Genomic Analysis of a Nutrient Response in Arabidopsis Reveals Diverse Expression Patterns and Novel Metabolic and Potential Regulatory Genes Induced by Nitrate

doi:10.1105/tpc.12.8.1491

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Genomic Analysis of a Nutrient Response in Arabidopsis Reveals Diverse Expression Patterns and Novel Metabolic and Potential Regulatory Genes Induced by Nitrate

Rongchen Wang^a, Karl Guegler^b, Samuel T. LaBrie^c, and Nigel M. Crawford^a
^a Division of Biology, University of California at San Diego, La Jolla, California 92093-0016
^b Incyte Pharmaceuticals, 3174 Porter Drive, Palo Alto, California 94304
^c Genome Systems Inc., 4633 World Parkway Circle, St. Louis, Missouri 63134

Correspondence to: Nigel M. Crawford, ncrawford{at}ucsd.edu (E-mail), 619-534-1637 (fax)

Microarray and RNA gel blot analyses were performed to identifyArabidopsis genes that responded to nitrate at both low (250µM) and high (5 to 10 mM) nitrate concentrations. Genesinvolved directly or indirectly with nitrite reduction werethe most highly induced by nitrate. Most of the known nitrate-regulatedgenes (including those encoding nitrate reductase, the nitratetransporter NRT1, and glutamate synthase) appeared in the 40most strongly nitrate-induced genes/clones on at least one ofthe microarrays of the 5524 genes/clones investigated. Novelnitrate-induced genes were also found, including those encoding(1) possible regulatory proteins, including an MYB transcriptionfactor, a calcium antiporter, and putative protein kinases;(2) metabolic enzymes, including transaldolase and transketolaseof the nonoxidative pentose pathway, malate dehydrogenase, asparaginesynthetase, and histidine decarboxylase; and (3) proteins withunknown functions, including nonsymbiotic hemoglobin, a senescence-associatedprotein, and two methyltransferases. The primary pattern ofinduction observed for many of these genes was a transient increasein mRNA at low nitrate concentrations and a sustained increasewhen treated with high nitrate concentrations. Other patternsof induction observed included transient inductions after bothlow and high nitrate treatments and sustained or increasingamounts of mRNA after either treatment. Two genes, AMT1;1 encodingan ammonium transporter and ANR1 encoding a MADS-box factor,were repressed by nitrate. These findings indicate that nitrateinduces not just one but many diverse responses at the mRNAlevel in Arabidopsis.

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[Abstract] [Full Text] [PDF]

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[Abstract] [Full Text] [PDF]

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[Abstract] [Full Text] [PDF]