Your search keyword '"Olsen CE"' showing total 17 results

1. Methyl Transfer in Glucosinolate Biosynthesis Mediated by Indole Glucosinolate O-Methyltransferase 5.

Author

Pfalz M, Mukhaimar M, Perreau F, Kirk J, Hansen CI, Olsen CE, Agerbirk N, and Kroymann J

Subjects

Animals, Arabidopsis genetics, Arabidopsis parasitology, DNA, Bacterial genetics, Disease Resistance genetics, Gene Expression Regulation, Plant, Genes, Plant, Mass Spectrometry, Metabolome genetics, Methylation, Mutagenesis, Insertional genetics, Mutation genetics, Plant Diseases genetics, Plant Diseases microbiology, Plant Diseases parasitology, Plant Roots enzymology, Plant Roots genetics, Plant Tumors parasitology, Promoter Regions, Genetic genetics, Tylenchoidea physiology, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Biosynthetic Pathways, Glucosinolates biosynthesis, Methyltransferases metabolism

Abstract

Indole glucosinolates (IGs) are plant secondary metabolites that are derived from the amino acid tryptophan. The product of Arabidopsis (Arabidopsis thaliana) IG core biosynthesis, indol-3-ylmethyl glucosinolate (I3M), can be modified by hydroxylation and subsequent methoxylation of the indole ring in position 1 (1-IG modification) or 4 (4-IG modification). Products of the 4-IG modification pathway mediate plant-enemy interactions and are particularly important for Arabidopsis innate immunity. While CYP81Fs encoding cytochrome P450 monooxygenases and IGMTs encoding indole glucosinolate O-methyltransferases have been identified as key genes for IG modification, our knowledge about the IG modification pathways is not complete. In particular, it is unknown which enzyme is responsible for methyl transfer in the 1-IG modification pathway and whether this pathway plays a role in defense, similar to 4-IG modification. Here, we analyze two Arabidopsis transfer DNA insertion lines with targeted metabolomics. We show that biosynthesis of 1-methoxyindol-3-ylmethyl glucosinolate (1MOI3M) from I3M involves the predicted unstable intermediate 1-hydroxyindol-3-ylmethyl glucosinolate (1OHI3M) and that IGMT5, a gene with moderate similarity to previously characterized IGMTs, encodes the methyltransferase that is responsible for the conversion of 1OHI3M to 1MOI3M. Disruption of IGMT5 function increases resistance against the root-knot nematode Meloidogyne javanica and suggests a potential role for the 1-IG modification pathway in Arabidopsis belowground defense., (© 2016 American Society of Plant Biologists. All Rights Reserved.)

Published

2016

2. The Arabidopsis NPF3 protein is a GA transporter.

Author

Tal I, Zhang Y, Jørgensen ME, Pisanty O, Barbosa IC, Zourelidou M, Regnault T, Crocoll C, Olsen CE, Weinstain R, Schwechheimer C, Halkier BA, Nour-Eldin HH, Estelle M, and Shani E

Subjects

Abscisic Acid metabolism, Abscisic Acid pharmacology, Arabidopsis genetics, Arabidopsis growth & development, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins metabolism, Biological Transport, Carrier Proteins metabolism, Gene Expression Regulation, Developmental, Gibberellins metabolism, Luminescent Proteins genetics, Luminescent Proteins metabolism, Mutation, Plant Growth Regulators metabolism, Plant Growth Regulators pharmacology, Plant Roots drug effects, Plant Roots genetics, Plant Roots growth & development, Plant Roots metabolism, Plants, Genetically Modified, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Seeds drug effects, Seeds genetics, Seeds growth & development, Seeds metabolism, Signal Transduction, Arabidopsis drug effects, Arabidopsis Proteins genetics, Carrier Proteins genetics, Gene Expression Regulation, Plant, Gibberellins pharmacology

Abstract

Gibberellins (GAs) are plant hormones that promote a wide range of developmental processes. While GA signalling is well understood, little is known about how GA is transported or how GA distribution is regulated. Here we utilize fluorescently labelled GAs (GA-Fl) to screen for Arabidopsis mutants deficient in GA transport. We show that the NPF3 transporter efficiently transports GA across cell membranes in vitro and GA-Fl in vivo. NPF3 is expressed in root endodermis and repressed by GA. NPF3 is targeted to the plasma membrane and subject to rapid BFA-dependent recycling. We show that abscisic acid (ABA), an antagonist of GA, is also transported by NPF3 in vitro. ABA promotes NPF3 expression and GA-Fl uptake in plants. On the basis of these results, we propose that GA distribution and activity in Arabidopsis is partly regulated by NPF3 acting as an influx carrier and that GA-ABA interaction may occur at the level of transport.

