Bound auxin metabolism in cultured crown-gall tissues of tobacco

Bound auxin metabolism in cultured crown-gall tumor cells and pith callus of tobacco was examined by feeding radiolabeled auxins and auxin conjugates. In all tissues fed [¹⁴C]indoleacetic acid (IAA), at least one-third of the IAA was decarboxylated, and most of the remaining radiolabel occurred in a compound(s) which did not release IAA with alkaline hydrolysis. In cells transformed by the A6 strain of Agrobacterium tumefaciens, the only detectable IAA conjugate was indole-3-acetylaspartic acid (IAAsp), whereas cells transformed by the gene 2 mutant strain A66 produced an unidentified amide conjugate but no IAAsp. By contrast, cells fed [¹⁴C]naphthaleneacetic acid (NAA) accumulated several amide and ester conjugates. The major NAA metabolite in A6-transformed cells was naphthaleneacetylaspartic acid (NAAsp), whereas the major metabolites in A66-transformed cells were NAA esters. In addition, A66-transformed cells produced an amide conjugate of NAA which was not found in A6-transformed cells and which showed chromatographic properties similar to the unknown IAA conjugate. Pith callus fed [¹⁴C] NAA differed from both tumor lines in that it preferentially accumulated amide conjugates other than NAAsp. Differences in the accumulation of IAA and NAA conjugates were attributed in part to the high capacity of tobacco cells to oxidize IAA and in part to the specificity of bound auxin hydrolases. All tissues readily metabolized IAAsp and indole-3-acetyl-myo-inositol, but hydrolyzed NAAsp very slowly. Indirect evidence is provided which suggests that ester conjugates of NAA are poorly hydrolyzed as well. Analysis of tissues fed [¹⁴C]NAA together with high concentrations of unlabeled IAA or NAA indicates that tissue-specific differences in NAA metabolism were not the result of variation in endogenous auxin levels. Our results support the view that bound auxin hydrolysis is highly specific and an important factor controlling bound auxin accumulation.     

Indole-3-acetic acid determination in cultured crown-gall and genetic tumour tissues by gas chromatography-mass spectrometry

Indole-3-acetic acid (IAA) was identified and quantified in three cultured tumour lines, which included crown-gall tissue of Datura (25.4 ng/g fresh wt.) and two genetic tumour lines of tobacco (4.6 and 8.0 ng/g fresh wt.). The analysis was carried out using a stable isotope dilution assay in combination with gas chromatography-mass spectrometry. This is the first unambiguous determination of endogenous IAA in genetic tumour tissues.     

Polar transport and content of indole-3-acetic acid in wounded sweet potato root tissues

In roots of sweet potato (Ipomoea batatas Lam. cv. Kokei 14),the metabolic response to wounding was remarkable in the proximalside and developed in the acropetal direction. We assumed thatthe polarity resulted from the increase in polar movement ofindoleacetic acid (IAA) (1977, Plant Physiol. 60: 563–566).Transport of IAA and change of the IAA level in the woundedtissue of sweet potato roots were investigated. Transport ofthe label from ¹⁴C-IAA was obviously polarized in the acropetaldirection. ¹⁴C-IAA administered to the wounded tissue was mainlymetabolized into two conjugates of IAA. The amount of IAA inthe wounded tissue, determined by the spectrofluorometric method,increased about 3-fold after 18 hr of incubation prior to thedevelopment of activities of some enzymes. The increase in IAAcontent was not affected with aseptic incubation, therefore,the possibility of IAA production by microorganisms on the woundedtissue was excluded. The results obtained strongly support ourhypothesis that IAA plays an important role in the metabolicresponse to wounding. (Received May 2, 1979; )     

A specific radioimmunoassay for nanogram quantities of the auxin,indole-3-acetic acid

We have developed a specific radioimmunoassay [RIA] for indole-3-acetic acid (IAA) in the 0.2 ng to 12 ng range which, in principle, can be extended to other indole auxins as well. Methods are presented for obtaining suitable antibody, for the RIA procedure, and for measuring IAA in methanolic extracts of plant tissues. Antibody specific for IAA was obtained from rabbits immunized with IAA bound to bovine serum albumin by formaldehyde treatment. In assays with this antibody, 2,4-dichlorophenoxyacetic acid and indoles structurally related to IAA reacted from 300- to 3000-fold less than did IAA itself. However, -and -naphthaleneacetic acid reacted significantly and hence interfered with the assay. Extracts of tobacco (Nicotiana tabacum L.) tissue were immunoassayed after partial purification by buffer-ether partition. Crown-gall tumor tissue, which is auxin-autotrophic, and pith tissue depleted of auxin by the diffusion method contained, respectively, 26.7 ng and <0.5 ng extractable IAA per gram fresh weight.Abbreviations BSA bovine serum albumin - 2,4-D 2,4-dichlorophenoxyacetic acid - IAA indole-3-acetic acid - -NAA -naphthalenacetic acid - PBS phosphate-buffered saline - RIA radioimmunoassay     

Channelling auxin action: modulation of ion transport by indole-3-acetic acid

The growth hormone auxin is a key regulator of plant cell division and elongation. Since plants lack muscles, processes involved in growth and movements rely on turgor formation, and thus on the transport of solutes and water. Modern electrophysiological techniques and molecular genetics have shed new light on the regulation of plant ion transporters in response to auxin. Guard cells, hypocotyls and coleoptiles have advanced to major model systems in studying auxin action. This review will therefore focus on the molecular mechanism by which auxin modulates ion transport and cell expansion in these model cell types.     

