Genome-wide Analysis of Endogenous Abscisic Acid-mediated Transcription in Dry and Imbibed Seeds of Arabidopsis Using Tiling Arrays

Overview

Journal Plant J

Specialties Biology
Cell Biology
Molecular Biology

Date 2010 Jan 22

PMID 20088898

Citations 61

Authors

Masanori Okamoto

Kiyoshi Tatematsu

Akihiro Matsui

Taeko Morosawa

Junko Ishida

Maho Tanaka

Takaho A Endo

Yoshiki Mochizuki

Tetsuro Toyoda

Yuji Kamiya

Kazuo Shinozaki

Eiji Nambara

Motoaki Seki

Affiliations

Soon will be listed here.

Abstract

The phytohormone abscisic acid (ABA) plays important roles in the induction and maintenance of seed dormancy. Although application of exogenous ABA inhibits germination, the effects of exogenous ABA on ABA-mediated gene transcription differ from those of endogenous ABA. To understand how endogenous ABA regulates the transcriptomes in seeds, we performed comprehensive expression analyses using whole-genome Affymetrix tiling arrays in two ABA metabolism mutants - an ABA-deficient mutant (aba2) and an ABA over-accumulation mutant (cyp707a1a2a3 triple mutant). Hierarchical clustering and principal components analyses showed that differences in endogenous ABA levels do not influence global expression of stored mRNA in dry seeds. However, the transcriptome after seed imbibition was related to endogenous ABA levels in both types of mutant. Endogenous ABA-regulated genes expressed in imbibed seeds included those encoding key ABA signaling factors and gibberellin-related components. In addition, cohorts of ABA-upregulated genes partially resembled those of dormant genes, whereas ABA-downregulated genes were partially overlapped with after-ripening-regulated genes. Bioinformatic analyses revealed that 6105 novel genes [non-Arabidopsis Genome Initiative (AGI) transcriptional units (TUs)] were expressed from unannotated regions. Interestingly, approximately 97% of non-AGI TUs possibly encoded hypothetical non-protein-coding RNAs, including a large number of antisense RNAs. In dry and imbibed seeds, global expression profiles of non-AGI TUs were similar to those of AGI genes. For both non-AGI TUs and AGI code genes, we identified those that were regulated differently in embryo and endosperm tissues. Our results suggest that transcription in Arabidopsis seeds is more complex and dynamic than previously thought.

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