Published

2016

3. Functional Expression and Characterization of Plant ABC Transporters in Xenopus laevis Oocytes for Transport Engineering Purposes.

Author

Xu D, Veres D, Belew ZM, Olsen CE, Nour-Eldin HH, and Halkier BA

Subjects

ATP-Binding Cassette Transporters metabolism, Animals, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Bioengineering methods, Biological Transport, Exons, Substrate Specificity, Xenopus laevis metabolism, ATP-Binding Cassette Transporters genetics, Arabidopsis genetics, Arabidopsis Proteins genetics, Cloning, Molecular methods, Oocytes metabolism, Xenopus laevis genetics

Abstract

Transport engineering in bioengineering is aimed at efficient export of the final product to reduce toxicity and feedback inhibition and to increase yield. The ATP-binding cassette (ABC) transporters with their highly diverse substrate specificity and role in cellular efflux are potentially suitable in transport engineering approaches, although their size and high number of introns make them notoriously difficult to clone. Here, we report a novel in planta "exon engineering" strategy for cloning of full-length coding sequence of ABC transporters followed by methods for biochemical characterization of ABC exporters in Xenopus oocytes. Although the Xenopus oocyte expression system is particularly suitable for expression of membrane proteins and powerful in screening for novel transporter activity, only few examples of successful expression of ABC transporter has been reported. This raises the question whether the oocytes system is suitable to express and characterize ABC transporters. Thus we have selected AtABCG25, previously characterized in insect cells as the exporter of commercially valuable abscisic acid-as case study for optimizing of characterization in Xenopus oocytes. The tools provided will hopefully contribute to more successful transport engineering in synthetic biology., (© 2016 Elsevier Inc. All rights reserved.)

Published

2016

4. Phosphorylation at serine 52 and 635 does not alter the transport properties of glucosinolate transporter AtGTR1.

Author

Jørgensen ME, Olsen CE, Halkier BA, and Nour-Eldin HH

Subjects

Arabidopsis Proteins genetics, Arabidopsis Proteins metabolism, Biological Transport, Cell Membrane metabolism, Monosaccharide Transport Proteins genetics, Monosaccharide Transport Proteins metabolism, Mutagenesis, Site-Directed, Phosphorylation, Serine metabolism, Arabidopsis metabolism, Arabidopsis Proteins physiology, Monosaccharide Transport Proteins physiology

Abstract

Little is known about how plants regulate transporters of defense compounds. In A. thaliana, glucosinolates are transported between tissues by NPF2.10 (AtGTR1) and NPF2.11 (AtGTR2). Mining of the PhosPhat4.0 database showed two cytosol exposed phosphorylation sites for AtGTR1 and one membrane-buried phosphorylation site for AtGTR2. In this study, we investigate whether mutation of the two potential regulatory sites of AtGTR1 affected transport of glucosinolates in Xenopus oocytes. Characterization of AtGTR1 phosphorylation mutants showed that phosphorylation of AtGTR1 - at the two reported phosphorylation sites - is not directly involved in regulating AtGTR1 transport activity. We hypothesize a role for AtGTR1-phosphorylation in regulating protein-protein interactions.

Published

2016

5. A Functional EXXEK Motif is Essential for Proton Coupling and Active Glucosinolate Transport by NPF2.11.

Author

Jørgensen ME, Olsen CE, Geiger D, Mirza O, Halkier BA, and Nour-Eldin HH

Subjects

Amino Acid Motifs, Amino Acid Sequence, Arabidopsis Proteins chemistry, Biological Transport, Culture Media, Epitopes metabolism, Hydrogen-Ion Concentration, Molecular Sequence Data, Monosaccharide Transport Proteins chemistry, Mutant Proteins metabolism, Mutation genetics, Sequence Alignment, Sequence Analysis, Protein, Structure-Activity Relationship, Substrate Specificity, Threonine metabolism, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Glucosinolates metabolism, Monosaccharide Transport Proteins metabolism, Protons

