Your search keyword '"Arsenate Reductases metabolism"' showing total 50 results

1. Arsenate reductase of Rufibacter tibetensis is a metallophosphoesterase evolved to catalyze redox reactions.

Author

Shen J, Song XW, Bickel D, Rosen BP, Zhao FJ, Messens J, and Zhang J

Subjects

Arsenates metabolism, Kinetics, Phosphoric Monoester Hydrolases metabolism, Phosphoric Monoester Hydrolases genetics, Phosphoric Monoester Hydrolases chemistry, Catalysis, Bacterial Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins chemistry, Arsenites metabolism, Arsenate Reductases metabolism, Arsenate Reductases genetics, Arsenate Reductases chemistry, Oxidation-Reduction, Catalytic Domain, Bacteroidetes enzymology, Bacteroidetes genetics

Abstract

An arsenate reductase (Car1) from the Bacteroidetes species Rufibacter tibetensis 1351 T was isolated from the Tibetan Plateau. The strain exhibits resistance to arsenite [As(III)] and arsenate [As(V)] and reduces As(V) to As(III). Here we shed light on the mechanism of enzymatic reduction by Car1. AlphaFold2 structure prediction, active site energy minimization, and steady-state kinetics of wild-type and mutant enzymes give insight into the catalytic mechanism. Car1 is structurally related to calcineurin-like metallophosphoesterases (MPPs). It functions as a binuclear metal hydrolase with limited phosphatase activity, particularly relying on the divalent metal Ni 2+ . As an As(V) reductase, it displays metal promiscuity and is coupled to the thioredoxin redox cycle, requiring the participation of two cysteine residues, Cys74 and Cys76. These findings suggest that Car1 evolved from a common ancestor of extant phosphatases by incorporating a redox function into an existing MPP catalytic site. Its proposed mechanism of arsenate reduction involves Cys74 initiating a nucleophilic attack on arsenate, leading to the formation of a covalent intermediate. Next, a nucleophilic attack of Cys76 leads to the release of As(III) and the formation of a surface-exposed Cys74-Cys76 disulfide, ready for reduction by thioredoxin., (© 2024 John Wiley & Sons Ltd.)

Published

2024

2. Variations of arsenic forms and the role of arsenate reductase in three hydrophytes exposed to different arsenic species.

Author

Wang H, Cui S, Ma L, Wang Z, and Wang H

Subjects

Adsorption, Hydroponics, Plant Roots chemistry, Plant Roots metabolism, Plant Shoots chemistry, Plant Shoots metabolism, Araceae chemistry, Araceae metabolism, Arsenate Reductases metabolism, Arsenic chemistry, Arsenic metabolism, Cacodylic Acid chemistry, Cacodylic Acid metabolism, Eichhornia chemistry, Eichhornia metabolism, Hydrocharitaceae chemistry, Hydrocharitaceae metabolism, Plant Proteins metabolism, Water Pollutants, Chemical chemistry, Water Pollutants, Chemical metabolism

Abstract

In order to understand the mechanisms of arsenic (As) accumulation and detoxification in aquatic plants exposed to different As species, a hydroponic experiment was conducted and the three aquatic plants (Hydrilla verticillata, Pistia stratiotes and Eichhornia crassipes) were exposed to different concentrations of As(III), As(V) and dimethylarsinate (DMA) for 10 days. The biomass, the surface As adsorption and total As adsorption of three plants were determined. Furthermore, As speciation in the culture solution and plant body, as well as the arsenate reductase (AR) activities of roots and shoots, were also analyzed. The results showed that the surface As adsorption of plants was far less than total As absorption. Compared to As(V), the plants showed a lower DMA accumulation. P. stratiotes showed the highest accumulation of inorganic arsenic but E. crassipes showed the lowest at the same As treatment. E. crassipes showed a strong ability to accumulate DMA. Results from As speciation analysis in culture solution showed that As(III) was transformed to As(V) in all As(III) treatments, and the oxidation rates followed as the sequence of H. verticillata>P. stratiotes>E. crassipes>no plant. As(III) was the predominant species in both roots (39.4-88.3%) and shoots (39-86%) of As(III)-exposed plants. As(V) and As(III) were the predominant species in roots (37-94%) and shoots (31.1-85.6%) in As(V)-exposed plants, respectively. DMA was the predominant species in both roots (23.46-100%) and shoots (72.6-100%) in DMA-exposed plants. The As(III) contents and AR activities in the roots of P. stratiotes and in the shoots of H. verticillata were significantly increased when exposed to 1 mg·L -1 or 3 mg·L -1 As(V). Therefore, As accumulation mainly occurred via biological uptake rather than physicochemical adsorption, and AR played an important role in As detoxification in aquatic plants. In the case of As(V)-exposed plants, their As tolerance was attributed to the increase of AR activities., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

3. Structural and Functional Investigation of the Periplasmic Arsenate-Binding Protein ArrX from Chrysiogenes arsenatis .

Author

Poddar N, Badilla C, Maghool S, Osborne TH, Santini JM, and Maher MJ

Subjects

Amino Acid Sequence genetics, Arsenate Reductases metabolism, Arsenates chemistry, Arsenates metabolism, Bacteria chemistry, Base Composition genetics, Binding Sites, Catalysis, Crystallography, X-Ray methods, Histidine Kinase metabolism, Oxidoreductases metabolism, Periplasm metabolism, Periplasmic Binding Proteins chemistry, Periplasmic Binding Proteins metabolism, Phylogeny, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA methods, Arsenate Reductases chemistry, Bacteria metabolism

Abstract

The anaerobic bacterium Chrysiogenes arsenatis respires using the oxyanion arsenate (AsO 4 3- ) as the terminal electron acceptor, where it is reduced to arsenite (AsO 3 3- ) while concomitantly oxidizing various organic (e.g., acetate) electron donors. This respiratory activity is catalyzed in the periplasm of the bacterium by the enzyme arsenate reductase (Arr), with expression of the enzyme controlled by a sensor histidine kinase (ArrS) and a periplasmic-binding protein (PBP), ArrX. Here, we report for the first time, the molecular structure of ArrX in the absence and presence of bound ligand arsenate. Comparison of the ligand-bound structure of ArrX with other PBPs shows a high level of conservation of critical residues for ligand binding by these proteins; however, this suite of PBPs shows different structural alterations upon ligand binding. For ArrX and its homologue AioX (from Rhizobium sp. str. NT-26), which specifically binds arsenite, the structures of the substrate-binding sites in the vicinity of a conserved and critical cysteine residue contribute to the discrimination of binding for these chemically similar ligands.

Published

2021

4. Improving Arsenic Tolerance of Pyrococcus furiosus by Heterologous Expression of a Respiratory Arsenate Reductase.

Author

Haja DK, Wu CH, Ponomarenko O, Poole FL 2nd, George GN, and Adams MWW

Subjects

Archaeal Proteins metabolism, Arsenate Reductases metabolism, Arsenic metabolism, Microorganisms, Genetically-Modified enzymology, Microorganisms, Genetically-Modified genetics, Microorganisms, Genetically-Modified metabolism, Pyrococcus furiosus enzymology, Pyrococcus furiosus metabolism, Archaeal Proteins genetics, Arsenate Reductases genetics, Gene Expression Regulation, Archaeal, Pyrococcus furiosus genetics, Thermoproteaceae genetics

Abstract

Arsenate is a notorious toxicant that is known to disrupt multiple biochemical pathways. Many microorganisms have developed mechanisms to detoxify arsenate using the ArsC-type arsenate reductase, and some even use arsenate as a terminal electron acceptor for respiration involving arsenate respiratory reductase (Arr). ArsC-type reductases have been studied extensively, but the phylogenetically unrelated Arr system is less investigated and has not been characterized from Archaea Here, we heterologously expressed the genes encoding Arr from the crenarchaeon Pyrobaculum aerophilum in the euryarchaeon Pyrococcus furiosus , both of which grow optimally near 100°C. Recombinant P. furiosus was grown on molybdenum (Mo)- or tungsten (W)-containing medium, and two types of recombinant Arr enzymes were purified, one containing Mo (Arr-Mo) and one containing W (Arr-W). Purified Arr-Mo had a 140-fold higher specific activity in arsenate [As(V)] reduction than Arr-W, and Arr-Mo also reduced arsenite [As(III)]. The P. furiosus strain expressing Arr-Mo (the Arr strain) was able to use arsenate as a terminal electron acceptor during growth on peptides. In addition, the Arr strain had increased tolerance compared to that of the parent strain to arsenate and also, surprisingly, to arsenite. Compared to the parent, the Arr strain accumulated intracellularly almost an order of magnitude more arsenic when cells were grown in the presence of arsenite. X-ray absorption spectroscopy (XAS) results suggest that the Arr strain of P. furiosus improves its tolerance to arsenite by increasing production of less-toxic arsenate and nontoxic methylated arsenicals compared to that by the parent. IMPORTANCE Arsenate respiratory reductases (Arr) are much less characterized than the detoxifying arsenate reductase system. The heterologous expression and characterization of an Arr from Pyrobaculum aerophilum in Pyrococcus furiosus provides new insights into the function of this enzyme. From in vivo studies, production of Arr not only enabled P. furiosus to use arsenate [As(V)] as a terminal electron acceptor, it also provided the organism with a higher resistance to arsenate and also, surprisingly, to arsenite [As(III)]. In contrast to the tungsten-containing oxidoreductase enzymes natively produced by P. furiosus , recombinant P. aerophilum Arr was much more active with molybdenum than with tungsten. It is also, to our knowledge, the only characterized Arr to be active with both molybdenum and tungsten in the active site., (Copyright © 2020 American Society for Microbiology.)

Published

2020

5. The controversy on the ancestral arsenite oxidizing enzyme; deducing evolutionary histories with phylogeny and thermodynamics.

Author

Szyttenholm J, Chaspoul F, Bauzan M, Ducluzeau AL, Chehade MH, Pierrel F, Denis Y, Nitschke W, and Schoepp-Cothenet B

Subjects

Arsenate Reductases genetics, Genomics, Oxidation-Reduction, Oxidoreductases genetics, Thermodynamics, Arsenate Reductases metabolism, Arsenites metabolism, Evolution, Molecular, Oxidoreductases metabolism, Phylogeny

Abstract

The three presently known enzymes responsible for arsenic-using bioenergetic processes are arsenite oxidase (Aio), arsenate reductase (Arr) and alternative arsenite oxidase (Arx), all of which are molybdoenzymes from the vast group referred to as the Mo/W-bisPGD enzyme superfamily. Since arsenite is present in substantial amounts in hydrothermal environments, frequently considered as vestiges of primordial biochemistry, arsenite-based bioenergetics has long been predicted to be ancient. Conflicting scenarios, however, have been put forward proposing either Arr/Arx or Aio as operating in the ancestral metabolism. Phylogenetic data argue in favor of Aio whereas biochemical and physiological data led several authors to propose Arx/Arr as the most ancient anaerobic arsenite metabolizing enzymes. Here we combine phylogenetic approaches with physiological and biochemical experiments to demonstrate that the Arx/Arr enzymes could not have been functional in the Archaean geological eon. We propose that Arr reacts with menaquinones to reduce arsenate whereas Arx reacts with ubiquinone to oxidize arsenite, in line with thermodynamic considerations. The distribution of the quinone biosynthesis pathways, however, clearly indicates that the ubiquinone pathway is recent. An updated phylogeny of Arx furthermore reinforces the hypothesis of a recent emergence of this enzyme. We therefore conclude that anaerobic arsenite redox conversion in the Archaean must have been performed in a metabolism involving Aio., 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. Published by Elsevier B.V.)

Published

2020

6. LEUNIG_HOMOLOG Mediates MYC2-Dependent Transcriptional Activation in Cooperation with the Coactivators HAC1 and MED25.

