40% increase in seedling biomass and a 26% increase in seed yield of mature plants compared to untreated control plants. AsIII exposure caused severe toxicity to rice; however, coexposure of plants to AsIII and NS alleviated As toxicity, and growth was significantly improved. Rice seedlings treated with AsIII + NS produced 159 and 248% more shoot and root biomass, respectively, compared to plants exposed to AsIII alone. Further, AsIII + NS-treated seedlings accumulated 32 and 11% less As in root and shoot tissues, respectively, than the AsIII-alone treatment. Mature plants treated with AsIII + NS produced 76, 110, and 108% more dry shoot biomass, seed number, and seed yield, respectively, and accumulated 69, 38, 18, and 54% less total As in the root, shoot, flag leaves, and grains, respectively, compared to AsIII-alone-treated plants. A similar trend was observed in seedlings treated with AsV and NS. The ability of sulfur (S) to alleviate As toxicity and accumulation is clearly size dependent as NS could effectively reduce bioavailability and accumulation of As in rice via modulating the gene expression activity of As transport, S assimilatory, and glutathione synthesis pathways to facilitate AsIII detoxification. These results have significant environmental implications as NS application in agriculture has the potential to decrease As in the food chain and simultaneously enable crops to grow and produce higher yields on marginal and contaminated lands.

Published

2021

202. Comparative transcriptome and metabolome analysis suggests bottlenecks that limit seed and oil yields in transgenic Camelina sativa expressing diacylglycerol acyltransferase 1 and glycerol-3-phosphate dehydrogenase.

Author

Abdullah HM, Chhikara S, Akbari P, Schnell DJ, Pareek A, and Dhankher OP

Abstract

Background: Camelina sativa has attracted much interest as alternative renewable resources for biodiesel, other oil-based industrial products and a source for edible oils. Its unique oil attributes attract research to engineering new varieties of improved oil quantity and quality. The overexpression of enzymes catalyzing the synthesis of the glycerol backbone and the sequential conjugation of fatty acids into this backbone is a promising approach for increasing the levels of triacylglycerol (TAG). In a previous study, we co-expressed the diacylglycerol acyltransferase (DGAT1) and glycerol-3-phosphate dehydrogenase (GPD1), involved in TAG metabolism, in Camelina seeds. Transgenic plants exhibited a higher-percentage seed oil content, a greater seed mass, and overall improved seed and oil yields relative to wild-type plants. To further increase seed oil content in Camelina, we utilized metabolite profiling, in conjunction with transcriptome profiling during seed development to examine potential rate-limiting step(s) in the production of building blocks for TAG biosynthesis., Results: Transcriptomic analysis revealed approximately 2518 and 3136 transcripts differentially regulated at significant levels in DGAT1 and GPD1 transgenics, respectively. These transcripts were found to be involved in various functional categories, including alternative metabolic routes in fatty acid synthesis, TAG assembly, and TAG degradation. We quantified the relative contents of over 240 metabolites. Our results indicate major metabolic switches in transgenic seeds associated with significant changes in the levels of glycerolipids, amino acids, sugars, and organic acids, especially the TCA cycle and glycolysis intermediates., Conclusions: From the transcriptomic and metabolomic analysis of DGAT1, GPD1 and DGAT1 + GPD1 expressing lines of C. sativa , we conclude that TAG production is limited by (1) utilization of fixed carbon from the source tissues supported by the increase in glycolysis pathway metabolites and decreased transcripts levels of transcription factors controlling fatty acids synthesis; (2) TAG accumulation is limited by the activity of lipases/hydrolases that hydrolyze TAG pool supported by the increase in free fatty acids and monoacylglycerols. This comparative transcriptomics and metabolomics approach is useful in understanding the regulation of TAG biosynthesis, identifying bottlenecks, and the corresponding genes controlling these pathways identified as limitations, for generating Camelina varieties with improved seed and oil yields.