Abstract

The proton-dependent oligopeptide transporter (POT/PTR) family shares a highly conserved E1X1X2E2RFXYY (E1X1X2E2R) motif across all kingdoms of life. This motif is suggested to have a role in proton coupling and active transport in bacterial homologs. For the plant POT/PTR family, also known as the NRT1/PTR family (NPF), little is known about the role of the E1X1X2E2R motif. Moreover, nothing is known about the role of the X1 and X2 residues within the E1X1X2E2R motif. We used NPF2.11-a proton-coupled glucosinolate (GLS) symporter from Arabidopsis thaliana-to investigate the role of the E1X1X2E2K motif variant in a plant NPF transporter. Using liquid chromatography-mass spectrometry (LC-MS)-based uptake assays and two-electrode voltage clamp (TEVC) electrophysiology, we demonstrate an essential role for the E1X1X2E2K motif for accumulation of substrate by NPF2.11. Our data suggest that the highly conserved E1, E2 and K residues are involved in translocation of protons, as has been proposed for the E1X1X2E2R motif in bacteria. Furthermore, we show that the two residues X1 and X2 in the E1X1X2E2[K/R] motif are conserved as uncharged amino acids in POT/PTRs from bacteria to mammals and that introducing a positive or negative charge in either position hampers the ability to overaccumulate substrate relative to the assay medium. We hypothesize that introducing a charge at X1 and X2 interferes with the function of the conserved glutamate and lysine residues of the E1X1X2E2K motif and affects the mechanism behind proton coupling., (© The Author 2015. Published by Oxford University Press on behalf of Japanese Society of Plant Physiologists.)

Published

2015

6. Elucidating the role of transport processes in leaf glucosinolate distribution.

Author

Madsen SR, Olsen CE, Nour-Eldin HH, and Halkier BA

Subjects

Arabidopsis Proteins genetics, Biological Transport, Gene Knockout Techniques, Monosaccharide Transport Proteins genetics, Plant Epidermis metabolism, Plant Leaves cytology, Plant Roots metabolism, Plasmodesmata metabolism, Xylem metabolism, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Glucosinolates metabolism, Monosaccharide Transport Proteins metabolism, Plant Leaves metabolism

Abstract

In Arabidopsis (Arabidopsis thaliana), a strategy to defend its leaves against herbivores is to accumulate glucosinolates along the midrib and at the margin. Although it is generally assumed that glucosinolates are synthesized along the vasculature in an Arabidopsis leaf, thereby suggesting that the margin accumulation is established through transport, little is known about these transport processes. Here, we show through leaf apoplastic fluid analysis and glucosinolate feeding experiments that two glucosinolate transporters, GTR1 and GTR2, essential for long-distance transport of glucosinolates in Arabidopsis, also play key roles in glucosinolate allocation within a mature leaf by effectively importing apoplastically localized glucosinolates into appropriate cells. Detection of glucosinolates in root xylem sap unambiguously shows that this transport route is involved in root-to-shoot glucosinolate allocation. Detailed leaf dissections show that in the absence of GTR1 and GTR2 transport activity, glucosinolates accumulate predominantly in leaf margins and leaf tips. Furthermore, we show that glucosinolates accumulate in the leaf abaxial epidermis in a GTR-independent manner. Based on our results, we propose a model for how glucosinolates accumulate in the leaf margin and epidermis, which includes symplasmic movement through plasmodesmata, coupled with the activity of putative vacuolar glucosinolate importers in these peripheral cell layers., (© 2014 American Society of Plant Biologists. All Rights Reserved.)

Published

2014

7. NRT/PTR transporters are essential for translocation of glucosinolate defence compounds to seeds.

Author

Nour-Eldin HH, Andersen TG, Burow M, Madsen SR, Jørgensen ME, Olsen CE, Dreyer I, Hedrich R, Geiger D, and Halkier BA

Subjects

Animals, Arabidopsis embryology, Arabidopsis genetics, Arabidopsis Proteins genetics, Biological Transport drug effects, Cell Extracts chemistry, Evolution, Molecular, Gene Deletion, Gene Library, Genes, Plant genetics, Glucosinolates pharmacology, Monosaccharide Transport Proteins deficiency, Monosaccharide Transport Proteins genetics, Oocytes drug effects, Oocytes metabolism, Organ Specificity, Phloem metabolism, Protons, Xenopus laevis, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Glucosinolates metabolism, Monosaccharide Transport Proteins metabolism, Seeds metabolism

Abstract

In plants, transport processes are important for the reallocation of defence compounds to protect tissues of high value, as demonstrated in the plant model Arabidopsis, in which the major defence compounds, glucosinolates, are translocated to seeds on maturation. The molecular basis for long-distance transport of glucosinolates and other defence compounds, however, remains unknown. Here we identify and characterize two members of the nitrate/peptide transporter family, GTR1 and GTR2, as high-affinity, proton-dependent glucosinolate-specific transporters. The gtr1 gtr2 double mutant did not accumulate glucosinolates in seeds and had more than tenfold over-accumulation in source tissues such as leaves and silique walls, indicating that both plasma membrane-localized transporters are essential for long-distance transport of glucosinolates. We propose that GTR1 and GTR2 control the loading of glucosinolates from the apoplasm into the phloem. Identification of the glucosinolate transporters has agricultural potential as a means to control allocation of defence compounds in a tissue-specific manner.