Author

You Y, Zhai Q, An C, and Li C

Subjects

Acetylation, Arabidopsis genetics, Arabidopsis Proteins genetics, Arsenate Reductases genetics, Basic Helix-Loop-Helix Leucine Zipper Transcription Factors genetics, DNA-Binding Proteins genetics, Gene Expression Regulation, Plant, Histones, Lipoxygenases genetics, Lipoxygenases metabolism, Plants, Genetically Modified, Promoter Regions, Genetic, Repressor Proteins genetics, Repressor Proteins metabolism, Signal Transduction genetics, Transcription Factors genetics, Transcription Factors metabolism, Transcription, Genetic, Transcriptional Activation genetics, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Arsenate Reductases metabolism, Basic Helix-Loop-Helix Leucine Zipper Transcription Factors metabolism, DNA-Binding Proteins metabolism, Transcriptional Activation physiology

Abstract

Groucho/Thymidine uptake 1 (Gro/Tup1) family proteins are evolutionarily conserved transcriptional coregulators in eukaryotic cells. Despite their prominent function in transcriptional repression, little is known about their role in transcriptional activation and the underlying mechanism. Here, we report that the plant Gro/Tup1 family protein LEUNIG_HOMOLOG (LUH) activates MYELOCYTOMATOSIS2 (MYC2)-directed transcription of JAZ2 and LOX2 via the Mediator complex coactivator and the histone acetyltransferase HAC1. We show that the Mediator subunit MED25 physically recruits LUH to MYC2 target promoters that then links MYC2 with HAC1-dependent acetylation of Lys-9 of histone H3 (H3K9ac) to activate JAZ2 and LOX2 Moreover, LUH promotes hormone-dependent enhancement of protein interactions between MYC2 and its coactivators MED25 and HAC1. Our results demonstrate that LUH interacts with MED25 and HAC1 through its distinct domains, thus imposing a selective advantage by acting as a scaffold for MYC2 activation. Therefore, the function of LUH in regulating jasmonate signaling is distinct from the function of TOPLESS, another member of the Gro/Tup1 family that represses MYC2-dependent gene expression in the resting stage., (© 2019 American Society of Plant Biologists. All rights reserved.)

Published

2019

7. Structure and function prediction of arsenate reductase from Deinococcus indicus DR1.

Author

Chauhan D, Srivastava PA, Agnihotri V, Yennamalli RM, and Priyadarshini R

Subjects

Amino Acid Sequence, Amino Acids chemistry, Amino Acids metabolism, Arsenate Reductases classification, Arsenate Reductases genetics, Arsenic chemistry, Bacterial Proteins chemistry, Bacterial Proteins genetics, Catalytic Domain, Deinococcus genetics, Molecular Dynamics Simulation, Phylogeny, Protein Binding, Protein Domains, Sequence Homology, Amino Acid, Arsenate Reductases metabolism, Arsenic metabolism, Bacterial Proteins metabolism, Deinococcus enzymology

Abstract

Arsenic prevalence in the environment impelled many organisms to develop resistance over the course of evolution. Tolerance to arsenic, either as the pentavalent [As(V)] form or the trivalent form [As(III)], by bacteria has been well studied in prokaryotes, and the mechanism of action is well defined. However, in the rod-shaped arsenic tolerant Deinococcus indicus DR1, the key enzyme, arsenate reductase (ArsC) has not been well studied. ArsC of D. indicus belongs to the Grx-linked prokaryotic arsenate reductase family. While it shares homology with the well-studied ArsC of Escherichia coli having a catalytic cysteine (Cys 12) and arginine triad (Arg 60, 94, and 107), the active site of D.indicus ArsC contains four residues Glu 9, Asp 53, Arg 86, and Glu 100, and with complete absence of structurally equivalent residue for crucial Cys 12. Here, we report that the mechanism of action of ArsC of D. indicus is different as a result of convergent evolution and most likely able to detoxify As(V) using a mix of positively- and negatively-charged residues in its active site, unlike the residues of E. coli. This suggests toward the possibility of an alternative mechanism of As (V) degradation in bacteria.

Published

2019

8. Structural and mechanistic analysis of the arsenate respiratory reductase provides insight into environmental arsenic transformations.

Author

Glasser NR, Oyala PH, Osborne TH, Santini JM, and Newman DK

Subjects

Amino Acid Sequence, Arsenate Reductases chemistry, Arsenate Reductases genetics, Arsenates chemistry, Arsenic chemistry, Arsenites chemistry, Arsenites metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Crystallography, X-Ray, Gene Expression Regulation, Bacterial, Kinetics, Models, Molecular, Oxidoreductases chemistry, Oxidoreductases genetics, Oxidoreductases metabolism, Protein Binding, Protein Domains, Sequence Homology, Amino Acid, Shewanella genetics, Arsenate Reductases metabolism, Arsenates metabolism, Arsenic metabolism, Bacterial Proteins metabolism, Shewanella metabolism

Abstract

Arsenate respiration by bacteria was discovered over two decades ago and is catalyzed by diverse organisms using the well-conserved Arr enzyme complex. Until now, the mechanisms underpinning this metabolism have been relatively opaque. Here, we report the structure of an Arr complex (solved by X-ray crystallography to 1.6-Å resolution), which was enabled by an improved Arr expression method in the genetically tractable arsenate respirer Shewanella sp. ANA-3. We also obtained structures bound with the substrate arsenate (1.8 Å), the product arsenite (1.8 Å), and the natural inhibitor phosphate (1.7 Å). The structures reveal a conserved active-site motif that distinguishes Arr [(R/K)GRY] from the closely related arsenite respiratory oxidase (Arx) complex (XGRGWG). Arr activity assays using methyl viologen as the electron donor and arsenate as the electron acceptor display two-site ping-pong kinetics. A Mo(V) species was detected with EPR spectroscopy, which is typical for proteins with a pyranopterin guanine dinucleotide cofactor. Arr is an extraordinarily fast enzyme that approaches the diffusion limit ( K m = 44.6 ± 1.6 μM, k cat = 9,810 ± 220 seconds -1 ), and phosphate is a competitive inhibitor of arsenate reduction ( K i = 325 ± 12 μM). These observations, combined with knowledge of typical sedimentary arsenate and phosphate concentrations and known rates of arsenate desorption from minerals in the presence of phosphate, suggest that ( i ) arsenate desorption limits microbiologically induced arsenate reductive mobilization and ( ii ) phosphate enhances arsenic mobility by stimulating arsenate desorption rather than by inhibiting it at the enzymatic level., Competing Interests: The authors declare no conflict of interest.

Published

2018

9. Arsenate-dependent growth is independent of an ArrA mechanism of arsenate respiration in the termite hindgut isolate Citrobacter sp. strain TSA-1.

Author

Blum JS, Hernandez-Maldonado J, Redford K, Sing C, Bennett SC, Saltikov CW, and Oremland RS

Subjects

Anaerobiosis genetics, Animals, Arsenate Reductases genetics, Bacterial Proteins genetics, Bacterial Proteins metabolism, Citrobacter genetics, Gene Expression Profiling, Gene Expression Regulation, Bacterial, Gene Expression Regulation, Enzymologic, Genes, Bacterial genetics, Genome, Bacterial genetics, Mutation, Arsenate Reductases metabolism, Arsenates metabolism, Citrobacter metabolism, Isoptera microbiology

Abstract

Citrobacter sp. strain TSA-1 is an enteric bacterium isolated from the hindgut of the termite. Strain TSA-1 displays anaerobic growth with selenite, fumarate, tetrathionate, nitrate, or arsenate serving as electron acceptors, and it also grows aerobically. In regards to arsenate, genome sequencing revealed that strain TSA-1 lacks a homolog for respiratory arsenate reductase, arrAB, and we were unable to obtain amplicons of arrA. This raises the question as to how strain TSA-1 achieves As(V)-dependent growth. We show that growth of strain TSA-1 on glycerol, which it cannot ferment, is linked to the electron acceptor arsenate. A series of transcriptomic experiments were conducted to discern which genes were upregulated during growth on arsenate, as opposed to those on fumarate or oxygen. For As(V), upregulation was noted for 1 of the 2 annotated arsC genes, while there was no clear upregulation for tetrathionate reductase (ttr), suggesting that this enzyme is not an alternative to arrAB as occurs in certain hyperthermophilic archaea. A gene-deletion mutant strain of TSA-1 deficient in arsC could not achieve anaerobic respiratory growth on As(V). Our results suggest that Citrobacter sp. strain TSA-1 has an unusual and as yet undefined means of achieving arsenate respiration, perhaps involving its ArsC as a respiratory reductase as well as a detoxifying agent.

Published

2018

10. Mediator, SWI/SNF and SAGA complexes regulate Yap8-dependent transcriptional activation of ACR2 in response to arsenate.

Author

Menezes RA, Pimentel C, Silva AR, Amaral C, Merhej J, Devaux F, and Rodrigues-Pousada C

Subjects

Arsenate Reductases metabolism, Basic-Leucine Zipper Transcription Factors chemistry, Cysteine metabolism, Promoter Regions, Genetic, Protein Binding, Protein Subunits metabolism, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Stress, Physiological drug effects, Arsenate Reductases genetics, Arsenates toxicity, Basic-Leucine Zipper Transcription Factors metabolism, Mediator Complex metabolism, Multiprotein Complexes metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Transcriptional Activation genetics

Abstract

Response to arsenic stress in Saccharomyces cerevisiae is orchestrated by the regulatory protein Yap8, which mediates transcriptional activation of ACR2 and ACR3. This study contributes to the state of art knowledge of the molecular mechanisms underlying yeast stress response to arsenate as it provides the genetic and biochemical evidences that Yap8, through cysteine residues 132, 137, and 274, is the sensor of presence of arsenate in the cytosol. Moreover, it is here reported for the first time the essential role of the Mediator complex in the transcriptional activation of ACR2 by Yap8. Based on our data, we propose an order-of-function map to recapitulate the sequence of events taking place in cells injured with arsenate. Modification of the sulfhydryl state of these cysteines converts Yap8 in its activated form, triggering the recruitment of the Mediator complex to the ACR2/ACR3 promoter, through the interaction with the tail subunit Med2. The Mediator complex then transfers the regulatory signals conveyed by Yap8 to the core transcriptional machinery, which culminates with TBP occupancy, ACR2 upregulation and cell adaptation to arsenate stress. Additional co-factors are required for the transcriptional activation of ACR2 by Yap8, particularly the nucleosome remodeling activity of SWI/SNF and SAGA complexes., (Copyright © 2017. Published by Elsevier B.V.)

Published

2017

11. Genetic identification of arsenate reductase and arsenite oxidase in redox transformations carried out by arsenic metabolising prokaryotes - A comprehensive review.

