Brassinolide-induced elongation and auxin

Segments from the hook and subhook zone of the stem of 6-day-old etiolated Pisum sativum L. cv. Victory Freezer seedlings were used to study the relationship between brassinolide and auxin in the promotion of elongation. Minor changes in exogenous indole-3-acetic acid or4-chloroindole-3-acetic acid concentration affected the kinetics markedly and the ethylene generator ethephon overcame brassinolide-induced elongation in an antagonistic interaction. Brassinolide-induced elongation was markedly inhibited by low concentrations of the cellulose biosynthesis inhibitor 2,6-dichlorobenzonitrile, and diagnostic concentrations of the antiauxin 2-( p -chlorophenoxy) isobutyric acid did not affect brassinolide-induced elongation. As the characteristics of auxin-induced growth are not displayed in brassinolide-induced elongation of the upper stem segment, it is proposed that brassinolide does not depend on auxin as a mediator in the promotion of elongation of younger tissues but that it can interact in a very complex manner with auxin. In the elongation of more mature tissues, and in bending responses, brassinolide probably accelerates auxin effects. When split, the upper stem segment was unusual in its lack of specific response to growth regulators, and the slight relief of epidermal tension.     

(+)-5-Hydroxy-dioxindole-3-acetic acid,a synergist from rice bran of auxin-induced ethylene production in plant tissue

(+)-5-Hydroxy-dioxindole-3-acetic acid (1) was isolated from rice bran as a substance synergistic with auxin in the auxin induced ethylene production by etiolated mungbean hypocotyl segments. 5-Hydroxy-oxindole-3-acetic acid (4) and IAA were also obtained. The importance of a hydroxyl group in the 5-position in the two compounds was suggested since synthesized (±)-dioxindole-3-acetic acid (6) was inactive.     

生长素合成途径的研究进展

生长素是一类含有一个不饱和芳香族环和一个乙酸侧链的内源激素, 参与植物生长发育的许多过程。植物和一些侵染植物的病原微生物都可以通过改变生长素的合成来调节植株的生长。吲哚-3-乙酸(IAA)是天然植物生长素的主要活性成分。近年来, 随着IAA生物合成过程中一些关键调控基因的克隆和功能分析, 人们对IAA的生物合成途径有了更加深入的认识。IAA的生物合成有依赖色氨酸和非依赖色氨酸两条途径。依据IAA合成的中间产物不同, 依赖色氨酸的生物合成过程通常又划分成4条支路: 吲哚乙醛肟途径、吲哚丙酮酸途径、色胺途径和吲哚乙酰胺途径。该文综述了近几年在IAA生物合成方面取得的新进展。     

Arabidopsis Seedlings Over-Accumulated Indole-3-acetic Acid in Response to Aminooxyacetic Acid

Previously we identified aminooxy compounds as auxin biosynthesis inhibitors. One of the compounds, aminooxyacetic acid (AOA) inhibited indole-3-acetic acid (IAA) biosynthesis in rice and tomato. Here, we found that AOA induced auxin over-accumulation in Arabidopsis. The results suggest that auxin-related metabolic pathways are divergent among these plant species.     

An NMR method for the study of proton transport across phospholipid vesicles

We have identified [1-¹⁴C]-oxindole-3-acetic acid as a catabolic product of [1-¹⁴C]-indole-3-acetic acid metabolism in Zea mays seedlings. The isolation, and chemical and mass spectral characterization of oxindole-3-acetic acid from corn kernel tissue is described together with data suggesting oxindole-3-acetic acid to be a major catabolic product of indole-3-acetic acid.     

Promotion of stem elongation by indole-3-butyric acid in intact plants of Pisum sativum L.

While indole-3-butyric acid (IBA) has been confirmed to be an endogenous form of auxin in peas, and may occur in the shoot tip in a level higher than that of indole-3-acetic acid (IAA), the physiological significance of IBA in plants remains unclear. Recent evidence suggests that endogenous IAA may play an important role in controlling stem elongation in peas. To analyze the potential contribution of IBA to stem growth we determined the effectiveness of exogenous IBA in stimulating stem elongation in intact light-grown pea seedlings. Aqueous IBA, directly applied to the growing internodes via a cotton wick, was found to be nearly as effective as IAA in inducing stem elongation, even though the action of IBA appeared to be slower than that of IAA. Apically applied IBA was able to stimulate elongation of the subtending internodes, indicating that IBA is transported downwards in the stem tissue. The profiles of growth kinetics and distribution suggest that the basipetal transport of IBA in the intact plant stem is slower than that of IAA. Following withdrawal of an application, the residual effect of IBA in growth stimulation was markedly stronger than that of IAA, which may support the notion that IBA conjugates can be a better source of free auxin through hydrolysis than IAA conjugates. It is suggested that IBA may serve as a physiologically active form of auxin in contributing to stem elongation in intact plants.     

