AI Article Synopsis
- - The Hooded (Kap) mutant of barley has a duplicated intron that causes overexpression of the Barley knox3 (Bkn3) gene, leading to an extra flower in its spikelet.
- - Four proteins were identified that bind to the intron region, with three key proteins (BERF1, BEIL1, BGRF1) showing DNA-binding capabilities and possible roles in both intron regulation and ethylene signaling.
- - Ethylene treatment influences the Kap phenotype in barley and modifies the expression of the involved proteins, suggesting that BEIL1 and BERF1 work together with other proteins to regulate Bkn3 expression and indicating a connection between KNOX and ethylene pathways. *
Article Abstract
In the barley (Hordeum vulgare) Hooded (Kap) mutant, the duplication of a 305-bp intron sequence leads to the overexpression of the Barley knox3 (Bkn3) gene, resulting in the development of an extra flower in the spikelet. We used a one-hybrid screen to identify four proteins that bind the intron-located regulatory element (Kap intron-binding proteins). Three of these, Barley Ethylene Response Factor1 (BERF1), Barley Ethylene Insensitive Like1 (BEIL1), and Barley Growth Regulating Factor1 (BGRF1), were characterized and their in vitro DNA-binding capacities verified. Given the homology of BERF1 and BEIL1 to ethylene signaling proteins, we investigated if these factors might play a dual role in intron-mediated regulation and ethylene response. In transgenic rice (Oryza sativa), constitutive expression of the corresponding genes produced phenotypic alterations consistent with perturbations in ethylene levels and variations in the expression of a key gene of ethylene biosynthesis. In barley, ethylene treatment results in partial suppression of the Kap phenotype, accompanied by up-regulation of BERF1 and BEIL1 expression, followed by down-regulation of Bkn3 mRNA levels. In rice protoplasts, BEIL1 activates the expression of a reporter gene driven by the 305-bp intron element, while BERF1 can counteract this activation. Thus, BEIL1 and BERF1, likely in association with other Kap intron-binding proteins, should mediate the fine-tuning of Bkn3 expression by ethylene. We propose a hypothesis for the cross talk between the KNOX and ethylene pathways.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2996029 | PMC |
| http://dx.doi.org/10.1104/pp.110.161984 | DOI Listing |
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