Conversion of Endogenous Indole-3-Butyric Acid to Indole-3-Acetic Acid Drives Cell Expansion in Arabidopsis Seedlings

Genetic evidence in Arabidopsis (Arabidopsis thaliana) suggests that the auxin precursor indole-3-butyric acid (IBA) is converted into active indole-3-acetic acid (IAA) by peroxisomal β-oxidation; however, direct evidence that Arabidopsis converts IBA to IAA is lacking, and the role of IBA-derived IAA is not well understood. In this work, we directly demonstrated that Arabidopsis seedlings convert IBA to IAA. Moreover, we found that several IBA-resistant, IAA-sensitive mutants were deficient in IBA-to-IAA conversion, including the indole-3-butyric acid response1 (ibr1) ibr3 ibr10 triple mutant, which is defective in three enzymes likely to be directly involved in peroxisomal IBA β-oxidation. In addition to IBA-to-IAA conversion defects, the ibr1 ibr3 ibr10 triple mutant displayed shorter root hairs and smaller cotyledons than wild type; these cell expansion defects are suggestive of low IAA levels in certain tissues. Consistent with this possibility, we could rescue the ibr1 ibr3 ibr10 short-root-hair phenotype with exogenous auxin. A triple mutant defective in hydrolysis of IAA-amino acid conjugates, a second class of IAA precursor, displayed reduced hypocotyl elongation but normal cotyledon size and only slightly reduced root hair lengths. Our data suggest that IBA β-oxidation and IAA-amino acid conjugate hydrolysis provide auxin for partially distinct developmental processes and that IBA-derived IAA plays a major role in driving root hair and cotyledon cell expansion during seedling development.The auxin indole-3-acetic acid (IAA) controls both cell division and cell expansion and thereby orchestrates many developmental events and environmental responses. For example, auxin regulates lateral root initiation, root and stem elongation, and leaf expansion (for review, see Davies, 2004). Normal plant morphogenesis and environmental responses require modulation of auxin levels by controlling biosynthesis, regulating transport, and managing storage forms (for review, see Woodward and Bartel, 2005a). In some storage forms, the carboxyl group of IAA is conjugated to amino acids or peptides or to sugars, and free IAA can be released by hydrolases when needed (Bartel et al., 2001; Woodward and Bartel, 2005a). A second potential auxin storage form is the side chain-lengthened compound indole-3-butyric acid (IBA), which can be synthesized from IAA (Epstein and Ludwig-Müller, 1993) and is suggested to be shortened into IAA by peroxisomal β-oxidation (Bartel et al., 2001; Woodward and Bartel, 2005a).Genetic evidence suggests that the auxin activity of both IAA-amino acid conjugates and IBA requires free IAA to be released from these precursors (Bartel and Fink, 1995; Zolman et al., 2000). Mutation of Arabidopsis (Arabidopsis thaliana) genes encoding IAA-amino acid hydrolases, including ILR1, IAR3, and ILL2, reduces plant sensitivity to the applied IAA-amino acid conjugates that are substrates of these enzymes, including IAA-Leu, IAA-Phe, and IAA-Ala (Bartel and Fink, 1995; Davies et al., 1999; LeClere et al., 2002; Rampey et al., 2004), which are present in Arabidopsis (Tam et al., 2000; Kowalczyk and Sandberg, 2001; Kai et al., 2007).Unlike the simple one-step release of free IAA from amino acid conjugates, release of IAA from IBA is suggested to require a multistep process (Zolman et al., 2007, 2008). Conversion of IBA to IAA has been demonstrated in a variety of plants (Fawcett et al., 1960; for review, see Epstein and