Indole-3-acetic acid and indole-3-butyric acid in tissues of carrot inoculated withAgrobacterium rhizogenes

The role of auxins in induction of roots byAgrobacterium rhizogenes was studied in carrot root disks. Transformed roots were produced on root disks by inoculation withA. rhizogenes, A4. Measurement of indole-3-acetic acid (IAA) by gas chromatography-mass spectrometry (GC-MS) indicated that there was a significant increase in the concentration of IAA in transformed callus and induced roots compared with initial IAA concentrations in carrot disks. Indole-3-butyric acid (IBA) was found to occur naturally in carrot roots. The presence of IBA, a potent root inducer, must be taken into account when assessing the role of auxin during transformation and induction of roots byA. rhizogenes.     

Transport of indole-3-butyric acid and indole-3-acetic acid in Arabidopsis hypocotyls using stable isotope labeling

The polar transport of the natural auxins indole-3-butyric acid (IBA) and indole-3-acetic acid (IAA) has been described in Arabidopsis (Arabidopsis thaliana) hypocotyls using radioactive tracers. Because radioactive assays alone cannot distinguish IBA from its metabolites, the detected transport from applied [3H]IBA may have resulted from the transport of IBA metabolites, including IAA. To test this hypothesis, we used a mass spectrometry-based method to quantify the transport of IBA in Arabidopsis hypocotyls by following the movement of [13C1]IBA and the [13C1]IAA derived from [13C1]IBA. We also assayed [13C6]IAA transport in a parallel control experiment. We found that the amount of transported [13C1]IBA was dramatically lower than [13C6]IAA, and the IBA transport was not reduced by the auxin transport inhibitor N-1-naphthylphthalamic acid. Significant amounts of the applied [13C1]IBA were converted to [13C1]IAA during transport, but [13C1]IBA transport was independent of IBA-to-IAA conversion. We also found that most of the [13C1]IBA was converted to ester-linked [13C1]IBA at the apical end of hypocotyls, and ester-linked [13C1]IBA was also found in the basal end at a level higher than free [13C1]IBA. In contrast, most of the [13C6]IAA was converted to amide-linked [13C6]IAA at the apical end of hypocotyls, but very little conjugated [13C6]IAA was found in the basal end. Our results demonstrate that the polar transport of IBA is much lower than IAA in Arabidopsis hypocotyls, and the transport mechanism is distinct from IAA transport. These experiments also establish a method for quantifying the movement of small molecules in plants using stable isotope labeling.     

Uptake and metabolism of indole-3-butyric acid and indole-3-acetic acid by Petunia cell suspension culture

The uptake and metabolism of indole-3-acetic acid (IAA) and indole-3-butyric acid (IBA) were studied in suspension cell cultures of Petunia hybrida. The initial uptake of ³H-IBA was much higher than that of ³H-IAA, and after 10 min of incubation with labeled IBA and IAA, 4.6 pM vs 0.35 (39% vs 12% of total applied radioactivity) respectively, were found in the cell extracts. The uptake of IBA reached a plateau of 6.0 pM (62%) after 2 h while that of IAA increased continuously up to 1.5 pM (46%) after 24 h. Following the addition of 40 µM of unlabeled auxin more IBA was taken in initially than IAA (39% vs 12%), but the level almost equalized after 24 h of incubation when IBA uptake reached 890 nM (55%) and IAA 840 nM (46%).IBA was metabolized very rapidly by Petunia cell suspension to new compounds. HPLC of the cell extracts demonstrated a new metabolite after only 2 min of incubation, and after 30 min 60% of the radioactivity was in the new metabolite vs 10% in the IBA. The new compound was resolved by autofluorography to two metabolites but after 24 h only one metabolite was present. The IBA metabolites were identified tentatively as IBA aspartic acid (IBAasp) and IBA glucose (IBAglu). In the medium IBA disappeared at a fast rate and after 24h most of the radioactivity was present in the new metabolite, probably IBAasp. IAA was also converted rapidly to two new metabolites and both were still present after 24 h. No attempt was made to identify the metabolites of IAA. IAA metabolism proceeded at a slower rate, and autofluorography showed that while free IBA disappeared after 0.5 h, free IAA was still present after 1 h of incubation. We postulate that Petunia cells conjugate IBA rapidly to IBAglu which in turn is converted to form IBAasp which probably acts as a slow release hormone. Only intact cells were able to metabolize IBA and the reaction was affected by low temperature and anaerobic conditions. The fast rate of IBA uptake, the need for whole cells for the metabolism to proceed, and the fast change of IBA to a new metabolite in the medium, all suggest that both uptake and metabolism of IBA in Petunia cells occur on the cell surface.     

