Metabolism of 1-naphthaleneacetic acid in explants of tobacco: Evidence for release of free hormone from conjugates

1-Naphthaleneacetic acid (1-NAA), required for in vitro flower bud formation, was taken up by pedicel explants of tobacco (Nicotiana tabacum L.) in large amounts and rapidly metabolized into various conjugates. These conjugates have been tentatively identified in four thin-layer Chromatographic systems using authentic standards as references. The major metabolite formed during the first hours of culture comigrated with 1-NAA-glucoside (1-NAGlu). From the 6th hour on, most 1-NAA had been converted into a yet unidentified metabolite. 1-NAglu was an intermediate in the formation of this metabolite. After 24 h, 1-NAA-aspartate (1-NAAsp) became the second major metabolite. The increase in 1-NAAsp formation was induced by 1-NAA. The inactive analog 2-naphthaleneacetic acid (2-NAA) was metabolized similar to 1-NAA, but was unable to increase the formation of the aspartate conjugate. When explants were fed labeled 1-NAGlu, 1-NAAsp or the major unidentified metabolite, radioactivity became associated with free 1-NAA and all major conjugates, indicating interconversion of conjugates and breakdown to free 1-NAA. A regulatory role of conjugation in maintaining a particular level of free 1-NAA in the tissue is proposed herein.     

Auxin-induced ethylene production as related to auxin metabolism in leaf discs of tobacco and sugar beet

Exogenously supplied indole-3-acetic acid (IAA) stimulated ethylene production in tobacco (Nicotiana glauca) leaf discs but not in those of sugar beet (Beta vulgaris L.). The stimulatory effect of IAA in tobacco was relatively small during the first 24 hours of incubation but became greater during the next 24 hours. It was found that leaf discs of these two species metabolized [1-¹⁴C]IAA quite differently. The rate of decarboxylation in sugar beet discs was much higher than in tobacco. The latter contained much less free IAA but a markedly higher level of IAA conjugates. The major conjugate in the sugar beet extracts was indole-3-acetylaspartic acid, whereas tobacco extracts contained mainly three polar IAA conjugates which were not found in the sugar beet extracts. The accumulation of the unidentified conjugates corresponded with the rise of ethylene production in the tobacco leaf discs. Reapplication of all the extracted IAA conjugates resulted in a great stimulation of ethylene production by tobacco leaf discs which was accompanied by decarboxylation of the IAA conjugates. The results suggest that in tobacco IAA-treated leaf discs the IAA conjugates could stimulate ethylene production by a slow release of free IAA. The inability of the exogenously supplied IAA to stimulate ethylene production in the sugar beet leaf discs was not due to a deficiency of free IAA within the tissue but rather to the lack of responsiveness of this tissue to IAA, probably because of an autoinhibitory mechanism existing in the sugar beet leaf discs.     

Metabolism of [14C]cholesterol in Manduca sexta pupae: Isolation and identification of sterol sulfates,free ecdysteroids,and ecdysteroid acids

[¹⁴C]Cholesterol was injected into fifth-instar larvae of Manduca sexta, and the metabolites were isolated and identified from 8-day-old male and female pupae. A major portion of the metabolized cholesterol was esterified either with a sulfate group or with fatty acids. The predominant ecdysteroid metabolites were 20-hydroxyecdysone, 20,26-dihydroxyecdysone, 20-hydroxyecdysonoic acid, and 3-epi-20-hydroxyecdysonoic acid. Smaller amounts of ecdysteroids were identified as conjugates of 26-hydroxyecdysone, 3-epi-20-hydroxyecdysone, 20,26-dihydroxyecdysone, and its 3α-epimer. The metabolic profiles were similar for both male and female pupae. The two ecdysteroid acids were identified by nuclear magnetic resonance spectroscopy and chemical ionization mass spectrometry and by mass spectral analyses of their methyl esters. Detection of 3-epi-20-hydroxyecdysonoic acid as a major metabolite is significant, as its occurrence has been scarcely reported. 3-Epiecdysteroid acid formation is discussed as a possible ecdysteroid-inactivating pathway that may be operating specifically in lepidopterous insects or in particular developmental stages such as eggs or pupae.     

