Characterization of a family of IAA-amino acid conjugate hydrolases from Arabidopsis

The mechanisms by which plants regulate levels of the phytohormone indole-3-acetic acid (IAA) are complex and not fully understood. One level of regulation appears to be the synthesis and hydrolysis of IAA conjugates, which function in both the permanent inactivation and temporary storage of auxin. Similar to free IAA, certain IAA-amino acid conjugates inhibit root elongation. We have tested the ability of 19 IAA-l-amino acid conjugates to inhibit Arabidopsis seedling root growth. We have also determined the ability of purified glutathione S-transferase (GST) fusions of four Arabidopsis IAA-amino acid hydrolases (ILR1, IAR3, ILL1, and ILL2) to release free IAA by cleaving these conjugates. Each hydrolase cleaves a subset of IAA-amino acid conjugates in vitro, and GST-ILR1, GST-IAR3, and GST-ILL2 have K(m) values that suggest physiological relevance. In vivo inhibition of root elongation correlates with in vitro hydrolysis rates for each conjugate, suggesting that the identified hydrolases generate the bioactivity of the conjugates.     

A family of auxin-conjugate hydrolases that contributes to free indole-3-acetic acid levels during Arabidopsis germination

Auxins are hormones important for numerous processes throughout plant growth and development. Plants use several mechanisms to regulate levels of the auxin indole-3-acetic acid (IAA), including the formation and hydrolysis of amide-linked conjugates that act as storage or inactivation forms of the hormone. Certain members of an Arabidopsis amidohydrolase family hydrolyze these conjugates to free IAA in vitro. We examined amidohydrolase gene expression using northern and promoter-beta-glucuronidase analyses and found overlapping but distinct patterns of expression. To examine the in vivo importance of auxin-conjugate hydrolysis, we generated a triple hydrolase mutant, ilr1 iar3 ill2, which is deficient in three of these hydrolases. We compared root and hypocotyl growth of the single, double, and triple hydrolase mutants on IAA-Ala, IAA-Leu, and IAA-Phe. The hydrolase mutant phenotypic profiles on different conjugates reveal the in vivo activities and relative importance of ILR1, IAR3, and ILL2 in IAA-conjugate hydrolysis. In addition to defective responses to exogenous conjugates, ilr1 iar3 ill2 roots are slightly less responsive to exogenous IAA. The triple mutant also has a shorter hypocotyl and fewer lateral roots than wild type on unsupplemented medium. As suggested by the mutant phenotypes, ilr1 iar3 ill2 imbibed seeds and seedlings have lower IAA levels than wild type and accumulate IAA-Ala and IAA-Leu, conjugates that are substrates of the absent hydrolases. These results indicate that amidohydrolases contribute free IAA to the auxin pool during germination in Arabidopsis.     

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.     

Auxin metabolism in representative land PLANTS

The plant hormone auxin (indole-3-acetic acid, IAA) appears to control many plant developmental processes, and studies performed in seed plants suggest that IAA conjugation is the critical mechanism to regulate free IAA concentration. The purpose of this investigation is to characterize the biochemical ability of one charophyte and 23 land plants ranging from liverworts to angiosperms to produce IAA conjugates, and to study the complexity of their conjugation patterns. Actively growing tissue was incubated with ¹⁴C-IAA, after which labeled IAA conjugates were separated using thin-layer chromatography. The conjugates were analyzed using radioimaging techniques and their tentative identity assigned by co-chromatography and/or by differential hydrolysis. The charophyte and the liverworts appear unable to conjugate IAA. The mosses and the hornwort are able to conjugate IAA into a few amide and ester conjugates. The tracheophytes examined synthesize several conjugates unique to the vascular plants, indole-3-acetyl-aspartic acid (-glutamic acid) and/or indole-3-acetyl-β-1-O-glucose, as well as a variety of other amide and ester conjugates. These three conjugation patterns are correlated to the type of conducting tissue characteristic of the plants analyzed. These biochemical differences may be indicative of significative differences in the hormonal regulation in these plant groups, thus suggesting that changes in IAA regulation accompanied the major evolutionary events in land plants.     