Published

2012

8. Microbial production of indolylglucosinolate through engineering of a multi-gene pathway in a versatile yeast expression platform.

Author

Mikkelsen MD, Buron LD, Salomonsen B, Olsen CE, Hansen BG, Mortensen UH, and Halkier BA

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Brassica chemistry, Glucosinolates chemistry, Humans, Neoplasms epidemiology, Neoplasms prevention & control, Recombinant Proteins biosynthesis, Recombinant Proteins genetics, Saccharomyces cerevisiae genetics, Arabidopsis enzymology, Arabidopsis Proteins biosynthesis, Glucosinolates biosynthesis, Metabolic Engineering, Saccharomyces cerevisiae enzymology

Abstract

Epidemiological studies have shown that consumption of cruciferous vegetables, such as, broccoli and cabbages, is associated with a reduced risk of developing cancer. This phenomenon has been attributed to specific glucosinolates among the ~30 glucosinolates that are typically present as natural products characteristic of cruciferous plants. Accordingly, there has been a strong interest to produce these compounds in microbial cell factories as it will allow production of selected beneficial glucosinolates. We have developed a versatile platform for stable expression of multi-gene pathways in the yeast, Saccharomyces cerevisiae. Introduction of the seven-step pathway of indolylglucosinolate from Arabidopsis thaliana to yeast resulted in the first successful production of glucosinolates in a microbial host. The production of indolylglucosinolate was further optimized by substituting supporting endogenous yeast activities with plant-derived enzymes. Production of indolylglucosinolate serves as a proof-of-concept for our expression platform, and provides a basis for large-scale microbial production of specific glucosinolates for the benefit of human health., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

9. O-glycosylated cell wall proteins are essential in root hair growth.

Author

Velasquez SM, Ricardi MM, Dorosz JG, Fernandez PV, Nadra AD, Pol-Fachin L, Egelund J, Gille S, Harholt J, Ciancia M, Verli H, Pauly M, Bacic A, Olsen CE, Ulvskov P, Petersen BL, Somerville C, Iusem ND, and Estevez JM

Subjects

Arabidopsis genetics, Arabidopsis growth & development, Arabidopsis Proteins chemistry, Arabidopsis Proteins genetics, Arabinose metabolism, Carbohydrate Conformation, Gene Expression Regulation, Plant, Genes, Plant, Glycoproteins chemistry, Glycosylation, Glycosyltransferases genetics, Glycosyltransferases metabolism, Hydroxylation, Models, Biological, Mutation, Pentosyltransferases chemistry, Pentosyltransferases metabolism, Phenotype, Plant Proteins chemistry, Plant Roots cytology, Plant Roots metabolism, Polysaccharides chemistry, Procollagen-Proline Dioxygenase genetics, Proline metabolism, Protein Conformation, Protein Processing, Post-Translational, Protein Structure, Secondary, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Cell Wall metabolism, Glycoproteins metabolism, Hydroxyproline metabolism, Plant Proteins metabolism, Plant Roots growth & development, Procollagen-Proline Dioxygenase metabolism

Abstract

Root hairs are single cells that develop by tip growth and are specialized in the absorption of nutrients. Their cell walls are composed of polysaccharides and hydroxyproline-rich glycoproteins (HRGPs) that include extensins (EXTs) and arabinogalactan-proteins (AGPs). Proline hydroxylation, an early posttranslational modification of HRGPs that is catalyzed by prolyl 4-hydroxylases (P4Hs), defines the subsequent O-glycosylation sites in EXTs (which are mainly arabinosylated) and AGPs (which are mainly arabinogalactosylated). We explored the biological function of P4Hs, arabinosyltransferases, and EXTs in root hair cell growth. Biochemical inhibition or genetic disruption resulted in the blockage of polarized growth in root hairs and reduced arabinosylation of EXTs. Our results demonstrate that correct O-glycosylation on EXTs is essential for cell-wall self-assembly and, hence, root hair elongation in Arabidopsis thaliana.