Author

Kumari N and Jagadevan S

Subjects

Arsenate Reductases metabolism, Arsenates metabolism, Arsenites metabolism, Bacteria genetics, Bacterial Proteins metabolism, Biodegradation, Environmental, Biotransformation, Oxidation-Reduction, Oxidoreductases metabolism, Arsenate Reductases genetics, Arsenic metabolism, Bacteria metabolism, Bacterial Proteins genetics, Environmental Pollutants metabolism, Oxidoreductases genetics

Abstract

Arsenic (As) contamination in water is a cause of major concern to human population worldwide, especially in Bangladesh and West Bengal, India. Arsenite (As(III)) and arsenate (As(V)) are the two common forms in which arsenic exists in soil and groundwater, the former being more mobile and toxic. A large number of arsenic metabolising microorganisms play a crucial role in microbial transformation of arsenic between its different states, thus playing a key role in remediation of arsenic contaminated water. This review focuses on advances in biochemical, molecular and genomic developments in the field of arsenic metabolising bacteria - covering recent developments in the understanding of structure of arsenate reductase and arsenite oxidase enzymes, their gene and operon structures and their mechanism of action. The genetic and molecular studies of these microbes and their proteins may lead to evolution of successful strategies for effective implementation of bioremediation programs., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016

12. OsHAC1;1 and OsHAC1;2 Function as Arsenate Reductases and Regulate Arsenic Accumulation.

Author

Shi S, Wang T, Chen Z, Tang Z, Wu Z, Salt DE, Chao DY, and Zhao FJ

Subjects

Adaptation, Physiological drug effects, Adaptation, Physiological genetics, Arsenic toxicity, Gene Expression Regulation, Plant drug effects, Gene Knockout Techniques, Genetic Speciation, Green Fluorescent Proteins metabolism, Mutation genetics, Oryza drug effects, Oryza genetics, Oryza growth & development, Plant Roots drug effects, Plant Roots metabolism, Plant Shoots drug effects, Plant Shoots metabolism, Plants, Genetically Modified, Recombinant Fusion Proteins metabolism, Soil, Subcellular Fractions drug effects, Subcellular Fractions metabolism, Xylem drug effects, Xylem metabolism, Arsenate Reductases metabolism, Arsenic metabolism, Oryza enzymology, Plant Proteins metabolism

Abstract

Rice is a major dietary source of the toxic metalloid arsenic (As). Reducing its accumulation in rice (Oryza sativa) grain is of critical importance to food safety. Rice roots take up arsenate and arsenite depending on the prevailing soil conditions. The first step of arsenate detoxification is its reduction to arsenite, but the enzyme(s) catalyzing this reaction in rice remains unknown. Here, we identify OsHAC1;1 and OsHAC1;2 as arsenate reductases in rice. OsHAC1;1 and OsHAC1;2 are able to complement an Escherichia coli mutant lacking the endogenous arsenate reductase and to reduce arsenate to arsenite. OsHAC1:1 and OsHAC1;2 are predominantly expressed in roots, with OsHAC1;1 being abundant in the epidermis, root hairs, and pericycle cells while OsHAC1;2 is abundant in the epidermis, outer layers of cortex, and endodermis cells. Expression of the two genes was induced by arsenate exposure. Knocking out OsHAC1;1 or OsHAC1;2 decreased the reduction of arsenate to arsenite in roots, reducing arsenite efflux to the external medium. Loss of arsenite efflux was also associated with increased As accumulation in shoots. Greater effects were observed in a double mutant of the two genes. In contrast, overexpression of either OsHAC1;1 or OsHAC1;2 increased arsenite efflux, reduced As accumulation, and enhanced arsenate tolerance. When grown under aerobic soil conditions, overexpression of either OsHAC1;1 or OsHAC1;2 also decreased As accumulation in rice grain, whereas grain As increased in the knockout mutants. We conclude that OsHAC1;1 and OsHAC1;2 are arsenate reductases that play an important role in restricting As accumulation in rice shoots and grain., (© 2016 American Society of Plant Biologists. All Rights Reserved.)

Published

2016

13. Functional analysis of ars gene cluster of Pannonibacter indicus strain HT23(T) (DSM 23407(T)) and identification of a proline residue essential for arsenate reductase activity.

Author

Bandyopadhyay S and Das SK

Subjects

Amino Acid Substitution, Arsenate Reductases metabolism, Arsenic metabolism, Bacterial Proteins metabolism, Cloning, Molecular, Escherichia coli genetics, Escherichia coli metabolism, Kinetics, Mutagenesis, Site-Directed, Open Reading Frames, Operon, Oxidation-Reduction, Plasmids chemistry, Plasmids metabolism, Proline metabolism, Protein Folding, Protein Tyrosine Phosphatases genetics, Protein Tyrosine Phosphatases metabolism, Recombinant Proteins genetics, Recombinant Proteins metabolism, Rhodobacteraceae enzymology, Structure-Activity Relationship, Arsenate Reductases genetics, Bacterial Proteins genetics, Gene Expression Regulation, Bacterial, Multigene Family, Proline chemistry, Rhodobacteraceae genetics

Abstract

Arsenic is a naturally occurring ubiquitous highly toxic metalloid. In this study, we have identified ars gene cluster in Pannonibacter indicus strain HT23(T) (DSM 23407(T)), responsible for reduction of toxic pentavalent arsenate. The ars gene cluster is comprised of four non-overlapping open reading frames (ORFs) encoding a transcriptional regulator (ArsR), a low molecular weight protein tyrosine phosphatases (LMW-PTPase) with hypothetical function, an arsenite efflux pump (Acr3), and an arsenate reductase (ArsC). Heterologous expression of arsenic inducible ars gene cluster conferred arsenic resistance to Escherichia coli ∆ars mutant strain AW3110. The recombinant ArsC was purified and assayed. Site-directed mutagenesis was employed to ascertain the role of specific amino acids in ArsC catalysis. Pro94X (X = Ala, Arg, Cys, and His) amino acid substitutions led to enzyme inactivation. Circular dichroism spectra analysis suggested Pro94 as an essential amino acid for enzyme catalytic activity as it is indispensable for optimum protein folding in P. indicus Grx-coupled ArsC.

Published

2016

14. Characterization of arsenite tolerant Halomonas sp. Alang-4, originated from heavy metal polluted shore of Gulf of Cambay.

Author

Jain R, Jha S, Mahatma MK, Jha A, and Kumar GN

Subjects

Arsenate Reductases genetics, Environmental Monitoring, Halomonas genetics, India, Arsenate Reductases metabolism, Arsenites metabolism, Halomonas chemistry, Metals, Heavy metabolism, Oxidoreductases metabolism, Seawater chemistry, Seawater microbiology

Abstract

Arsenite [As(III)]-oxidizing bacteria were isolated from heavy metal contaminated shore of Gulf of Cambay at Alang, India. The most efficient bacterial strain Alang-4 could tolerate up to 15 mM arsenite [As(III)] and 200 mM of arsenate [As(V)]. Its 16S rRNA gene sequence was 99% identical to the 16S rRNA genes of genus Halomonas (Accession no. HQ659187). Arsenite oxidase enzyme localized on membrane helped in conversion of As(III) to As(V). Arsenite transporter genes (arsB, acr3(1) and acr3(2)) assisted in extrusion of arsenite from Halomonas sp. Alang-4. Generation of ROS in response to arsenite stress was alleviated by higher activities of catalase, ascorbate peroxidase, superoxide dismutase and glutathione S-transferase enzymes. Down-regulation in the specific activities of nearly all dehydrogenases of carbon assimilatory pathway viz., glucose-6-phosphate, pyruvate, α-ketoglutarate, isocitrate and malate dehydrogenases, was observed in presence of As(III), whereas, the specific activities of phosphoenol pyruvate carboxylase, pyruvate carboxylase and isocitrate lyase enzymes were found to increase two times in As(III) treated cells. The results suggest that in addition to efficient ars operon, alternative pathways of carbon utilization exist in the marine bacterium Halomonas sp. Alang-4 to overcome the toxic effects of arsenite on its dehydrogenase enzymes.

Published

2016

15. Interaction of Thermus thermophilus ArsC enzyme and gold nanoparticles naked-eye assays speciation between As(III) and As(V).

Author

Politi J, Spadavecchia J, Fiorentino G, Antonucci I, Casale S, and De Stefano L

Subjects

Arsenate Reductases genetics, Arsenate Reductases metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Ions chemistry, Microscopy, Electron, Transmission, Particle Size, Polyethylene Glycols chemistry, Recombinant Proteins biosynthesis, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Spectrophotometry, Ultraviolet, Spectroscopy, Fourier Transform Infrared, Surface Plasmon Resonance, Arsenate Reductases chemistry, Arsenic chemistry, Bacterial Proteins chemistry, Gold chemistry, Metal Nanoparticles chemistry, Thermus thermophilus enzymology

Abstract

The thermophilic bacterium Thermus thermophilus HB27 encodes chromosomal arsenate reductase (TtArsC), the enzyme responsible for resistance to the harmful effects of arsenic. We report on adsorption of TtArsC onto gold nanoparticles for naked-eye monitoring of biomolecular interaction between the enzyme and arsenic species. Synthesis of hybrid biological-metallic nanoparticles has been characterized by transmission electron microscopy (TEM), ultraviolet-visible (UV-vis), dynamic light scattering (DLS) and phase modulated infrared reflection absorption (PM-IRRAS) spectroscopies. Molecular interactions have been monitored by UV-vis and Fourier transform-surface plasmon resonance (FT-SPR). Due to the nanoparticles' aggregation on exposure to metal salts, pentavalent and trivalent arsenic solutions can be clearly distinguished by naked-eye assay, even at 85 μM concentration. Moreover, the assay shows partial selectivity against other heavy metals.

Published

2015

16. The arsenic hyperaccumulating Pteris vittata expresses two arsenate reductases.

Author

Cesaro P, Cattaneo C, Bona E, Berta G, and Cavaletto M

Subjects

Amino Acid Sequence, Arsenate Reductases chemistry, Gene Expression Regulation, Plant, Molecular Sequence Data, Phosphorus metabolism, Plant Proteins genetics, Plant Proteins metabolism, Plant Roots metabolism, Arsenate Reductases genetics, Arsenate Reductases metabolism, Arsenic metabolism, Pteris genetics, Pteris metabolism

Abstract

Enzymatic reduction of arsenate to arsenite is the first known step in arsenate metabolism in all organisms. Although the presence of one mRNA arsenate reductase (PvACR2) has been characterized in gametophytes of P. vittata, no arsenate reductase protein has been directly observed in this arsenic hyperaccumulating fern, yet. In order to assess the possible presence of arsenate reductase in P. vittata, two recombinant proteins, ACR2-His6 and Trx-His6-S-Pv2.5-8 were prepared in Escherichia coli, purified and used to produce polyclonal antibodies. The presence of these two enzymes was evaluated by qRT-PCR, immunoblotting and direct MS analysis. Enzymatic activity was detected in crude extracts. For the first time we detected and identified two arsenate reductase proteins (PvACR2 and Pv2.5-8) in sporophytes and gametophytes of P. vittata. Despite an increase of the mRNA levels for both proteins in roots, no difference was observed at the protein level after arsenic treatment. Overall, our data demonstrate the constitutive protein expression of PvACR2 and Pv2.5-8 in P. vittata tissues and propose their specific role in the complex metabolic network of arsenic reduction.

Published

2015

17. A Hybrid Mechanism for the Synechocystis Arsenate Reductase Revealed by Structural Snapshots during Arsenate Reduction.

Author

Hu C, Yu C, Liu Y, Hou X, Liu X, Hu Y, and Jin C

Subjects

Amino Acid Sequence, Arsenate Reductases chemistry, Arsenate Reductases genetics, Arsenates chemistry, Bacterial Proteins chemistry, Bacterial Proteins genetics, Binding Sites, Disulfides metabolism, Glutaredoxins chemistry, Glutaredoxins genetics, Glutaredoxins metabolism, Glutathione metabolism, Models, Molecular, Molecular Sequence Data, Oxidation-Reduction, Protein Conformation, Protein Structure, Secondary, Protein Structure, Tertiary, Sequence Homology, Amino Acid, Sulfhydryl Compounds metabolism, Synechocystis genetics, Thioredoxins chemistry, Thioredoxins genetics, Thioredoxins metabolism, Arsenate Reductases metabolism, Arsenates metabolism, Bacterial Proteins metabolism, Synechocystis enzymology

Abstract

Evolution of enzymes plays a crucial role in obtaining new biological functions for all life forms. Arsenate reductases (ArsC) are several families of arsenic detoxification enzymes that reduce arsenate to arsenite, which can subsequently be extruded from cells by specific transporters. Among these, the Synechocystis ArsC (SynArsC) is structurally homologous to the well characterized thioredoxin (Trx)-coupled ArsC family but requires the glutaredoxin (Grx) system for its reactivation, therefore classified as a unique Trx/Grx-hybrid family. The detailed catalytic mechanism of SynArsC is unclear and how the "hybrid" mechanism evolved remains enigmatic. Herein, we report the molecular mechanism of SynArsC by biochemical and structural studies. Our work demonstrates that arsenate reduction is carried out via an intramolecular thiol-disulfide cascade similar to the Trx-coupled family, whereas the enzyme reactivation step is diverted to the coupling of the glutathione-Grx pathway due to the local structural difference. The current results support the hypothesis that SynArsC is likely a molecular fossil representing an intermediate stage during the evolution of the Trx-coupled ArsC family from the low molecular weight protein phosphotyrosine phosphatase (LMW-PTPase) family., (© 2015 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2015

18. Biotransformation of arsenic by bacterial strains mediated by oxido-reductase enzyme system.

Author

Vishnoi N and Singh DP

Subjects

Arsenic isolation & purification, Arsenicals isolation & purification, Bacillus isolation & purification, Bacillus metabolism, Biotransformation, Escherichia coli isolation & purification, Escherichia coli metabolism, Soil Microbiology, Soil Pollutants isolation & purification, Arsenate Reductases metabolism, Arsenic metabolism, Arsenicals metabolism, Bacillus enzymology, Escherichia coli enzymology, Oxidoreductases metabolism, Soil Pollutants metabolism

Abstract

The present study deals with the enzyme mediated biotransformation of arsenic in five arsenic tolerant strains (Bacillus subtilis, Bacillus megaterium, Bacillus pumilus, Paenibacillus macerans and Escherichia coli). Biotransformation ability of these isolates was evaluated by monitoring arsenite oxidase and arsenate reductase activity. Results showed that arsenic oxidase activity was exclusively present in P. macerans and B. pumilus while B. subtilis, B. megaterium and E. coli strains showed presence of Arsenic oxido-reductase enzyme. The reversible nature of arsenic oxido- reductase suggested that same enzyme can carry out oxidation and reduction of arsenic depending upon the relative concentration of arsenic species. Lineweaver-Burk plot of the arsenite oxidase activity in P. macerans showed highest Km value (Km- 200 μM) and lower Vmax (0.012 μmol mg-1 protein min-1) indicating lowest affinity of the enzyme for arsenite. On the contrary, E. coli showed the lower Km value ( Km- 38.46 μM) and higher Vmax (0.044 μmol mg-1 protein min-1) suggesting for higher affinity for the arsenite. Lineweaver-Burk plot of arsenate reductase activity showed the presence of this enzyme in B. subtilis, B. megaterium and E. coli which were in the range of 200-360 μM Km and Vmax value between 0.256- 0.129 mmol mg-1 protein min-1. These results suggested that affinity of the as reductase enzyme is lowest for arsenate than that for the arsenite. Thus, arsenite oxidase system appears to be a predominant mechanism of cellular defense in these bacterial strains.