Ludwig-Müller, 1993) and may involve β-oxidation of the four-carbon carboxyl side chain of IBA to the two-carbon side chain of IAA (Fawcett et al., 1960; Zolman et al., 2000, 2007). Mutation of genes encoding the apparent β-oxidation enzymes INDOLE-3-BUTYRIC ACID RESPONSE1 (IBR1), IBR3, or IBR10 results in IBA resistance, but does not alter IAA response or confer a dependence on exogenous carbon sources for growth following germination (Zolman et al., 2000, 2007, 2008), consistent with the possibility that these enzymes function in IBA β-oxidation but not fatty acid β-oxidation.Both conjugate hydrolysis and IBA β-oxidation appear to be compartmentalized. The IAA-amino acid hydrolases are predicted to be endoplasmic reticulum localized (Bartel and Fink, 1995; Davies et al., 1999) and enzymes required for IBA responses, including IBR1, IBR3, and IBR10, are peroxisomal (Zolman et al., 2007, 2008). Moreover, many peroxisome biogenesis mutants, such as peroxin5 (pex5) and pex7, are resistant to exogenous IBA, but remain IAA sensitive (Zolman et al., 2000; Woodward and Bartel, 2005b).Although the contributions of auxin transport to environmental and developmental auxin responses are well documented (for review, see Petrášek and Friml, 2009), the roles of various IAA precursors in these processes are less well understood. Expansion of root epidermal cells to control root architecture is an auxin-regulated process in which these roles can be dissected. Root epidermal cells provide soil contact and differentiate into files of either nonhair cells (atrichoblasts) or hair cells (trichoblasts). Root hairs emerge from trichoblasts as tube-shaped outgrowths that increase the root surface area, thus aiding in water and nutrient uptake (for review, see Grierson and Schiefelbein, 2002). Root hair length is determined by the duration of root hair tip growth, which is highly sensitive to auxin levels (for review, see Grierson and Schiefelbein, 2002). Mutants defective in the ABCG36/PDR8/PEN3 ABC transporter display lengthened root hairs and hyperaccumulate [³H]IBA, but not [³H]IAA, in root tip auxin transport assays (Strader and Bartel, 2009), suggesting that ABCG36 functions as an IBA effluxer and that IBA promotes root hair elongation. The related ABCG37/PDR9 transporter also can efflux IBA (Strader et al., 2008b; Růžička et al., 2010) and may have some functional overlap with ABCG36 (Růžička et al., 2010). In addition to lengthened root hairs, abcg36/pdr8/pen3 mutants display enlarged cotyledons, a second high-auxin phenotype. Both of these developmental phenotypes are suppressed by the mildly peroxisome-defective mutant pex5-1 (Strader and Bartel, 2009), suggesting that IBA contributes to cell expansion by serving as a precursor to IAA, which directly drives the increased cell expansion that underlies these phenotypes. However, whether IBA-derived IAA contributes to cell expansion events during development of wild-type plants is not known.Here, we directly demonstrate that peroxisome-defective mutants are defective in the conversion of IBA to IAA, consistent with previous reports that these genes are necessary for full response to applied IBA. We found that a mutant defective in three suggested IBA-to-IAA conversion enzymes displays low-auxin phenotypes, including decreased root hair expansion and decreased cotyledon size. We further found that these mutants suppress the long-root-hair and enlarged cotyledon phenotypes of an abcg36/pdr8 mutant, suggesting that endogenous IBA-derived IAA drives root hair and cotyledon expansion in wild-type seedlings.     