Published

2011

10. Cytosolic γ-glutamyl peptidases process glutathione conjugates in the biosynthesis of glucosinolates and camalexin in Arabidopsis.

Author

Geu-Flores F, Møldrup ME, Böttcher C, Olsen CE, Scheel D, and Halkier BA

Subjects

Animals, Arabidopsis genetics, Arabidopsis Proteins genetics, Glutathione chemistry, Humans, Mass Spectrometry, Molecular Sequence Data, Molecular Structure, Peptide Hydrolases genetics, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Sulfur metabolism, Arabidopsis enzymology, Arabidopsis metabolism, Arabidopsis Proteins metabolism, Cytosol enzymology, Glucosinolates biosynthesis, Glutathione metabolism, Indoles metabolism, Peptide Hydrolases metabolism, Thiazoles metabolism

Abstract

The defense-related plant metabolites known as glucosinolates play important roles in agriculture, ecology, and human health. Despite an advanced biochemical understanding of the glucosinolate pathway, the source of the reduced sulfur atom in the core glucosinolate structure remains unknown. Recent evidence has pointed toward GSH, which would require further involvement of a GSH conjugate processing enzyme. In this article, we show that an Arabidopsis thaliana mutant impaired in the production of the γ-glutamyl peptidases GGP1 and GGP3 has altered glucosinolate levels and accumulates up to 10 related GSH conjugates. We also show that the double mutant is impaired in the production of camalexin and accumulates high amounts of the camalexin intermediate GS-IAN upon induction. In addition, we demonstrate that the cellular and subcellular localization of GGP1 and GGP3 matches that of known glucosinolate and camalexin enzymes. Finally, we show that the purified recombinant GGPs can metabolize at least nine of the 10 glucosinolate-related GSH conjugates as well as GS-IAN. Our results demonstrate that GSH is the sulfur donor in the biosynthesis of glucosinolates and establish an in vivo function for the only known cytosolic plant γ-glutamyl peptidases, namely, the processing of GSH conjugates in the glucosinolate and camalexin pathways.

Published

2011

11. Metabolic engineering in Nicotiana benthamiana reveals key enzyme functions in Arabidopsis indole glucosinolate modification.

Author

Pfalz M, Mikkelsen MD, Bednarek P, Olsen CE, Halkier BA, and Kroymann J

Subjects

Animals, Arabidopsis genetics, Arabidopsis Proteins genetics, Cell Line, Cytochrome P-450 Enzyme System genetics, DNA, Bacterial genetics, DNA, Plant genetics, Gene Expression Regulation, Plant, Mutagenesis, Insertional, Mutation, Spodoptera cytology, Nicotiana genetics, Nicotiana metabolism, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Cytochrome P-450 Enzyme System metabolism, Glucosinolates biosynthesis, Indoles metabolism

Abstract

Indole glucosinolates, derived from the amino acid Trp, are plant secondary metabolites that mediate numerous biological interactions between cruciferous plants and their natural enemies, such as herbivorous insects, pathogens, and other pests. While the genes and enzymes involved in the Arabidopsis thaliana core biosynthetic pathway, leading to indol-3-yl-methyl glucosinolate (I3M), have been identified and characterized, the genes and gene products responsible for modification reactions of the indole ring are largely unknown. Here, we combine the analysis of Arabidopsis mutant lines with a bioengineering approach to clarify which genes are involved in the remaining biosynthetic steps in indole glucosinolate modification. We engineered the indole glucosinolate biosynthesis pathway into Nicotiana benthamiana, showing that it is possible to produce indole glucosinolates in a noncruciferous plant. Building upon this setup, we demonstrate that all members of a small gene subfamily of cytochrome P450 monooxygenases, CYP81Fs, are capable of carrying out hydroxylation reactions of the glucosinolate indole ring, leading from I3M to 4-hydroxy-indol-3-yl-methyl and/or 1-hydroxy-indol-3-yl-methyl glucosinolate intermediates, and that these hydroxy intermediates are converted to 4-methoxy-indol-3-yl-methyl and 1-methoxy-indol-3-yl-methyl glucosinolates by either of two family 2 O-methyltransferases, termed indole glucosinolate methyltransferase 1 (IGMT1) and IGMT2.