Published

2018

203. Growth, physiological adaptation, and NHX gene expression analysis of Iris halophila under salt stress.

Author

Yang Y, Guo Z, Liu Q, Tang J, Huang S, Dhankher OP, and Yuan H

Subjects

Iris Plant genetics, Iris Plant growth & development, Plant Leaves genetics, Plant Leaves growth & development, Plant Leaves physiology, Plant Roots genetics, Plant Roots growth & development, Potassium metabolism, Proline metabolism, RNA, Plant metabolism, Seedlings metabolism, Sodium metabolism, Sugars metabolism, Iris Plant physiology, Plant Roots physiology, Salt Stress genetics, Salt Tolerance genetics, Sodium-Hydrogen Exchangers genetics

Abstract

This study investigated the growth, physiological changes, and the transcript levels of NHX1 gene of Iris halophila in response to low NaCl concentration (50 mM) and high NaCl concentration (150 mM). Our results showed that both 50 and 150 mM NaCl had no obvious negative effects on plant growth; what is more, low NaCl concentration (50 mM) increased root length, root fresh weight, and the ratio of root length to leaf length compared with the control group. The malondialdehyde (MDA) contents in leaves and roots of I. halophila had no obvious difference as compared with control. Proline levels of I. halophila exhibited basically an enhancement under salt stress conditions. Particularly at 4 days, the proline contents in leaves reached 1.85 to 2.31-fold higher and the contents in roots reached 1.27 to 1.62-fold higher than that of control at 50 and 150 mM NaCl, respectively. The contents of the soluble sugar in leaves and roots of I. halophila under 150 mM NaCl at 7 days were 32.4 and 98.7% higher than that of control, respectively. The increase rate of K + contents with the increasing concentration of salt was less than that of Na + contents, but K + contents in the seedlings under NaCl stress was still higher than Na + contents and the ratio of K + to Na + was also greater than 1. The transcript levels of IhNHX1 in leaves of I. halophila at 4 and 7 days under 150 mM NaCl were higher than that of control; however, the transcript levels of IhNHX1 in roots had no significant difference compared with the control under low and high salt stress at 1, 4, and 7 days. Therefore, salt tolerance in I. halophila could be partially due to higher proline, soluble sugar, and K + accumulation.

Published

2018

204. Engineering Camelina sativa (L.) Crantz for enhanced oil and seed yields by combining diacylglycerol acyltransferase1 and glycerol-3-phosphate dehydrogenase expression.

Author

Chhikara S, Abdullah HM, Akbari P, Schnell D, and Dhankher OP

Subjects

Arabidopsis enzymology, Arabidopsis genetics, Arabidopsis Proteins metabolism, Biofuels, Brassicaceae genetics, Brassicaceae growth & development, Diacylglycerol O-Acyltransferase genetics, Gene Expression, Glycerol-3-Phosphate Dehydrogenase (NAD+) metabolism, Glycerolphosphate Dehydrogenase genetics, Lipid Metabolism, Metabolic Engineering, Organ Specificity, Plants, Genetically Modified, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism, Seeds genetics, Seeds growth & development, Seeds metabolism, Arabidopsis Proteins genetics, Brassicaceae metabolism, Diacylglycerol O-Acyltransferase metabolism, Glycerol-3-Phosphate Dehydrogenase (NAD+) genetics, Glycerolphosphate Dehydrogenase metabolism, Plant Oils metabolism, Saccharomyces cerevisiae Proteins genetics

Abstract

Plant seed oil-based liquid transportation fuels (i.e., biodiesel and green diesel) have tremendous potential as environmentally, economically and technologically feasible alternatives to petroleum-derived fuels. Due to their nutritional and industrial importance, one of the major objectives is to increase the seed yield and oil production of oilseed crops via biotechnological approaches. Camelina sativa, an emerging oilseed crop, has been proposed as an ideal crop for biodiesel and bioproduct applications. Further increase in seed oil yield by increasing the flux of carbon from increased photosynthesis into triacylglycerol (TAG) synthesis will make this crop more profitable. To increase the oil yield, we engineered Camelina by co-expressing the Arabidopsis thaliana (L.) Heynh. diacylglycerol acyltransferase1 (DGAT1) and a yeast cytosolic glycerol-3-phosphate dehydrogenase (GPD1) genes under the control of seed-specific promoters. Plants co-expressing DGAT1 and GPD1 exhibited up to 13% higher seed oil content and up to 52% increase in seed mass compared to wild-type plants. Further, DGAT1- and GDP1-co-expressing lines showed significantly higher seed and oil yields on a dry weight basis than the wild-type controls or plants expressing DGAT1 and GPD1 alone. The oil harvest index (g oil per g total dry matter) for DGTA1- and GPD1-co-expressing lines was almost twofold higher as compared to wild type and the lines expressing DGAT1 and GPD1 alone. Therefore, combining the overexpression of TAG biosynthetic genes, DGAT1 and GPD1, appears to be a positive strategy to achieve a synergistic effect on the flux through the TAG synthesis pathway, and thereby further increase the oil yield., (© 2017 The Authors. Plant Biotechnology Journal published by Society for Experimental Biology and The Association of Applied Biologists and John Wiley & Sons Ltd.)