Auxin-conjugate hydrolysis in Chinese cabbage: Characterization of an amidohydrolase and its role during infection with clubroot disease

Auxin conjugates play a role in the regulation of free indole-3-acetic acid (IAA) content in plants. Not much is known about the enzymes involved in either conjugate synthesis or hydrolysis. In this study we have isolated and characterized an auxin conjugate hydrolase from Chinese cabbage seedlings and investigated it during the development of both the Chinese cabbage plants and the clubroot disease. The hydrolase isolated from light- and dark-grown seedlings accepted the amide conjugates indole-3-acetic acid-alanine (IAAla), IAA-phenylalanine (IAPhe), but not IAA-aspartate (IAAsp) as substrates. We also found a substantial amount of hydrolysis of an ester conjugate (IAA-glucose, IAGlu) in our enzyme preparation. The tentative reaction product IAA was identified by HPLC and subsequent GC-MS analysis. The pH optima for the different substrates were not identical, suggesting several hydrolase isoforms. After gel filtration chromatography we found at least two peaks containing different hydrolase isoforms. The isoform, which converted IAGlu to IAA, exhibited a molecular mass of ca 63 kDa, and an isoform of ca 21 kDa converted IAAla and IAPhe. The increased free IAA content in clubroot-diseased roots of Brassicaceae can be due to either de novo synthesis or release of IAA from conjugates. To answer this question free, ester- and amide-bound IAA was measured in 24- and 30-day-old leaves and roots of healthy and Plasmodiophora brassicae-infected Chinese cabbage, and the hydrolase activity with different substrates measured in the same tissues. The amide conjugates were dramatically enhanced in infected roots, whereas free IAA was only slightly enhanced compared to the control tissue. Hydrolase activity was also enhanced in clubbed roots, but the substrate specificity differed from that found in the seedlings. Especially, IAAsp hydrolysis was induced after inoculation with P. brassicae. We conclude that different auxin conjugates can be hydrolyzed at different developmental stages or under stress.     

Expression of AMIDASE1 (AMI1) is suppressed during the first two days after germination

The regulation of cellular auxin levels is a critical factor in determining plant growth and architecture, as indole-3-acetic acid (IAA) gradients along the plant axis and local IAA maxima are known to initiate numerous plant growth responses. The regulation of auxin homeostasis is mediated in part by transport, conjugation and deconjugation, as well as by de novo biosynthesis. However, the pathways of IAA biosynthesis are yet not entirely characterized at the molecular and biochemical level. It is suggested that several biosynthetic routes for the formation of IAA have evolved. One such pathway proceeds via the intermediate indole-3-acetamide (IAM), which is converted into IAA by the activity of specific IAM hydrolases, such as Arabidopsis AMIDASE1 (AMI1). In this article we present evidence to support the argument that AMI1-dependent IAA synthesis is likely not to be used during the first two days of seedling development.Key words: Arabidopsis thaliana, auxin biosynthesis, AMIDASE1, indole-3-acetic acid, indole-3-acetamide, LEAFY COTYLEDON1, seed developmentAuxins are versatile plant hormones that play diverse roles in regulating many aspects of plant growth and development.¹ To enable auxins to develop their activity, a tight spatiotemporal control of cellular indole-3-acetic acid (IAA) contents is absolutely necessary since it is well-documented that auxin action is dose dependent, and that high IAA levels can have inhibitory effects on plant growth.² To achieve this goal, plants have evolved a set of different mechanisms to control cellular hormone levels. On the one hand, plants possess several pathways that contribute to the de novo synthesis of IAA. This multiplicity of biosynthetic routes presumably facilitates fine-tuning of the IAA production. On the other hand, plants are equipped with a variety of enzymes that are used to conjugate free auxin to either sugars, amino acids or peptides and small proteins, respectively, or on the contrary, that act as IAA-conjugate hydrolases, releasing free IAA from corresponding conjugates. IAA-conjugates serve as a physiologically inactive storage form of IAA from which the active hormone can be quickly released on demand. Alternatively, conjugation of IAA can mark the first step of IAA catabolism. In general, conjugation and deconjugation of free IAA are ways to positively or negatively affect active hormone levels, which adds another level of complexity to the system. Additionally, IAA can be transported from cell to cell in a polar manner, which is dependent on the action of several transport proteins. All together, these means are used to form auxin gradients and local maxima that are essential to initiate plant growth processes, such as root or leaf primordia formation.³     

