Global Changes in Gene Expression in Response to High Light in Arabidopsis

doi:10.1104/pp.005595

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Global Changes in Gene Expression in Response to High Light in Arabidopsis¹^,^[w]

Jan Bart Rossel, Iain W. Wilson, and Barry J. Pogson^*

School of Biochemistry and Molecular Biology, The Australian National University, Canberra, Australian Capital Territory 0200, Australia (J.B.R., B.J.P.); and Commonwealth Scientific and Industrial Research Organisation Plant Industry, Black Mountain, Canberra, Australian Capital Territory 2601, Australia (I.W.W.)

A range of environmental conditions can lead to oxidative stress; thus, a prompt and effective response to oxidative stressis crucial for the survival of plants. Microarray and northern-blotanalyses were performed toward the identification of the factorsand signaling pathways that enable plants to limit oxidative damagecaused by exposure to high light (HL). Arabidopsis plants grownunder moderate light (100 µmol m² s¹) were exposed to HL (1,000 µmol m² s¹) for 1 h. The microarray analyses revealed that exposure of Arabidopsisto HL caused an increase in known antioxidant genes, as well asseveral unknown genes. Some of these unknown genes had homologiesto possible regulatory genes and metabolic enzymes. Furthermore,it was found that a range of chaperones were up-regulated in theHL treatment and that this induction was specifically due to theHL stress. The temporal expression under HL and different oxidativestress conditions of a subset of HL-responsive genes was confirmedvia northern-blot analysis. Results from the arrays were alsocompared with publicly available microarray data sets from a rangeof different stress conditions at the Arabidopsis Functional GenomicsConsortium. This cross comparison enabled the identification ofgenes that may be induced by changes in redox poise. Finally,to determine if the genes that were differentially expressed byHL stress were under similar transcriptional control, we analyzedthe promoter sequences for the presence of commonmotifs.

¹ This work was supported by The Australian National University's International Postgraduate Research Award to J.B.R. and bythe Australian Research Council (grant no. F00077 to B.J.P.).

^[w] The online version of this article contains Web-only data. The supplemental material is available at www.plantphysiol.org.

^* Corresponding author; e-mail barry.pogson{at}anu.edu.au; fax 61-2-6125-0313.

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Global Changes in Gene Expression in Response to High Light in Arabidopsis1,[w]

Global Changes in Gene Expression in Response to High Light in Arabidopsis¹^,^[w]