Published

2011

12. Metabolomic, transcriptional, hormonal, and signaling cross-talk in superroot2.

Author

Morant M, Ekstrøm C, Ulvskov P, Kristensen C, Rudemo M, Olsen CE, Hansen J, Jørgensen K, Jørgensen B, Møller BL, and Bak S

Subjects

Arabidopsis genetics, Arabidopsis Proteins genetics, Ethylenes metabolism, Gene Expression Regulation, Plant genetics, Gene Expression Regulation, Plant physiology, Indoleacetic Acids metabolism, Models, Biological, Phenotype, Plants, Genetically Modified genetics, Plants, Genetically Modified metabolism, Seedlings genetics, Seedlings metabolism, Signal Transduction physiology, Transcription Factors genetics, Transcription Factors metabolism, Arabidopsis metabolism, Arabidopsis Proteins metabolism

Abstract

Auxin homeostasis is pivotal for normal plant growth and development. The superroot2 (sur2) mutant was initially isolated in a forward genetic screen for auxin overproducers, and SUR2 was suggested to control auxin conjugation and thereby regulate auxin homeostasis. However, the phenotype was not uniform and could not be described as a pure high auxin phenotype, indicating that knockout of CYP83B1 has multiple effects. Subsequently, SUR2 was identified as CYP83B1, a cytochrome P450 positioned at the metabolic branch point between auxin and indole glucosinolate metabolism. To investigate concomitant global alterations triggered by knockout of CYP83B1 and the countermeasures chosen by the mutant to cope with hormonal and metabolic imbalances, 10-day-old mutant seedlings were characterized with respect to their transcriptome and metabolome profiles. Here, we report a global analysis of the sur2 mutant by the use of a combined transcriptomic and metabolomic approach revealing pronounced effects on several metabolic grids including the intersection between secondary metabolism, cell wall turnover, hormone metabolism, and stress responses. Metabolic and transcriptional cross-talks in sur2 were found to be regulated by complex interactions between both positively and negatively acting transcription factors. The complex phenotype of sur2 may thus not only be assigned to elevated levels of auxin, but also to ethylene and abscisic acid responses as well as drought responses in the absence of a water deficiency. The delicate balance between these signals explains why minute changes in growth conditions may result in the non-uniform phenotype. The large phenotypic variation observed between and within the different surveys may be reconciled by the complex and intricate hormonal balances in sur2 seedlings decoded in this study.

Published

2010

13. Controlled indole-3-acetaldoxime production through ethanol-induced expression of CYP79B2.

Author

Mikkelsen MD, Fuller VL, Hansen BG, Nafisi M, Olsen CE, Nielsen HB, and Halkier BA

Subjects

Arabidopsis metabolism, Arabidopsis Proteins metabolism, Biosynthetic Pathways, Chromatography, Liquid, Cluster Analysis, Cytochrome P-450 Enzyme System metabolism, Gene Expression Profiling, Gene Expression Regulation, Plant drug effects, Glucosinolates chemistry, Glucosinolates metabolism, Indoleacetic Acids chemistry, Indoleacetic Acids metabolism, Indoles chemistry, Mass Spectrometry, Molecular Structure, Mutation, Oligonucleotide Array Sequence Analysis methods, Oximes chemistry, Plants, Genetically Modified, Thiazoles chemistry, Thiazoles metabolism, Arabidopsis genetics, Arabidopsis Proteins genetics, Cytochrome P-450 Enzyme System genetics, Ethanol pharmacology, Gene Expression Regulation, Enzymologic drug effects, Indoles metabolism, Oximes metabolism

Abstract

Indole-3-acetaldoxime (IAOx) is a key branching point between primary and secondary metabolism. IAOx serves as an intermediate in the biosynthesis of indole glucosinolates (I-GLSs), camalexin and the plant hormone indole-3-acetic acid (IAA). The cytochrome P450s CYP79B2 and CYP79B3 catalyze the conversion of tryptophan to IAOx. CYP83B1 channels IAOx into I-GLS biosynthesis, CYP71A13 channels IAOx into camalexin biosynthesis, whereas the IAOx-metabolizing enzyme in IAA biosynthesis is not known. In this report, we demonstrate controlled production of I-GLSs by introducing an ethanol (EtOH)-inducible CYP79B2 construct into double (cyp79b2 cyp79b3) or triple (cyp79b2 cyp79b3 cyp83b1) mutant lines. We show EtOH-dependent induction of camalexin and identify a number of candidate IAA homeostasis- or defense-related genes by clustered microarray analysis. The transgenic mutant lines are thus promising tools for elucidating the interplay between primary and secondary metabolism.

