Your search keyword '"Banks JA"' showing total 6 results

1. Three Genes Define a Bacterial-Like Arsenic Tolerance Mechanism in the Arsenic Hyperaccumulating Fern Pteris vittata.

Author

Cai C, Lanman NA, Withers KA, DeLeon AM, Wu Q, Gribskov M, Salt DE, and Banks JA

Subjects

Ferns metabolism, Plant Proteins metabolism, Arsenic metabolism, Ferns genetics, Plant Proteins genetics

Abstract

Arsenic is a carcinogenic contaminant of water and food and a growing threat to human health in many regions of the world. This study focuses on the fern Pteris vittata (Pteridaceae), which is extraordinary in its ability to tolerate and hyperaccumulate very high levels of arsenic that would kill any other plant or animal outside the Pteridaceae. Here, we use RNA-seq to identify three genes (GLYCERALDEHYDE 3-PHOSPHATE DEHYDROGENASE (PvGAPC1), ORGANIC CATION TRANSPORTER 4 (PvOCT4), and GLUTATHIONE S-TRANSFERASE (PvGSTF1) that are highly upregulated by arsenic and are necessary for arsenic tolerance, as demonstrated by RNAi. The proteins encoded by these genes have unexpected properties: PvGAPC1 has an unusual active site and a much greater affinity for arsenate than phosphate; PvGSTF1 has arsenate reductase activity; and PvOCT4 localizes as puncta in the cytoplasm. Surprisingly, PvGAPC1, PvGSTF1, and arsenate localize in a similar pattern. These results are consistent with a model that describes the fate of arsenate once it enters the cell. It involves the conversion of arsenate into 1-arseno-3-phosphoglycerate by PvGAPC1. This "chemically trapped" arsenate is pumped into specific arsenic metabolizing vesicles by the PvOCT4 protein. Once inside these vesicles, 1-arseno-3-phosphoglycerate hydrolyses to release arsenate, which is then reduced by PvGSTF1 to arsenite, the form of arsenic stored in the vacuoles of this fern. This mechanism is strikingly similar to one recently described Pseudomonas aeruginosa, whose tolerance to arsenic also involves the biosynthesis and transport of 1-arseno-3-phosphoglycerate, indicating that P. vittata has evolved a simple, bacterial-like mechanism for arsenic tolerance., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

2. Dissecting the components controlling root-to-shoot arsenic translocation in Arabidopsis thaliana.

Author

Wang C, Na G, Bermejo ES, Chen Y, Banks JA, Salt DE, and Zhao FJ

Subjects

Aminoacyltransferases genetics, Aminoacyltransferases metabolism, Arabidopsis metabolism, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Arsenate Reductases genetics, Arsenate Reductases metabolism, Biological Transport, Gene Knockout Techniques, Mutation, Plant Proteins genetics, Plant Roots genetics, Plant Roots metabolism, Plant Shoots genetics, Plant Shoots metabolism, Arabidopsis genetics, Arsenic metabolism, Plant Proteins metabolism, Pteris genetics

Abstract

Arsenic (As) is an important environmental and food-chain toxin. We investigated the key components controlling As accumulation and tolerance in Arabidopsis thaliana. We tested the effects of different combinations of gene knockout, including arsenate reductase (HAC1), γ-glutamyl-cysteine synthetase (γ-ECS), phytochelatin synthase (PCS1) and phosphate effluxer (PHO1), and the heterologous expression of the As-hyperaccumulator Pteris vittata arsenite efflux (PvACR3), on As tolerance, accumulation, translocation and speciation in A. thaliana. Heterologous expression of PvACR3 markedly increased As tolerance and root-to-shoot As translocation in A. thaliana, with PvACR3 being localized to the plasma membrane. Combining PvACR3 expression with HAC1 mutation led to As hyperaccumulation in the shoots, whereas combining HAC1 and PHO1 mutation decreased As accumulation. Mutants of γ-ECS and PCS1 were hypersensitive to As and had higher root-to-shoot As translocation. Combining γ-ECS or PCS1 with HAC1 mutation did not alter As tolerance or accumulation beyond the levels observed in the single mutants. PvACR3 and HAC1 have large effects on root-to-shoot As translocation. Arsenic hyperaccumulation can be engineered in A. thaliana by knocking out the HAC1 gene and expressing PvACR3. PvACR3 and HAC1 also affect As tolerance, but not to the extent of γ-ECS and PCS1., (© 2017 The Authors. New Phytologist © 2017 New Phytologist Trust.)

Published

2018

3. A vacuolar arsenite transporter necessary for arsenic tolerance in the arsenic hyperaccumulating fern Pteris vittata is missing in flowering plants.