Comparison of movement and metabolism of indole-3-acetic acid and indole-3-butyric acid in mung bean cuttings

Indole-3-butyric acid (IBA) was much more effective than indole-3-acetic acid (IAA) in inducing adventitious root formation in mung bean ( Vigna radiata L.) cuttings. Prolonging the duration of treatment with both auxins from 24 to 96 h significantly increased the number of roots formed. Labelled IAA and IBA applied to the basal cut surface of the cuttings were transported acropetally. With both auxins, most radioactivity was detected in the hypocotyl, where roots were formed, but relatively more IBA was found in the upper sections of the cuttings. The rate of metabolism of IAA and IBA in these cuttings was similar. Both auxins were metabolized very rapidly and 24 h after application only a small fraction of the radioactivity corresponded to the free auxins. Hydrolysis with 7 M NaOH indicates that conjugation is the major pathway of IAA and IBA metabolism in mung bean tissues. The major conjugate of IAA was identified tentatively as indole-3-acetylaspartic acid, whereas IBA formed at least two major conjugates. The data indicate that the higher root-promoting activity of IBA was not due to a different transport pattern and/or a different rate of conjugation. It is suggested that the IBA conjugates may be a better source of free auxin than those of IAA and this may explain the higher activity of IBA.     

Transport of the two natural auxins, indole-3-butyric acid and indole-3-acetic acid, in Arabidopsis

Polar transport of the natural auxin indole-3-acetic acid (IAA) is important in a number of plant developmental processes. However, few studies have investigated the polar transport of other endogenous auxins, such as indole-3-butyric acid (IBA), in Arabidopsis. This study details the similarities and differences between IBA and IAA transport in several tissues of Arabidopsis. In the inflorescence axis, no significant IBA movement was detected, whereas IAA is transported in a basipetal direction from the meristem tip. In young seedlings, both IBA and IAA were transported only in a basipetal direction in the hypocotyl. In roots, both auxins moved in two distinct polarities and in specific tissues. The kinetics of IBA and IAA transport appear similar, with transport rates of 8 to 10 mm per hour. In addition, IBA transport, like IAA transport, is saturable at high concentrations of auxin, suggesting that IBA transport is protein mediated. Interestingly, IAA efflux inhibitors and mutations in genes encoding putative IAA transport proteins reduce IAA transport but do not alter IBA movement, suggesting that different auxin transport protein complexes are likely to mediate IBA and IAA transport. Finally, the physiological effects of IBA and IAA on hypocotyl elongation under several light conditions were examined and analyzed in the context of the differences in IBA and IAA transport. Together, these results present a detailed picture of IBA transport and provide the basis for a better understanding of the transport of these two endogenous auxins.     

Indole-3-butyric acid in Arabidopsis thaliana

Indole-3-butyric acid (IBA) was identified by HPLC and GC-MS as an endogenous compound in plantlets of the crucifer Arabidopsis thaliana (L.) Heynh. A. thaliana was cultivated under sterile conditions as shaking culture in different liquid media with and without supply of hormones. Free and total IBA and indole-3-acetic acid (IAA) were determined at different stages of development during the culture period as well as in culture media of different initial pH values. The results showed that IAA was present in higher concentrations than IBA, but both hormones seemed to show the same behaviour under the different experimental conditions. Differences were found in the mode of conjugation of the two hormones. While IAA was mostly conjugated via amide bonds, the main IBA conjugates were ester bound. The ethylene concentration derived from the seedlings, when they were grown in flasks of different size, seemed not to influence the auxin content in the same cultures.     

Indole-3-acetic acid and indole-3-acetylaspartic acid isolated from seeds of Heracleum laciniatum Horn

Seeds from mature flowers of Heracleum laciniatum were collected locally (Tromsø, Norway). Seed coats were removed and the seeds were analyzed for their content of free, free plus ester-conjugate, and total indole-3-acetic acid (IAA) by quantitative gas chromatography-mass spectrometry. Seeds contained high levels of free and amide-linked IAA relative to other dicotyledonous seeds for which values have been published. The major amide conjugate in this material was identified as indole-3-acetylaspartate by gas chromatography-mass spectrometry of its bis-methyl ester.     