Published

2018

205. Sulfur mediated reduction of arsenic toxicity involves efficient thiol metabolism and the antioxidant defense system in rice.

Author

Dixit G, Singh AP, Kumar A, Singh PK, Kumar S, Dwivedi S, Trivedi PK, Pandey V, Norton GJ, Dhankher OP, and Tripathi RD

Subjects

Biomass, Carrier Proteins metabolism, Glutathione metabolism, Hydrogen Peroxide metabolism, Metabolic Networks and Pathways, Oryza enzymology, Oxidative Stress drug effects, Phytochelatins, Plant Roots metabolism, Antioxidants metabolism, Arsenic toxicity, Oryza metabolism, Sulfhydryl Compounds metabolism, Sulfur pharmacology

Abstract

Arsenic (As) contamination is a global issue, with South Asia and South East Asia being worst affected. Rice is major crop in these regions and can potentially pose serious health risks due to its known As accumulation potential. Sulfur (S) is an essential macronutrient and a vital element to combat As toxicity. The aim of this study was to investigate the role of S with regards to As toxicity in rice under different S regimes. To achieve this aim, plants were stressed with AsIII and AsV under three different S conditions (low sulfur (0.5mM), normal sulfur (3.5mM) and high sulfur (5.0mM)). High S treatment resulted in increased root As accumulation, likely due to As complexation through enhanced synthesis of thiolic ligands, such as non-protein thiols and phytochelatins, which restricted As translocation to the shoots. Enzymes of S assimilatory pathways and downstream thiolic metabolites were up-regulated with increased S supplementation; however, to maintain optimum concentrations of S, transcript levels of sulfate transporters were down-regulated at high S concentration. Oxidative stress generated due to As was counterbalanced in the high S treatment by reducing hydrogen peroxide concentration and enhancing antioxidant enzyme activities. The high S concentration resulted in reduced transcript levels of Lsi2 (a known transporter of As). This reduction in Lsi2 expression level is a probable reason for low shoot As accumulation, which has potential implications in reducing the risk of As in the food chain., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2015

206. Two rice plasma membrane intrinsic proteins, OsPIP2;4 and OsPIP2;7, are involved in transport and providing tolerance to boron toxicity.

Author

Kumar K, Mosa KA, Chhikara S, Musante C, White JC, and Dhankher OP

Subjects

ATP-Binding Cassette Transporters genetics, ATP-Binding Cassette Transporters metabolism, Arabidopsis drug effects, Arabidopsis genetics, Biological Transport drug effects, Boron pharmacokinetics, Gene Expression Regulation, Plant drug effects, Membrane Proteins genetics, Membrane Transport Proteins genetics, Membrane Transport Proteins metabolism, Oryza drug effects, Oryza genetics, Plant Leaves genetics, Plant Leaves metabolism, Plant Proteins genetics, Plant Roots genetics, Plant Roots metabolism, Plants, Genetically Modified, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Boron toxicity, Membrane Proteins metabolism, Oryza metabolism, Plant Proteins metabolism