Auxin biosynthesis in maize

For the biosynthesis of the phytohormone indole-3-acetic acid (IAA), a number of tryptophan-dependent and -independent pathways have been discussed. Maize is an appropriate model system to analyze IAA biosynthesis particularly because high quantities of IAA conjugates are stored in the endosperm. This allowed precursor feeding experiments in a kernel culture system followed by retrobiosynthetic NMR analysis, which strongly suggested that tryptophan-dependent IAA synthesis is the predominant route for auxin biosynthesis in the maize kernel. Two nitrilases ZmNIT1 and ZmNIT2 are expressed in seeds. ZmNIT2 efficiently hydrolyzes indole-3-acetonitrile (IAN) to IAA and thus could be involved in auxin biosynthesis. Redundant pathways, e.g., via indole-3-acetaldehyde could imply that multiple mutants will be necessary to obtain IAA-deficient plants and to conclusively identify relevant genes for IAA biosynthesis.     

Many roads lead to "auxin": of nitrilases, synthases, and amidases

Recent progress in understanding the biosynthesis of the auxin, indole-3-acetic acid (IAA) in Arabidopsis thaliana is reviewed. The current situation is characterized by considerable progress in identifying, at the molecular level and in functional terms, individual reactions of several possible pathways. It is still too early to piece together a complete picture, but it becomes obvious that A. thaliana has multiple pathways of IAA biosynthesis, not all of which may operate at the same time and some only in particular physiological situations. There is growing evidence for the presence of an indoleacetamide pathway to IAA in A. thaliana, hitherto known only from certain plant-associated bacteria, among them the phytopathogen Agrobacterium tumefaciens.     

Dynamics of the concentration of IAA and some of its conjugates during the induction of somatic embryogenesis in Coffea canephora

Most of the somatic embryogenesis (SE) process requires the presence, either before or during the embryogenic process, of at least one exogenous auxin. This exogenous auxin induces the presence of endogenous auxins, which appears to be essential for SE induction. We found that during the preincubation period of SE in Coffea canephora, there is an important increase in both free and conjugated indole-3-acetic acid (IAA), as well as indole-3-butyric acid. This increase is accompanied by an increase in the expression of YUCCA (CcYUC), TRYPTOPHAN AMINOTRANSFERASE OF ARABIDOPSIS 1 (CcTAA1), and GRETCHEN HAGEN 3 (GH3) genes. On the other hand, most of the IAA compounds decreased during the induction of SE. The results presented in this research suggest that a balance between free IAA and its amide conjugates is necessary to allow the expression of SE-related genes.     

Current aspects of auxin biosynthesis in plants

Auxin is an important plant hormone essential for many aspects of plant growth and development. Indole-3-acetic acid (IAA) is the most studied auxin in plants, and its biosynthesis pathway has been investigated for over 70 years. Although the complete picture of auxin biosynthesis remains to be elucidated, remarkable progress has been made recently in understanding the mechanism of IAA biosynthesis. Genetic and biochemical studies demonstrate that IAA is mainly synthesized from l-tryptophan (Trp) via indole-3-pyruvate by two-step reactions in Arabidopsis. While IAA is also produced from Trp via indole-3-acetaldoxime in Arabidopsis, this pathway likely plays an auxiliary role in plants of the family Brassicaceae. Recent studies suggest that the Trp-independent pathway is not a major route for IAA biosynthesis, but they reveal an important role for a cytosolic indole synthase in this pathway. In this review, I summarize current views and future prospects of IAA biosynthesis research in plants.     

Tryptophan-dependent biosynthesis of auxins in soil

The presence of auxins in soil may have an ecological impact affecting plant growth and development. A rapid and simple colorimetric method was used to assess California soils for their potential to produce auxins upon the addition of L-tryptophan (L-TRP). The auxin content measured by colorimetry was expressed as indole-3-acetic acid (IAA)-equivalents. A substrate (L-TRP) concentration of 5.3 g kg^-1, glucose concentration of 6.7 g kg^-1, no nitrogen, pH 7.0, 40°C, shaking (aeration) and 48 h incubation time were selected as standardized conditions to assay for auxin biosynthesis in soil. IAA was confirmed as a major microbial metabolite derived from L-TRP in soil by use of high performance liquid chromatography (HPLC). Under standardized conditions, L-TRP-derived auxins in 19 soils varied greatly ranging from 18.2 to 303.2 mg IAA equivalents (auxins) kg^-1 soil. This study suggests that the phenotypic character of the soil microbiota has more of an influence on auxin production than the soil physicochemical properties (e.g., pH, organic C content, CEC, etc.).     

