Abstract
AtERF73/HRE1 is an AP2/ERF transcription factor in Arabidopsis and has two distinct alternative splicing variants, HRE1α and HRE1β. In this study, we examined the differences between the molecular functions of HRE1α and HRE1β. We found that HRE1α and HRE1β are both involved in hypoxia response and root development and have transactivation activity. Two conserved motifs in the C-terminal region of HRE1α and HRE1β, EELL and LWSY-like, contributed to their transactivation activity, specifically the four E residues in the EELL motif and the MGLWS amino acid sequence at the end of the LWSY-like motif. The N-terminal region of HRE1β also showed transactivation activity, mediated by the VDDG motif, whereas that of HRE1α did not. The transactivation activity of HRE1β was stronger than that of HRE1α in Arabidopsis protoplasts. Both transcription factors transactivated downstream genes via the GCC box. RNA-sequencing analysis further supported that both HRE1α and HRE1β might regulate gene expression associated with the hypoxia stress response, although they may transactivate different subsets of genes in downstream pathways. Our results, together with previous studies, suggested that HRE1α and HRE1β differentially transactivate downstream genes in hypoxia response and root development in Arabidopsis.
Highlights
To survive under stressful conditions, plants change the expression patterns of stress-responsive genes
HRE1 is an Arabidopsis APETALA2/ethylene-responsive factor (AP2/ERF) transcription factor, and its gene has two alternative splicing variants, HRE1α and HRE1β [33]; both are involved in the response to hypoxia in Arabidopsis [33,34]
We describe the differences between the functions of HRE1α and HRE1β in the hypoxia response and root development of Arabidopsis
Summary
To survive under stressful conditions, plants change the expression patterns of stress-responsive genes In this process, transcription factors are the trans-acting elements that play major roles in regulating gene expression by binding to cis-acting elements [1]. AP2/ERF transcription factors are divided into four subfamilies: AP2, ERF, dehydration-responsive element-binding factor/C-repeat-binding factor (DREB/CBF), and RAV [4,6]. They function as either transcriptional activators or repressors in gene regulation. Transcription factors in the ERF subfamily bind to the GCC box (5 -AGCCGCC-3 ) and/or to dehydration-responsive element/C-repeat (DRE/CRT) (5 -A/GCCGAC-3 ) to regulate the expression of downstream genes [16,17]
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