Differential responses of primary and lateral roots to indole-3-acetic acid,indole-3-butyric acid,and 1-naphthaleneacetic acid in maize seedlings

The role of auxins on root system architecture was studied by applying indole-3-acetic acid (IAA), indole-3-butyric acid (IBA), and 1-naphthaleneacetic acid (NAA) to maize roots and analysing the main processes involved in root development: primary root (PR) elongation, lateral root (LR) formation, and LR root elongation. We found that these effects were not dependent only on concentration, but also on the type of auxin applied. We also studied temporal changes in auxin inhibition of PR elongation. These temporal changes were analysed calculating the elongation ratio between two consecutive one day periods after auxin application. It was observed that a reduction in root elongation was also dependent on the type of auxin applied and its concentration. The inhibitory effect of IBA and IAA decreased on the second day, and the ratio also increased with the concentration. In contrast, NAA increased root elongation inhibition with time. Indeed, the ratio decreased as the NAA concentration increased. Regarding LR formation, we observed that external auxin increased only LR formation in certain zones of the PR. Finally, comparison of inhibition elongation associated with auxin in the LR and PR clearly demonstrates that PR elongation was more sensitive to auxin than LR elongation.     

Lateral root formation in rice (Oryza Sativa L.): differential effects of indole-3-acetic acid and indole-3-butyric acid

Comparative effects of indole-3-acetic acid (IAA) and indole-3-butyric acid (IBA) on lateral root (LR) formation were studied using 2-day-old seedlings of IR8 rice (Oryza sativa L.). Results showed that IBA at all concentrations (0.8–500 nmol/L) increased the number of LRs in the seminal root. However exogenous IAA, failed to increase the number of LRs. On the other hand, both IBA and IAA caused inhibition of seminal root elongation and promotion of LR elongation, but IAA can only reach to the same degree of that of IBA at a more than 20-fold concentration. Exogenous IBA had no effect on endogenous IAA content. We conclude from the results that IBA could act directly as a distinct auxin, promoting LR formation in rice, and that the signal transduction pathway for IBA is at least partially different from that for IAA.     

Indole-3-butyric acid in plant growth and development

Within the last ten years it has been established by GC-MS thatindole-3-butyric acid (IBA) is an endogenous compound in a variety ofplant species. When applied exogenously, IBA has a variety of differenteffects on plant growth and development, but the compound is stillmainly used for the induction of adventitious roots. Using moleculartechniques, several genes have been isolated that are induced duringadventitious root formation by IBA. The biosynthesis of IBA in maize(Zea mays L.) involves IAA as the direct precursor. Microsomalmembranes from maize are able to convert IAA to IBA using ATP andacetyl-CoA as cofactors. The enzyme catalyzing this reaction wascharacterized from maize seedlings and partially purified. The invitro biosynthesis of IBA seems to be regulated by several externaland internal factors: i) Microsomal membranes from light-grownmaize seedlings directly synthesize IBA, whereas microsomal membranesfrom dark-grown maize plants release an as yet unknown reaction product,which is converted to IBA in a second step. ii) Drought and osmoticstress increase the biosynthesis of IBA maybe via the increaseof endogenous ABA, because application of ABA also results in elevatedlevels of IBA. iii) IBA synthesis is specifically increased byherbicides of the sethoxydim group. iv) IBA and IBA synthesizingactivity are enhanced during the colonization of maize roots with themycorrhizal fungus Glomus intraradices. The role of IBA forcertain developmental processes in plants is discussed and somearguments presented that IBA is per se an auxin and does notact via the conversion to IAA.     

Effects of Azospirillum brasilense indole-3-acetic acid production on inoculated wheat plants

The production of phytohormones by plant-growth promoting rhizobacteria is considered to be an important mechanism by which these bacteria promote plant growth. In this study the importance of indole-3-acetic acid (IAA) produced by Azospirillum brasilense Sp245 in the observed plant growth stimulation was investigated by using Sp245 strains genetically modified in IAA production. Firstly wild-type A. brasilense Sp245 and an ipdC knock-out mutant which produces only 10% of wild-type IAA levels (Vande Broek et al., J Bacteriol 181:1338–1342, 1999) were compared in a greenhouse inoculation experiment for a number of plant parameters, thereby clearly demonstrating the IAA effect in plant growth promotion. Secondly, the question was addressed whether altering expression of the ipdC gene, encoding the key enzyme for IAA biosynthesis in A. brasilense, could also contribute to plant growth promotion. For that purpose, the endogenous promoter of the ipdC gene was replaced by either a constitutive or a plant-inducible promoter and both constructs were introduced into the wild-type strain. Based on a greenhouse inoculation experiment it was found that the introduction of these recombinant ipdC constructs could further improve the plant-growth promoting effect of A. brasilense. These data support the possibility of constructing Azospirillum strains with better performance in plant growth promotion.     