ILR2, a novel gene regulating IAA conjugate sensitivity and metal transport in Arabidopsis thaliana

Plants can regulate levels of the auxin indole-3-acetic acid (IAA) by conjugation to amino acids or sugars, and subsequent hydrolysis of these conjugates to release active IAA. These less active auxin conjugates constitute the majority of IAA in plants. We isolated the Arabidopsis ilr2-1 mutant as a recessive IAA-leucine resistant mutant that retains wild-type sensitivity to free IAA. ilr2-1 is also defective in lateral root formation and primary root elongation. In addition, ilr2-1 is resistant to manganese- and cobalt-mediated inhibition of root elongation, and microsomal preparations from the ilr2-1 mutant exhibit enhanced ATP-dependent manganese transport. We used a map-based positional approach to clone the ILR2 gene, which encodes a novel protein with no predicted membrane-spanning domains that is polymorphic among Arabidopsis accessions. Our results demonstrate that ILR2 modulates a metal transporter, providing a novel link between auxin conjugate metabolism and metal homeostasis.     

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.     

Phototropic stimulation does not induce unequal distribution of indole-3-acetic acid in maize coleoptiles

Distribution of endogenous diffusible auxin into agar blocks from phototropically stimulated maize coleoptile tips was studied using a bioassay and a physicochemical assay, to clarify whether phototropism in maize coleoptiles involves a lateral gradient in the amount of auxin. At 50 min after the onset of phototropic stimulation, when the phototropic response was still developing, direct assay of the blocks with the Avena curvature test showed that the auxin activity in the blocks from the shaded half-tips was twice that of the lighted side, at both the first and second positive phototropic curvatures. However, physicochemical determination following purification showed that the amount of indole-3-acetic acid (IAA) was evenly distributed in the blocks from lighted and shaded coleoptile half-tips at both the first and second positive phototropic curvatures. The even distribution of the IAA was also confirmed with the Avena curvature test following purification by HPLC. These results indicate that phototropism in maize coleoptiles is not caused by a lateral gradient of IAA itself and thus cannot be described by the Cholodny-Went theory. Furthermore, the lower auxin activity in the blocks from the lighted half-tips suggests the presence of inhibitor(s) interfering with the action of auxin and their significant diffusion from unilaterally illuminated coleoptile tips.     

Regulation of cell wall synthesis by auxin and fusicoccin in different tissues of pea stem segments

Cell wall synthesis was studied by determining the incorporation of [¹⁴C]-glucose into epidermal and cortical cell walls of etiolated Pisum sativum L. cv. Alaska stem segments. Walls were fractionated into the matrix and cellulose components, and incorporation into these components assessed in terms of the total uptake of label into that tissue. When segments were allowed to elongate, the stimulation of total glucose uptake by indole-3-acetic acid (IAA) and fusicoccin (FC) was greater than their stimulation of incorporation. IAA and FC thus did not stimulate precursor incorporation in elongating segments. When elongation was inhibited by calcium, however, IAA and FC significantly promoted wall synthesis in the cortex and vasular tissue (which shows almost no growth or acidification response to auxin). In these tissues incorporation into matrix and cellulose was promoted approximately equally. In the epidermis (thought to be the tissue responsive to auxin in the control of growth), FC promoted a significant increase in wall synthesis, although less than that in the cortex, while there was some evidence of a similar promotion by IAA. Both IAA and FC had a greater effect on incorporation into the matrix component of the wall than into cellulose. The results that FC caused a substantial promotion of cell wall synthesis which was not due solely to elongation, and that the inner non-growth responsive cortical tissues can respond to IAA. Moreover, a comparison of the effects of IAA and FC on the different components of the wall suggests that the response in the epidermis differs from that in the other tissues.     