IAR3 encodes an auxin conjugate hydrolase from Arabidopsis

Amide-linked conjugates of indole-3-acetic acid (IAA) are putative storage or inactivation forms of the growth hormone auxin. Here, we describe the Arabidopsis iar3 mutant that displays reduced sensitivity to IAA-Ala. IAR3 is a member of a family of Arabidopsis genes related to the previously isolated ILR1 gene, which encodes an IAA-amino acid hydrolase selective for IAA-Leu and IAA-Phe. IAR3 and the very similar ILL5 gene are closely linked on chromosome 1 and comprise a subfamily of the six Arabidopsis IAA-conjugate hydrolases. The purified IAR3 enzyme hydrolyzes IAA-Ala in vitro. iar 3 ilr1 double mutants are more resistant than either single mutant to IAA-amino acid conjugates, and plants overexpressing IAR3 or ILR1 are more sensitive than is the wild type to certain IAA-amino acid conjugates, reflecting the overlapping substrate specificities of the corresponding enzymes. The IAR3 gene is expressed most strongly in roots, stems, and flowers, suggesting roles for IAA-conjugate hydrolysis in those tissues.     

Auxins in the development of an arbuscular mycorrhizal symbiosis in maize

While the levels of free auxins in maize (Zea mays L.) roots during arbuscular mycorrhiza formation have been previously described in detail, conjugates of indole-3-acetic acid (IAA) and indole-3-butyric acid (IBA) with amino acids and sugars were neglected. In this study, we have therefore determined free, ester and amide bound auxins in roots of maize inoculated with Glomus intraradices during early stages of the colonization process. Ester conjugates of IAA and IBA were found only in low amounts and they did not increase in AM colonized roots. The Levels of IAA and IBA amide conjugates increased 20 and 30 days past inoculation (dpi). The formation of free and conjugated IBA but not IAA was systemically induced during AM colonization in leaves of maize plants. This implicated a role for auxin conjugate synthesis and hydrolysis during AM. We have therefore investigated the in vivo metabolism of 3H-labeled IBA by TLC but only slight differences between control and AM-inoculated roots were observed. The activity of auxin conjugate hydrolase activity measured with three different putative substrates showed a decrease in infected roots compared to controls. The fluorinated IBA analog TFIBA inhibited IBA formation in leaves after application to the root system, but was not transported from roots to shoots. AM hyphae were also not able to transport TFIBA. Our results indicate complex control mechanisms to regulate the levels of free and conjugated auxins, which are locally and systemically induced during early stages of the formation of an arbuscular mycorrhizal symbiosis.     

Characterization of an Arabidopsis enzyme family that conjugates amino acids to indole-3-acetic acid

Substantial evidence indicates that amino acid conjugates of indole-3-acetic acid (IAA) function in auxin homeostasis, yet the plant enzymes involved in their biosynthesis have not been identified. We tested whether several Arabidopsis thaliana enzymes that are related to the auxin-induced soybean (Glycine max) GH3 gene product synthesize IAA-amino acid conjugates. In vitro reactions with six recombinant GH3 enzymes produced IAA conjugates with several amino acids, based on thin layer chromatography. The identity of the Ala, Asp, Phe, and Trp conjugates was verified by gas chromatography-mass spectrometry. Insertional mutations in GH3.1, GH3.2, GH3.5, and GH3.17 resulted in modestly increased sensitivity to IAA in seedling root. Overexpression of GH3.6 in the activation-tagged mutant dfl1-D did not significantly alter IAA level but resulted in 3.2- and 4.5-fold more IAA-Asp than in wild-type seedlings and mature leaves, respectively. In addition to IAA, dfl1-D was less sensitive to indole-3-butyric acid and naphthaleneacetic acid, consistent with the fact that GH3.6 was active on each of these auxins. By contrast, GH3.6 and the other five enzymes tested were inactive on halogenated auxins, and dfl1-D was not resistant to these. This evidence establishes that several GH3 genes encode IAA-amido synthetases, which help to maintain auxin homeostasis by conjugating excess IAA to amino acids.     