Oxidation of Indole-3-Acetic Acid to Oxindole-3-Acetic Acid by an Enzyme Preparation from Zea mays

Indole-3-acetic acid is oxidized to oxindole-3-acetic acid by Zea mays tissue extracts. Shoot, root, and endosperm tissues have enzyme activities of 1 to 10 picomoles per hour per milligram protein. The enzyme is heat labile, is soluble, and requires oxygen for activity. Cofactors of mixed function oxygenase, peroxidase, and intermolecular dioxygenase are not stimulatory to enzymic activity. A heat-stable, detergent-extractable component from corn enhances enzyme activity 6- to 10-fold. This is the first demonstration of the in vitro enzymic oxidation of indole-3-acetic acid to oxindole-3-acetic acid in higher plants.     

Conversion of Indole-3-Acetaldehyde to Indole-3-Acetic Acid in Cell-Wall Fraction of Barley (Hordeum vulgare) Seedlings

The cell-wall fraction of barley seedlings was able to oxidizeindole-3-acetaldehyde (IAAld) to form IAA, whereas the fractiondid not catalyze the conversion of in-dole-3-acetonitrile orindole-3-acetamide to IAA. The activity was lower in a semi-dwarfmutant that had an endogenous IAA level lower than that of thenormal isogenic strain [Inouhe et al. (1982) Plant Cell Physiol.23: 689]. The soluble fraction also contained some activity;the activity was similar in the normal and mutant strains. Theoptimal pH for the conversion of IAAld to IAA in the cell-wallfraction was 7; that of soluble fraction was 6. The K^m valueof the cell-wall fraction for IAAld was 5 µM; that ofsoluble fraction was 31 µM. The activity was not solubi-lizedby treatments with 1% Nonidet P-40,1 M NaCI, 3 M LiCl, or 50mM MgCl2. The oxidation activity was increased by the additionof NAD⁺. These results suggest that IAAld oxidation activityis bound to cell-wall components and that the lower level ofIAA in the mutant probably results from reduced activity ofoxidation enzyme bound to cell-wall components. (Received July 31, 1996; Accepted December 16, 1996)     

Production of the Phytohormone Indole-3-Acetic Acid by Estuarine Species of the Genus Vibrio

Strains of Vibrio spp. isolated from roots of the estuarine grasses Spartina alterniflora and Juncus roemerianus produce the phytohormone indole-3-acetic acid (IAA). The colorimetric Salkowski assay was used for initial screening of IAA production. Gas chromatography-mass spectroscopy (GC-MS) was then employed to confirm and quantify IAA production. The accuracy of IAA quantification by the Salkowski assay was examined by comparison to GC-MS assay values. Indole-3-acetamide, an intermediate in IAA biosynthesis by the indole-3-acetamide pathway, was also identified by GC-MS. Multilocus sequence typing of concatenated 16S rRNA, recA, and rpoA genes was used for phylogenetic analysis of environmental isolates within the genus Vibrio. Eight Vibrio type strains and five additional species-level clades containing a total of 16 environmental isolates and representing five presumptive new species were identified as IAA-producing Vibrio species. Six additional environmental isolates similar to four of the Vibrio type strains were also IAA producers. To our knowledge, this is the first report of IAA production by species of the genus Vibrio or by bacteria isolated from an estuarine environment.Estuaries along the east coast of temperate North America are ecologically valuable, productive systems dominated by only a few species of plants. Spartina alterniflora (smooth cord grass; hereinafter referred to as Spartina) is a keystone species responsible for very high rates of primary production in Atlantic coast marshes and is a major contributor to the global cycling of several elements (10, 14, 15, 35, 38, 39, 45). Juncus roemerianus (black needle rush; hereinafter referred to as Juncus) is a common subdominant species (28) residing in areas of higher elevation, lower salinity, and less frequent tidal inundation. The roots of these macrophytes are associated with a diverse assemblage of microorganisms, including N₂-fixing and sulfate-reducing bacteria, which greatly contribute to their productivity (30, 31).The phytohormone indole-3-acetic acid (IAA) is the most commonly occurring naturally produced auxin and the most thoroughly studied plant growth regulator. IAA directs several aspects of plant growth and development (37), including the induction and regulation of a variety of processes: e.g., cell division, root extension, vascularization, apical dominance, and tropisms (6, 32). The effects of IAA on plant root tissue are concentration dependent and can be species specific. Responses to increasing IAA concentrations advance from the stimulation of primary root tissue to the development of lateral and adventitious roots and finally to the complete cessation of root growth (1, 6, 16, 29, 32, 37, 44).Many microorganisms interact with and affect their environment through the production and transudation of signal compounds (17). The findings of numerous studies (see, e.g., references 8, 23, 25, and 37) demonstrate that a variety of plant-associated terrestrial bacteria produce and exude IAA. Auxin synthesis by cyanobacteria has also been reported previously (40). IAA is thought to reduce the integrity of plant cell walls by upregulating the production of cellulases and hemicelluloses, resulting in the leakage of some simple sugars and other nutrients that would benefit root-associated microorganisms (17). Likewise, root growth would be an advantage to resident bacteria due to the increased availability of root exudates and root surface for growth. Microorganisms that produce IAA can influence the host plant and function as pathogens, symbionts, or growth regulators, depending on how their IAA production influences the concentration of the plant''s endogenous IAA pool and on the sensitivity of the plant to auxin. Organisms such as Erwinia chrysanthemi, Pseudomonas savastanoi, and Agrobacterium tumefaciens are phytopathogens of many host plants (11, 21, 23, 46). Other organisms, including Azospirillum brasilense and Pseudomonas putida GR12-2, have proven beneficial to plants, and many IAA producers have been shown to stimulate increases in root mass and/or length (20, 37, 44).The aim of the present study was to assess IAA synthesis by Vibrio strains isolated from the roots of highly productive salt marsh grasses. The Salkowski assay was used to perform an initial screening for the presence of IAA, gas chromatography-mass spectroscopy (GC-MS) verified and quantified IAA production, and multilocus sequence typing (MLST) analysis classified all isolates within the genus Vibrio.     

