EC Number |
General Information |
Reference |
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1.13.11.54 | physiological function |
either facilitates recycling of methionine in living cells or exits this recycling pathway. Fe2+-dependent acireductone dioxygenase produces the 2-oxo acid precursor of methionine and formate |
725214 |
1.13.11.54 | physiological function |
enzyme overexpression improves submergence, drought, and salt tolerances of seedling through the enhancement of ethylene synthesis in rice |
764775 |
1.13.11.54 | more |
Fe2+-dependent acireductone dioxygenase passes through an additional split dioxygen intermediate and then proceeds through an epoxy-like transition state with a small activation energy to the two products, crystal structure analysis, structure modeling and molecular simulations of the Fe2+ and Ni2+ enzyme, cf. 1.13.11.53, QM-DMD domain, overview. The ability of Fe2+-dependent acireductone dioxygenase to stabilize an additional intermediate and thus produce the two products is due to the RedOx flexibility of the Fe2+ as compared to the more electron-rich Ni2+ |
725214 |
1.13.11.54 | more |
identification of potential effectors in the Arabidopsis thaliana G protein beta signaling pathway by an activation tagging approach to randomly create dominant suppressors of agb1-2, overview. Homology modeling of acireductone dioxygenase 1, overview |
-, 725438 |
1.13.11.54 | physiological function |
isoform ARD4 regulates the ethylene and carotenoid signaling pathway, increases ethylene and carotenoid concentrations, and accelerates fruit ripening. Furthermore, ARD4 increases the antioxidative ability and cold hardiness in tomato |
764909 |
1.13.11.54 | physiological function |
matrix metalloproteinase MT1-MMP physically interacts with claudin-1 and acireductone dioxygenase 1, both associated with hepatitis C virus cell entry |
743184 |
1.13.11.54 | physiological function |
one function of acireductone dioxygenases is to operate in the methionine salvage pathway. Acireductone dioxygenase 1 physically interacts with Arabidopsis thaliana G protein beta, and acireductone dioxygenase enzymatic activity is stimulated by Arabidopsis thaliana G protein beta in vitro. Overexpression of acireductone dioxygenase 1 suppresses the 2-day-old etiolated phenotype of agb1-2. Acireductone dioxygenase 1 and Arabidopsis thaliana G protein beta both control embryonic hypocotyl length by modulating cell division. They also may contribute to the production of ethylene, a product of the methionine salvage pathway. Arabidopsis thaliana G protein beta regulates acireductone dioxygenase 1 activity to control cell division, possible mechanism for Arabidopsis thaliana G protein beta activation of acireductone dioxygenase 1 activity, overview |
-, 725438 |
1.13.11.54 | metabolism |
the enzyme plays an important role in ethylene synthesis pathway |
764775 |
1.13.11.54 | physiological function |
the enzyme regulates the activity of matrix metalloproteinase I, which is involved in tumor metastasis, by binding the cytoplasmic transmembrane tail peptide of matrix metalloproteinase I |
764179 |
1.13.11.54 | physiological function |
transgenic rice plants overexpressing isoform ARD4 exhibit root growth characteristics including faster radical emergence, more rapid elongation of primary roots, early initiation of crown/lateral roots, and higher root biomass than the non-transgenic plants |
765809 |