Published

2014

19. How plants control arsenic accumulation.

Author

Meadows R

Subjects

Arabidopsis enzymology, Arabidopsis genetics, Arabidopsis Proteins metabolism, Arsenate Reductases metabolism, Arsenic metabolism, Genome-Wide Association Study

Abstract

Competing Interests: The author has declared that no competing interests exist.

Published

2014

20. Genome-wide association mapping identifies a new arsenate reductase enzyme critical for limiting arsenic accumulation in plants.

Author

Chao DY, Chen Y, Chen J, Shi S, Chen Z, Wang C, Danku JM, Zhao FJ, and Salt DE

Subjects

Amino Acid Sequence, Arabidopsis Proteins genetics, Arsenate Reductases genetics, Epistasis, Genetic, Genes, Plant, Genetic Loci, Models, Biological, Molecular Sequence Data, Plant Leaves metabolism, Plant Roots metabolism, Plant Shoots metabolism, Reproducibility of Results, Sequence Analysis, Protein, Arabidopsis enzymology, Arabidopsis genetics, Arabidopsis Proteins metabolism, Arsenate Reductases metabolism, Arsenic metabolism, Genome-Wide Association Study

Abstract

Inorganic arsenic is a carcinogen, and its ingestion through foods such as rice presents a significant risk to human health. Plants chemically reduce arsenate to arsenite. Using genome-wide association (GWA) mapping of loci controlling natural variation in arsenic accumulation in Arabidopsis thaliana allowed us to identify the arsenate reductase required for this reduction, which we named High Arsenic Content 1 (HAC1). Complementation verified the identity of HAC1, and expression in Escherichia coli lacking a functional arsenate reductase confirmed the arsenate reductase activity of HAC1. The HAC1 protein accumulates in the epidermis, the outer cell layer of the root, and also in the pericycle cells surrounding the central vascular tissue. Plants lacking HAC1 lose their ability to efflux arsenite from roots, leading to both increased transport of arsenic into the central vascular tissue and on into the shoot. HAC1 therefore functions to reduce arsenate to arsenite in the outer cell layer of the root, facilitating efflux of arsenic as arsenite back into the soil to limit both its accumulation in the root and transport to the shoot. Arsenate reduction by HAC1 in the pericycle may play a role in limiting arsenic loading into the xylem. Loss of HAC1-encoded arsenic reduction leads to a significant increase in arsenic accumulation in shoots, causing an increased sensitivity to arsenate toxicity. We also confirmed the previous observation that the ACR2 arsenate reductase in A. thaliana plays no detectable role in arsenic metabolism. Furthermore, ACR2 does not interact epistatically with HAC1, since arsenic metabolism in the acr2 hac1 double mutant is disrupted in an identical manner to that described for the hac1 single mutant. Our identification of HAC1 and its associated natural variation provides an important new resource for the development of low arsenic-containing food such as rice., Competing Interests: The authors have declared that no competing interests exist.

Published

2014

21. ArsC3 from Desulfovibrio alaskensis G20, a cation and sulfate-independent highly efficient arsenate reductase.

Author

Nunes CI, Brás JL, Najmudin S, Moura JJ, Moura I, and Carepo MS

Subjects

Amino Acid Sequence, Arsenate Reductases genetics, Arsenate Reductases isolation & purification, Biocatalysis, Calorimetry, Kinetics, Sequence Alignment, Arsenate Reductases metabolism, Desulfovibrio enzymology

Abstract

Desulfovibrio alaskensis G20, a sulfate-reducing bacterium, contains an arsRBC2C3 operon that encodes two putative arsenate reductases, DaG20_ArsC2 and DaG20_ArsC3. In this study, resistance assays in E. coli transformed with plasmids containing either of the two recombinant arsenate reductases, showed that only DaG20_ArsC3 is functional and able to confer arsenate resistance. Kinetic studies revealed that this enzyme uses thioredoxin as electron donor and therefore belongs to Staphylococcus aureus plasmid pI258 and Bacillus subtilis thioredoxin-coupled arsenate reductases family. Both enzymes from this family contain a potassium-binding site, but only in Sa_ArsC does potassium actually binds resulting in a lower K m. Important differences between the S. aureus and B. subtilis enzymes and DaG20_ArsC3 are observed. DaG20_ArsC3 contains only two (Asn10, Ser33) of the four (Asn10, Ser33, Thr63, Asp65) conserved amino acid residues that form the potassium-binding site and the kinetics is not significantly affected by the presence of either potassium or sulfate ions. Isothermal titration calorimetry measurements confirmed nonspecific binding of K(+) and Na(+), corroborating the non-relevance of these cations for catalysis. Furthermore, the low K m and high k cat values determined for DaG20_ArsC3 revealed that this enzyme is the most catalytically efficient potassium-independent arsenate reductase described so far and, for the first time indicates that potassium binding is not essential to have low K m, for Trx-arsenate reductases.

Published

2014

22. Natural variation in arsenate tolerance identifies an arsenate reductase in Arabidopsis thaliana.

Author

Sánchez-Bermejo E, Castrillo G, del Llano B, Navarro C, Zarco-Fernández S, Martinez-Herrera DJ, Leo-del Puerto Y, Muñoz R, Cámara C, Paz-Ares J, Alonso-Blanco C, and Leyva A

Subjects

Alleles, Amino Acid Sequence, Arabidopsis drug effects, Arsenites chemistry, Chromosome Mapping, Escherichia coli metabolism, Genetic Complementation Test, Models, Molecular, Molecular Conformation, Molecular Sequence Data, Mutation, Oxygen chemistry, Phenotype, Polymorphism, Genetic, Quantitative Trait Loci, Sequence Homology, Amino Acid, Thiosulfate Sulfurtransferase chemistry, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Arsenate Reductases metabolism, Arsenic chemistry, Gene Expression Regulation, Plant

Abstract

The enormous amount of environmental arsenic was a major factor in determining the biochemistry of incipient life forms early in the Earth's history. The most abundant chemical form in the reducing atmosphere was arsenite, which forced organisms to evolve strategies to manage this chemical species. Following the great oxygenation event, arsenite oxidized to arsenate and the action of arsenate reductases became a central survival requirement. The identity of a biologically relevant arsenate reductase in plants nonetheless continues to be debated. Here we identify a quantitative trait locus that encodes a novel arsenate reductase critical for arsenic tolerance in plants. Functional analyses indicate that several non-additive polymorphisms affect protein structure and account for the natural variation in arsenate reductase activity in Arabidopsis thaliana accessions. This study shows that arsenate reductases are an essential component for natural plant variation in As(V) tolerance.

Published

2014

23. Myxococcus xanthus low-molecular-weight protein tyrosine phosphatase homolog, ArsA, possesses arsenate reductase activity.

Author

Mori Y and Kimura Y

Subjects

Arsenate Reductases chemistry, Bacterial Proteins chemistry, Molecular Weight, Protein Tyrosine Phosphatases chemistry, Sequence Homology, Amino Acid, Arsenate Reductases metabolism, Bacterial Proteins metabolism, Myxococcus xanthus enzymology

Abstract

Myxococcus xanthus MXAN_0575, ArsA, exhibited sequence homology to low-molecular-weight protein tyrosine phosphatases (LMWPTPs) and arsenate reductases. ArsA exhibited weak phosphatase activity toward p-nitrophenyl phosphate, and high arsenate reductase activity, suggesting that ArsA may play a role in arsenate reductase, but not LMWPTP., (Copyright © 2013 The Society for Biotechnology, Japan. Published by Elsevier B.V. All rights reserved.)

Published

2014

24. A SAM-dependent methyltransferase cotranscribed with arsenate reductase alters resistance to peptidyl transferase center-binding antibiotics in Azospirillum brasilense Sp7.

Author

Singh S, Singh C, and Tripathi AK

Subjects

Anti-Bacterial Agents metabolism, Arsenate Reductases genetics, Azospirillum brasilense genetics, Chloramphenicol metabolism, Chloramphenicol pharmacology, Clindamycin metabolism, Clindamycin pharmacology, Cloning, Molecular, Diterpenes metabolism, Diterpenes pharmacology, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, Gene Knockout Techniques, Methyltransferases genetics, Mutagenesis, Insertional, Ribosomes metabolism, Anti-Bacterial Agents pharmacology, Arsenate Reductases metabolism, Azospirillum brasilense drug effects, Azospirillum brasilense enzymology, Drug Resistance, Bacterial, Methyltransferases metabolism

Abstract

The genome of Azospirillum brasilense harbors a gene encoding S-adenosylmethionine-dependent methyltransferase, which is located downstream of an arsenate reductase gene. Both genes are cotranscribed and translationally coupled. When they were cloned and expressed individually in an arsenate-sensitive strain of Escherichia coli, arsenate reductase conferred tolerance to arsenate; however, methyltransferase failed to do so. Sequence analysis revealed that methyltransferase was more closely related to a PrmB-type N5-glutamine methyltransferase than to the arsenate detoxifying methyltransferase ArsM. Insertional inactivation of prmB gene in A. brasilense resulted in an increased sensitivity to chloramphenicol and resistance to tiamulin and clindamycin, which are known to bind at the peptidyl transferase center (PTC) in the ribosome. These observations suggested that the inability of prmB:km mutant to methylate L3 protein might alter hydrophobicity in the antibiotic-binding pocket of the PTC, which might affect the binding of chloramphenicol, clindamycin, and tiamulin differentially. This is the first report showing the role of PrmB-type N5-glutamine methyltransferases in conferring resistance to tiamulin and clindamycin in any bacterium.