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.     

Quantification of free plus conjugated indoleacetic acid in arabidopsis requires correction for the nonenzymatic conversion of indolic nitriles.

The genetic advantages to the use of Arabidopsis thaliana mutants for the study of auxin metabolism previously have been partially offset by the complexity of indolic metabolism in this plant and by the lack of proper methods. To address some of these problems, we developed isotopic labeling methods to determine amounts and examine the metabolism of indolic compounds in Arabidopsis. Isolation and indentification of endogenous indole-3-acetonitrile (IAN; a possible precursor of the auxin indole-3-acetic acid [IAA]) was carried out under mild conditions, thus proving its natural occurrence. We describe here the synthesis of 13C1-labeled IAN and its utility in the gas chromatography-mass spectrometry quantification of endogenous IAN levels. We also quantified the nonenzymatic conversion of IAN to IAA under conditions used to hydrolyze IAA conjugates. 13C1-Labeled IAN was used to assess the contribution of IAN to measured IAA following hydrolysis of IAA conjugates. We studied the stability and breakdown of the indolic glucosinolate glucobrassicin, which is known to be present in Arabidopsis. This is potentially an important concern when using Arabidopsis for studies of indolic biochemistry, since the levels of indolic auxins and auxin precursors are well below the levels of the indolic glucosinolates. We found that under conditions of extraction and base hydrolysis, formation of IAA from glucobrassicin was negligible.     

Dead end for auxin conjugates in Physcomitrella?