Abstract

Boron (B) toxicity is responsible for low cereal crop production in a number of regions worldwide. In this report, we characterized two rice genes, OsPIP2;4 and OsPIP2;7, for their involvement in B permeability and tolerance. Transcript analysis demonstrated that the expression of OsPIP2;4 and OsPIP2;7 were downregulated in shoots and strongly upregulated in rice roots by high B treatment. Expression of both OsPIP2;4 and OsPIP2;7 in yeast HD9 strain lacking Fps1, ACR3, and Ycf1 resulted in an increased B sensitivity. Furthermore, yeast HD9 strain expressing OsPIP2;4 and OsPIP2;7 accumulated significantly higher B as compared to empty vector control, which suggests their involvement in B transport. Overexpression of OsPIP2;4 and OsPIP2;7 in Arabidopsis imparted higher tolerance under B toxicity. Arabidopsis lines overexpressing OsPIP2;4 and OsPIP2;7 showed significantly higher biomass production and greater root length, however there was no difference in B accumulation in long term uptake assay. Short-term uptake assay using tracer B (¹⁰B) in shoots and roots demonstrated increased ¹⁰B accumulation in Arabidopsis lines expressing OsPIP2;4 and OsPIP2;7, compare to wild type control plants. Efflux assay of B in the roots showed that ¹⁰B was effluxed from the Arabidopsis transgenic plants overexpressing OsPIP2;4 or OsPIP2;7 during the initial 1-h of assay. These data indicate that OsPIP2;4 and OsPIP2;7 are involved in mediating B transport in rice and provide tolerance via efflux of excess B from roots and shoot tissues. These genes will be highly useful in developing B tolerant crops for enhanced yield in the areas affected by high B toxicity.

Published

2014

207. A γ-glutamyl cyclotransferase protects Arabidopsis plants from heavy metal toxicity by recycling glutamate to maintain glutathione homeostasis.

Author

Paulose B, Chhikara S, Coomey J, Jung HI, Vatamaniuk O, and Dhankher OP

Subjects

Arabidopsis enzymology, Arabidopsis genetics, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Arsenites toxicity, Cadmium toxicity, DNA, Bacterial, Gene Expression Regulation, Plant drug effects, Homeostasis drug effects, Inactivation, Metabolic, Mutagenesis, Insertional, Nitrogen metabolism, Plants, Genetically Modified, Pyrrolidonecarboxylic Acid metabolism, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae genetics, gamma-Glutamylcyclotransferase genetics, Arabidopsis drug effects, Arabidopsis metabolism, Glutamic Acid metabolism, Glutathione metabolism, Metals, Heavy toxicity, gamma-Glutamylcyclotransferase metabolism

Abstract

Plants detoxify toxic metals through a GSH-dependent pathway. GSH homeostasis is maintained by the γ-glutamyl cycle, which involves GSH synthesis and degradation and the recycling of component amino acids. The enzyme γ-glutamyl cyclotransferase (GGCT) is involved in Glu recycling, but the gene(s) encoding GGCT has not been identified in plants. Here, we report that an Arabidopsis thaliana protein with a cation transport regulator-like domain, hereafter referred to as GGCT2;1, functions as γ-glutamyl cyclotransferase. Heterologous expression of GGCT2;1 in Saccharomyces cerevisiae produced phenotypes that were consistent with decreased GSH content attributable to either GSH degradation or the diversion of γ-glutamyl peptides to produce 5-oxoproline (5-OP). 5-OP levels were further increased by the addition of arsenite and GSH to the medium, indicating that GGCT2;1 participates in the cellular response to arsenic (As) via GSH degradation. Recombinant GGCT2;1 converted both GSH and γ-glutamyl Ala to 5-OP in vitro. GGCT2;1 transcripts were upregulated in As-treated Arabidopsis, and ggct2;1 knockout mutants were more tolerant to As and cadmium than the wild type. Overexpression of GGCT2;1 in Arabidopsis resulted in the accumulation of 5-OP. Under As toxicity, the overexpression lines showed minimal changes in de novo Glu synthesis, while the ggct2;1 mutant increased nitrogen assimilation by severalfold, resulting in a very low As/N ratio in tissue. Thus, our results suggest that GGCT2;1 ensures sufficient GSH turnover during abiotic stress by recycling Glu.