Published

2014

25. Prokaryotic arsenate reductase enhances arsenate resistance in Mammalian cells.

Author

Wu D, Tao X, Wu G, Li X, and Liu P

Subjects

Genome, Hep G2 Cells, Humans, Arsenate Reductases metabolism, Arsenates toxicity, Gene Expression Regulation physiology, Prokaryotic Cells enzymology, Transfection

Abstract

Arsenic is a well-known heavy metal toxicant in the environment. Bioremediation of heavy metals has been proposed as a low-cost and eco-friendly method. This article described some of recent patents on transgenic plants with enhanced heavy metal resistance. Further, to test whether genetic modification of mammalian cells could render higher arsenic resistance, a prokaryotic arsenic reductase gene arsC was transfected into human liver cancer cell HepG2. In the stably transfected cells, the expression level of arsC gene was determined by quantitative real-time PCR. Results showed that arsC was expressed in HepG2 cells and the expression was upregulated by 3 folds upon arsenate induction. To further test whether arsC has function in HepG2 cells, the viability of HepG2-pCI-ArsC cells exposed to arsenite or arsenate was compared to that of HepG2-pCI cells without arsC gene. The results indicated that arsC increased the viability of HepG2 cells by 25% in arsenate, but not in arsenite. And the test of reducing ability of stably transfected cells revealed that the concentration of accumulated trivalent arsenic increased by 25% in HepG2-pCI-ArsC cells. To determine the intracellular localization of ArsC, a fusion vector with fluorescent marker pEGFP-N1-ArsC was constructed and transfected into.HepG2. Laser confocal microscopy showed that EGFP-ArsC fusion protein was distributed throughout the cells. Taken together, these results demonstrated that prokaryotic arsenic resistant gene arsC integrated successfully into HepG2 genome and enhanced arsenate resistance of HepG2, which brought new insights of arsenic detoxification in mammalian cells.

Published

2014

26. Molecular characterization of Alr1105 a novel arsenate reductase of the diazotrophic cyanobacterium Anabaena sp. PCC7120 and decoding its role in abiotic stress management in Escherichia coli.

Author

Pandey S, Shrivastava AK, Rai R, and Rai LC

Subjects

Amino Acid Sequence, Anabaena genetics, Arsenate Reductases isolation & purification, Arsenate Reductases metabolism, Bacterial Proteins genetics, Bacterial Proteins isolation & purification, Bacterial Proteins metabolism, Cloning, Molecular, Escherichia coli drug effects, Escherichia coli genetics, Escherichia coli growth & development, Escherichia coli physiology, Gene Expression, Hot Temperature, Hydrogen Peroxide pharmacology, Hydrogen-Ion Concentration, Metals pharmacology, Molecular Sequence Data, Mutation, Oxidative Stress, Phenotype, Sequence Alignment, Ultraviolet Rays, Anabaena enzymology, Arsenate Reductases genetics, Arsenates pharmacology, Stress, Physiological

Abstract

This paper constitutes the first report on the Alr1105 of Anabaena sp. PCC7120 which functions as arsenate reductase and phosphatase and offers tolerance against oxidative and other abiotic stresses in the alr1105 transformed Escherichia coli. The bonafide of 40.8 kDa recombinant GST+Alr1105 fusion protein was confirmed by immunoblotting. The purified Alr1105 protein (mw 14.8 kDa) possessed strong arsenate reductase (Km 16.0 ± 1.2 mM and Vmax 5.6 ± 0.31 μmol min⁻¹ mg protein⁻¹) and phosphatase activity (Km 27.38 ± 3.1 mM and Vmax 0.077 ± 0.005 μmol min⁻¹ mg protein⁻¹) at an optimum temperature 37 °C and 6.5 pH. Native Alr1105 was found as a monomeric protein in contrast to its homologous Synechocystis ArsC protein. Expression of Alr1105 enhanced the arsenic tolerance in the arsenate reductase mutant E. coli WC3110 (∆arsC) and rendered better growth than the wild type W3110 up to 40 mM As (V). Notwithstanding above, the recombinant E. coli strain when exposed to CdCl₂, ZnSO₄, NiCl₂, CoCl₂, CuCl₂, heat, UV-B and carbofuron showed increase in growth over the wild type and mutant E. coli transformed with the empty vector. Furthermore, an enhanced growth of the recombinant E. coli in the presence of oxidative stress producing chemicals (MV, PMS and H₂O₂), suggested its protective role against these stresses. Appreciable expression of alr1105 gene as measured by qRT-PCR at different time points under selected stresses reconfirmed its role in stress tolerance. Thus the Alr1105 of Anabaena sp. PCC7120 functions as an arsenate reductase and possess novel properties different from the arsenate reductases known so far.

Published

2013

27. Identification of a possible respiratory arsenate reductase in Denitrovibrio acetiphilus, a member of the phylum Deferribacteres.

Author

Denton K, Atkinson MM, Borenstein SP, Carlson A, Carroll T, Cullity K, Demarsico C, Ellowitz D, Gialtouridis A, Gore R, Herleikson A, Ling AY, Martin R, McMahan K, Naksukpaiboon P, Seiz A, Yearwood K, O'Neill J, and Wiatrowski H

Subjects

Amino Acid Sequence, Arsenate Reductases genetics, Arsenate Reductases metabolism, Bacteria classification, Bacteria genetics, Operon, Phylogeny, Sequence Alignment, Shewanella enzymology, Arsenate Reductases isolation & purification, Bacteria enzymology

Abstract

Denitrovibrio acetiphilus N2460(T) is one of the few members of the phylum Deferribacteres with a sequenced genome. N2460(T) was capable of growing with dimethyl sulfoxide, selenate, or arsenate provided as a terminal electron acceptor, and we identified 15 genes that could possibly encode respiratory reductases for these compounds. The protein encoded by one of these genes, YP_003504839, clustered with respiratory arsenate reductases on a phylogenetic tree. Transcription of the gene for YP_003504839, Dacet_2121, was highly induced when arsenate was provided as a terminal electron acceptor. Dacet_2121 exists in a possible operon that is distinct from the previously characterized respiratory arsenate reductase operon in Shewanella sp. ANA-3.

Published

2013

28. Computational identification and analysis of arsenate reductase protein in Cronobacter sakazakii ATCC BAA-894 suggests potential microorganism for reducing arsenate.

Author

Chaturvedi N, Singh VK, and Pandey PN

Subjects

Arsenate Reductases metabolism, Arsenicals metabolism, Bacterial Proteins metabolism, Binding Sites, Computational Biology, Cronobacter sakazakii classification, Cronobacter sakazakii metabolism, Escherichia coli metabolism, Ligands, Models, Molecular, Oxidation-Reduction, Protein Conformation, Protein Structure, Tertiary, Structure-Activity Relationship, Arsenate Reductases chemistry, Bacterial Proteins chemistry, Cronobacter sakazakii enzymology

Abstract

This study focuses a bioinformatics-based prediction of arsC gene product arsenate reductase (ArsC) protein in Cronobacter sakazakii BAA-894 strain. A protein structure-based study encloses three-dimensional structural modeling of target ArsC protein, was carried out by homology modeling method. Ultimately, the detection of active binding regions was carried out for characterization of functional sites in protein. The ten probable ligand binding sites were predicted for target protein structure and highlighted the common binding residues between target and template protein. It has been first time identified that modeled ArsC protein structure in C. sakazakii was structurally and functionally similar to well-characterized ArsC protein of Escherichia coli because of having same structural motifs and fold with similar protein topology and function. Investigation revealed that ArsC from C. sakazakii can play significant role during arsenic resistance and potential microorganism for bioremediation of arsenic toxicity.

Published

2013

29. A new arsenate reductase involved in arsenic detoxification in Anabaena sp. PCC7120.

Author

Pandey S, Shrivastava AK, Singh VK, Rai R, Singh PK, Rai S, and Rai LC

Subjects

Amino Acid Motifs, Amino Acid Sequence, Anabaena genetics, Arsenate Reductases chemistry, Arsenate Reductases genetics, Bacterial Proteins chemistry, Bacterial Proteins genetics, Catalytic Domain, Conserved Sequence, Models, Molecular, Molecular Sequence Data, Mutation, Protein Structure, Tertiary, Anabaena enzymology, Arsenate Reductases metabolism, Arsenates toxicity, Bacterial Proteins metabolism

Abstract

In silico analysis followed by experimental validation leads us to propose that the predicted protein All0195 of Anabaena sp. PCC7120 showing enhanced expression under sodium arsenate (Na2HAsO4) stress belongs to the thioredoxin superfamily with structural similarity to bacterial arsenate reductase. The All0195 protein demonstrated C-X-TC-X-K, NTSG-X2-YR, and D-X2-L-X-KRP as functional motifs that show similarity to seven known bacterial arsenate reductase family protein homologs with Cys, Arg, and Pro as conserved residues. In view of physicochemical properties, such as aliphatic index, ratio of Glu + Lys to Gln + His, and secondary structure, it was evident that All0195 was also a thermostable protein. The predicted three-dimensional structure on molecular docking with arsenate oxyanion ([Formula: see text]) revealed its interaction with conserved Cys residue as also known for other bacterial arsenate reductase. In silico derived properties were experimentally attested by cloning and heterologous expression of all0195. Furthermore, this protein functionally complemented the arsenate reductase-deficient sodium arsenate-hypersensitive phenotype of Escherichia coli strainWC3110 (ΔarsC) and depicted arsenate reductase activity on purification. In view of the above properties, All0195 appears to be a new arsenate reductase involved in arsenic detoxification in Anabaena sp. PCC7120.

Published

2013

30. Inhibition of microbial arsenate reduction by phosphate.

Author

Slaughter DC, Macur RE, and Inskeep WP

Subjects

Agrobacterium tumefaciens genetics, Arsenate Reductases genetics, Arsenates toxicity, Bacterial Proteins genetics, Binding, Competitive, Biological Transport, Active, Gene Expression, Kinetics, Oxidation-Reduction, Phosphates pharmacology, Protein Binding, Soil chemistry, Soil Pollutants metabolism, Soil Pollutants toxicity, Agrobacterium tumefaciens enzymology, Arsenate Reductases metabolism, Arsenates metabolism, Arsenites metabolism, Bacterial Proteins metabolism, Soil Microbiology

Abstract

The ratio of arsenite (As(III)) to arsenate (As(V)) in soils and natural waters is often controlled by the activity of As-transforming microorganisms. Phosphate is a chemical analog to As(V) and, consequently, may competitively inhibit microbial uptake and enzymatic binding of As(V), thus preventing its reduction to the more toxic, mobile, and bioavailable form - As(III). Five As-transforming bacteria isolated either from As-treated soil columns or from As-impacted soils were used to evaluate the effects of phosphate on As(V) reduction and As(III) oxidation. Cultures were initially spiked with various P:As ratios, incubated for approximately 48 h, and analyzed periodically for As(V) and As(III) concentration. Arsenate reduction was inhibited at high P:As ratios and completely suppressed at elevated levels of phosphate (500 and 1,000 μM; P inhibition constant (K(i))∼20-100 μM). While high P:As ratios effectively shut down microbial As(V) reduction, the expression of the arsenate reductase gene (arsC) was not inhibited under these conditions in the As(V)-reducing isolate, Agrobacterium tumefaciens str. 5B. Further, high phosphate ameliorated As(V)-induced cell growth inhibition caused by high (1mM) As pressure. These results indicate that phosphate may inhibit As(V) reduction by impeding As(V) uptake by the cell via phosphate transport systems or by competitively binding to the active site of ArsC., (Copyright © 2011 Elsevier GmbH. All rights reserved.)

Published

2012

31. Response to arsenate treatment in Schizosaccharomyces pombe and the role of its arsenate reductase activity.

Author

Salgado A, López-Serrano Oliver A, Matia-González AM, Sotelo J, Zarco-Fernández S, Muñoz-Olivas R, Cámara C, and Rodríguez-Gabriel MA

Subjects

Cell Cycle Proteins metabolism, Chromatography, Ion Exchange, Chromatography, Liquid, Genotype, Immunoblotting, Mass Spectrometry, Mitogen-Activated Protein Kinase Kinases metabolism, Mitogen-Activated Protein Kinases metabolism, Protein Tyrosine Phosphatases metabolism, Schizosaccharomyces enzymology, Spectrophotometry, Atomic, Arsenate Reductases metabolism, Arsenates toxicity, Phosphoprotein Phosphatases metabolism, Schizosaccharomyces drug effects, Schizosaccharomyces pombe Proteins metabolism

Abstract

Arsenic toxicity has been studied for a long time due to its effects in humans. Although epidemiological studies have demonstrated multiple effects in human physiology, there are many open questions about the cellular targets and the mechanisms of response to arsenic. Using the fission yeast Schizosaccharomyces pombe as model system, we have been able to demonstrate a strong activation of the MAPK Spc1/Sty1 in response to arsenate. This activation is dependent on Wis1 activation and Pyp2 phosphatase inactivation. Using arsenic speciation analysis we have also demonstrated the previously unknown capacity of S. pombe cells to reduce As (V) to As (III). Genetic analysis of several fission yeast mutants point towards the cell cycle phosphatase Cdc25 as a possible candidate to carry out this arsenate reductase activity. We propose that arsenate reduction and intracellular accumulation of arsenite are the key mechanisms of arsenate tolerance in fission yeast.

