Inputs to the Active Indole-3-Acetic Acid Pool: De Novo Synthesis, Conjugate Hydrolysis, and Indole-3-Butyric Acid b-Oxidation

Abstract

The phytohormone auxin is important in virtually all aspects of plant growth and development, yet our understanding of auxin homeostasis is far from complete. Plants use several mechanisms to control levels of the active auxin, indole-3-acetic acid (IAA). Plants can synthesize IAA both from tryptophan (Trp-dependent pathways) and from a Trp precursor but bypassing Trp (Trp-independent pathways). Despite progress in identifying enzymes in Trp-dependent IAA biosynthesis, no single IAA biosynthetic pathway is yet defined to the level that all of the relevant genes, enzymes, and intermediates are identified. In addition to de novo synthesis, vascular plants can obtain IAA from the hydrolysis of IAA conjugates. IAA can be conjugated to amino acids, sugars, and peptides; endogenous conjugates that are active in bioassays and hydrolyzed in plants are likely to be important free IAA sources. Conjugation is also used to permanently inactivate excess IAA, and these conjugates may be distinct from the hydrolyzable conjugates. The peroxisomal (3-oxidation of endogenous indole-3-butyric acid (IBA) also can supply plants with IAA, which may account for part of the auxin activity of exogenous IBA. Compartmentalization of enzymes and precursors may contribute to the regulation of auxin metabolism. IAA obtained through de novo synthesis, conjugate hydrolysis, or IBA β-oxidation may have different functions in plant development, and possible roles for the IAA derived from the various pathways are discussed.