For proper development of plants auxin levels need to be tightly controlled. For this, several routes have evolved and it is plausible that different organisms use these differently. To determine whether members of the family of GH3 proteins, which partially act as auxin conjugate synthetases in Arabidopsis thaliana, have similar roles in the moss Physcomitrella patens, we have investigated the in vitro activity of the two GH3 members in moss. We showed that both proteins can form amino acid conjugates with indole-3-acetic acid (IAA) but also with jasmonic acid (JA). Confirming these findings, single and double knockout-mutants showed lower levels of IAA conjugates than wild type. We discuss the results in light of the possible functions of IAA conjugate formation in lower land plants.Key words: Arabidopsis thaliana, auxin metabolism, jasmonic acid, GH3 genes, moss, Physcomitrella patensAuxins play diverse roles in many aspects of plant growth and development. Their activity is relying on the correct concentration in a given tissue and developmental stage.¹ If higher levels of indole-3-acetic acid (IAA) are present, the hormone can also have an inhibitory effect on growth processes.² Therefore, the tight control of IAA concentrations is absolutely necessary. To this end plants have evolved different mechanisms.³ First, biosynthesis is contributing to increasing IAA concentrations, mostly in young tissues such as meristems. Second, IAA can be transported in a polar way, depending on transport molecules, from cell to cell, away from the site of synthesis, thereby forming an auxin gradient along the plant axis. Third, IAA can be degraded, and fourth, IAA can be reversibly inactivated by conjugation to small molecules such as amino acids or sugars, but also be linked to larger molecules such as peptides or proteins.⁴ The inactive IAA conjugates can be hydrolyzed to yield free (i.e., active) IAA if needed. In higher plants the levels of free IAA constitutes between 5 and 20% depending on the tissue or age of the plant, whereas the conjugated form constitutes the major part.⁴ However, it is not yet clear in which way auxin homeostasis has evolved. The hypothesis that auxin has to be present during the evolution of a body plan has been tested by using different lower land plants which were compared in their mechanism to control auxin homeostasis. In algae, e.g., charophytes, the major metabolic way of controlling IAA is via biosynthesis. In bryophytes, the formation of IAA conjugates has been shown, although the amount was lower than for example in seed plants such as Arabidopsis thaliana.^5,6 Since the molecular biology of auxin homeostasis in Arabidopsis is most advanced, we will use this model plant to compare the knowledge on seed plants with that in the moss Physcomitrella patens. The recent publication of the Physcomitrella genome⁷ gives the possibility to investigate components of the machinery controlling IAA levels in a lower land plant.In general, there seem to be high levels of redundancy involved in the pathways leading to decrease or increase of IAA, respectively. In Figure 1 we compare the current knowledge about genes related to IAA concentrations in Physcomitrella with Arabidopsis. While in Arabidopsis many different biosynthetic routes leading to IAA were identified,⁸ in the Physcomitrella genome homologs of the YUCCA genes have been detected.⁷ The presence of auxin conjugate synthetases has been experimentally verified in the moss (see below) and additional evidence for ester conjugate synthesis comes from sequence homology to UDP-glucosyl transferases.⁷ There is also the possibility of degradation of either IAA or an amino acid conjugate with IAA^9,10 as discussed below.Open in a separate windowFigure 1Comparison of possibilities to regulate auxin homeostasis in Physcomitrella (solid lines) and Arabidopsis (dotted lines). Biosynthesis—AO, aldehyde oxidase; AMI1, amidase; CYP, cytochrome P450; NIT, nitrilase; TAA1, tryptophan aminotransferase; YUCCA, flavin monooxygenase; transport—AUX/LAX, auxin influx facilitator family; PIN, auxin efflux carrier family; PGP, ABC transporter type auxin efflux carrier family; conjugation/hydrolysis—UGT, UDP-glucosyl transferase; GH3, auxin conjugate synthetase family; ILR/IAR, auxin conjugate hydrolase family; Ox-IAA, oxindole-3-acetic acid; Ox-IAAsp, oxindole-3-aspartic acid.So far our work has focussed on the characterization of two members of the so called GH3 family, of which several from Arabidopsis can form conjugates of IAA with a variety of amino acids.¹¹ While 19 members of this family have been described in Arabidopsis, only two are present in Physcomitrella.¹² The Arabidopsis family clusters in three groups: group I containing the jasmonic acid conjugate synthetase JAR1 and a few others with as yet unkown function, group II the auxin conjugate synthetases, and group III with mostly as yet uncharacterized members.^11,13 Sequence similarity of the GH3 genes from Physcomitrella showed that both cluster within the JAR1 group.¹² Therefore, we analyzed the enzymatic activity of the two Physcomitrella GH3 proteins (PpGH3-1 and PpGH3-2) in vitro¹⁴ and found that both were active on jasmonic acid and a variety of different amino acids, whereas PpGH3-2 was active mostly with IAA. PpGH3-1 showed only weak activity with IAA and only two amino acids. For this reason, it could be assumed that the two Physcomitrella genes evolved by gene duplication, from which the initial activities would be for IAA and jasmonic acid. One of these genes might have evolved into a jasmonate conjugate synthetase (maybe AtJAR1),¹³ thereby loosing its activity on IAA. The second may have given rise to the auxin conjugate synthetase family in Arabidopsis,¹¹ but the conjugate synthetases of Physcomitrella have still activity with both hormones. Interestingly, there is no evidence as yet that jasmonic acid itself has a role during Physcomitrella development, although a possible function of JA-conjugates has not been closely investigated. Since in Arabidopsis the JA conjugate with isoleucine is the active compound to be recognized by the COI1 receptor protein,¹⁵ it could be the case that JA itself has no effect in Physcomitrella. However, in our growth experiments a small growth promoting effect of JA, independently on the presence of GH3 genes was found. Similar observations were made with gibberellins in Physcomitrella.¹⁶Further characterization of single and double KO mutants in each of the PpGH3 genes has led to the hypothesis that GH3 proteins are indeed involved in regulating the auxin homeostasis in Physcomitrella.¹⁴ Both single KO mutants were more sensitive to increasing IAA concentrations in the medium than the wild type. Furthermore, the levels of free IAA were higher and the levels of conjugated IAA concomitantly dropped. A double KO mutant had almost no IAA conjugates when compared to the wild type. However, this mutant was still able to synthesize ester conjugates with IAA. Interestingly, the role of GH3 proteins in auxin conjugation seemed to be only important in the gametophore stage, whereas protonema cultures of GH3 KO mutants did not show any changes in auxin homeostasis. Therefore, we hypothesize that the role of GH3 proteins is dependent on a certain developmental stage of the moss. Additionally, we propose other detoxification mechanisms for example, export or degradation, in protonema.In higher plants the ester conjugate formation of IAA has been shown to be dependent on UDP-glucosyl transferases (AtUGT84B1 for Arabidopsis¹⁷ and ZmIAGLU for maize¹⁸). In the genome of Physcomitrella we could detect candidate sequence(s) for these genes, indicating that Physcomitrella has indeed the potential to synthesise the ester conjugates found in the gametophores in addition to amide conjugates. However, in the Physcomitrella genome, no homolog for an auxin conjugate hydrolase was found. In higher plants, auxin conjugate hydrolysis is thought to contribute to free IAA and depending on the plant species, large gene families with overlapping but distinct substrate preferences for individual amino acid conjugates with IAA are present.^19,20 Since this is not the case for Physcomitrella, one has to ask the question whether the conjugation of auxin is a one-way road for inactivation of excess auxin and whether auxin conjugate hydrolysis has evolved later during plant evolution.In the Selaginella moellendorffii genome (http://genome.jgi-psf.org/Selmo1/Selmo1.home.html), an auxin conjugate hydrolase sequence related to higher plant ones, has been found based on homology searches, but the completion of the genome has to be awaited to draw final conclusions. Likewise, it is not clear, if this effect is specific for Physcomitrella, or found in bryophytes in general. Therefore, additional sequenced bryophyte genomes are needed.²¹Since in Arabidopsis the degradation of the IAA-Aspartate conjugate to Ox-IAA-Asp (see Fig. 1) has been described,^9,10 a similar scenario could be suggested to occur in Physcomitrella with the amino acid conjugates formed. Alternatively, the hydrolysis of IAA conjugates by members of the M20 dipeptidase family can be envisioned. However, this would need the activity of enzymes with very low sequence conservation to auxin conjugate hydrolases. These questions will be addressed in future research by studying the metabolism of IAA and IAA conjugates of Physcomitrella in more detail.     