Indole-3-Pyruvic Acid as an Intermediate in the Conversion of Tryptophan to Indole-3-Acetic Acid. I. Some Characteristics of Tryptophan Transaminase from Mung Bean Seedlings

Seedlings of mung bean (Phaseolus aureus) contain a soluble enzyme capable of converting l-tryptophan to indole-3-pyruvic acid by transamination. The concentration of the enzyme is highest in the stem meristem and primary leaves and lowest in the roots. The enzyme was purified 28.6 fold by ammonium sulphate precipitation, Sephadex G-200 filtration, and electrophoresis. The isoelectric point of the enzyme protein was pH 6.6. The optimum pH and temperature for the catalytic conversion were ca. 8.5 and 53°C respectively. Using l -tryptophan and α-ketoglutarate as substrates Km was found to be 3.3 × 10^?4 M and the activation energy 18,270 cal per mole. The enzyme converted only the l -form of tryptophan, phenylalanine, tyrosine, and histidine. Out of 13 other l -amino acids tested 8 could be transaminated. Eight α-keto acids tested could all be used as substrates. High efficiency of an α-keto acid as an amino group acceptor agreed usually with high efficiency of the corresponding amino acid as a donor. The pari ß-methyl-α-ketoisovaleric acid and isoleucine was an exception to that rule. Addition of pyridoxalphosphate to the reaction mixture was not needed. The indole-3-pyruvic acid formed in the reaction was trapped and partly stabilized as its borate complex and measured spectrophotometrically at 327 nm. The keto acid formed was further identified by chromatography of its 2,4-dinitrophenylhydrazone in 4 solvent systems. When using α-keto-glutaric acid as a substrate, the glutamic acid produced was determined by the glutamate dehydrogenase method. The sensitivity of the assay permits enzyme determinations in extracts from 5 mg leaves or 100 mg roots.     

Biosynthesis of Indole-3-Acetic Acid from L-Tryptophan in Coleoptile Tips of Maize (Zea mays L.)