Author

Indriolo E, Na G, Ellis D, Salt DE, and Banks JA

Subjects

Amino Acid Sequence, Biological Transport, Cloning, Molecular, Gene Duplication, Gene Knockdown Techniques, Genes, Plant, Germ Cells, Plant drug effects, Germ Cells, Plant metabolism, Membrane Transport Proteins genetics, Molecular Sequence Data, Phylogeny, Plant Proteins genetics, Pteris drug effects, Pteris metabolism, RNA, Plant genetics, Sequence Alignment, Arsenites metabolism, Membrane Transport Proteins metabolism, Plant Proteins metabolism, Pteris genetics, Vacuoles metabolism

Abstract

The fern Pteris vittata tolerates and hyperaccumulates exceptionally high levels of the toxic metalloid arsenic, and this trait appears unique to the Pteridaceae. Once taken up by the root, arsenate is reduced to arsenite as it is transported to the lamina of the frond, where it is stored in cells as free arsenite. Here, we describe the isolation and characterization of two P. vittata genes, ACR3 and ACR3;1, which encode proteins similar to the ACR3 arsenite effluxer of yeast. Pv ACR3 is able to rescue the arsenic-sensitive phenotypes of yeast deficient for ACR3. ACR3 transcripts are upregulated by arsenic in sporophyte roots and gametophytes, tissues that directly contact soil, whereas ACR3;1 expression is unaffected by arsenic. Knocking down the expression of ACR3, but not ACR3;1, in the gametophyte results in an arsenite-sensitive phenotype, indicating that ACR3 plays a necessary role in arsenic tolerance in the gametophyte. We show that ACR3 localizes to the vacuolar membrane in gametophytes, indicating that it likely effluxes arsenite into the vacuole for sequestration. Whereas single-copy ACR3 genes are present in moss, lycophytes, other ferns, and gymnosperms, none are present in angiosperms. The duplication of ACR3 in P. vittata and the loss of ACR3 in angiosperms may explain arsenic tolerance in this unusual group of ferns while precluding the same trait in angiosperms.

Published

2010

4. The GID1-mediated gibberellin perception mechanism is conserved in the Lycophyte Selaginella moellendorffii but not in the Bryophyte Physcomitrella patens.

Author

Hirano K, Nakajima M, Asano K, Nishiyama T, Sakakibara H, Kojima M, Katoh E, Xiang H, Tanahashi T, Hasebe M, Banks JA, Ashikari M, Kitano H, Ueguchi-Tanaka M, and Matsuoka M

Subjects

Amino Acid Sequence, Bryopsida drug effects, Bryopsida metabolism, Gas Chromatography-Mass Spectrometry, Immunoblotting, Models, Biological, Molecular Sequence Data, Phylogeny, Plant Growth Regulators pharmacology, Plant Proteins metabolism, Plants, Genetically Modified, Protein Binding, Selaginellaceae drug effects, Selaginellaceae metabolism, Sequence Homology, Amino Acid, Two-Hybrid System Techniques, Bryopsida genetics, Gibberellins pharmacology, Plant Proteins genetics, Selaginellaceae genetics

Abstract

In rice (Oryza sativa) and Arabidopsis thaliana, gibberellin (GA) signaling is mediated by GIBBERELLIN-INSENSITIVE DWARF1 (GID1) and DELLA proteins in collaboration with a GA-specific F-box protein. To explore when plants evolved the ability to perceive GA by the GID1/DELLA pathway, we examined these GA signaling components in the lycophyte Selaginella moellendorffii and the bryophyte Physcomitrella patens. An in silico search identified several homologs of GID1, DELLA, and GID2, a GA-specific F-box protein in rice, in both species. Sm GID1a and Sm GID1b, GID1 proteins from S. moellendorffii, showed GA binding activity in vitro and interacted with DELLA proteins from S. moellendorffii in a GA-dependent manner in yeast. Introduction of constitutively expressed Sm GID1a, Sm G1D1b, and Sm GID2a transgenes rescued the dwarf phenotype of rice gid1 and gid2 mutants. Furthermore, treatment with GA(4), a major GA in S. moellendorffii, caused downregulation of Sm GID1b, Sm GA20 oxidase, and Sm GA3 oxidase and degradation of the Sm DELLA1 protein. These results demonstrate that the homologs of GID1, DELLA, and GID2 work in a similar manner in S. moellendorffii and in flowering plants. Biochemical studies revealed that Sm GID1s have different GA binding properties from GID1s in flowering plants. No evidence was found for the functional conservation of these genes in P. patens, indicating that GID1/DELLA-mediated GA signaling, if present, differs from that in vascular plants. Our results suggest that GID1/DELLA-mediated GA signaling appeared after the divergence of vascular plants from the moss lineage.