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.     

Structural characterization and auxin properties of dichlorinated indole-3-acetic acids

The dichlorinated indole-3-acetic acids: 4,5-Cl2-IAA, 4,6-Cl2-IAA, 4,7-Cl2-IAA, 5,6-Cl2-IAA, 5,7-Cl2-IAA and 6,7-Cl2-IAA were synthesized and characterized by X-ray structure analysis to unambiguously identify the substances for bioassays required to establish structure activity relationships of auxins and their analogues. Straight-growth tests were performed on Avena sativa coleoptiles to correlate their auxin activity with molecular properties which could reveal information on the topology of the auxin binding site. Structure/activity correlations revealed that the 5,6-Cl2-IAA molecule, by virtue of its size and shape, fits particularly well into the active site cavity of the receptor protein. The main contact of the substrate or inhibitor in the receptor active site via the carboxylic group determines their orientation in the active site cavity. As a consequence, the 5,6-substituted sites protrude into the widest part of the active site whereas the 7-, 4-, and 5-substituted sites are oriented towards the narrowest part of the active site. These topological parameters are in agreement with the high auxin activity of 5,6-Cl2-IAA and the low activity of 4,7-Cl2-IAA.     

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.     

Excitation of indole-3-acetic acid (an auxin) in a linoleate-lipoxygenase system.

The weak luminescence that accompanies the linoleate-lipoxygenase reaction was greatly enhanced by the addition of indole analogues, and especially indole acetic acid. The main emitting species in the indole acetic acid-linoleate-lipoxygenase system was analysed spectrophotometrically in the visible region and ascribed to the transition of excited indole acetate in triplet state to its ground state. Such an excited indole acetate could be generated by transfer of energy from the excited CO2 and excited carbonyl (generated by the linoleate-lipoxygenase reaction) to indole acetate in the ground state, but not by cleavage of the dioxetane analog (positions 2 and 3 on the indole ring).     

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.     

Effects of cytokinins on the auxin requirement and auxin content of tobacco calluses

High concentrations (0.1–1 mg/liter) of kinetin permittedcontinuous growth of auxin-requiring and cytokinin-nonrequiringtobacco calluses on a medium without auxin. This effect of kinetindid not seem to be due to perpetuating change in the tissuecharacter, because tissue was auxin-requiring when returnedto a kinetin free medium. Cytokinins, i.e. benzylaminopurineand geranylaminopurine, showed the same effect as kinetin inmaking auxin-requiring calluses grow without a supply of auxin. In auxin-requiring and cytokinin-nonrequiring calluses subculturedfor 3 years on a medium containing 1 mg/liter kinetin withoutauxin, at least 3 auxins were detected by bioassay; 2 in theacidic and 1 in the neutral fraction. One was identified asIAA by paper chromatography (bioassay), thin-layer chromatographyand gas chromatography. Reduced or no auxin activity was foundin calluses transferred to a medium without kinetin. Kinetinwas apparently required to maintain the endogenous auxin levelin callus tissues. Kinetin may act on the auxin requirement of callus via its effectson auxin metabolism. ¹ Part XVI in the series "Studies on Plant Tissue Cultures". (Received April 11, 1972; )     

Changes in indole-3-acetic acid,indole-3-acetic acid oxidase,and peroxidase isoenzymes in the seeds of developing peach fruits

Changes in indole-3-acetic acid (IAA) content of peach (Prunus persica L. Batsch cv. Merry) seeds were followed during fruit development. The highest concentration of IAA, 2.7 g/g fresh weight, was found at the beginning of Stage III of fruit development, approximately 50–60 days after anthesis. The IAA-decarboxylating capacity of crude extracts of seeds was also greatest at 55–60 days after anthesis. Four soluble peroxidase isoenzymes were found on anionic electrophoresis. There were no marked changes in two isoenzymes (R _f 0.23 and 0.51), which were present in all three stages of fruit growth. There was a marked increase in a band atR _f 0.59 between Stages II and III, and a decrease in a band atR _f 0.68 from Stages II to III. Neither band (R _f 0.59 and 0.68) was present at Stage I.     

Influence of indole-3-acetic acid,kinetin and abscisic acid on the estrogens content of beans

No influence of IAA on the endogenous estrogen content in bean plants was stated. At the same time kinetin was found to increase and abscisic acid to decrease the amounts of estrogens.     

Comparison of growth,exogenous auxin sensitivity,and endogenous indole-3-acetic acid content in roots ofHordeum vulgare L. and an agravitropic mutant

The chemically induced barley (Hordeum vulgare L.) mutation, agr, was found to be a simple recessive trait resulting in agravitropic roots and normal gravitropic shoots. The total seedling root growth was similar for mutant and wild-type roots, although the mutant had fewer roots per seed and greater elongation per root. Although the concentration of exogenous indole-3-acetic acid (IAA) required to reduce root growth by 50% (GR50) was 12 times greater for the agravitropic mutant, agravitropic and gravitropic roots were equally sensitive to exogenous applications of 2,4-dichlorophenoxyacetic acid (2,4-D) and naphthalene acetic acid (NAA). Root IAA contents, determined by high-pressure liquid chromatography (HPLC), were not different for gravitropes and agravitropes. The greater root elongation rates, lack of sensitivity to exogenous IAA, and normal endogenous IAA levels indicate that auxin-controlled growth regulation may be altered in the mutant.     

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.