Coleoptile tips (about 2.5 mm in length) were excised from 3-day-olddark-adapted maize (Zea mays L.) seedlings and incubated indarkness in potassium phosphate buffer that contained ¹⁴C-L-tryptophan(Trp). Subsequent analysis by gas chromatography-mass spectrometryindicated that a significant portion of endogenous indole-3-aceticacid (IAA) had been labeled with ¹⁴C. About 8% of the IAA thatdiffused from the tissue into the medium during incubation from0.5 to 2 h was labeled, and 12% of the IAA extracted from thetissue after a 2-h incubation was labeled. On the other hand,30% of the Trp extracted from the tissue after a 2-h incubationwas ¹⁴C-Trp, which was more than those determined for IAA. Sincethe experiments were carried out under the non-steady-stateconditions in which the tissue content of ¹⁴C-Trp increasedwith time, and since the extracted Trp included the ¹⁴C-Trpin the apoplastic space, it seemed that synthesis de novo fromTrp was the major means by which IAA was produced in the coleoptiletip. The conversion of Trp to IAA was not detected in sub-apicalsegments (5–7.5 mm from the top) that were incubated similarly,an indication that synthesis of IAA occurs specifically in thetip region. When intact seedlings were irradiated with a pulseof red light 2 h before excision of tips and the applicationof ¹⁴C-Trp, the amounts of extractable and diffusible IAA werereduced by 40–60% without a change in the rate of ¹⁴Cincorporation. This result indicated that the production ofIAA from Trp is controlled by a red-light signal. (Received May 15, 1995; Accepted September 1, 1995)     