Published

2013

208. Hyperaccumulation of arsenic in the shoots of Arabidopsis silenced for arsenate reductase (ACR2).

Author

Dhankher OP, Rosen BP, McKinney EC, and Meagher RB

Subjects

Amino Acid Sequence, Arabidopsis enzymology, Arabidopsis genetics, Arabidopsis Proteins chemistry, Genetic Complementation Test, Molecular Sequence Data, Multienzyme Complexes, Oxidoreductases chemistry, Phosphorus metabolism, RNA Interference, Sequence Homology, Amino Acid, cdc25 Phosphatases, Arabidopsis metabolism, Arabidopsis Proteins genetics, Arsenic metabolism, Gene Silencing, Oxidoreductases genetics, Plant Shoots metabolism

Abstract

Endogenous plant arsenate reductase (ACR) activity converts arsenate to arsenite in roots, immobilizing arsenic below ground. By blocking this activity, we hoped to construct plants that would mobilize more arsenate aboveground. We have identified a single gene in the Arabidopsis thaliana genome, ACR2, with moderate sequence homology to yeast arsenate reductase. Expression of ACR2 cDNA in Escherichia coli complemented the arsenate-resistant and arsenate-sensitive phenotypes of various bacterial ars operon mutants. RNA interference reduced ACR2 protein expression in Arabidopsis to as low as 2% of wild-type levels. The various knockdown plant lines were more sensitive to high concentrations of arsenate, but not arsenite, than wild type. The knockdown lines accumulated 10- to 16-fold more arsenic in shoots (350-500 ppm) and retained less arsenic in roots than wild type, when grown on arsenate medium with <8 ppm arsenic. Reducing expression of ACR2 homologs in tree, shrub, and grass species should play a vital role in the phytoremediation of environmental arsenic contamination.

Published

2006

209. Arsenic metabolism in plants: an inside story.

Author

Dhankher OP

Subjects

Arsenic pharmacology, Biodegradation, Environmental, Biological Transport, Drug Tolerance, Inactivation, Metabolic, Plant Roots metabolism, Plant Shoots metabolism, Arsenic pharmacokinetics, Plants metabolism

Published

2005

210. Arsenic and mercury tolerance and cadmium sensitivity in Arabidopsis plants expressing bacterial gamma-glutamylcysteine synthetase.

Author

Li Y, Dhankher OP, Carreira L, Balish RS, and Meagher RB

Subjects

Arabidopsis genetics, Arabidopsis metabolism, Arsenic pharmacokinetics, Arsenic toxicity, Arsenic Poisoning genetics, Arsenic Poisoning metabolism, Bacterial Proteins biosynthesis, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Blotting, Western, Cadmium pharmacokinetics, Cadmium toxicity, Cadmium Poisoning genetics, Cadmium Poisoning metabolism, Chromatography, High Pressure Liquid, Cloning, Molecular, Escherichia coli genetics, Glutamate-Cysteine Ligase chemistry, Glutamate-Cysteine Ligase genetics, Glutamate-Cysteine Ligase metabolism, Glutathione biosynthesis, Glutathione metabolism, Mercury pharmacokinetics, Mercury toxicity, Mercury Poisoning genetics, Mercury Poisoning metabolism, Phytochelatins, Plant Diseases chemically induced, Plant Diseases genetics, Plants, Genetically Modified drug effects, Plants, Genetically Modified enzymology, Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Arabidopsis drug effects, Arabidopsis enzymology, Arsenic Poisoning prevention & control, Cadmium Poisoning prevention & control, Glutamate-Cysteine Ligase biosynthesis, Mercury Poisoning prevention & control

Abstract

Cysteine sulfhydryl-rich peptide thiols are believed to play important roles in the detoxification of many heavy metals and metalloids such as arsenic, mercury, and cadmium in plants. The gamma-glutamylcysteine synthetase (gamma-ECS) catalyzes the synthesis of the dipeptidethiol gamma-glu-cys (gamma-EC), the first step in the biosynthesis of phytochelatins (PCs). Arabidopsis thaliana, engineered to express the bacterial gamma-ECS gene under control of a strong constitutive actin regulatory sequence (A2), expressed gamma-ECS at levels approaching 0.1% of total protein. In response to arsenic, mercury, and cadmium stresses, the levels of gamma-EC and its derivatives, glutathione (GSH) and PCs, were increased in the A2::ECS transgenic plants to three- to 20-fold higher concentrations than the increases that occurred in wild-type (WT). Compared to cadmium and mercury treatments, arsenic treatment most significantly increased levels of gamma-EC and PCs in both the A2::ECS transgenic and WT plants. The A2::ECS transgenic plants were highly resistant to arsenic and weakly resistant to mercury. Although exposure to cadmium produced three- to fivefold increases in levels of gamma-EC-related peptides in the A2::ECS lines, these plants were significantly more sensitive to Cd(II) than WT and trace levels of Cd(II) blocked resistance to arsenic and mercury. A few possible mechanisms for gamma-ECS-enhanced arsenic and mercury resistance and cadmium hypersensitivity are discussed.