Indole-3-methanol as an intermediate in the oxidation of indole-3-acetic acid by peroxidase

During oxidation of indole-3-acetic acid catalyzed by horseradish peroxidase, indole-3-aldehyde and 3-hydroxymethayloxindole cease to be produced a few minutes after initiation of the reaction even though IAA is still being consumed. At the same time an increased accumulation of indole-3-methanol is observed and the ratio of oxygen to indole-3-acetic acid consumed becomes less than unity. Indole-3-niethanol can be a substrate for horseradish peroxidase provided that H₂O₂ is present. In this reaction, indole-3-aldehyde but not 3-hydroxymethyloxindole is formed. H₂O₂ is not merely an activating agent for the enzyme but also a true oxidant because it is consumed stoichiometrically (1 mol of H₂O₂ per mol of indole-3-methanol) and the reaction is independent of the presence of oxygen. Indole-3-methanol is proposed as an intermediate in the process of oxidation of indole-3-acetic acid into indole-3-al-denyde, the second step of which requires peroxide as an oxidant.     

Metabolism of auxin in pine tissues: Indole-3-acetic acid conjugation

Incubation of sections of various tissues of Pinus pinea L. with a relatively low concentration (3.6 μM) of indole-3-acetic acid-2-¹⁴C (IAA) resulted in the formation of two major metabolites. The first, which has not been identified, seemed to be a polar acidic compound and the second was identified as indole-3-acetylaspartic acid (IAAsp). The polar acidic metabolite has been found to be the major metabolite in needles, shoot wood and roots, while IAAsp has been found to be the major metabolite in shoot bark. Increasing the concentration of IAA in the incubation medium resulted in an increase in the formation of a third metabolite which proved to be l-O-(indole-3-acetyl)-β-d -glucose (IAGlu) and a concomitant decrease in the amount of the polar acidic metabolite. This phenomenon was prominent particularly in needles. IAGlu was isolated from needles and IAAsp was isolated from shoot bark by means of polyvinylpolypyrrolidone column chromatography and preparative thin-layer chromatography. IAGlu was identified by comparison with authentic material by co-chromatography in three different solvent systems and by ¹H-nuclear magnetic resonance analysis. IAAsp was identified by comparison with authentic material by gas-liquid chromatography and ¹H-nuclear magnetic resonance analysis. Several aspects of formation, separation and isolation of IAA metabolites are discussed.     

Influence of Aryl Esters of Indole-3-acetic and Indole-3-butyric Acids on Adventitious Root Primordium Initiation and Development

Synthetic aryl esters of indole-3-acetic acid (IAA) and indole-3-butyric acid (IBA) greatly enhanced adventitious root primordium initiation in bean (Phaseolus vulgaris L. cv. Top Crop) and jack pine (Pinus banksiana Lamb.) cuttings, respectively. Bean cuttings produced 95 to 154% more macroscopically visible root primordia in 2 days when treated with phenyl indole-3-acetate (P-IAA), in comparison with an equal concentration of IAA. Substantial but lesser increases occurred when treatment was done with 3-hydroxyphenyl indole-3-acetate (3HP-IAA). On a molar basis, either P-IAA or 3HP-IAA were 10 or more times as efficient as IAA in inducing adventitious root primordium initiation in bean cuttings. Methyl indole-3-acetate was no more effective than IAA in these tests. Phenyl indole-3-butyrate (P-IBA) consistently enhanced the number of rooted jack pine seedling cuttings by 11 to 12% in comparison with a 27% higher concentration of IBA. The number of elongated roots (2 mm or more) after 5 days was 165 to 276% greater for P-IAA than for IAA-treated bean cuttings. Similar but lesser increases occurred as a result of 3HP-IAA treatment. P-IBA in comparison with IBA treatment did not influence either the number of roots or length of the longest root per rooted jack pine cutting. Enzymes in bean and jack pine cuttings hydrolyzed the aryl esters. However, check experiments showed that initial integrity of the esters was required for enhanced activity in inducing root primordium initiation. Treatment of bean cuttings with hydrolysates of P-IAA, or with IAA and phenol, alone or combined, did not influence root primordium initiation or development in a manner different from treatment with IAA alone.     

