Genome-Wide Analysis of the ERF Gene Family in Arabidopsis and Rice

Nakano, Tsutomu; Suzuki, Kaoru; Fujimura, Tatsuhito; Shinshi, Hideaki

doi:10.1104/pp.105.073783

Cited by 1,871 publications

(2,590 citation statements)

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“…However, it should be noted that the nature of the regulation was not always consistent between the DEX‐inducible in planta system and the TEA experiments. The repressing function of the literature‐described repressors ERF8 and ERF9 (Ohta et al , 2001; Nakano et al , 2006) seemed to be abolished by fusion with the GR domain, as observed in planta (Appendix Figs S3–S22) and in TEAs performed with ERF8‐GR or ERF9‐GR (Appendix Fig S24). The discrepancy is thus most likely due to the presence of the GR domain close to the EAR motif.…”

Section: Resultsmentioning

confidence: 66%

“…Half of the TFs of the putative mannitol‐responsive GRN belong to the ERF family (Appendix Table S1) (Nakano et al , 2006; Skirycz et al , 2011; Phukan et al , 2017), containing a single AP2/ERF domain that is responsible for the specific binding to GCC boxes in the promoter of their target genes (Fujimoto et al , 2000; Yang et al , 2009). Three ERF proteins, ERF8, ERF9, and ERF11, belong to group VIII and are putative transcriptional repressors, because they contain an ERF‐associated amphiphilic repression (EAR) domain (Nakano et al , 2006).…”

Section: Resultsmentioning

confidence: 99%

“…Three ERF proteins, ERF8, ERF9, and ERF11, belong to group VIII and are putative transcriptional repressors, because they contain an ERF‐associated amphiphilic repression (EAR) domain (Nakano et al , 2006). Six other stress‐induced ERFs belong to group IX: ERF‐1, ERF2, ERF5, ERF6, ERF59, and ERF98.…”

Section: Resultsmentioning

confidence: 99%

“…Six other stress‐induced ERFs belong to group IX: ERF‐1, ERF2, ERF5, ERF6, ERF59, and ERF98. ERF5 and ERF6 contain an additional motif, CMIX‐5, which is a predicted phosphorylation site (Fujimoto et al , 2000; Nakano et al , 2006). The last ERF protein part of the putative mannitol‐induced network, RAP2.6L, belongs to group X (Nakano et al , 2006).…”

Section: Resultsmentioning

confidence: 99%

“…ERF5 and ERF6 contain an additional motif, CMIX‐5, which is a predicted phosphorylation site (Fujimoto et al , 2000; Nakano et al , 2006). The last ERF protein part of the putative mannitol‐induced network, RAP2.6L, belongs to group X (Nakano et al , 2006). Seven members of the proposed GRN are part of the WRKY TF family: WRKY6, WRKY15, WRKY28, WRKY30, WRKY33, WRKY40, and WRKY48, which contain a conserved sequence (WRKYGQK) followed by a zinc finger motif, enabling the binding to DNA at the position of a W‐box TTGAC(C/T) (Wu et al , 2005).…”

Section: Resultsmentioning

confidence: 99%

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From network to phenotype: the dynamic wiring of an Arabidopsis transcriptional network induced by osmotic stress

Broeck

Dubois

Vermeersch

et al. 2017

Molecular Systems Biology

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Plants have established different mechanisms to cope with environmental fluctuations and accordingly fine‐tune their growth and development through the regulation of complex molecular networks. It is largely unknown how the network architectures change and what the key regulators in stress responses and plant growth are. Here, we investigated a complex, highly interconnected network of 20 Arabidopsis transcription factors (TFs) at the basis of leaf growth inhibition upon mild osmotic stress. We tracked the dynamic behavior of the stress‐responsive TFs over time, showing the rapid induction following stress treatment, specifically in growing leaves. The connections between the TFs were uncovered using inducible overexpression lines and were validated with transient expression assays. This study resulted in the identification of a core network, composed of ERF6, ERF8, ERF9, ERF59, and ERF98, which is responsible for most transcriptional connections. The analyses highlight the biological function of this core network in environmental adaptation and its redundancy. Finally, a phenotypic analysis of loss‐of‐function and gain‐of‐function lines of the transcription factors established multiple connections between the stress‐responsive network and leaf growth.

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Section: Resultsmentioning

confidence: 66%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

See 3 more Smart Citations

From network to phenotype: the dynamic wiring of an Arabidopsis transcriptional network induced by osmotic stress

Broeck

Dubois

Vermeersch

et al. 2017

Molecular Systems Biology

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Overexpression of BcERF3 increases the biosynthesis of saikosaponins in Bupleurum chinense

Han

Wan

et al. 2022

FEBS Open Bio

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Chaihu, the dried roots of some species of Bupleurum L., is a famous Chinese herbal medicine for treatment of liver‐ and cold‐related diseases, in which saikosaponins (SSs) are the major active compounds. Many of the genetic components upstream of SS biosynthetic pathways have been characterized; however, the regulatory mechanisms remain elusive. In this study we identified the APETALA2/Ethylene Responsive Factor family transcription factor gene BcERF3 from B. chinense. The expression of BcERF3 was induced in methyl‐jasmonate‐treated adventitious root of B. chinense; it was also expressed at higher levels in roots than in other tissues (stem, leaf, flower, and tender fruit of early fruiting plants). Transient expression of BcERF3 in the leaves of Nicotiana benthamiana resulted in intracellular localization of the protein in the nucleus. It was also demonstrated that the number of SSs was greater in BcERF3‐overexpressing hairy roots of B. chinense than in plants treated with empty vector controls. This coincided with upregulation of β‐AS, which encodes a key enzyme involved with triterpenoid biosynthesis. In conclusion, BcERF3 plays a positive regulatory role in the biosynthesis of SSs.

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