Polar transport of 1-naphthaleneacetic Acid determines the distribution of flower buds on explants of tobacco

Upon addition of 1-naphthaleneacetic acid (1-NAA) and benzylaminopurine, flower buds developed on explants from flower stalks of Nicotiana tabacum L. cv Samsun cultured in vitro. At low concentrations of 1-NAA, buds emerged mainly at the basal edge, whereas at high concentrations they developed on the remaining surface. The optimum concentrations for the two groups of buds were 0.45 micromolar and 2.2 micromolar, respectively, and the shapes of the concentration versus response curves were similar. The level of benzylaminopurine in the medium affected neither the shape nor the optimum concentration of these curves. The distribution of the buds over the explants was shown to be caused by polar auxin transport, leading to accumulation at the basal side. First, in the presence of the inhibitors 2,3,5-triiodobenzoic acid and 1-naphthylphthalamic acid, both groups of buds had the same optimum concentration of 1 micromolar 1-NAA. Second, after 6 hours of culture applied 1-NAA had accumulated in the basal part of the explant. In the presence of 1-naphthylphthalamic acid, no transport or accumulation of applied 1-NAA occurred.     

Formation of Phenolic and Indolic Compounds by Anaerobic Bacteria in the Human Large Intestine

Abstract Batch culture incubations were used to investigate the effects of pH (6.8 or 5.5) and carbohydrate (starch) availability on dissimilatory aromatic amino acid metabolism in human fecal bacteria. During growth on peptide mixtures, tyrosine and phenylalanine fermentations occurred optimally at pH 6.8, while individual metabolic reactions were inhibited by up to 80% in the presence of 10 g l⁻¹ starch. Tryptophan metabolites were not detected in these experiments. When free amino acids replaced peptides, phenol production was increased during carbohydrate fermentation, although formation of p-cresol, another tyrosine metabolite was strongly inhibited. Phenylpropionate, which is produced from phenylalanine, was unaffected by starch. Tryptophan was fermented in these studies, although indole production was reduced in the starch fermentors. The importance of different fermentation substrates (casein, peptide mixtures, free amino acids) on aromatic amino acid metabolism was investigated in incubations of material taken from the proximal bowel. The phenylalanine metabolites, phenylacetate and phenylpropionate, were the principal phenolic compounds formed from all three substrates. Phenol was the major tyrosine metabolite produced in casein and peptide fermentations, while hydroxyphenylpropionate was a more important tyrosine product from free amino acids. Indole was the sole product of tryptophan metabolism, but was formed only from the free amino acid. Bacterial metabolism of individual phenolic and indolic compounds was also investigated. Phenol, p-cresol, phenylacetate, phenylpropionate, 4-ethylphenol, indole, indoleacetate, and indolepropionate were not metabolized by colonic bacteria. However, hydroxyphenylacetate was hydrolyzed to p-cresol, while hydroxyphenylpropionate was transformed into phenylpropionate. Indolepyruvate was either converted to indoleacetate or metabolized into indole. Indolepropionate, and to a lesser degree indoleacetate were produced from indolelactate. These data show that human colonic anaerobes are able to extensively degrade either free or peptide-bound aromatic amino acids, with the concomitant formation of toxic metabolic products. These processes are controlled to a significant degree by environmental factors such as pH and carbohydrate availability, and this ultimately influences the types and amounts of fermentation products that can be formed in different regions of the large bowel. Received: 25 January 1996; Accepted: 8 May 1996     

Role of IAA conjugates in inducing ethylene production by tobacco leaf discs

Indole-3-acetic acid (IAA) labeled in its carboxyl group was metabolized by tobacco leaf discs (Nicotiana tabacum L. cv. Xanthi) into three metabolites, two of which were preliminarily characterized as a peptide and an ester-conjugated IAA. Reapplication of each of the three metabolites (at 10 M) resulted in a marked stimulation of ethylene production and decarboxylation by the leaf discs. Similarly, these three IAA metab olites could induce elongation of wheat coleoptile segments, which was accompanied by decarboxylation. Both the exogenously supplied esteric and peptidic IAA conjugates were converted by the leaf discs into the same metabolites as free IAA. (1-¹⁴C)IAA, applied to an isolated epidermis tissue, was completely metabolized to the esteric and peptidic IAA conjugates. This epidermis tissue showed much higher ethylene production rates and lower decarboxylation rates than did the whole leaf disc.The results suggest that the participation of IAA conjugates in the regulation of various physiological processes depends on the release of free IAA, which is obtained by enzymatic hydrolysis of the conjugates in the tissue. The present study demonstrates biological activity of endogenous IAA conjugates that were synthesized by tobacco leaf discs in response to exogenously supplied IAA.Contribution No. 952-E, 1983 series, from the Agricultural Research Organization, The Volcani Center, Bet Dagan, Israel.     

