Evidence That IAA Conjugates Are Slow-Release Sources of Free IAA in Plant Tissues

Evidence that indoleacetic acid (IAA) conjugates are metabolized via enzyme-catalyzed hydrolysis to free IAA and that their biological activities are related to the rates at which they are hydrolyzed by the tissue is presented. These conclusions are based on the following observations. Slow but continuous decarboxylation of the IAA moiety of IAA-l-alanine and IAA-glycine occurs when these conjugates are applied to pea (Pisum sativum L. cv. Alaska) stem segments. Inasmuch as IAA conjugates are protected from peroxidase-catalyzed oxidative decarboxylation, the conjugates are probably hydrolyzed and the freed IAA then further metabolized. Free IAA and IAA-l-alanine are converted, by pea stem tissue, into the same metabolites. The metabolism is enzymic, since conjugates of IAA with the d-isomers of the amino acids are inactive. Ethylene production induced by IAA-l-alanine and by IAA-glycine is correlated with their hydrolysis, as indicated by their decarboxylation and with the appearance or nonappearance of IAA metabolites in the tissues.     

Elisa determination of IAA using antibodies against ring-linked IAA

An enzyme-linked immunosorbent assay (ELISA) for indole-3-acetic acid (IAA) is described which uses antibodies raised against IAA conjugated to carrier protein on the indolic ring of IAA. As little as 0.5 pmol of IAA is detectable with the ELISA. There is no significant cross-reactivity with amide conjugates of IAA and samples do not need methylation, in contrast to an ELISA using antibodies raised against carboxyl-linked IAA. Affinity chromatography on IAA-agarose was used to purify antibody preparations. Measurements of IAA levels in crown gall tumour tissue lines were made using the assay.     

A hypothetical route for the biogenisis of IAA

Summary A method is described for using apical sections of Avena coleoptiles grown in the dark for 70 hours as an assay for IAA and for potential precursors of IAA. The experiments were carried out under as sterile conditions as possible.Tryptophan appeared not to act as a precursor of IAA. Tryptamine however showed a marked stimulation of growth indicating its possible conversion to IAA. Other compounds that stimulated growth and hence may be regarded as potential precursors of IAA were anthranilic acid and indole. Kynurenine and shikimic acid were among those without an effect. A hypothetical route for the biogenisis of IAA is suggested based on the findings of this work.     

The effect of light on metabolism of IAA in maize seedlings

Carbon 14-labelled indole-3-acetic acid (IAA) was fed to segments of shoots of Zea mays seedlings grown in light or dark to find the effect of light on IAA metabolism. The seedling parts coleoptile, with enclosed leaf, and mesocotyl were also used to examine differences in IAA metabolism between tissue types. The rate of metabolite formation as a function of time ranging from 1 to 12 hours was determined. Light did not significantly influence the amount of IAA taken up, but significantly increased its rate of metabolism and greatly increased the content of amide conjugates formed. There were also differences in metabolism depending on tissue type. In all tissues, IAA was metabolized mainly into six compounds. Four were tentatively identified as IAA-glucose (IAGlc), IAA-myo-inositol} (IAInos), indole acetamide (IAAm) and IAA-aspartic acid (IAAsp). 1-O-IAA-D-glucose (1-O-IAGlc) was the first conjugate formed and, except for mesocotyls in the light, it was the most abundant conjugate in maize tissue. In mesocotyl tissue the conversion of IAA into IAAsp was greatly stimulated by light, and the biosynthesis of IAAsp exceeded that of IAGlc. Since light strongly inhibited the growth of the mesocotyl, it is possible that the stimulation of IAAsp synthesis by light causes depletion of free IAA with resultant inhibition of mesocotyl growth.     

Identification of conjugated IAA in carrot crown gall as indole-3-acetylaspartic acid (IAAsp) by LC/MS

In carrot crown gall cells transformed with Ti plasmids, Ti-derived IAA biosynthetic genes are transcribed and translated, followed by overproduction of IAA. However, the newly synthesized IAA is immediately metabolized to IAA-amino acid conjugate, and the content of endogenous free IAA is maintained at a low level. In this study, IAA-amino acid conjugate in carrot tissues transformed with Ti plasmids was identified as indole-3-acetylaspartic acid (IAAsp) by using frit-fast atom bombardment liquid chromatography/mass spectrometry (LC/MS).     