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。     

Plant hormone conjugation: A signal decision

Tight regulation of the auxin hormone indole-3-acetic acid (IAA) is crucial for plant development. Newly discovered IAA antagonists are the amide-linked tryptophan conjugates of IAA and jasmonic acid (JA). JA-Trp and IAA-Trp interfered with root gravitropism in Arabidopsis, and inhibited several responses to exogenously supplied IAA. Relatively low concentrations of the inhibitors occurred in Arabidopsis, but Pisum sativum flowers contained over 300 pmole g⁻¹ FW of JA-Trp. DihydroJA was an even more effective inhibitor than JA-Trp, suggesting that Trp conjugates with other JA derivatives may also be functional. JA-Trp and IAA-Trp add to the list of documented bioactive amide hormone conjugates. The only other example is JA-Ile, the recently discovered jasmonate signal. These examples establish that conjugation not only inactivates hormones, but in some cases creates novel compounds that function in hormone signaling.Key words: jasmonic acid, indole-3-acetic acid, auxin, tryptophan, conjugate, plant hormone, signaling, amino acid, antagonistPlants hold an amazing capacity to auto-regulate their growth and respond to a host of environmental challenges. Since the early discovery of the first plant hormone, indole-3-acetic acid (IAA),¹ science has progressively unveiled ever more complex, and sometimes surprising, ways that plants manipulate hormones to optimize their growth and thwart their opponents. Until recently, the covalent coupling of hormones to sugars, amino acids and peptides was thought to be merely a way to dispose of excess hormone.² The amide linkage of IAA to Asp and Glu does indeed result in IAA catabolism, while IAA-Ala and IAA-Leu are inactive stored forms of IAA.³ But the perception that all hormone conjugates are inactive changed abruptly with the discovery that the isoleucine conjugate of jasmonic acid (JA-Ile) is an active hormonal signal.     

