ETR1 Antibody

1. ETR1-receiver domain already exists as an active formation and executes its function through binding with the downstream factors without phosphorylation. PMID: 27486797
2. The ETR1 receiver domain has multiple functions where different surfaces are involved in the control of different traits. PMID: 26160962
3. Data show that the cytosolic domain of ETR1 plays a key role, interacting with all other receptors and several participants of the ethylene signaling pathway. PMID: 25451923
4. Data show that Bacillus sp B55, which associated with Nicotiana attenuata roots, promotes growth of wild-type and, particularly, ethylene (ET)-insensitive (35)S-ethylene response1 (etr1) plants expressing the mutant Arabidopsis thaliana receptor ETR1-1. PMID: 23903320
5. Histidine kinase activity of ETR1 is not required for but plays a modulating role in the regulation of ethylene responses. PMID: 22467798
6. Transgenic and genetic analyses revealed that this organelle abnormality was not linked to etr1-1 or ethylene signaling, but linked to a second mutation in ARC3, which was further verified by genetic complementation analysis. PMID: 22228186
7. A mutation in the kinase domain of ETR1 that prevents auto-phosphorylation (H353A), increases the affinity of the receptors for EIN2. PMID: 20591837
8. Impaired perception of ethylene via ETR1 results in increased disease resistance to Verticillium dahliae. PMID: 20447269
9. Induction of etr1-1 expression repressed the epinastic response to ethylene as well as delayed fruit ripening. Restoration of ethylene sensitivity was achieved following the cessation of the induction PMID: 20181754
10. Inhibition of autophosphorylation in ETR1 by cyanide in Arabidopsis thaliana can be controlled by etehylene or ethylene agonists. PMID: 19825547
11. histidine kinase activity is not necessary for ethylene receptor function in plants and its signal transduction does not occur through a phosphorelay mechanism PMID: 15358768
12. The His kinase domain in the C-terminal region of Arabidopsis ETR1 plays a role in the repression of ethylene responses. PMID: 15466228
13. Five receptor isoforms from Arabidopsis thaliana confirmed that all members of the family are capable of high-affinity ethylene-binding activity. PMID: 15703053
14. Data demonstrate an unexpected role for ETR1, that of mediating stomatal closure in response to H2O2. PMID: 15761208
15. These findings demonstrate that RTE1 is a negative regulator of ethylene signaling and suggest that RTE1 plays an important role in ETR1 function. PMID: 16682642
16. Possible roles of subfamily I receptors and disulfide linkages in ETR1 receptor signal output mediated through the N terminus are discussed. PMID: 16891553
17. The ETR1 receptor is required for ethylene-stimulated nutations. PMID: 17071649
18. These findings yield insight into the structure and function of the ethylene binding domain (EBD) and suggest a conserved role of the EBD as a negative regulator of the signal transmitter domain. PMID: 17189345
19. The role of the histidine kinase activity of ETR1 in A. thaliana growth and development is reported. PMID: 17284582
20. ETR1 is positively regulated by RTE1 via the ethylene-binding domain, independently from RAN1 activity. PMID: 18643990

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KEGG: ath:AT1G66340

STRING: 3702.AT1G66340.1

UniGene: At.43238