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Literature DB >> 16657650

Mechanism of Auxin-induced Ethylene Production.

Abstract

Indoleacetic acid-induced ethylene production and growth in excised segments of etiolated pea shoots (Pisum sativum L. var. Alaska) parallels the free indoleacetic acid level in the tissue which in turn depends upon the rate of indoleacetic acid conjugation and decarboxylation. Both ethylene synthesis and growth require the presence of more than a threshold level of free endogenous indoleacetic acid, but in etiolated tissue the rate of ethylene production saturates at a high concentration and the rate of growth at a lower concentration of indoleacetic acid. Auxin stimulation of ethylene synthesis is not mediated by induction of peroxidase; to the contrary, the products of the auxin action which induce growth and ethylene synthesis are highly labile.

Entities: Chemical Species

Year: 1971 PMID： 16657650 PMCID： PMC396716 DOI： 10.1104/pp.47.4.504

Source DB: PubMed Journal: Plant Physiol ISSN： 0032-0889 Impact factor: 8.340

15 in total

7. Further studies on ethylene formation from alpha-keto-gamma-methylthiobutyric acid or beta-methylthiopropionaldehyde by peroxidase in the presence of sulfite and oxygen.

Authors: S F Yang
Journal: J Biol Chem Date: 1969-08-25 Impact factor: 5.157

9. Probing a Membrane Matrix Regulating Hormone Action: II. The Kinetics of Lipid-Induced Growth and Ethylene Production.

Authors: T Iwata; B B Stowe
Journal: Plant Physiol Date: 1973-04 Impact factor: 8.340

10. Mechanism of naphthaleneacetic Acid conjugation: no effect of ethylene.

Authors: R Goren; M J Bukovac
Journal: Plant Physiol Date: 1973-05 Impact factor: 8.340

Mechanism of Auxin-induced Ethylene Production.

1. The destruction of indoleacetic acid. III. Relationships between peroxidase action and indoleacetic acid oxidation.

2. Flavoprotein and peroxidase as components of the indoleacetic acid oxidase system of peas.

3. An effect of light on the production of ethylene and the growth of the plumular portion of etiolated pea seedlings.

4. Timing of the auxin response in etiolated pea stem sections.

5. Ethylene and auxin participation in pollen induced fading of vanda orchid blossoms.

6. The Histochemical Localization of Peroxidase in Roots and Its Induction by Indoleacetic Acid.

7. Further studies on ethylene formation from alpha-keto-gamma-methylthiobutyric acid or beta-methylthiopropionaldehyde by peroxidase in the presence of sulfite and oxygen.

8. The interaction between auxin and ethylene and its role in plant growth.

9. Regulation of root growth by auxin-ethylene interaction.

10. Timing of the auxin response in coleoptiles and its implications regarding auxin action.

1. Effects of Ethylene and 2,4-Dichlorophenoxyacetic Acid on Cellular Expansion in Pisum sativum.

2. Mechanism of a Synergistic Effect of Kinetin on Auxin-induced Ethylene Production: Suppression of Auxin Conjugation.

3. Peroxidase Activity in the Abscission Zone of Bean Leaves during Abscission.

4. Effects of Cycloheximide on Indoleacetic Acid-induced Ethylene Production in Pea Root Tips.

5. Inhibition of ethylene production by cobaltous ion.

6. Oxidative turnover of auxins in relation to the onset of ripening in bartlett pear.

7. Ethylene-forming Systems in Etiolated Pea Seedling and Apple Tissue.

8. Relation of Phytochrome-enhanced Geotropic Sensitivity to Ethylene Production.

9. Probing a Membrane Matrix Regulating Hormone Action: II. The Kinetics of Lipid-Induced Growth and Ethylene Production.

10. Mechanism of naphthaleneacetic Acid conjugation: no effect of ethylene.