Temperature-Sensitive Plant Cells with Shunted Indole-3-Acetic Acid Conjugation

Cells of henbane (Hyoscyamus muticus L.) grow indefinitely in culture without exogenous auxin. Cells of its temperature-sensitive variant XIIB2 grow like the wild type at 26[deg]C but die rapidly at 33[deg]C unless auxin is added to the medium. Despite this temperature-sensitive auxin auxotrophy, XIIB2 produces wild-type amounts of indole-3-acetic acid (IAA). IAA is the predominant auxin and is important for plant growth and development. Since the IAA production of the variant is functional, we investigated whether the synthesis or degradation of IAA metabolites, possibly active auxins themselves, is altered. The IAA metabolites were IAA-aspartate (IAAsp) and IAA-glucose. The wild type converted IAA mainly to IAAsp, whereas the variant produced mainly IAA-glucose. Exogenous auxin corrected the shunted IAA metabolism of the variant. The half-life of labeled IAAsp in the variant was reduced 21-fold, but in the presence of exogenous auxin it was not different from the wild type. The temperature sensitivity of XIIB2 was also corrected by supplying IAAsp. Pulse-chase experiments revealed that henbane rapidly metabolizes IAAsp to compounds not identical to IAA. The data show that the variant XIIB2 is a useful tool to study the function of IAA conjugates to challenge the popular hypothesis that IAA conjugates are merely slow-release storage forms of IAA.     

Maize nitrilases have a dual role in auxin homeostasis and beta-cyanoalanine hydrolysis

The auxin indole-3-acetic acid (IAA), which is essential for plant growth and development, is suggested to be synthesized via several redundant pathways. In maize (Zea mays), the nitrilase ZmNIT2 is expressed in auxin-synthesizing tissues and efficiently hydrolyses indole-3-acetonitrile to IAA. Zmnit2 transposon insertion mutants were compromised in root growth in young seedlings and sensitivity to indole-3-acetonitrile, and accumulated lower quantities of IAA conjugates in kernels and root tips, suggesting a substantial contribution of ZmNIT2 to total IAA biosynthesis in maize. An additional enzymatic function, turnover of beta-cyanoalanine, is acquired when ZmNIT2 forms heteromers with the homologue ZmNIT1. In plants carrying an insertion mutation in either nitrilase gene this activity was strongly reduced. A dual role for ZmNIT2 in auxin biosynthesis and in cyanide detoxification as a heteromer with ZmNIT1 is therefore proposed.     

IAR4, a gene required for auxin conjugate sensitivity in Arabidopsis, encodes a pyruvate dehydrogenase E1alpha homolog

The formation and hydrolysis of indole-3-acetic acid (IAA) conjugates represent a potentially important means for plants to regulate IAA levels and thereby auxin responses. The identification and characterization of mutants defective in these processes is advancing the understanding of auxin regulation and response. Here we report the isolation and characterization of the Arabidopsis iar4 mutant, which has reduced sensitivity to several IAA-amino acid conjugates. iar4 is less sensitive to a synthetic auxin and low concentrations of an ethylene precursor but responds to free IAA and other hormones tested similarly to wild type. The gene defective in iar4 encodes a homolog of the E1alpha-subunit of mitochondrial pyruvate dehydrogenase, which converts pyruvate to acetyl-coenzyme A. We did not detect glycolysis or Krebs-cycle-related defects in the iar4 mutant, and a T-DNA insertion in the IAR4 coding sequence conferred similar phenotypes as the originally identified missense allele. In contrast, we found that disruption of the previously described mitochondrial pyruvate dehydrogenase E1alpha-subunit does not alter IAA-Ala responsiveness or confer any obvious phenotypes. It is possible that IAR4 acts in the conversion of indole-3-pyruvate to indole-3-acetyl-coenzyme A, which is a potential precursor of IAA and IAA conjugates.     

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.