Metabolism of Indole-3-Acetic Acid in Arabidopsis

The metabolism of indole-3-acetic acid (IAA) was investigated in 14-d-old Arabidopsis plants grown in liquid culture. After ruling out metabolites formed as an effect of nonsterile conditions, high-level feeding, and spontaneous interconversions, a simple metabolic pattern emerged. Oxindole-3-acetic acid (OxIAA), OxIAA conjugated to a hexose moiety via the carboxyl group, and the conjugates indole-3-acetyl aspartic acid (IAAsp) and indole-3-acetyl glutamate (IAGlu) were identified by mass spectrometry as primary products of IAA fed to the plants. Refeeding experiments demonstrated that none of these conjugates could be hydrolyzed back to IAA to any measurable extent at this developmental stage. IAAsp was further oxidized, especially when high levels of IAA were fed into the system, yielding OxIAAsp and OH-IAAsp. This contrasted with the metabolic fate of IAGlu, since that conjugate was not further metabolized. At IAA concentrations below 0.5 μm, most of the supplied IAA was metabolized via the OxIAA pathway, whereas only a minor portion was conjugated. However, increasing the IAA concentrations to 5 μm drastically altered the metabolic pattern, with marked induction of conjugation to IAAsp and IAGlu. This investigation used concentrations for feeding experiments that were near endogenous levels, showing that the metabolic pathways controlling the IAA pool size in Arabidopsis are limited and, therefore, make good targets for mutant screens provided that precautions are taken to avoid inducing artificial metabolism.The plant hormone IAA is an important signal molecule in the regulation of plant development. Its central role as a growth regulator makes it necessary for the plant to have mechanisms that strictly control its concentration. The hormone is believed to be active primarily as the free acid, and endogenous levels are controlled in vivo by processes such as synthesis, oxidation, and conjugation. IAA has been shown to form conjugates with sugars, amino acids, and small peptides. Conjugates are believed to be involved in IAA transport, in the storage of IAA for subsequent use, in the homeostatic control of the pool of the free hormone, and as a first step in the catabolic pathways (Cohen and Bandurski, 1978; Nowacki and Bandurski, 1980; Tuominen et al., 1994; Östin et al., 1995; Normanly, 1997). It is generally accepted that in some species conjugated IAA is the major source of free IAA during the initial stages of seed germination (Ueda and Bandurski, 1969; Sandberg et al., 1987; Bialek and Cohen, 1989), and there is also evidence that in some plants (but not all; see Bialek et al., 1992), the young seedling is entirely dependent on the release of free IAA from conjugated pools until the plant itself is capable of de novo synthesis (Epstein et al., 1980; Sandberg et al., 1987).The function of conjugated IAA during vegetative growth is somewhat less clear. It has been shown that conjugated IAA constitutes as much as 90% of the total IAA in the plant during vegetative growth (Normanly, 1997). However, the role of the IAA conjugates at this stage of the plant''s life cycle remains unknown. Analysis of endogenous IAA conjugates in vegetative tissues has revealed the presence of a variety of different compounds, including indole-3-acetyl-inositol, indole-3-acetyl-Ala, IAAsp, and IAGlu (Anderson and Sandberg, 1982; Cohen and Baldi, 1983; Chisnell, 1984; Cohen and Ernstsen, 1991; Östin et al., 1992). Studies of vegetative tissues have indicated that IAAsp, one of the major conjugates in many plants, is the first intermediate in an irreversible deactivation pathway (Tsurumi and Wada, 1986; Tuominen et al., 1994; Östin, 1995). Another mechanism that is believed to be involved in the homeostatic control of the IAA pool is catabolism by direct oxidation of IAA to OxIAA, which has been shown to occur in several plant species (Reinecke and Bandurski, 1983; Ernstsen et al., 1987).One area in the study of IAA metabolism in which our knowledge is increasing is the analysis of the homeostatic controls of IAA levels in plants. It has been possible, for instance, to increase the levels of IAA in transgenic plants expressing iaaM and iaaH genes from Agrobacterium tumefaciens. Analysis of these transgenic plants has indicated that plants have several pathways that can compensate for the increased production of IAA (Klee et al., 1987; Sitbon, 1992). It is expected that future studies using now-available genes will provide further insight into IAA metabolism. For example, a gene in maize encoding IAA-Glc synthetase has been identified, and several genes (including ILR1, which may be involved in hydrolysis of the indole-3-acetyl-Leu conjugate) have been cloned from Arabidopsis (Szerszen et al., 1994; Bartel and Fink, 1995). Furthermore, Chou et al. (1996) identified a gene that hydrolyzes the conjugate IAAsp to free IAA in the bacterium Enterobacter aggloremans.Because of its small genome size, rapid life cycle, and the ease of obtaining mutants, Arabidopsis is increasingly used as a genetic model system to investigate various aspects of plant growth and development. IAA signal transduction is also being investigated intensively in Arabidopsis in many laboratories (Leyser, 1997). Mutants with altered responses to externally added auxins or IAA conjugates have been identified in Arabidopsis. The identified mutants are either signal transduction mutants such as axr1-4 (Lincoln et al., 1990), or have mutations in genes involved in auxin uptake or transport, such as aux1 and pin1 (Okada et al., 1991; Bennett et al., 1996). A few mutants that are unable to regulate IAA levels or are unable to hydrolyze IAA conjugates, sur1-2 and ilr1, respectively, have also been identified (Bartel and Fink, 1995; Boerjan et al., 1995). To our knowledge, no mutant that is auxotrophic for IAA has been identified to date, which may reflect the redundancy in IAA biosynthetic pathways or the lethality of such mutants.In spite of the work reported thus far, many aspects of the metabolism of IAA in Arabidopsis require further investigation, because few details of the processes involved in IAA regulation are known. This lack of knowledge puts severe constraints on genetic analysis of IAA metabolism in Arabidopsis. For example, it is essential to have prior knowledge of IAA metabolism to devise novel and relevant screens with which to identify mutants of IAA metabolism. We have sought to address this issue by identifying the metabolic pathways involved in catabolism and conjugation under conditions that minimally perturb physiological processes. In this investigation we studied the conjugation and catabolic pattern of IAA by supplying relatively low levels of labeled IAA and identifying the catabolites and conjugates by MS. Different feeding systems were tested to optimize the application of IAA and to avoid irregularities in metabolism attributable to culturing, feeding conditions, or microbial activity. It is well documented that IAA metabolism is altered according to the amount of exogenous auxin applied; therefore, we placed special emphasis on distinguishing between catabolic routes that occur at near-physiological concentrations and those that occur at the high auxin concentrations commonly used in mutant screens.     