Metabolism and Synthesis of Indole-3-Acetic Acid (IAA) in Zea mays (Levels of IAA during Kernel Development and the Use of in Vitro Endosperm Systems for Studying IAA Biosynthesis)

Kernels of Zea mays on an intact plant accumulate indole-3-acetic acid (IAA) at the rate of 190 ng g-1 fresh weight h-1. Of the IAA synthesized, 97% is in the esterified form and less than 3% remains as the free acid. The site of biosynthesis of the IAA, whether synthesized in the leaf and transported to the kernel, or in the kernel and remaining in the kernel, has not been established. In an attempt to determine the locus of synthesis, we grew isolated kernels on agar media not containing tryptophan or other possible aromatic precursors of IAA and observed IAA synthesis of 99 ng g-1 fresh weight h-1, approximately 52% of the in situ rate. Thus, the kernel contains all of the enzymes required for de novo aromatic biosynthesis of IAA and its ester conjugates. Furthermore, endosperm cells in suspension culture, grown on hormone-free media and in the absence of aromatic precursors, are able to synthesize IAA at a rate of 9.2 ng g-1 fresh weight h-1, or 4.8% of the in situ rate. This finding establishes that all of the enzymes of IAA biosynthesis occur in the endosperm and that the endosperm is a site of IAA biosynthesis. Isolated endosperm, prepared from developing kernels, synthesized IAA from labeled anthranilate at a rate of 8.6 ng g-1 fresh weight h-1, or 4.5% of the in situ rate. Frozen endosperm preparations maintained the ability to synthesize labeled IAA from labeled anthranilate. The identity of the synthesized IAA was established by mass spectral analysis. We suggest that endosperm preparations of Z. mays are suitable for study of the mechanism(s) of IAA biosynthesis because they (a) have high rates of synthesis; (b) show stability to freezing, enabling enzyme storage; (c) provide a system with a known rate of in situ synthesis; and (d) are available in large amounts for use as an enzyme source.     

IAA Metabolism in Embryogenic and Non-Embryogenic Carrot Cells

Carrot somatic embryos can readily be induced from embryogeniccells transferred from auxin-containing medium to auxin-freemedium, but not from transferred non-embryogenic cells. It iswell-known that IAA, a natural auxin, plays important rolesin many physiological responses including somatic embryogenesis,but, there is no report of the IAA metabolism in embryogenicand non-embryogenic cells. Therefore, we examined IAA metabolismin embryogenic and nonembryogenic carrot cells. In this paper the IAA metabolism in embryogenic cells and non-embryogeniccells is described. The induction of IAAsp formation was clarifiedin both cells. On the other hand, in non-embryogenic cells,an unknown metabolite was detected and identified as oxindole-3-acetylasparticacid (oxIAAsp). OxIAAsp formation may be induced to eliminateexcess auxin. Furthermore, endogenous IAA contents in both cellswere quantified and the relationship between somatic embryogenesisand IAA metabolism is discussed. (Received May 2, 1994; Accepted August 30, 1994)     

Biochemical Bases for the Loss of Basipetal IAA Transport with Advancing Physiological Age in Etiolated Helianthus Hypocotyls: Changes in IAA Movement, Net IAA Uptake, and Phytotropin Binding

Basipetal transport of [¹⁴C]IAA in hypocotyl segments isolated from various regions of etiolated Helianthus annuus L. cv NK 265 seedlings declines with increasing physiological age. This decline was the result of a reduction in both transport capacity and apparent velocity. Net IAA uptake was greater and the abilities of auxin transport inhibitors to stimulate net IAA uptake were reduced in older tissues. Net IAA accumulation by microsomal vesicles exhibited a similar behavior with respect to age. Specific binding of [³H]N-1-naphthylphthalamic acid (NPA) to microsomes prepared from young and older hypocotyl regions was saturable and consistent with a single class of binding sites. The apparent affinity constants for NPA binding in microsomes prepared from young versus older tissues were 6.4 and 10.8 nanomolar, respectively, and the binding site densities for young versus old tissues were 7.44 and 3.29 picomoles/milligram protein, respectively. Specific binding of [³H]NPA in microsomes prepared from both tissues displayed similar sensitivities toward unlabeled flurenol and exhibited only slight differences in sensitivity toward 2,3,5-triiodobenzoic acid. These results demonstrate that the progressive loss of basipetal IAA transport capacity in etiolated Helianthus hypocotyls with advancing age is associated with substantial alterations in the phytotropin-sensitive, IAA efflux system and they suggest that these changes are, at least partially, responsible for the observed reduction of polar IAA transport with advancing tissue age.     