Published

2012

32. Corynebacterium glutamicum survives arsenic stress with arsenate reductases coupled to two distinct redox mechanisms.

Author

Villadangos AF, Van Belle K, Wahni K, Dufe VT, Freitas S, Nur H, De Galan S, Gil JA, Collet JF, Mateos LM, and Messens J

Subjects

Amino Acid Sequence, Arsenate Reductases genetics, Arsenic metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Corynebacterium glutamicum genetics, Gene Expression Regulation, Bacterial, Gene Expression Regulation, Enzymologic, Gene Knockout Techniques, Kinetics, Metabolic Networks and Pathways genetics, Models, Biological, Models, Molecular, Molecular Sequence Data, Oxidation-Reduction, Protein Conformation, Protein Multimerization, Sequence Homology, Amino Acid, Arsenate Reductases metabolism, Arsenic toxicity, Corynebacterium glutamicum drug effects, Corynebacterium glutamicum enzymology, Stress, Physiological

Abstract

Arsenate reductases (ArsCs) evolved independently as a defence mechanism against toxic arsenate. In the genome of Corynebacterium glutamicum, there are two arsenic resistance operons (ars1 and ars2) and four potential genes coding for arsenate reductases (Cg_ArsC1, Cg_ArsC2, Cg_ArsC1' and Cg_ArsC4). Using knockout mutants, in vitro reconstitution of redox pathways, arsenic measurements and enzyme kinetics, we show that a single organism has two different classes of arsenate reductases. Cg_ArsC1 and Cg_ArsC2 are single-cysteine monomeric enzymes coupled to the mycothiol/mycoredoxin redox pathway using a mycothiol transferase mechanism. In contrast, Cg_ArsC1' is a three-cysteine containing homodimer that uses a reduction mechanism linked to the thioredoxin pathway with a k(cat)/K(M) value which is 10(3) times higher than the one of Cg_ArsC1 or Cg_ArsC2. Cg_ArsC1' is constitutively expressed at low levels using its own promoter site. It reduces arsenate to arsenite that can then induce the expression of Cg_ArsC1 and Cg_ArsC2. We also solved the X-ray structures of Cg_ArsC1' and Cg_ArsC2. Both enzymes have a typical low-molecular-weight protein tyrosine phosphatases-I fold with a conserved oxyanion binding site. Moreover, Cg_ArsC1' is unique in bearing an N-terminal three-helical bundle that interacts with the active site of the other chain in the dimeric interface., (© 2011 Blackwell Publishing Ltd.)

Published

2011

33. Arsenate reduction and expression of multiple chromosomal ars operons in Geobacillus kaustophilus A1.

Author

Cuebas M, Villafane A, McBride M, Yee N, and Bini E

Subjects

Arsenate Reductases biosynthesis, Arsenates pharmacology, Bacterial Proteins genetics, Bacterial Proteins metabolism, Base Sequence, Gene Expression Regulation, Bacterial, Geobacillus drug effects, Geobacillus growth & development, Molecular Sequence Data, Oxidation-Reduction, Reverse Transcriptase Polymerase Chain Reaction, Sequence Analysis, DNA, Sequence Analysis, RNA, Arsenate Reductases genetics, Arsenate Reductases metabolism, Arsenates metabolism, Geobacillus genetics, Geobacillus metabolism, Operon

Abstract

Geobacillus kaustophilus strain A1 was previously isolated from a geothermal environment for its ability to grow in the presence of high arsenate levels. In this study, the molecular mechanisms of arsenate resistance of the strain were investigated. As(V) was reduced to As(III), as shown by HPLC analysis. Consistent with the observation that the micro-organism is not capable of anaerobic growth, no respiratory arsenate reductases were identified. Using specific PCR primers based on the genome sequence of G. kaustophilus HTA426, three unlinked genes encoding detoxifying arsenate reductases were detected in strain A1. These genes were designated arsC1, arsC2 and arsC3. While arsC3 is a monocistronic locus, sequencing of the regions flanking arsC1 and arsC2 revealed the presence of additional genes encoding a putative arsenite transporter and an ArsR-like regulator upstream of each arsenate reductase, indicating the presence of sequences with putative roles in As(V) reduction, As(III) export and arsenic-responsive regulation. RT-PCR demonstrated that both sets of genes were co-transcribed. Furthermore, arsC1 and arsC2, monitored by quantitative real-time RT-PCR, were upregulated in response to As(V), while arsC3 was constitutively expressed at a low level. A mechanism for regulation of As(V) detoxification by Geobacillus that is both consistent with our findings and relevant to the biogeochemical cycle of arsenic and its mobility in the environment is proposed.

Published

2011

34. An arsenate reductase homologue possessing phosphatase activity from sweet potato (Ipomoea batatas [L.] Lam): kinetic studies and characterization.

Author

Chan YH, Lin CY, Pai SH, Huang JK, and Lin CT

Subjects

Amino Acid Sequence, Arsenate Reductases chemistry, Arsenate Reductases genetics, Cloning, Molecular, Hydrogen-Ion Concentration, Kinetics, Models, Molecular, Molecular Sequence Data, Plant Tubers enzymology, Sequence Alignment, Arsenate Reductases metabolism, Ipomoea batatas enzymology, Phosphoric Monoester Hydrolases metabolism

Abstract

A cDNA encoding a putative arsenate reductase homologue (IbArsR) was cloned from sweet potato (Ib). The deduced protein showed a high level of sequence homology (16-66%) with ArsRs from other organisms. A 3-D homology structure was created based on AtArsR (PDB code 1T3K ) from Arabidopsis thaliana. The putative active site of protein tyrosine phosphatase (HC(X)(5)R) is conserved in all reported ArsRs. IbArsR was overexpressed and purified. The monomeric nature of the enzyme was confirmed by 15% SDS-PAGE and molecular mass determination of the native enzyme via ESI Q-TOF. The IbArsR lacks arsenate reductase activity but possesses phosphatase activity. The Michaelis constant (K(M)) value for p-nitrophenyl phosphate (pNPP) was 11.11 mM. The phosphatase activity was inhibited by 0.5 mM sodium arsenate [As(V)]. The protein's half-life of deactivation at 25 °C was 6.1 min, and its inactivation rate constant K(d) was 1.1 × 10(-1) min(-1). The enzyme was active in a broad pH range from 4.0 to 11.0 with optimum activity at pH 10.0. Phosphatase would remove phosphate group from nucleic acid or dephosphorylation of other enzymes as regulation signaling.

Published

2011

35. Monitoring biodegradative enzymes with nanobodies raised in Camelus dromedarius with mixtures of catabolic proteins.

Author

Zafra O, Fraile S, Gutiérrez C, Haro A, Páez-Espino AD, Jiménez JI, and de Lorenzo V

Subjects

Animals, Arsenate Reductases immunology, Bacterial Proteins immunology, Bacterial Proteins metabolism, Biodegradation, Environmental, Camelus immunology, Dioxygenases immunology, Gene Library, Male, Models, Molecular, Peptide Library, Sequence Analysis, Protein, Arsenate Reductases metabolism, Burkholderia enzymology, Dioxygenases metabolism, Immunoglobulin Heavy Chains biosynthesis, Staphylococcus aureus enzymology

Abstract

Functional studies of biodegradative activities in environmental microorganisms require molecular tools for monitoring catabolic enzymes in the members of the native microbiota. To this end, we have generated repertories of single-domain V(HH) fragments of camel immunoglobulins (nanobodies) able to interact with multiple proteins that are descriptors of environmentally relevant processes. For this, we immunized Camelus dromedarius with a cocktail of up to 12 purified enzymes that are representative of major types of detoxifying activities found in aerobic and anaerobic microorganisms. Following the capture of the antigen-binding modules from the mRNA of the camel lymphocytes and the selection of sub-libraries for each of the enzymes in a phage display system we found a large number of V(HH) modules that interacted with each of the antigens. Those associated to the enzyme 2,3 dihydroxybiphenyl dioxygenase of Burkholderia xenovorans LB400 (BphC) and the arsenate reductase of Staphylococcus aureus (ArsC) were examined in detail and found to hold different qualities that were optimal for distinct protein recognition procedures. The repertory of anti-BphC V(HH) s included variants with a strong affinity and specificity for linear epitopes of the enzyme. When the anti-BphC V(HH) library was recloned in a prokaryotic intracellular expression system, some nanobodies were found to inhibit the dioxygenase activity in vivo. Furthermore, anti-ArsC V(HH) s were able to discriminate between proteins stemming from different enzyme families. The easiness of generating large collections of binders with different properties widens considerably the molecular toolbox for analysis of biodegradative bacteria and opens fresh possibilities of monitoring protein markers and activities in the environment., (© 2011 Society for Applied Microbiology and Blackwell Publishing Ltd.)

Published

2011

36. Validation of arsenic resistance in Bacillus cereus strain AG27 by comparative protein modeling of arsC gene product.

Author

Jain S, Saluja B, Gupta A, Marla SS, and Goel R

Subjects

Amino Acid Sequence, Arsenate Reductases genetics, Arsenate Reductases metabolism, Arsenates chemistry, Arsenates metabolism, Arsenic chemistry, Arsenites chemistry, Arsenites metabolism, Computer Simulation, Microbial Sensitivity Tests, Models, Molecular, Molecular Sequence Data, Protein Folding, Protein Structure, Secondary, RNA, Ribosomal, 16S chemistry, RNA, Ribosomal, 16S genetics, Arsenate Reductases chemistry, Arsenic toxicity, Bacillus cereus drug effects, Bacillus cereus enzymology

Abstract

The ars gene system provides arsenic resistance to a variety of microorganisms and can be chromosomal or plasmid-borne. The arsC gene, which codes for an arsenate reductase is essential for arsenate resistance and transforms arsenate into arsenite, which is extruded from the cell. Therefore, arsC gene from Bacillus cereus strain AG27 isolated from soil was amplified, cloned and sequenced. The strain exhibited a minimum inhibitory concentration of 40 and 35 mM to sodium arsenate and sodium arsenite, respectively. Homology of the sequence, when compared with available database using BLASTn search showed that 300 bp amplicons obtained possess partial arsC gene sequence which codes for arsenate reductase, an enzyme involved in the reduction of arsenate to arsenite which is then effluxed out of the cell, thereby indicating the presence of efflux mechanism of resistance in strain. The efflux mechanism was further confirmed by atomic absorption spectroscopy and scanning electron microscopy studies. Moreover, three dimensional structure of modeled arsC from Bacillus cereus strain shares significant structural similarity with arsenate reductase protein of B.subtilis, consisting of, highly similar overall fold with single α/β domain containing a central four stranded, parallel, open-twisted β-sheet flanked by α-helices on both sides. The structure harbors the arsenic binding motif AB loop or P-loop that is highly conserved in arsenate reductase family.

Published

2011

37. Characterization of arsenate transformation and identification of arsenate reductase in a green alga Chlamydomonas reinhardtii.

Author

Yin X, Wang L, Duan G, and Sun G

Subjects

Arsenate Reductases metabolism, Arsenates metabolism, Chlamydomonas reinhardtii enzymology, Chlamydomonas reinhardtii metabolism

Abstract

Arsenic (As) is a pervasive and ubiquitous environmental toxin that has created catastrophic human health problems world-wide. Chlamydomonas reinhardtii is a unicellular green alga, which exists ubiquitously in freshwater aquatic systems. Arsenic metabolism processes of this alga through arsenate reduction and sequent store and efflux were investigated. When supplied with 10 micromol/L arsenate, arsenic speciation analysis showed that arsenite concentration increased from 5.7 to 15.7 mg/kg dry weight during a 7-day period, accounting for 18%-24% of the total As in alga. When treated with different levels of arsenate (10, 20, 30, 40, 50 micromol/L) for 7 days, the arsenite concentration increased with increasing external arsenate concentrations, the proportion of arsenite was up to 23%-28% of the total As in alga. In efflux experiments, both arsenate and arsenite could be found in the efflux solutions. Additionally, the efflux of arsenate was more than that of arsenite. Furthermore, two arsenate reductase genes of C. reinhardtii (CrACR2s) were cloned and expressed in Escherichia coli strain WC3110 (deltaarsC) for the first time. The abilities of both CrACR2s genes to complement the arsenate-sensitive strain were examined. CrACR2.1 restored arsenate resistance at 0.8 mmol/L. However, CrACR2.2 showed much less ability to complement. The gene products were demonstrated to reduce arsenate to arsenite in vivo. In agreement with the complementation results, CrACR2.1 showed higher reduction ability than CrACR2.2, when treated with 0.4 mmol/L arsenate for 16 hr incubation.