Published

2009

14. Functional characterisation of a putative rhamnogalacturonan II specific xylosyltransferase.

Author

Egelund J, Damager I, Faber K, Olsen CE, Ulvskov P, and Petersen BL

Subjects

Arabidopsis genetics, Arabidopsis Proteins classification, Arabidopsis Proteins genetics, Cloning, Molecular, Fucose metabolism, Genes, Plant, Pentosyltransferases classification, Pentosyltransferases genetics, Phylogeny, Pichia genetics, Substrate Specificity, UDP Xylose-Protein Xylosyltransferase, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Pectins metabolism, Pentosyltransferases metabolism

Abstract

An Arabidopsis thaliana gene, At1g56550, was expressed in Pichia pastoris and the recombinant protein was shown to catalyse transfer of D-xylose from UDP-alpha-D-xylose onto methyl alpha-L-fucoside. The product formed was shown by 1D and 2D 1H NMR spectroscopy to be Me alpha-D-Xyl-(1,3)-alpha-L-Fuc, which is identical to the proposed target structure in the A-chain of rhamnogalacturonan II. Chemically synthesized methyl L-fucosides derivatized by methyl groups on either the 2-, 3- or 4 position were tested as acceptor substrates but only methyl 4-O-methyl-alpha-L-fucopyranoside acted as an acceptor, although to a lesser extent than methyl alpha-L-fucoside. At1g56550 is suggested to encode a rhamnogalacturonan II specific xylosyltransferase.

Published

2008

15. Arabidopsis cytochrome P450 monooxygenase 71A13 catalyzes the conversion of indole-3-acetaldoxime in camalexin synthesis.

Author

Nafisi M, Goregaoker S, Botanga CJ, Glawischnig E, Olsen CE, Halkier BA, and Glazebrook J

Subjects

Alternaria physiology, Arabidopsis genetics, Arabidopsis microbiology, Arabidopsis Proteins genetics, Carbon Monoxide analysis, Catalysis, DNA, Bacterial, Gene Expression Regulation, Plant, Genes, Plant, Immunity, Innate, Mutagenesis, Insertional, Plant Diseases immunology, Plant Diseases microbiology, Plant Leaves microbiology, Pseudomonas syringae physiology, RNA, Messenger genetics, RNA, Messenger metabolism, Recombinant Proteins metabolism, Substrate Specificity, Nicotiana, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Cytochrome P-450 Enzyme System metabolism, Indoles metabolism, Oximes metabolism, Thiazoles metabolism

Abstract

Camalexin (3-thiazol-2-yl-indole) is an indole alkaloid phytoalexin produced by Arabidopsis thaliana that is thought to be important for resistance to necrotrophic fungal pathogens, such as Alternaria brassicicola and Botrytis cinerea. It is produced from Trp, which is converted to indole acetaldoxime (IAOx) by the action of cytochrome P450 monooxygenases CYP79B2 and CYP79B3. The remaining biosynthetic steps are unknown except for the last step, which is conversion of dihydrocamalexic acid to camalexin by CYP71B15 (PAD3). This article reports characterization of CYP71A13. Plants carrying cyp71A13 mutations produce greatly reduced amounts of camalexin after infection by Pseudomonas syringae or A. brassicicola and are susceptible to A. brassicicola, as are pad3 and cyp79B2 cyp79B3 mutants. Expression levels of CYP71A13 and PAD3 are coregulated. CYP71A13 expressed in Escherichia coli converted IAOx to indole-3-acetonitrile (IAN). Expression of CYP79B2 and CYP71A13 in Nicotiana benthamiana resulted in conversion of Trp to IAN. Exogenously supplied IAN restored camalexin production in cyp71A13 mutant plants. Together, these results lead to the conclusion that CYP71A13 catalyzes the conversion of IAOx to IAN in camalexin synthesis and provide further support for the role of camalexin in resistance to A. brassicicola.

Published

2007

16. Arabidopsis thaliana RGXT1 and RGXT2 encode Golgi-localized (1,3)-alpha-D-xylosyltransferases involved in the synthesis of pectic rhamnogalacturonan-II.