Published

2005

211. Increased cadmium tolerance and accumulation by plants expressing bacterial arsenate reductase.

Author

Dhankher OP, Shasti NA, Rosen BP, Fuhrmann M, and Meagher RB

Abstract

•  Cadmium (Cd) is a major environmental pollutant that poses a serious threat to natural ecosystems. However, most initial attempts to engineer phytoremediation of Cd have not succeeded in developing sufficient Cd tolerance for vigorous plant growth. •  We found that the bacterial arsenate reductase gene (arsC) provided Cd(II) resistance to Escherichia coli. When ArsC is overexpressed in tobacco (Nicotiana tabacum) and Arabidopsis thaliana, both transgenic plant species showed significantly greater Cd tolerance than wild-type controls. •  At 50, 75, and 100 µm concentrations of Cd (II), the ArsC expressing transgenic lines grew bigger with broader leaves and longer roots than wild-type controls, which were stunted, turned yellow, flowered early, and often died. At the various Cd(II) concentrations, ArsC transgenic plants attained f. wt 2-3-fold higher than the wild-type plants and had roots significantly longer than wild-type plants. These transgenic plants also contained 30-50% higher Cd concentrations than wild-type plants. •  It is likely that the arsC gene directs Cd tolerance via the electrochemical reduction of Cd(II) to Cd(0).

Published

2003

212. Engineering tolerance and hyperaccumulation of arsenic in plants by combining arsenate reductase and gamma-glutamylcysteine synthetase expression.

Author

Dhankher OP, Li Y, Rosen BP, Shi J, Salt D, Senecoff JF, Sashti NA, and Meagher RB

Subjects

Arsenates metabolism, Arsenite Transporting ATPases, Biodegradation, Environmental, Dipeptides genetics, Drug Tolerance genetics, Escherichia coli enzymology, Escherichia coli genetics, Gene Expression Regulation, Plant, Genetic Engineering methods, Ion Pumps genetics, Multienzyme Complexes genetics, Plant Leaves metabolism, Plant Roots metabolism, Plants, Genetically Modified enzymology, Plants, Genetically Modified genetics, Recombinant Proteins genetics, Recombinant Proteins metabolism, Reference Values, Refuse Disposal methods, Soil Pollutants metabolism, Species Specificity, Transformation, Genetic, Water Pollutants, Chemical metabolism, Arabidopsis genetics, Arabidopsis metabolism, Arsenic metabolism, Dipeptides metabolism, Ion Pumps metabolism, Multienzyme Complexes metabolism, Plants, Genetically Modified metabolism

Abstract

We have developed a genetics-based phytoremediation strategy for arsenic in which the oxyanion arsenate is transported aboveground, reduced to arsenite, and sequestered in thiol-peptide complexes. The Escherichia coli arsC gene encodes arsenate reductase (ArsC), which catalyzes the glutathione (GSH)-coupled electrochemical reduction of arsenate to the more toxic arsenite. Arabidopsis thaliana plants transformed with the arsC gene expressed from a light-induced soybean rubisco promoter (SRS1p) strongly express ArsC protein in leaves, but not roots, and were consequently hypersensitive to arsenate. Arabidopsis plants expressing the E. coli gene encoding gamma-glutamylcysteine synthetase (gamma-ECS) from a strong constitutive actin promoter (ACT2p) were moderately tolerant to arsenic compared with wild type. However, plants expressing SRS1p/ArsC and ACT2p/gamma-ECS together showed substantially greater arsenic tolerance than gamma-ECS or wild-type plants. When grown on arsenic, these plants accumulated 4- to 17-fold greater fresh shoot weight and accumulated 2- to 3-fold more arsenic per gram of tissue than wild type or plants expressing gamma-ECS or ArsC alone. This arsenic remediation strategy should be applicable to a wide variety of plant species.

Published

2002