Published

2011

38. Pentavalent arsenate reductase activity in cytosolic fractions of Pseudomonas sp., isolated from arsenic-contaminated sites of Tezpur, Assam.

Author

Srivastava D, Madamwar D, and Subramanian RB

Subjects

Arsenate Reductases classification, Arsenate Reductases isolation & purification, Hydrogen-Ion Concentration, India, Phylogeny, RNA, Ribosomal, 16S genetics, Substrate Specificity, Temperature, Arsenate Reductases metabolism, Arsenic toxicity, Cytosol enzymology, Pseudomonas drug effects, Pseudomonas enzymology

Abstract

Pentavalent arsenate reductase activity was localized and characterized in vitro in the cytosolic fraction of a newly isolated bacterial strain from arsenic-contaminated sites. The bacterium was gram negative, rod-shaped, nonmotile, non-spore-forming, and noncapsulated, and the strain was identified as Pseudomonas sp. DRBS1 following biochemical and molecular approaches. The strain Pseudomonas sp. DRBS1 exhibited enzymatic machinery for reduction of arsenate(V) to arsenite(III). The suspended culture of the bacterium reduced more than 97% of As(V) (40-100 mM) to As(III) in 48 h. The growth rate and total cellular yield decreased in the presence of higher concentration of arsenate. The suspended culture repeatedly reduced 10 mM As(V) within 5 h up to five consecutive inputs. The cell-free extracts reduced 86% of 100 microM As(V) in 40 min. The specific activity of arsenate reductase enzyme in the presence of 100 microM arsenate is 6.68 micromol/min per milligram protein. The arsenate reductase activity is maximum at 30 degrees C and at pH 5.2. The arsenate reductase activity increased in the presence of electron donors like citrate, glucose, and galactose and metal ions like Cd(+2), Cu(+2), Ca(+2), and Fe(+2). Selenate as an electron donor also supports the growth of strain DRBS1 and significantly increased the arsenate reduction.

Published

2010

39. Adventitious arsenate reductase activity of the catalytic domain of the human Cdc25B and Cdc25C phosphatases.

Author

Bhattacharjee H, Sheng J, Ajees AA, Mukhopadhyay R, and Rosen BP

Subjects

Binding Sites, Catalytic Domain, Humans, Isoenzymes chemistry, Isoenzymes metabolism, Protein Structure, Tertiary, Arsenate Reductases metabolism, cdc25 Phosphatases chemistry, cdc25 Phosphatases metabolism

Abstract

A number of eukaryotic enzymes that function as arsenate reductases are homologues of the catalytic domain of the human Cdc25 phosphatase. For example, the Leishmania major enzyme LmACR2 is both a phosphatase and an arsenate reductase, and its structure bears similarity to the structure of the catalytic domain of human Cdc25 phosphatase. These reductases contain an active site C-X(5)-R signature motif, where C is the catalytic cysteine, the five X residues form a phosphate binding loop, and R is a highly conserved arginine, which is also present in human Cdc25 phosphatases. We therefore investigated the possibility that the three human Cdc25 isoforms might have adventitious arsenate reductase activity. The sequences for the catalytic domains of Cdc25A, -B, and -C were cloned individually into a prokaryotic expression vector, and their gene products were purified from a bacterial host using nickel affinity chromatography. While each of the three Cdc25 catalytic domains exhibited phosphatase activity, arsenate reductase activity was observed only with Cdc25B and -C. These two enzymes reduced inorganic arsenate but not methylated pentavalent arsenicals. Alteration of either the cysteine and arginine residues of the Cys-X(5)-Arg motif led to the loss of both reductase and phosphatase activities. Our observations suggest that Cdc25B and -C may adventitiously reduce arsenate to the more toxic arsenite and may also provide a framework for identifying other human protein tyrosine phosphatases containing the active site Cys-X(5)-Arg loop that might moonlight as arsenate reductases.

Published

2010

40. How thioredoxin dissociates its mixed disulfide.

Author

Roos G, Foloppe N, Van Laer K, Wyns L, Nilsson L, Geerlings P, and Messens J

Subjects

Arsenate Reductases metabolism, Computer Simulation, Cysteine chemistry, Cysteine metabolism, Disulfides metabolism, Kinetics, Linear Models, Models, Chemical, Models, Molecular, Oxidation-Reduction, Protein Conformation, Sulfhydryl Compounds chemistry, Sulfhydryl Compounds metabolism, Thioredoxins metabolism, Arsenate Reductases chemistry, Disulfides chemistry, Thioredoxins chemistry

Abstract

The dissociation mechanism of the thioredoxin (Trx) mixed disulfide complexes is unknown and has been debated for more than twenty years. Specifically, opposing arguments for the activation of the nucleophilic cysteine as a thiolate during the dissociation of the complex have been put forward. As a key model, the complex between Trx and its endogenous substrate, arsenate reductase (ArsC), was used. In this structure, a Cys29(Trx)-Cys89(ArsC) intermediate disulfide is formed by the nucleophilic attack of Cys29(Trx) on the exposed Cys82(ArsC)-Cys89(ArsC) in oxidized ArsC. With theoretical reactivity analysis, molecular dynamics simulations, and biochemical complex formation experiments with Cys-mutants, Trx mixed disulfide dissociation was studied. We observed that the conformational changes around the intermediate disulfide bring Cys32(Trx) in contact with Cys29(Trx). Cys32(Trx) is activated for its nucleophilic attack by hydrogen bonds, and Cys32(Trx) is found to be more reactive than Cys82(ArsC). Additionally, Cys32(Trx) directs its nucleophilic attack on the more susceptible Cys29(Trx) and not on Cys89(ArsC). This multidisciplinary approach provides fresh insights into a universal thiol/disulfide exchange reaction mechanism that results in reduced substrate and oxidized Trx.

Published

2009

41. The glutathione/glutaredoxin system is essential for arsenate reduction in Synechocystis sp. strain PCC 6803.

Author

López-Maury L, Sánchez-Riego AM, Reyes JC, and Florencio FJ

Subjects

Amino Acid Sequence, Arsenate Reductases chemistry, Arsenate Reductases genetics, Bacterial Proteins chemistry, Bacterial Proteins genetics, Blotting, Northern, Cloning, Molecular, Molecular Sequence Data, Mutagenesis, Insertional, Open Reading Frames genetics, Oxidation-Reduction, Sequence Homology, Amino Acid, Synechocystis genetics, Thioredoxins metabolism, Arsenate Reductases metabolism, Arsenates metabolism, Bacterial Proteins metabolism, Glutaredoxins metabolism, Glutathione metabolism, Synechocystis metabolism

Abstract

Arsenic resistance in Synechocystis sp. strain PCC 6803 is mediated by an operon of three genes in which arsC codes for an arsenate reductase with unique characteristics. Here we describe the identification of two additional and nearly identical genes coding for arsenate reductases in Synechocystis sp. strain PCC 6803, which we have designed arsI1 and arsI2, and the biochemical characterization of both ArsC (arsenate reductase) and ArsI. Functional analysis of single, double, and triple mutants shows that both ArsI enzymes are active arsenate reductases but that their roles in arsenate resistance are essential only in the absence of ArsC. Based on its biochemical properties, ArsC belongs to a family that, though related to thioredoxin-dependent arsenate reductases, uses the glutathione/glutaredoxin system for reduction, whereas ArsI belongs to the previously known glutaredoxin-dependent family. We have also analyzed the role in arsenate resistance of the three glutaredoxins present in Synechocystis sp. strain PCC 6803 both in vitro and in vivo. Only the dithiolic glutaredoxins, GrxA (glutaredoxin A) and GrxB (glutaredoxin B), are able to donate electrons to both types of reductases in vitro, while GrxC (glutaredoxin C), a monothiolic glutaredoxin, is unable to donate electrons to either type. Analysis of glutaredoxin mutant strains revealed that only those lacking the grxA gene have impaired arsenic resistance.

Published

2009

42. Arsenate reductase, mycothiol, and mycoredoxin concert thiol/disulfide exchange.

Author

Ordóñez E, Van Belle K, Roos G, De Galan S, Letek M, Gil JA, Wyns L, Mateos LM, and Messens J

Subjects

Arsenates metabolism, Arsenites metabolism, Biocatalysis, Corynebacterium glutamicum genetics, Electron Transport, Electrons, Genes, Bacterial, Kinetics, Oxidation-Reduction, Substrate Specificity, Arsenate Reductases metabolism, Corynebacterium glutamicum enzymology, Cysteine metabolism, Disulfides metabolism, Glycopeptides metabolism, Inositol metabolism, Sulfhydryl Compounds metabolism

Abstract

We identified the first enzymes that use mycothiol and mycoredoxin in a thiol/disulfide redox cascade. The enzymes are two arsenate reductases from Corynebacterium glutamicum (Cg_ArsC1 and Cg_ArsC2), which play a key role in the defense against arsenate. In vivo knockouts showed that the genes for Cg_ArsC1 and Cg_ArsC2 and those of the enzymes of the mycothiol biosynthesis pathway confer arsenate resistance. With steady-state kinetics, arsenite analysis, and theoretical reactivity analysis, we unraveled the catalytic mechanism for the reduction of arsenate to arsenite in C. glutamicum. The active site thiolate in Cg_ArsCs facilitates adduct formation between arsenate and mycothiol. Mycoredoxin, a redox enzyme for which the function was never shown before, reduces the thiol-arseno bond and forms arsenite and a mycothiol-mycoredoxin mixed disulfide. A second molecule of mycothiol recycles mycoredoxin and forms mycothione that, in its turn, is reduced by the NADPH-dependent mycothione reductase. Cg_ArsCs show a low specificity constant of approximately 5 m(-1) s(-1), typically for a thiol/disulfide cascade with nucleophiles on three different molecules. With the in vitro reconstitution of this novel electron transfer pathway, we have paved the way for the study of redox mechanisms in actinobacteria.

Published

2009

43. Respiratory arsenate reductase as a bidirectional enzyme.

Author

Richey C, Chovanec P, Hoeft SE, Oremland RS, Basu P, and Stolz JF

Subjects

Amino Acid Sequence, Arsenate Reductases classification, Arsenate Reductases genetics, Ectothiorhodospiraceae genetics, Genome, Bacterial, Molecular Sequence Data, Operon, Oxidoreductases classification, Oxidoreductases genetics, Phylogeny, Shewanella enzymology, Shewanella genetics, Arsenate Reductases metabolism, Ectothiorhodospiraceae enzymology, Oxidoreductases metabolism

Abstract

The haloalkaliphilic bacterium Alkalilimnicola ehrlichii is capable of anaerobic chemolithoautotrophic growth by coupling the oxidation of arsenite (As(III)) to the reduction of nitrate and carbon dioxide. Analysis of its complete genome indicates that it lacks a conventional arsenite oxidase (Aox), but instead possesses two operons that each encode a putative respiratory arsenate reductase (Arr). Here we show that one homolog is expressed under chemolithoautotrophic conditions and exhibits both arsenite oxidase and arsenate reductase activity. We also demonstrate that Arr from two arsenate respiring bacteria, Alkaliphilus oremlandii and Shewanella sp. strain ANA-3, is also biochemically reversible. Thus Arr can function as a reductase or oxidase. Its physiological role in a specific organism, however, may depend on the electron potentials of the molybdenum center and [Fe-S] clusters, additional subunits, or constitution of the electron transfer chain. This versatility further underscores the ubiquity and antiquity of microbial arsenic metabolism.

