Access the full text.
Sign up today, get DeepDyve free for 14 days.
David Alabadí, Marta Agüero, M. Perez-Amador, Juan Carbonell (1996)
Arginase, Arginine Decarboxylase, Ornithine Decarboxylase, and Polyamines in Tomato Ovaries (Changes in Unpollinated Ovaries and Parthenocarpic Fruits Induced by Auxin or Gibberellin), 112
MA Perez-Amador, P Lidder, MA Johnson (2001)
New molecular phenotypes in the dst mutants of arabidopsis revealed by DNA microarray analysisPlant Cell, 13
M. Perez-Amador, P. Lidder, Mark Johnson, J. Landgraf, E. Wisman, P. Green (2001)
New Molecular Phenotypes in the dst Mutants of Arabidopsis Revealed by DNA Microarray Analysis Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.010295.The Plant Cell Online, 13
E. Ward, S. Uknes, Shericca Williams, Sandra Dincher, Deanna Wiederhold, D. Alexander, Patricia Ahl-Goy, J. Metraux, J. Ryals (1991)
Coordinate Gene Activity in Response to Agents That Induce Systemic Acquired Resistance.The Plant cell, 3
D. Prestridge (1991)
SIGNAL SCAN: a computer program that scans DNA sequences for eukaryotic transcriptional elementsComputer applications in the biosciences : CABIOS, 7 2
E. Pahlich, Chr. Gerlitz (1980)
A rapid DNA isolation procedure for small quantities of fresh leaf tissuePhytochemistry, 19
C. Todd, J. Cooke, R. Mullen, D. Gifford (2001)
Regulation of loblolly pine (Pinus taeda L.) arginase in developing seedling tissue during germination and post-germinative growthPlant Molecular Biology, 45
L. Zonia, N. Stebbins, J. Polacco (1995)
Essential Role of Urease in Germination of Nitrogen-Limited Arabidopsis thaliana Seeds, 107
Ariel Goldraij, J. Polacco (1999)
Arginase is inoperative in developing soybean embryos.Plant physiology, 119 1
Hui Chen, Bonnie Mccaig, M. Melotto, S. He, G. Howe (2004)
Regulation of Plant Arginase by Wounding, Jasmonate, and the Phytotoxin Coronatine*Journal of Biological Chemistry, 279
SA Filichkin, JM Leonard, A Monteros (2004)
A novel endo-beta-mannanase associated with anther and gene in tomato leman5 is pollen developmentPlant Physiol, 134
A. Saeed, V. Sharov, J. White, J. Li, W. Liang, N. Bhagabati, J. Braisted, M. Kłapa, T. Currier, M. Thiagarajan, A. Sturn, M. Snuffin, A. Rezantsev, D. Popov, A. Ryltsov, E. Kostukovich, I. Borisovsky, Z. Liu, A. Vinsavich, V. Trush, John Quackenbush (2003)
TM4: a free, open-source system for microarray data management and analysis.BioTechniques, 34 2
F. Corpas, J. Barroso, A. Carreras, R. Valderrama, J. Palma, A. León, L. Sandalio, L. Río (2006)
Constitutive arginine-dependent nitric oxide synthase activity in different organs of pea seedlings during plant developmentPlanta, 224
J. Cooke, K. Brown, R. Wu, J. Davis (2003)
Gene expression associated with N‐induced shifts in resource allocation in poplarPlant Cell and Environment, 26
C. Jenkinson, W. Grody, S. Cederbaum (1996)
Comparative properties of arginases.Comparative biochemistry and physiology. Part B, Biochemistry & molecular biology, 114 1
(1995)
Nucleotide sequence of Arabidopsis thaliana arginase expressed in yeast.
