Genome-wide Gene Expression Analysis Reveals a Critical Role for CRY1 in the Response of Arabidopsis to High Irradiance

Tatjana Kleine , Peter Kindgren , Catherine Benedict , Luke Hendrickson , and Asa Strand ^*

Umea Plant Science Centre, Department of Plant Physiology, Umea University, S-901 87 Umea, Sweden

^* Corresponding author; email: Asa.Strand{at}plantphys.umu.se.

Exposure to high irradiance results in dramatic changes in nucleargene expression in plants. However, little is known about themechanisms by which changes in irradiance are sensed and howthe information is transduced to the nucleus to initiate thegenetic response. To investigate whether the photoreceptorsare involved in the response to high irradiance, we analyzedexpression of ELIP1, ELIP2, APX2 and LHCB2.4 in the phyA, phyB,cry1 and cry2 photoreceptor mutants and hy5 and hyh transcriptionfactor mutants. Following exposure to high intensity white lightfor 3 h (HL, 1000 micro mol quanta m^-2 s^-1) expression of ELIP1/2and APX2 was strongly induced and LHCB2.4 expression repressedin wild type. The cry1 and hy5 mutants showed specific mis-regulationof ELIP1/2 and we show that the induction of ELIP1/2 expressionis mediated via CRY1 in a blue light intensity-dependent manner.Furthermore, using the Affymetrix Arabidopsis 24K Gene-Chipwe showed that 77 of the HL responsive genes are regulated viaCRY1, and 26 of those genes were also HY5 dependent. As a consequenceof the mis-regulation of these genes the cry1 mutant displayeda high irradiance-sensitive phenotype with significant photoinactivationof PSII, indicated by reduced F_v/F_m. Thus, we describe a novelfunction of CRY1 in mediating plant responses to high irradiancesthat is essential to the induction of photoprotective mechanisms.This indicates that high irradiance can be sensed in a chloroplast-independentmanner by a cytosolic/nucleic component.

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