A protein from maize labeled with azido-IAA has novel β-glucosidase activity

A biologically active and photolabile auxin analog, 5-azido-[7-³H]indole-3-acetic acid ([³H]N₃IAA), was used to search for auxin-binding proteins in cytosolic extracts from maize coleoptiles (Zea mays L.) and identified a protein with a molecular mass of 60 kDa (p60). Binding of [³H]N₃IAA is highly specific as demonstrated by competition analysis with functionally relevant auxin analogs. p60 is found in coleoptiles and roots of etiolated maize seedlings and was detected in cytosolic as well as in microsomal fractions. The protein binds to 1-naphthylacetic acid (1-NAA) sepharose and is eluted with auxins. A purification scheme resulting in homogenous p60 protein was devised and it was shown that p60 has β-d -glucoside glucohydrolase activity (E.C.3.2.1.21). The hydrolytic activity of p60 for the synthetic substrate p-nitro-phenyl-β-d -glucopyranoside is diminished by 1-NAA. p60 shows high substrate specificity since it hydrolyzes indoxyl-O-glucoside, but not β-(1,4)-cellobiose, IAA-inositol or IAA-amino acid conjugates. The present data suggest that p60 might be involved in the hydrolysis of auxin conjugates.     

Polyamine metabolism and in vitro cell multiplication and differentiation in leaf explants of Chrysanthemum morifolium Ramat

Arginine decarboxylase (ADC), ornithine decarboxylase (ODC), diamine oxydase (DAO) free amine and conjugated amine titers were estimated in leaf explants of Chrysanthemum morifolium Ramat. var. Spinder cultivated in vitro in relation to hormone treatment. Addition of benzyladenine (BA) to a basal medium caused the formation of buds on the explants. BA plus 2,4 dichlorophenoxyacetic acid (2,4 D) caused callus formation and proliferation. Formation of roots was obtained by addition of indolylacetic acid (IAA). Arginine decarboxylase (ADC) ornithine decarboxylase (ODC) and diamine oxidase (DAO) activities increased during the first days of culture when cell multiplication was rapid, followed by a sharp decline as the rate of cell division decreased and differentiation took place. DAO activities increased rapidly in proliferating and growing organs and decreased during maturity. This increase was concomitant with ADC and ODC activities and polyamine content (free and conjugated polyamines). The biosynthesis and oxidation of polyamines which occurred simultaneously in physiological states of intense metabolism such as cell division or organ formation were directly correlated. In callus cultures DAO activity was blocked throughout development and regulated neither the cellular levels of polyamines nor polyamine conjugates. Levels of polyamine conjugates were high in callus cultures throughout development. In foliar explants cultivated on a medium promoting callus, inhibition of ODC activity by DFMO (-DL-difluoromethylornithine, a specific enzyme-activated ODC inhibitor) resulting in an amide deficiency facilated the expression of differentiated cell function; substantial activation of DAO was observed until the emergence of the buds. On a medium promoting bud formation, -OH ethylhydrazine (DAO inhibitor) promoted callus formation without differentiation. In this system DAO activity was blocked and there were high levels of polyamines, especially polyamine conjugates, throughout the culture period. The relationship among free and conjugated polyamines related biosynthetic enzyme activities, DAO activities, cell division and organ formation is discussed.Abbreviations ADC = arginine decarboxylase - ODC = ornithine decarboxylase - DOA = diamine oxidase - DFMA = -DL-difluoromethylarginine - DFMO = -DL-difluoromethylornithine - Put = putrescine     

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.     

Folylpolyglutamates in Leishmania major

The intracellular folates of the protozoan parasite Leishmania major have been examined. About 95% of the exogenous [3H]folate accumulated by the protozoan is metabolized to polyglutamate conjugates within 65 hr, and the intracellular folates are about forty-fold concentrated over the folate in the medium. The predominant metabolite of folic acid is the pentaglutamate conjugate (85%), with lessor amounts of the tetraglutamate (approximately 9%) and hexaglutamate (approximately 3%), and trace (less than 2.5%) amounts of di-, tri- and hepta-glutamate conjugates. Chromatographic properties of the products indicate that the conjugates are linked through the gamma-carboxyl groups. The folylpolyglutamate distribution in Leishmania is similar to that found in mammalian tissues.     