B. Micallef, B. Shelp (1989)
Arginine metabolism in developing soybean cotyledons : I. Relationship to nitrogen nutrition.Plant physiology, 90 2
A. Devoto, J. Turner (2005)
Jasmonate‐regulated Arabidopsis stress signalling networkPhysiologia Plantarum, 123
S. Filichkin, J. Leonard, Á. Monteros, Po-Pu Liu, H. Nonogaki (2004)
A Novel Endo-β-Mannanase Gene in Tomato LeMAN5 Is Associated with Anther and Pollen Development1Plant Physiology, 134
Hilary Rogers, Neil Bate, Jonathan Combe, J. Sullivan, J. Sweetman, C. Swan, David Lonsdale, David Twell (2001)
Functional analysis of cis-regulatory elements within the promoter of the tobacco late pollen gene g10Plant Molecular Biology, 45
M. Lescot, P. Déhais, G. Thijs, K. Marchal, Y. Moreau, Y. Peer, P. Rouzé, S. Rombauts (2002)
PlantCARE, a database of plant cis-acting regulatory elements and a portal to tools for in silico analysis of promoter sequencesNucleic acids research, 30 1
Yuan-Qing Jiang, M. Deyholos (2006)
Comprehensive transcriptional profiling of NaCl-stressed Arabidopsis roots reveals novel classes of responsive genesBMC Plant Biology, 6
A Devoto, C Ellis, A Magusin (2005)
Expression profiling reveals coi1 to be a key regulator of genes involved in wound- and methyl jasmonate-induced secondary metabolism, defence, and hormone interactionsPlant Mol Biol, 58
JE King, DJ Gifford (1997)
Amino acid utilization in seeds of loblolly pine during germination and early seedling growthPlant Physiol, 113
E. Lebel, P. Heifetz, L. Thorne, S. Uknes, J. Ryals, E. Ward (1998)
Functional analysis of regulatory sequences controlling PR-1 gene expression in Arabidopsis.The Plant journal : for cell and molecular biology, 16 2
Hong-qi Zhang, A. Croes, H. Linskens (1982)
Protein synthesis in germinating pollen of Petunia: role of prolinePlanta, 154
L. Palmieri, C. Todd, R. Arrigoni, M. Hoyos, A. Santoro, J. Polacco, F. Palmieri (2006)
Arabidopsis mitochondria have two basic amino acid transporters with partially overlapping specificities and differential expression in seedling development.Biochimica et biophysica acta, 1757 9-10
D. Honys, D. Twell (2003)
Comparative Analysis of the Arabidopsis Pollen Transcriptome1[w]Plant Physiology, 132
D. Twell, J. Yamaguchi, R. Wing, J. Ushiba, S. McCormick (1991)
Promoter analysis of genes that are coordinately expressed during pollen development reveals pollen-specific enhancer sequences and shared regulatory elements.Genes & development, 5 3
J. Rouster, J. Mechelen, V. Cameron-Mills (1998)
The untranslated leader sequence of the barley lipoxygenase 1 (Lox1) gene confers embryo-specific expression.The Plant journal : for cell and molecular biology, 15 3
Neil Bate, David Twell (1998)
Functional architecture of a late pollen promoter: pollen-specific transcription is developmentally regulated by multiple stage-specific and co-dependent activator elementsPlant Molecular Biology, 37
K. Higo, Y. Ugawa, M. Iwamoto, Tomoko Korenaga (1999)
Plant cis-acting regulatory DNA elements (PLACE) database: 1999Nucleic acids research, 27 1
D. Klessig, J. Malamy (1994)
The salicylic acid signal in plantsPlant Molecular Biology, 26
D. Weigel, J. Glazebrook (2002)
Arabidopsis : a laboratory manual
J. King, D. Gifford (1997)
Amino Acid Utilization in Seeds of Loblolly Pine during Germination and Early Seedling Growth (I. Arginine and Arginase Activity), 113
B. Micallef, B. Shelp (1989)
Arginine Metabolism in Developing Soybean Cotyledons: III. Utilization.Plant physiology, 91 1
M. Boter, O. Ruíz-Rivero, Ashraf Abdeen, S. Prat (2004)
Conserved MYC transcription factors play a key role in jasmonate signaling both in tomato and Arabidopsis.Genes & development, 18 13
K. Livak, Thomas Schmittgen (2001)
Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method.Methods, 25 4
R. Schwacke, Silke Grallath, K. Breitkreuz, E. Stransky, H. Stransky, W. Frommer, D. Rentsch (1999)
LeProT1, a Transporter for Proline, Glycine Betaine, and γ-Amino Butyric Acid in Tomato PollenPlant Cell, 11
A. Devoto, Christine Ellis, Andreas Magusin, Hur-Song Chang, C. Chilcott, T. Zhu, J. Turner (2005)
Expression profiling reveals COI1 to be a key regulator of genes involved in wound- and methyl jasmonate-induced secondary metabolism, defence, and hormone interactionsPlant Molecular Biology, 58
B. Buchanan, W. Gruissem, Russell Jones (2002)
Biochemistry & Molecular Biology of Plants
VG Tusher, R Tibshirani, G Chu (2001)
Significance analysis of microarrays applied to the ionizing radiation responseProc Natl Acad Sci USA, 98
The detailed expression patterns of transcripts of two Arabidopsis arginase genes, ARGAH1 and ARGAH2, have not been previously described, and phylogenetic analysis suggests that they diverged independently of duplication events in other lineages. Therefore, we used β-glucuronidase reporter fusions and quantitative reverse-transcriptase PCR to analyze tissue-specific expression of ARGAH1 and ARGAH2 during Arabidopsis development, and in response to the availability of nutrients and exposure to methyl jasmonate (MeJA). We demonstrated tissue-specific transcript expression and enzyme activity in pollen for ARGAH1, but not ARGAH2. Conversely, we demonstrated MeJA-inducibility of ARGAH2, but not ARGAH1. In addition, we used microarrays to identify genes for which transcript abundance following MeJA treatment differed in wild type and ARGAH2 mutants. These ARGAH2 and MeJA responsive genes included a putative pathogenesis-related protein pathogenesis response-1 (At2g14610), and a gene of unknown function (At5g03090). Interestingly, these genes had opposite responses to the loss of ARGAH2, suggesting multiple downstream effects of arginase activity, following MeJA treatment. These results, and the variety and complexity of expression patterns of ARGAH1 and ARGAH2 transcript expression and their related reporter gene fusions that we observed point to multiple functions of arginase genes in Arabidopsis, some of which have resulted through a sub-functionalization not shared by all angiosperms.
Plant Molecular Biology – Springer Journals
Published: Apr 19, 2008
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.