AXR2 encodes a member of the Aux/IAA protein family

The dominant gain-of-function axr2-1 mutation of Arabidopsis causes agravitropic root and shoot growth, a short hypocotyl and stem, and auxin-resistant root growth. We have cloned the AXR2 gene using a map-based approach, and find that it is the same as IAA7, a member of the IAA (indole-3-acetic acid) family of auxin-inducible genes. The axr2-1 mutation changes a single amino acid in conserved domain II of AXR2/IAA7. We isolated loss-of-function mutations in AXR2/IAA7 as intragenic suppressors of axr2-1 or in a screen for insertion mutations in IAA genes. A null mutant has a slightly longer hypocotyl than wild-type plants, indicating that AXR2/IAA7 controls development in light-grown seedlings, perhaps in concert with other gene products. Dark-grown axr2-1 mutant plants have short hypocotyls and make leaves, suggesting that activation of AXR2/IAA7 is sufficient to induce morphological responses normally elicited by light. Previously described semidominant mutations in two other Arabidopsis IAA genes cause some of the same phenotypes as axr2-1, but also cause distinct phenotypes. These results illustrate functional differences among members of the Arabidopsis IAA gene family.     

Comparison of effects of ABA and IAA on phospholipid bilayers

The plant hormones indole-3-acetic acid (IAA) and abscisic acid (ABA) affect the properties of phospholipid bilayers differently. IAA enhances permeability of bilayers composed of phosphatidylcholine to the non-electrolyte erythritol while ABA requires an additional phospholipid in the membrane to produce substantial enhancement. Similar conclusions are obtained by measuring hormone-induced permeability to chloride ions; IAA is effective with single component phosphatidylcholine membranes while ABA requires a second phospholipid. Erythritol permeability is shown to be pH dependent for both hormones. Although IAA is more effective at increasing erythritol permeability at pH 4 than at pH 7, both dissociated and undissociated IAA affect the process. In comparison ABA is almost totally ineffective in the dissociated form (at pH 7). Spin label electron spin resonance measurements demonstrated that neither hormone substantially disrupts acyl chain mobility within the membrane, indicating that the mechanism of permeability enhancement is not a general non-specific pertubation of membrane ordering and fluidity. Both hormones can also effect the stability of small unilamellar (sonicated) vesicles. Phosphatidylcholine vesicles are relatively stable and do not rapidly aggregate with either ABA or IAA. However, when phosphatidylethanolamine is incorporated as a minor component (10 mol%) into phosphatidylcholine vesicles ABA causes rapid aggregation while IAA has no effect. These experiments indicate that the two hormones may exhibit completely different behaviour on membranes without the requirement for specific proteinaceous receptors.     

Distribution and transport of IAA in tomato plants

We determined as to indole-3-acetic acid (IAA), endogenous levels byliquid chromatography-mass spectrometry using ¹³C₆-IAA, diffusible levels byfluorometric detection using indole-propionic acid, and polar transportactivityby radioactive IAA in 3-month-old tomato plants (stems, leaves or roots). TheIAA concentration in the apoplast (AP) solution was higher than those in thesymplast (SP) solution in both the upper and lower parts of stems, showing thatIAA analysis of AP solution is important. Younger leaves exported much morediffusible IAA than older leaves. The IAA concentration in the main roots wasalmost at the same level as in the stems. The results suggested that thetransport capacity of IAA is probably the limiting factor for the amount of IAAtransported in stems and the amount of polar IAA transport might be only 19% ofthe endogenous IAA amount in stems.     

Redundancy as a way of life - IAA metabolism.

Plants have evolved elaborate systems for regulating cellular levels of indole-3-acetic acid (IAA). The redundancy of this network has complicated the elucidation of IAA metabolism, but molecular genetic studies and precise analytical methods have begun to expose the circuitry. It is now clear that plants synthesize, inactivate and catabolize IAA by multiple pathways, and multiple genes can encode a particular enzyme within a pathway. A number of these genes are now cloned, which greatly facilitates the future dissection of IAA metabolism.     

Indole-3-acetic Acid (IAA) and IAA Conjugates Applied to Bean Stem Sections: IAA Content and the Growth Response

High resolution growth recording techniques and reverse isotope dilution analysis were used to study the relationship between indole-3-acetic acid (IAA) concentration and curvature of excised bean (Phaseolus vulgaris L. cv Bush Burpee Stringless) first internode sections unilaterally treated with hormone. The maximum rate of curvature occurred rapidly (within 25 minutes) and was proportional to the log of the amount of applied IAA recovered in the tissue. The rate of curvature decreased after 30 minutes although little or no lateral migration of applied IAA occurred and tissue levels of IAA increased. The biologic activity of IAA-amino acid conjugates was found to be directly related to the amount of free IAA, resulting from their hydrolysis, which could be recovered from the tissue.     