Isolation and Identification of a Pyrogallol Oxidase Producing Microorganism and the Enzyme Production

A carbazole-using bacterium was isolated from oil polluted soil and identified as Flavobacterium sp. OCM-1 from its taxonomical characteristics. Its optimal culture conditions were identified. The growth and carbazole-degradation were found in the ranges of 20–30°C and pH 6–8. We found microbial production of indole-3-acetic acid from carbazole by strain OCM-1. Indole-3-acetic acid was identified as a metabolite of carbazole using thin-layer chromatography, mass and ¹H-NMR-spectra. 1.5 mg of indole-3-acetic acid was formed from 250 mg of carbazole.     

Comparative effect of IBA, BSAA and 5,6-Cl2-IAA-Me on the rooting of hypocotyl in mung bean

Mung bean hypocotyl cuttings were treated with indole-3-butyric acid (IBA), 3-(benzo[b]selenienyl)acetic acid (BSAA) and 5,6-dichloroindole-3-acetic acid methyl ester (5,6-Cl2-IAA-Me) at different concentrations, respectively. Each chemical produced the maximum number of adventitious roots at a different concentration. Compared with IBA treatment, 5,6-Cl2-IAA-Me and BSAA treatments significantly increased root numbers on hypocotyl cuttings at lower concentration, particularly of 5,6-Cl2-IAA-Me treatment. Combinations of paclobutrazol (PB) with either 5,6-Cl2-IAA-Me or BSAA significantly stimulated the production of more adventitious roots than either chemical alone or combined. Capillary electrophoresis analysis have shown that the levels of IAA, IBA and BSAA in IBA plus PB or BSAA plus PB treatments were higher than those of IBA or BSAA alone. It was suggested that the cause of the synergistic effect of IBA (or BSAA) plus PB treatment might be due to increased endogenous auxin level. The activities of peroxidase and IAA oxidase in the rooting zone coincided with root development, indicating that the activities of these two enzymes were positively correlated to rooting. Peroxidase and IAA oxidase activity in all treatments started 24 h and 12 h after cutting, respectively. It is suggested that the major role of IAA oxidase differed from that of peroxidase in adventitious root formation.     

Indole-3-acetic acid in microbial and microorganism-plant signaling

Diverse bacterial species possess the ability to produce the auxin phytohormone indole-3-acetic acid (IAA). Different biosynthesis pathways have been identified and redundancy for IAA biosynthesis is widespread among plant-associated bacteria. Interactions between IAA-producing bacteria and plants lead to diverse outcomes on the plant side, varying from pathogenesis to phyto-stimulation. Reviewing the role of bacterial IAA in different microorganism-plant interactions highlights the fact that bacteria use this phytohormone to interact with plants as part of their colonization strategy, including phyto-stimulation and circumvention of basal plant defense mechanisms. Moreover, several recent reports indicate that IAA can also be a signaling molecule in bacteria and therefore can have a direct effect on bacterial physiology. This review discusses past and recent data, and emerging views on IAA, a well-known phytohormone, as a microbial metabolic and signaling molecule.     

Immunocytochemical localization of indole-3-acetic acid in primary roots of Zea mays

Colloidal gold-labelled antibody was used to localize indole-3-acetic acid in caps of primary roots of Z. mays cv. Kys. Gold particles accumulated on the nucleus, vacuoles, mitochondria, and some dictyosomes and dictyosome-derived vesicles. This is the first localization of indole-3-acetic acid in dictyosomes and dictyosome-derived vesicles and indicates that dictyosomes and vesicles constitute a pathway for indole-3-acetic acid movement in and secretion from root cap cells. Our findings provide cytochemical evidence to support the hypothesis that indole-3-acetic acid plays an important role in root gravitropism.     

Pseudomonas fluorescens CHA0 can kill subterranean termite Odontotermes obesus by inhibiting cytochrome c oxidase of the termite respiratory chain

In the rhizosphere and their interaction with plants rhizobia encounter many different plant compounds, including phytohormones like auxins. Moreover, some rhizobial strains are capable of producing the auxin, indole-3-acetic acid (IAA). However, the role of IAA for the bacterial partner in the legume– Rhizobium symbiosis is not known. To identify the effect of IAA on rhizobial gene expression, a transposon (mTn 5gusA - oriV ) mutant library of Rhizobium etli , enriched for mutants that show differential gene expression under microaerobiosis and/or addition of nodule extracts as compared with control conditions, was screened for altered gene expression upon IAA addition. Four genes were found to be regulated by IAA. These genes appear to be involved in plant signal processing, motility or attachment to plant roots, clearly demonstrating a distinct role for IAA in legume– Rhizobium interactions.