Author

Egelund J, Petersen BL, Motawia MS, Damager I, Faik A, Olsen CE, Ishii T, Clausen H, Ulvskov P, and Geshi N

Subjects

Amino Acid Sequence, Animals, Arabidopsis Proteins chemistry, Arabidopsis Proteins metabolism, Baculoviridae genetics, Base Sequence, DNA Primers, Insecta, Isoenzymes chemistry, Isoenzymes metabolism, Molecular Sequence Data, Pentosyltransferases chemistry, Pentosyltransferases metabolism, Reverse Transcriptase Polymerase Chain Reaction, Sequence Homology, Amino Acid, Substrate Specificity, UDP Xylose-Protein Xylosyltransferase, Arabidopsis Proteins genetics, Golgi Apparatus enzymology, Isoenzymes genetics, Pectins biosynthesis, Pentosyltransferases genetics

Abstract

Two homologous plant-specific Arabidopsis thaliana genes, RGXT1 and RGXT2, belong to a new family of glycosyltransferases (CAZy GT-family-77) and encode cell wall (1,3)-alpha-d-xylosyltransferases. The deduced amino acid sequences contain single transmembrane domains near the N terminus, indicative of a type II membrane protein structure. Soluble secreted forms of the corresponding proteins expressed in insect cells showed xylosyltransferase activity, transferring d-xylose from UDP-alpha-d-xylose to l-fucose. The disaccharide product was hydrolyzed by alpha-xylosidase, whereas no reaction was catalyzed by beta-xylosidase. Furthermore, the regio- and stereochemistry of the methyl xylosyl-fucoside was determined by nuclear magnetic resonance to be an alpha-(1,3) linkage, demonstrating the isolated glycosyltransferases to be (1,3)-alpha-d-xylosyltransferases. This particular linkage is only known in rhamnogalacturonan-II, a complex polysaccharide essential to vascular plants, and is conserved across higher plant families. Rhamnogalacturonan-II isolated from both RGXT1 and RGXT2 T-DNA insertional mutants functioned as specific acceptor molecules in the xylosyltransferase assay. Expression of RGXT1- and RGXT2-enhanced green fluorescent protein constructs in Arabidopsis revealed that both fusion proteins were targeted to a Brefeldin A-sensitive compartment and also colocalized with the Golgi marker dye BODIPY TR ceramide, consistent with targeting to the Golgi apparatus. Taken together, these results suggest that RGXT1 and RGXT2 encode Golgi-localized (1,3)-alpha-d-xylosyltransferases involved in the biosynthesis of pectic rhamnogalacturonan-II.

Published

2006

17. CYP71B15 (PAD3) catalyzes the final step in camalexin biosynthesis.

Author

Schuhegger R, Nafisi M, Mansourova M, Petersen BL, Olsen CE, Svatos A, Halkier BA, and Glawischnig E

Subjects

Arabidopsis anatomy & histology, Arabidopsis genetics, Arabidopsis Proteins chemistry, Arabidopsis Proteins genetics, Catalysis, Cytochrome P-450 Enzyme System chemistry, Cytochrome P-450 Enzyme System genetics, Glucuronidase analysis, Indoles chemistry, Microsomes metabolism, Mixed Function Oxygenases chemistry, Mixed Function Oxygenases genetics, Mutation, Phenotype, Plant Leaves anatomy & histology, Plant Leaves enzymology, Plant Leaves metabolism, Plant Roots anatomy & histology, Plant Roots enzymology, Plant Roots metabolism, Plants, Genetically Modified metabolism, Recombinant Fusion Proteins analysis, Saccharomyces cerevisiae genetics, Thiazoles chemistry, Arabidopsis enzymology, Arabidopsis Proteins metabolism, Cytochrome P-450 Enzyme System metabolism, Indoles metabolism, Mixed Function Oxygenases metabolism, Thiazoles metabolism

Abstract

Camalexin represents the main phytoalexin in Arabidopsis (Arabidopsis thaliana). The camalexin-deficient phytoalexin deficient 3 (pad3) mutant has been widely used to assess the biological role of camalexin, although the exact substrate of the cytochrome P450 enzyme 71B15 encoded by PAD3 remained elusive. 2-(Indol-3-yl)-4,5-dihydro-1,3-thiazole-4-carboxylic acid (dihydrocamalexic acid) was identified as likely intermediate in camalexin biosynthesis downstream of indole-3-acetaldoxime, as it accumulated in leaves of silver nitrate-induced pad3 mutant plants and it complemented the camalexin-deficient phenotype of a cyp79b2/cyp79b3 double-knockout mutant. Recombinant CYP71B15 heterologously expressed in yeast catalyzed the conversion of dihydrocamalexic acid to camalexin with preference of the (S)-enantiomer. Arabidopsis microsomes isolated from leaves of CYP71B15-overexpressing and induced wild-type plants were capable of the same reaction but not microsomes from induced leaves of pad3 mutants. In conclusion, CYP71B15 catalyzes the final step in camalexin biosynthesis.

Published

2006