Role of IAA conjugates in inducing ethylene production by tobacco leaf discs

Indole-3-acetic acid (IAA) labeled in its carboxyl group was metabolized by tobacco leaf discs (Nicotiana tabacum L. cv. Xanthi) into three metabolites, two of which were preliminarily characterized as a peptide and an ester-conjugated IAA. Reapplication of each of the three metabolites (at 10 μM) resulted in a marked stimulation of ethylene production and decarboxylation by the leaf discs. Similarly, these three IAA metab olites could induce elongation of wheat coleoptile segments, which was accompanied by decarboxylation. Both the exogenously supplied esteric and peptidic IAA conjugates were converted by the leaf discs into the same metabolites as free IAA. (1-¹⁴C)IAA, applied to an isolated epidermis tissue, was completely metabolized to the esteric and peptidic IAA conjugates. This epidermis tissue showed much higher ethylene production rates and lower decarboxylation rates than did the whole leaf disc. The results suggest that the participation of IAA conjugates in the regulation of various physiological processes depends on the release of free IAA, which is obtained by enzymatic hydrolysis of the conjugates in the tissue. The present study demonstrates biological activity of endogenous IAA conjugates that were synthesized by tobacco leaf discs in response to exogenously supplied IAA.     

Metabolism of 2,4-Dichlorophenoxyacetic Acid (2,4-D) in Soybean Root Callus : EVIDENCE FOR THE CONVERSION OF 2,4-D AMINO ACID CONJUGATES TO FREE 2,4-D

An auxin-requiring soybean root callus metabolized [1-¹⁴C]-2,4-dichlorophenoxyacetic acid (2,4-D) to diethyl ether-soluble amino acid conjugates and water-soluble metabolites. The uptake in tissue varied with incubation time, concentration, and amount of tissue. Uptake was essentially complete (80%) after a 24-hour incubation and the percentage of free 2,4-D in the tissue fell to its lowest point at this time. At later times, the percentage of free 2,4-D increased and the percentage of amino acid conjugates decreased, whereas the percentage of water-soluble metabolites increased only slightly. Similar trends were seen if the tissue was incubated for 24 hours in radioactive 2,4-D, followed by incubation in media without 2,4-D for 24 hours. Inclusion of nonlabeled 2,4-D during the 24-hour chase period did not reduce amino acid conjugate disappearance but did reduce the percentage of free [1-¹⁴C]2,4-D. Thus, an external supply of 2,4-D does not directly prevent amino acid conjugate metabolism in this tissue. It is concluded that 2,4-D amino acid conjugates were actively metabolized by this tissue to free 2,4-D and water-soluble metabolites.     

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.     

The effect of light on metabolism of IAA in maize seedlings

Carbon 14-labelled indole-3-acetic acid (IAA) was fed to segments of shoots of Zea mays seedlings grown in light or dark to find the effect of light on IAA metabolism. The seedling parts coleoptile, with enclosed leaf, and mesocotyl were also used to examine differences in IAA metabolism between tissue types. The rate of metabolite formation as a function of time ranging from 1 to 12 hours was determined. Light did not significantly influence the amount of IAA taken up, but significantly increased its rate of metabolism and greatly increased the content of amide conjugates formed. There were also differences in metabolism depending on tissue type. In all tissues, IAA was metabolized mainly into six compounds. Four were tentatively identified as IAA-glucose (IAGlc), IAA-myo-inositol} (IAInos), indole acetamide (IAAm) and IAA-aspartic acid (IAAsp). 1-O-IAA-D-glucose (1-O-IAGlc) was the first conjugate formed and, except for mesocotyls in the light, it was the most abundant conjugate in maize tissue. In mesocotyl tissue the conversion of IAA into IAAsp was greatly stimulated by light, and the biosynthesis of IAAsp exceeded that of IAGlc. Since light strongly inhibited the growth of the mesocotyl, it is possible that the stimulation of IAAsp synthesis by light causes depletion of free IAA with resultant inhibition of mesocotyl growth.     