Enhancement of Indole-3-Acetic Acid Photodegradation by Vitamin B6

Dear Editor, The plant hormone indole-3-acetic acid （IAA） has long been used in plant culture media for practical applications and sci- entific inquiries. The use of IAA is complicated by the fact that IAA is a photo-labile compound. In Murashige and Skoog （MS） plant media （Murashige and Skoog, 1962）, the concen- trations of salts and mineral nutrients are known to hasten the photodegradation of IAA under white light （Dunlap and Robacker, 1988）. This degradation can be virtually eliminated by the use of a yellow-colored light filter that removes UV, violet, and some of the blue wavelengths from the incident light （Stasinopoulos and Hangarter, 1990）. However, the use of yellow light clearly affects the quality of light that the plants under study receive. In addition to applications in plants, IAA has been used in human health applications.     

Indole-3-Pyruvic Acid as an Intermediate in the Conversion of Tryptophan to Indole-3-Acetic Acid. II. Distribution of Tryptophan Transaminase Activity in Plants

Extracts from different organs of 30 plant species belonging to 16 families have been analysed for tryptophan transaminase activity. Only the brown alga Fucus spiralis was found to be devoid of the enzymes. Among the other plants tested, a difference in activity of two orders of magnitude was recorded. None of the genera or families investigated could be considered as particularly rich or poor sources of the enzyme. Extracts from leaves and stem tips contained generally more transaminase activity than extracts from stems and roots. The results are discussed in relation to other reports on the occurrence of the enzyme in plants.     

Quantitative Analysis of Indole-3-Acetic Acid Metabolites in Arabidopsis

A general gas chromatography/mass spectrometry (MS)-based screen was performed to identify catabolites and conjugates of indole-3-acetic acid (IAA) during vegetative growth of Arabidopsis. This experiment revealed the existence of two new conjugates: N-(indole-3-acetyl)-alfa-alanine (IA-Ala) and N-(indole-3-acetyl)-alfa-leucine (IA-Leu). A method for quantitative analysis of IAA metabolites in plant extracts by liquid chromatography-electrospray tandem MS has been developed. The accuracy and precision of the new method are better than 10% for standards close to the detection limit, and are between 6% and 16% for the entire protocol applied to plant extracts. The low detection limits, 0.02 to 0.1 pmol for the different metabolites, made it possible to use as little as 50 to 100 mg of tissue for quantitative analysis. The analysis was performed on different tissues of an Arabidopsis plant at two stages of development, using heavy labeled internal standards of the catabolite 2-oxoindole-3-acetic acid as well as IAA conjugated to amino acids: aspartate, glutamate, Ala, and Leu. Expanding leaves and roots that generally contain high amounts of the free hormone also contained the highest levels of IA-aspartate, IA-glutamate, and 2-oxoindole-3-acetic acid, supporting their role as irreversible catabolic products. The levels of IA-Leu and IA-Ala did not follow the general distribution of IAA. Interestingly, the level of IA-Leu was highest in roots and IA-Ala in the aerial tissues.     

Immuno-Gold Localization of Indole-3-Acetic Acid in Peach Seedlings

The localization of indole-3-acetic acid (IAA) in peach seedlings(Prunus persica [L.] Batsch ‘Momo Daigi Tsukuba 4’)was investigated using immunocytochemical technique. In meristematiccells of root tip, the gold particles were accumulated in nucleolus,while in leaf cells, they were mainly associated to chloroplastsand mitochondria. Physiological meaning of these localizationswas discussed. (Received December 13, 1989; Accepted April 12, 1990)     

Indole-3-Acetic Acid (IAA) Oxidation by Leghemoglobin form Soybean

Leghemoglobin from nudules of soybean prepated by ammonium sulfate frationation appeared to be able to destroy substantial quantities of IAA, Degradation still occurred in purified leghemoglobin preparations isolated by G-100 Sephadex chromatography. Nicotinic acid and acetate affecting the conformation of leghemoglobin both inhibited IAA oxidation by this hemoprotein. The ferric form was found to be the most active in this catabolism. This oxication, related to the psedudoperocidase activity of leghemoghlobin, is undoubtedly restricted in vivo by the very low level of the ferric form present in efficient nodules.     