Published

2009

44. The role of arsenate reductase and superoxide dismutase in As accumulation in four Pteris species.

Author

Liu Y, Wang HB, Wong MH, and Ye ZH

Subjects

Plant Leaves chemistry, Plant Leaves enzymology, Plant Roots chemistry, Plant Roots enzymology, Pteris metabolism, Arsenate Reductases metabolism, Arsenic metabolism, Pteris enzymology, Superoxide Dismutase metabolism

Abstract

Using arsenic (As) hyperaccumulators to extract As from contaminated soils is an effective and low-cost technology. Most of the known As hyperaccumulators belong to Pteris species. The present study aims to explore the responses and role of arsenate reductase (AR) and superoxide dismutase (SOD) in As hyperaccumulating fern species (Pteris vittata, and P. multifida) and non-As hyperaccumulating species (P. ensiformis, and P. semipinnata) when grown in soils added with 0 (control), 100, and 200 mg/kg (dry weight) of arsenic as Na(2)HAsO(4).7H(2)O. The results show that AR activities of roots, SOD activities and As concentrations in both roots and fronds of the four Pteris plants increased when exposed to As-contaminated soils. AR activities of roots were much higher, but SOD activities and As concentrations of roots were lower than those of fronds. It is concluded that AR of roots and SOD of both roots and fronds may play important roles to accumulate and detoxify As in the four Pteris species.

Published

2009

45. Comment on "Arsenic (III) fuels anoxygenic photosynthesis in hot spring biofilms from Mono Lake, California".

Author

Schoepp-Cothenet B, Duval S, Santini JM, and Nitschke W

Subjects

California, Oxidation-Reduction, Phylogeny, Arsenate Reductases metabolism, Arsenites metabolism, Bacteria metabolism, Biofilms, Hot Springs microbiology, Photosynthesis

Abstract

Kulp et al. (Reports, 15 August 2008, p. 967) described a bacterium able to photosynthetically oxidize arsenite [As(III)] via arsenate [As(V)] reductase functioning in reverse. Based on their phylogenetic analysis of As(V) reductase, they proposed that this enzyme was responsible for the anaerobic oxidation of As(III) in the Archean. We challenge this proposition based on paleogeochemical, bioenergetic, and phylogenetic arguments.

Published

2009

46. Characterization of the arsenate respiratory reductase from Shewanella sp. strain ANA-3.

Author

Malasarn D, Keeffe JR, and Newman DK

Subjects

Arsenate Reductases chemistry, Arsenate Reductases genetics, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Cell Membrane enzymology, DNA Primers, Gene Expression Regulation, Bacterial, Genetic Vectors, Kinetics, Membrane Proteins genetics, Membrane Proteins metabolism, Plasmids, Polymerase Chain Reaction, Protein Subunits metabolism, Recombinant Proteins metabolism, Shewanella genetics, Arsenate Reductases metabolism, Shewanella enzymology

Abstract

Microbial arsenate respiration contributes to the mobilization of arsenic from the solid to the soluble phase in various locales worldwide. To begin to predict the extent to which As(V) respiration impacts arsenic geochemical cycling, we characterized the expression and activity of the Shewanella sp. strain ANA-3 arsenate respiratory reductase (ARR), the key enzyme involved in this metabolism. ARR is expressed at the beginning of the exponential phase and persists throughout the stationary phase, at which point it is released from the cell. In intact cells, the enzyme localizes to the periplasm. To purify ARR, a heterologous expression system was developed in Escherichia coli. ARR requires anaerobic conditions and molybdenum for activity. ARR is a heterodimer of approximately 131 kDa, composed of one ArrA subunit (approximately 95 kDa) and one ArrB subunit (approximately 27 kDa). For ARR to be functional, the two subunits must be expressed together. Elemental analysis of pure protein indicates that one Mo atom, four S atoms associated with a bis-molybdopterin guanine dinucleotide cofactor, and four to five [4Fe-4S] are present per ARR. ARR has an apparent melting temperature of 41 degrees C, a Km of 5 microM, and a Vmax of 11,111 micromol of As(V) reduced min(-1) mg of protein(-1) and shows no activity in the presence of alternative electron acceptors such as antimonite, nitrate, selenate, and sulfate. The development of a heterologous overexpression system for ARR will facilitate future structural and/or functional studies of this protein family.

Published

2008

47. Regulation of arsenate resistance in Desulfovibrio desulfuricans G20 by an arsRBCC operon and an arsC gene.

Author

Li X and Krumholz LR

Subjects

Arsenates metabolism, Arsenites metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Drug Resistance, Bacterial, Escherichia coli, Gene Expression Regulation, Bacterial, Gene Expression Regulation, Enzymologic, Genome, Bacterial, Mutagenesis, Operon, Oxidation-Reduction, Phylogeny, Arsenate Reductases genetics, Arsenate Reductases metabolism, Arsenates toxicity, Desulfovibrio desulfuricans enzymology, Desulfovibrio desulfuricans genetics

Abstract

Desulfovibrio desulfuricans G20 grows and reduces 20 mM arsenate to arsenite in lactate-sulfate media. Sequence analysis and experimental data show that D. desulfuricans G20 has one copy of arsC and a complete arsRBCC operon in different locations within the genome. Two mutants of strain G20 with defects in arsenate resistance were generated by nitrosoguanidine mutagenesis. The arsRBCC operons were intact in both mutant strains, but each mutant had one point mutation in the single arsC gene. Mutants transformed with either the arsC1 gene or the arsRBCC operon displayed wild-type arsenate resistance, indicating that the two arsC genes were equivalently functional in the sulfate reducer. The arsC1 gene and arsRBCC operon were also cloned into Escherichia coli DH5alpha independently, with either DNA fragment conferring increased arsenate resistance. The recombinant arsRBCC operon allowed growth at up to 50 mM arsenate in LB broth. Quantitative PCR analysis of mRNA products showed that the single arsC1 was constitutively expressed, whereas the operon was under the control of the arsR repressor protein. We suggest a model for arsenate detoxification in which the product of the single arsC1 is first used to reduce arsenate. The arsenite formed is then available to induce the arsRBCC operon for more rapid arsenate detoxification.

Published

2007

48. Conformational fluctuations coupled to the thiol-disulfide transfer between thioredoxin and arsenate reductase in Bacillus subtilis.

Author

Li Y, Hu Y, Zhang X, Xu H, Lescop E, Xia B, and Jin C

Subjects

Arsenate Reductases genetics, Bacillus subtilis chemistry, Bacillus subtilis genetics, Crystallography, X-Ray, Disulfides chemistry, Models, Molecular, Protein Binding, Protein Structure, Quaternary, Sulfhydryl Compounds chemistry, Thioredoxins genetics, Arsenate Reductases chemistry, Arsenate Reductases metabolism, Bacillus subtilis metabolism, Disulfides metabolism, Sulfhydryl Compounds metabolism, Thioredoxins chemistry, Thioredoxins metabolism

Abstract

Arsenic compounds commonly exist in nature and are toxic to nearly all kinds of life forms, which directed the evolution of enzymes in many organisms for arsenic detoxification. In bacteria, the thioredoxin-coupled arsenate reductase catalyzes the reduction of arsenate to arsenite by intramolecular thiol-disulfide cascade. The oxidized arsenate reductase ArsC is subsequently regenerated by thioredoxin through an intermolecular thiol-disulfide exchange process. The solution structure of the Bacillus subtilis thioredoxin-arsenate reductase complex represents the transiently formed intermediate during the intermolecular thiol-disulfide exchange reaction. A comparison of the complex structure with that of thioredoxin and arsenate reductase proteins in redox states showed substantial conformational changes coupled to the reaction process, with arsenate reductase, especially, adopting an "intermediate" conformation in the complex. Our current studies provide novel insights into understanding the reaction mechanisms of the thioredoxin-arsenate reductase pathway.

Published

2007

49. The cymA gene, encoding a tetraheme c-type cytochrome, is required for arsenate respiration in Shewanella species.

Author

Murphy JN and Saltikov CW

Subjects

Amino Acid Sequence, Arsenate Reductases genetics, Culture Media, Cytochrome c Group metabolism, Iron-Sulfur Proteins metabolism, Molecular Sequence Data, Molybdenum metabolism, Mutation, Oxidation-Reduction, Shewanella enzymology, Shewanella genetics, Shewanella physiology, Shewanella putrefaciens enzymology, Shewanella putrefaciens genetics, Shewanella putrefaciens physiology, Arsenate Reductases metabolism, Arsenates metabolism, Cytochrome c Group genetics, Gene Expression Regulation, Bacterial, Shewanella classification, Shewanella metabolism

Abstract

In Shewanella sp. strain ANA-3, utilization of arsenate as a terminal electron acceptor is conferred by a two-gene operon, arrAB, which lacks a gene encoding a membrane-anchoring subunit for the soluble ArrAB protein complex. Analysis of the genome sequence of Shewanella putrefaciens strain CN-32 showed that it also contained the same arrAB operon with 100% nucleotide identity. Here, we report that CN-32 respires arsenate and that this metabolism is dependent on arrA and an additional gene encoding a membrane-associated tetraheme c-type cytochrome, cymA. Deletion of cymA in ANA-3 also eliminated growth on and reduction of arsenate. The DeltacymA strains of CN-32 and ANA-3 negatively affected the reduction of Fe(III) and Mn(IV) but not growth on nitrate. Unlike the CN-32 DeltacymA strain, growth on fumarate was absent in the DeltacymA strain of ANA-3. Both homologous and heterologous complementation of cymA in trans restored growth on arsenate in DeltacymA strains of both CN-32 and ANA-3. Transcription patterns of cymA showed that it was induced under anaerobic conditions in the presence of fumarate and arsenate. Nitrate-grown cells exhibited the greatest level of cymA expression in both wild-type strains. Lastly, site-directed mutagenesis of the first Cys to Ser in each of the four CXXCH c-heme binding motifs of the CN-32 CymA nearly eliminated growth on and reduction of arsenate. Together, these results indicate that the biochemical mechanism of arsenate respiration and reduction requires the interactions of ArrAB with a membrane-associated tetraheme cytochrome, which in the non-arsenate-respiring Shewanella species Shewanella oneidensis strain MR-1, has pleiotropic effects on Fe(III), Mn(IV), dimethyl sulfoxide, nitrate, nitrite, and fumarate respiration.

Published

2007

50. A CDC25 homologue from rice functions as an arsenate reductase.

Author

Duan GL, Zhou Y, Tong YP, Mukhopadhyay R, Rosen BP, and Zhu YG

Subjects

Amino Acid Sequence, Arsenate Reductases genetics, Escherichia coli genetics, Gene Expression Regulation, Plant, Genetic Complementation Test, Molecular Sequence Data, Oryza genetics, Phenotype, Phylogeny, Saccharomyces cerevisiae genetics, cdc25 Phosphatases genetics, Arsenate Reductases metabolism, Arsenates metabolism, Oryza enzymology, Phosphates metabolism, cdc25 Phosphatases metabolism

Abstract

Enzymatic reduction of arsenate to arsenite is the first step in arsenate metabolism in all organisms studied. The rice genome contains two ACR2-like genes, OsACR2.1 and OsACR2.2, which may be involved in regulating arsenic metabolism in rice. Here, we cloned both OsACR2 genes and expressed them in an Escherichia coli strain in which the arsC gene was deleted and in a yeast (Saccharomyces cerevisiae) strain with a disrupted ACR2 gene. OsACR2.1 complemented the arsenate hypersensitive phenotype of E. coli and yeast. OsACR2.2 showed much less ability to complement. The gene products were purified and demonstrated to reduce arsenate to arsenite in vitro, and both exhibited phosphatase activity. In agreement with the complementation results, OsACR2.1 exhibited higher reductase activity than OsACR2.2. Mutagenesis of cysteine residues in the putative active site HC(X)(5)R motif led to nearly complete loss of both phosphatase and arsenate reductase activities. In planta expression of OsACR2.1 increased dramatically after exposure to arsenate. OsACR2.2 was observed only in roots following arsenate exposure, and its expression was less than OsACR2.1.

Published

2007