Gibberellin-enhanced indole-3-acetic acid biosynthesis: D-Tryptophan as the precursor of indole-3-acetic acid

Stem segments excised from light-grown Pisum sativum L. (cv. Little Marvel) plants elongated in the presence of indole-3-acetic acid and its precursors, except for L-tryptophan, which required the addition of gibberellin A, for induction of growth. Segment elongation was promoted by D-tryptophan without a requirement for gibberellin, and growth in the presence of both D-tryptophan and L-tryptophan with gibberellin A3, was inhibited by the D-aminotransferase inhibitor D-cycloserine. Tryp-tophan racemase activity was detected in apices and promoted conversion of L-tryptophan to the D isomer; this activity was enhanced by gibberellin A3. When applied to apices of intact untreated plants, radiolabeled D-tryptophan was converted to indole-3-acetic acid and indoleacetylaspartic acid much more readily than L-tryptophan. Treatment of plants with gibberellin A3, 3 days prior to application of labeled tryptophan increased conversion of L-tryptophan to the free auxin and its conjugate by more than 3-fold, and led to labeling of N-malonyl-D-tryptophan. It is proposed that gibberellin increases the biosynthesis of indole-3-acetic acid by regulating the conversion of L-tryptophan to D-tryptophan, which is then converted to the auxin.     

Indole-3-acetic acid and indole-3-ethanol in light-grown Pisum sativum seedlings and their localization in chloroplast fractions

Studies have been carried out on the compartmentation ofindole-3-acetic acid (IAA) and related indoles in Pisum sativum cv. Meteor. By the use of HPLC, GC and combined GC-MS, data were obtained demonstrating the presence of IAA and indole-3-ethanol (IEt) in light-grown pea seedlings. HPLC, GC and GC-MS analyses also confirmed IAA as an endogenous constituent in pea chloroplast fractions while HPLC and GC provided strong evidence for the presence of IEt in chloroplast preparations.     

Biocontrol of Botrytis cinerea in apple fruit by Cryptococcus laurentii and indole-3-acetic acid

This study evaluated the effect of a yeast antagonist Cryptococcus laurentii and a plant regulator indole-3-acetic acid (IAA) on inhibition of Botrytis cinerea infection in harvested apple fruit. The results showed that the combined treatment with C. laurentii and IAA at 20 μg/ml was a more effective approach to reduce the gray mold rot in apple wounds than the C. laurentii alone. After 4 days of incubation, gray mold incidence in the combined treatment with C. laurentii and IAA was about 18%, which was a 50% reduction in incidence compared to the treatment with C. laurentii alone. Although IAA had no direct antifungal activity against B. cinerea infection when the time interval between IAA treatment and pathogen inoculation was within 2 h, application of IAA strongly reduced gray mold infection when IAA was applied 24 h prior to inoculation with B. cinerea in apple fruit wounds. Moreover, combination of IAA and C. laurentii stimulated the activities of superoxide dismutase, catalase and peroxidase with above 1.5-fold higher than that treatment with C. laurentii alone at 48 h. Therefore, combination of C. laurentii with IAA, which integrated the dual biological activity from the antagonistic yeast and plant regulator, might be developed to be a useful approach to control gray mold in harvested apple fruit.     

Metabolism of indole-3-acetic acid in rice: identification and characterization of N-beta-D-glucopyranosyl indole-3-acetic acid and its conjugates

A search was made for conjugates of indole-3-acetic acid (IAA) in rice (Oryza sativa) using liquid chromatography-electrospray ionization-tandem mass spectrometry (LC-ESI-MS/MS) in order to elucidate unknown metabolic pathways for IAA. N-beta-d-Glucopyranosyl indole-3-acetic acid (IAA-N-Glc) was found in an alkaline hydrolysate of rice extract. A quantitative analysis of 3-week-old rice demonstrated that the total amount of IAA-N-Glc was equal to that of IAA. A LC-ESI-MS/MS-based analysis established that the major part of IAA-N-Glc was present as bound forms with aspartate and glutamate. Their levels were in good agreement with the total amount of IAA-N-Glc during the vegetative growth of rice. Further detailed analysis showed that both conjugates highly accumulated in the root. The free form of IAA-N-Glc accounted for 60% of the total in seeds but could not be detected in the vegetative tissue. An incorporation study using deuterium-labeled compounds showed that the amino acid conjugates of IAA-N-Glc were biosynthesized from IAA-amino acids. IAA-N-Glc and/or its conjugates were also found in extracts of Arabidopsis, Lotus japonicus, and maize, suggesting that N-glucosylation of indole can be the common metabolic pathway of IAA in plants.