Published

2007

5. A novel arsenate reductase from the arsenic hyperaccumulating fern Pteris vittata.

Author

Ellis DR, Gumaelius L, Indriolo E, Pickering IJ, Banks JA, and Salt DE

Subjects

Amino Acid Motifs, Amino Acid Sequence, Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Arsenate Reductases, Arsenates metabolism, Arsenite Transporting ATPases, Cloning, Molecular, Gene Deletion, Genetic Complementation Test, Ion Pumps chemistry, Ion Pumps genetics, Molecular Sequence Data, Multienzyme Complexes chemistry, Multienzyme Complexes genetics, Phenotype, Phylogeny, Plant Proteins chemistry, Plant Proteins genetics, Pteris genetics, Pteris growth & development, Recombinant Fusion Proteins metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins, Sequence Alignment, Sequence Analysis, Protein, cdc25 Phosphatases genetics, cdc25 Phosphatases metabolism, Arsenic metabolism, Ion Pumps metabolism, Multienzyme Complexes metabolism, Plant Proteins metabolism, Pteris enzymology

Abstract

Pteris vittata sporophytes hyperaccumulate arsenic to 1% to 2% of their dry weight. Like the sporophyte, the gametophyte was found to reduce arsenate [As(V)] to arsenite [As(III)] and store arsenic as free As(III). Here, we report the isolation of an arsenate reductase gene (PvACR2) from gametophytes that can suppress the arsenate sensitivity and arsenic hyperaccumulation phenotypes of yeast (Saccharomyces cerevisiae) lacking the arsenate reductase gene ScACR2. Recombinant PvACR2 protein has in vitro arsenate reductase activity similar to ScACR2. While PvACR2 and ScACR2 have sequence similarities to the CDC25 protein tyrosine phosphatases, they lack phosphatase activity. In contrast, Arath;CDC25, an Arabidopsis (Arabidopsis thaliana) homolog of PvACR2 was found to have both arsenate reductase and phosphatase activities. To our knowledge, PvACR2 is the first reported plant arsenate reductase that lacks phosphatase activity. CDC25 protein tyrosine phosphatases and arsenate reductases have a conserved HCX5R motif that defines the active site. PvACR2 is unique in that the arginine of this motif, previously shown to be essential for phosphatase and reductase activity, is replaced with a serine. Steady-state levels of PvACR2 expression in gametophytes were found to be similar in the absence and presence of arsenate, while total arsenate reductase activity in P. vittata gametophytes was found to be constitutive and unaffected by arsenate, consistent with other known metal hyperaccumulation mechanisms in plants. The unusual active site of PvACR2 and the arsenate reductase activities of cell-free extracts correlate with the ability of P. vittata to hyperaccumulate arsenite, suggesting that PvACR2 may play an important role in this process.

Published

2006

6. ANI1. A sex pheromone-induced gene in ceratopteris gametophytes and its possible role in sex determination.

Author

Wen CK, Smith R, and Banks JA

Subjects

Amino Acid Sequence, Base Sequence, Cycloheximide pharmacology, DNA, Complementary, Gene Expression Regulation, Plant drug effects, Molecular Sequence Data, Mutation, Plant Development, Plant Proteins genetics, Protein Synthesis Inhibitors pharmacology, Plant Proteins physiology, Plants genetics, Sex Determination Processes

Abstract

Antheridiogen (ACE) is a pheromone that is required for the development of male gametophytes in the homosporous fern Ceratopteris richardii. Subtractive hybridization of cDNAs isolated from ACE-treated and non-ACE-treated gametophytes was used to isolate genes that are induced by the pheromone. The expression of one gene, ANI1 (for antheridiogen induced), was induced within 3 hr of ACE treatment, but its expression was transient. Patterns of ANI1 expression in wild-type and mutant gametophytes show that ANI1 expression inversely correlates with the predicted activity of one of the sex-determining genes, TRANSFORMER5 (TRA5). These data suggest that ANI1 transcription or transcript accumulation is directly or indirectly prevented by TRA5 in the absence of ACE and that ACE inactivates the TRA5 gene or its product, leading to the upregulation of ANI1. Cycloheximide (no ACE) induced the expression of ANI1, also indicating that ANI1 expression is subject to negative regulation in the absence of ACE. The sequence and inferred protein structure of ANI1 suggest that it is a novel, extracellular protein. The secreted portion of the ANI1 protein potentially forms a beta barrel with superficial similarities to lipocalins, which bind small hydrophobic molecules such as pheromones, steroids, and odorants. ANI1 may be an extracellular carrier of ACE that is required to initiate the male program of development as the sexual fate of the young gametophyte is determined.

Published

1999