Molecular requirements for the biological activity of ethylene
- PMID: 16656478
- PMCID: PMC1086501
- DOI: 10.1104/pp.42.1.144
Molecular requirements for the biological activity of ethylene
Abstract
The molecular requirements for ethylene action were investigated using the pea straight growth test. Biological activity requires an unsaturated bond adjacent to a terminal carbon atom, is inversely related to molecular size, and is decreased by substitutions which lower the electron density in the unsaturated position. Evidence is presented that ethylene binds to a metal containing receptor site. CO(2) is a competitive inhibitor of ethylene action, and prevents high concentrations of auxin (which stimulate ethylene formation) from retarding the elongation of etiolated pea stem sections. It is suggested that CO(2) delays fruit ripening by displacing the ripening hormone, ethylene, from its receptor site. Binding of ethylene to the receptor site is also impeded when the O(2) concentration is lowered, and this may explain why fruit ripening is delayed at low O(2) tensions.
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