Abstract
Arabidopsis, like most plants, exhibits tissue-specific, light-dependent growth responses. Cotyledon and leaf growth and the accumulation of photosynthetic pigments are promoted by light, whereas hypocotyl growth is inhibited. The identification and characterization of distinct phytochrome-dependent molecular effectors that are associated with these divergent tissue-specific, light-dependent growth responses are limited. To identify phytochrome-dependent factors that impact the photoregulation of hypocotyl length, we conducted comparative gene expression studies using Arabidopsis lines exhibiting distinct patterns of phytochrome chromophore inactivation and associated disparate hypocotyl elongation responses under far-red (FR) light. A large number of genes was misregulated in plants lacking mesophyll-specific phytochromes relative to constitutively-deficient phytochrome lines. We identified and characterized genes whose expression is impacted by light and by phyA and phyB that have roles in the photoregulation of hypocotyl length. We characterized the functions of several identified target genes by phenotyping of T-DNA mutants. Among these genes is a previously uncharacterized LHE (LIGHT-INDUCED HYPOCOTYL ELONGATION) gene, which we show impacts light- and phytochrome-mediated regulation of hypocotyl elongation under red (R) and FR illumination. We describe a new approach for identifying genes involved in light- and phytochrome-dependent, tissue-specific growth regulation and confirmed the roles of three such genes in the phytochrome-dependent photoregulation of hypocotyl length.Electronic supplementary materialThe online version of this article (doi:10.1007/s11103-013-0029-0) contains supplementary material, which is available to authorized users.
Highlights
Plants exhibit distinct growth and developmental phenotypes in response to light exposure
Using FRc-grown seedlings, we identified 712 differentially-expressed genes (C2-fold changes) by GeneSpringÒ analyses of data from a microarray-based comparison of CAB3::pBVR2 lines (CAB3)::pBVR2 and 35S::pBVR3 lines grown in FRc light (Fig. 1; full Microarray Experiment (MIAME)-compliant array data set submitted to Gene Expression Omnibus with submission number GSE38989)
We were interested in identifying genes that are associated with the misregulation of light-dependent hypocotyl elongation
Summary
Plants exhibit distinct growth and developmental phenotypes in response to light exposure. A number of photoreceptor families have been identified as regulators of lightdependent growth and development including ultraviolet B (UV-B), blue/ultraviolet A (B/UV-A) and red/far-red (R/FR) receptors. The R/FR-absorbing phytochromes are the most extensively studied of the higher plant photoreceptors. Phytochromes are composed of an apoprotein and a covalently attached linear tetrapyrrole chromophore (bilin). Five distinct apoprotein-encoding genes, i.e., PHYA–PHYE, exist in Arabidopsis (Quail 1994; Sharrock and Quail 1989), whereas a single chromophore species, i.e., phytochromobilin, has been identified (Terry et al 1993). Phytochromes are linked to the regulation of numerous aspects of light-regulated growth and development, including seed
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