ABA and IAA in rice seedlings under anaerobic conditions

The rice is important in plant science for its ability to germinate and grow with restricted or without oxygen availability. In this work we have investigated the variation of growth substances when anoxia was imposed to rice seedlings previously grown in air. An increase, in all the organs of a seedling and in particular in the fraction released in the medium, was observed for ABA (abscisic acid), PA (phaseic acid) and DPA (dihydrophaseic acid) quantities.Vice versa a reduction of total IAA (indol-3-ylacetic acid) was observed in seedlings. This was accompanied by its accumulation in roots. IAA was poorly released in aerobic conditions and anoxia has not changed this pattern.     

Effects of IAA and four IAA conjugates on morphogenesis and callus growth from tomato leaf discs

The effects of indole-3-acetic acid (IAA) and four IAA conjugates, indoleacetylalanine (IAAla), indoleacetylaspartic acid (IAAsp), indoleacetylglycine (IAGly), and indoleacetylphenylalanine (IAPhe), on growth and morphogenesis in tomato leaf discs in vitro were examined. Free IAA stimulated root initiation in the absence of cytokinin and stimulated callus growth in the presence of 0.89 M benzylaminopurine (BAP). Free IAA also inhibited shoot initiation obtained with 8.9 M BAP. The activities of the IAA conjugates depended on the conjugating amino acid, the concentration of the conjugate, and the response being measured. IAAsp had little or no activity in promoting root initiation or callus growth or in inhibiting shoots, while IAPhe was similarly inactive except at the highest concentration tested (100 M). IAAla and IAGly were both very active in inhibiting shoots and promoting callus growth, but were much less active in stimulating rooting, except at 100 M, at which concentration they were as effective as free IAA. Thin-layer chromatography of the IAA conjugates revealed that IAAla, IAGly and IAPhe were largely stable to autoclaving, but that IAAsp underwent some hydrolysis to products identical with free IAA and aspartic acid. Pretreatment of seedlings with IAA, IAAla or IAGly altered the subsequent shoot initiation response from leaf discs on media with and without IAA.     

The effect of 4-chlororesorcinol on the endogenous levels of IAA,ABA and oxidative enzymes in cuttings

Treatment of bean cuttings with 4-chlororesorcinol (4-CR), known to increase the number of roots and extend their distribution, prevented the accumulation of free indol-3-yl-acetic acid (IAA) in the hypocotyls within 24 h after cutting preparation. In mung bean there was no change in the distribution (upper half vs. 1 ower half of the hypocotyl) of IAA within the hypocotyl as a result of the treatment. In bean cuttings the treatment with 4-CR prevented the accumulation of IAA in the bottom of the cutting. Oxidation of IAA as a measure of IAA oxidase activity in bean was enhanced appreciably by 4-chlororesorcinol. The level of abscisic acid in mung bean, on the other hand, remained 3–4 fold higher than in the control, yet still about 50% lower than the zero time level. In untreated mung bean cuttings the activity of peroxidase increased after cutting preparation. In contrast, the activity of peroxidase in 4-Cr-treated cuttings was consistently lower. In order to relate to the effect of exogenously applied auxin the level of peroxidase was measured also in indol-3-yl-butyric acid-treated cuttings. The overall peroxidase activity in IBA-treated cuttings was not affected. However, when assaying for the different isozymes the drop in peroxidase activity was most evident in the inducible basic isoperoxidases both in 4-CR and IBA treatments. It appears that the exposure to 4-CR exerts an effect that is similar to that of exogenously applied auxin, affecting the activity of basic peroxidases and enhancing the oxidation of endogenous IAA, thus allowing the organization of the primordia.Abbreviations ABA - abscisic acid - 4-CR - 4-chlororesorcinol - IAA - indol-3-yl-acetic acid - IBA - indol-3-yl-butyric acid     

An Auxin Gradient and Maximum in the Arabidopsis Root Apex Shown by High-Resolution Cell-Specific Analysis of IAA Distribution and Synthesis

Local concentration gradients of the plant growth regulator auxin (indole-3-acetic acid [IAA]) are thought to instruct the positioning of organ primordia and stem cell niches and to direct cell division, expansion, and differentiation. High-resolution measurements of endogenous IAA concentrations in support of the gradient hypothesis are required to substantiate this hypothesis. Here, we introduce fluorescence-activated cell sorting of green fluorescent protein–marked cell types combined with highly sensitive mass spectrometry methods as a novel means for analyses of IAA distribution and metabolism at cellular resolution. Our results reveal the presence of IAA concentration gradients within the Arabidopsis thaliana root tip with a distinct maximum in the organizing quiescent center of the root apex. We also demonstrate that the root apex provides an important source of IAA and that cells of all types display a high synthesis capacity, suggesting a substantial contribution of local biosynthesis to auxin homeostasis in the root tip. Our results indicate that local biosynthesis and polar transport combine to produce auxin gradients and maxima in the root tip.