The Identification of Indole-3-Acetic Acid and Indole-3-Acetamide in the Hypocotyls of Japanese Cherry

Both indole-3-acetamide (IAM) and indole-3-acetic acid (IAA)were identified in extracts of the hypocotyls of Japanese cherryby GC/MS. Exogenous IAA and IAM promoted the elongation of segmentsof these hypocotyls and the effect of IAA applied together withIAM was the same as that of IAA alone. (Received July 29, 1992; Accepted October 19, 1992)     

Translocation of Radiolabeled Indole-3-Acetic Acid and Indole-3-Acetyl-myo-Inositol from Kernel to Shoot of Zea mays L.

Either 5-[³H]indole-3-acetic acid (IAA) or 5-[³H]indole-3-acetyl-myo-inositol was applied to the endosperm of kernels of dark-grown Zea mays seedlings. The distribution of total radioactivity, radiolabeled indole-3-acetic acid, and radiolabeled ester conjugated indole-3-acetic acid, in the shoots was then determined. Differences were found in the distribution and chemical form of the radiolabeled indole-3-acetic acid in the shoot depending upon whether 5-[³H]indole-3-acetic acid or 5-[³H]indole-3-acetyl-myo-inositol was applied to the endosperm. We demonstrated that indole-3-acetyl-myo-inositol applied to the endosperm provides both free and ester conjugated indole-3-acetic acid to the mesocotyl and coleoptile. Free indole-3-acetic acid applied to the endosperm supplies some of the indole-3-acetic acid in the mesocotyl but essentially no indole-3-acetic acid to the coleoptile or primary leaves. It is concluded that free IAA from the endosperm is not a source of IAA for the coleoptile. Neither radioactive indole-3-acetyl-myo-inositol nor IAA accumulates in the tip of the coleoptile or the mesocotyl node and thus these studies do not explain how the coleoptile tip controls the amount of IAA in the shoot.     

Enhancement of Enzymatic Synthesis of Citrate in vitro by Indole-3-Acetic Acid

Indoleacetic acid in physiological concentrations was shown to enhance the synthesis of citiate by purified citrate condensing enzyme from castor beans and pig heart. Michaelis constants reveal that with indoleacetic acid in the reaction mixture a higher concentration of acetyl-CoA was necessary to give maximal velocity. V values with indoleacetic acid in the reaction (physiological concentrations) exceeded V without indoleacetic acid in reaction. Citric acid synthesized from ¹⁴C acetyl CoA was highly radioactive when indoleacetie acid was present in the reaction, indicating that indoleacetic acid did in fact enhance the synthesis. The data were discussed from the point of view that these studies may provide the basis for studies directed at ultimate understanding of the mechanism of action of indoleacetic acid.     

Enhancement of Lipid Peroxidation by Indole-3-Acetic Acid and Derivatives: Substituent Effects

The peroxidation of liposomes by a haem peroxidase and hydrogen peroxide in the presence of indole-3-acetic acid and derivatives was investigated. It was found that these compounds can accelerate the lipid peroxidation up to 65 fold and this is attributed to the formation of peroxyl radicals that may react with the lipids, possibly by hydrogen abstraction. The peroxyl radicals are formed by peroxidase-catalyzed oxidation of the enhancers to radical cations which undergo cleavage of the carbon-carbon bond on the side-chain to yield CO2 and carbon-centred radicals that rapidly add oxygen. In competition with decarboxylation, the radical cations deprotonate reversibly from the Nl position. Rates of decarboxylation,pK_a values and rate of reaction with the peroxidase compound I indicate consistent substituent effects which, however, can not be quantitatively related to the usual Hammett or Brown parameters. Assuming that the rate of decarboxylation of the radical cations taken is a measure of the electron density of the molecule (or radical), it is found that the efficiency of these compounds as enhancers of lipid peroxidation increases with increasing electron density, suggesting that, at least in the model system, the oxidation of the substrates is the limiting step in causing lipid peroxidation.