Uptake and metabolism of NAA and BAP in explants of tobacco in relation toin vitro flower bud formation

In vitro flower bud initiation and development depend on the presence of two hormones in the culture medium—auxin (NAA) and cytokinin (BAP). The uptake of both NAA and BAP by the explants was shown to be proportional to the concentrations supplied in the medium over a period of 4 days after the onset of culture. However, when supplied at equal concentrations for 24 h, the NAA uptake was up to 10-fold higher than the BAP uptake. Both hormones are rapidly metabolized by the explants. Nevertheless, the concentrations of free hormones inside the explants appeared to be high and in the case of NAA exceeded the concentration in the medium by more than 1 order of magnitude within 24 h. Apparently flower bud initiation in tobacco explants requires relatively high concentrations free NAA and BAP in the tissue maintained by a continuous supply in the medium. There are at present no indications that the products of hormone metabolism are directly involved in bud formation.     

Metabolism of [3H]-ecdysone in embryos and larvae of the tick Ornithodoros moubata

The fate of [³H]-ecdysone ([³H]-E) was investigated in hanging drop cultures of embryos and larvae of the tick Ornithodoros moubata using HPLC. The hormone was metabolized more slowly during described periods of increasing endogenous ecdysteroid (ES) titers than during periods of low titers except for young embryos. Three different classes of metabolites were produced: (1) apolar products (AP) corresponding to C-22 fatty acid ester conjugates of E and, in some cases, of 20-hydroxyecdysone (20E), (2) unidentified polar products (PP) more polar than E, one peak of which had the same retention times as 20,26-dihydroxyecdysone, and finally, (3) 20E verified by comigration of cold standards on RP-18 and silica columns. Hydroxylation of E to 20E first became evident in cultures of 2 day old embryos and was present in all cultures of older animals. Highest production of free 20E occurred during increasing endogenous ES titers in embryos and during the ES peak in larvae. Conjugation of E to AP occurred in all stages investigated, but was more pronounced during periods of low endogenous ES titers, and may correspond to a detoxification mechanism. In contrast, PP were produced during high 20E production in embryos and during periods of high and decreasing endogenous titers in larvae. © 1993 Wiley-Liss, Inc.     

Metabolism of Monoamine Oxidase Inhibitors

1. The principal routes of metabolism of the following monoamine oxidase inhibitors (MAOIs) are described: phenelzine, tranylcypromine, pargyline, deprenyl, moclobemide, and brofaromine.2. Acetylation of phenelzine appears to be a minor metabolic pathway. Phenelzine is a substrate as well as an inhibitor of MAO, and major identified metabolites of phenelzine include phenylacetic acid and p-hydroxyphenylacetic acid. Phenelzine also elevates brain GABA levels, and as yet unidentified metabolites of phenelzine may be responsible for this effect. -Phenylethylamine is a metabolite of phenelzine, and there is indirect evidence that phenelzine may also be ring-hydroxylated and N-methylated.3. Tranylcypromine is ring-hydroxylated and N-acetylated. There is considerable debate about whether or not it is metabolized to amphetamine, with most of studies in the literature indicating that this does not occur.4. Pargyline and R(–)-deprenyl, both propargylamines, are N-demethylated and N-depropargylated to yield arylalkylamines (benzylamine, N-methylbenzylamine, and N-propargylbenzylamine in the case of pargyline and amphetamine, N-methylamphetamine and N-propargylamphetamine in the case of deprenyl). These metabolites may then undergo further metabolism, e.g., hydroxylation.5. Moclobemide is biotransformed by C- and N-oxidation on the morpholine ring and by aromatic hydroxylation. An active metabolite of brofaromine is formed by O-demethylation. It has been proposed that another as yet unidentified active metabolite may also be formed in vivo. 6. Preliminary results indicate that several of the MAOIs mentioned above are substrates and/or inhibitors of various cytochrome P450 (CYP) enzymes, which may result in pharmacokinetic interactions with some coadministered drugs.     

In-vitro auxin transport in membrane vesicles from maize coleoptiles

When membrane vesicles from maize (Zea mays L.) coleoptiles are extracted at high buffer strength, a pH-driven, saturable association of [¹⁴C] indole-3-acetic acid is found, similar to the in-vitro auxin-transport system previously described for Cucurbita hypocotyls. The phytotropins naphthylphthalamic acid and pyrenoylbenzoic acid increase net uptake, pressumably by inhibiting the auxin-efflux carrier.Abbreviations IAA indole-3-acetic acid - ION3 ionophore mixture of carbonylcyanide-3-chlorophenylhydrazone, nigericin and valinomycin - 1-NAA, 2-NAA 1-, 2-naphthaleneacetic acid - NPA 1-N-naphthylphthalamic acid - PBA 2-(1-pyrenoyl)benzoic acid     

Indole-3-acetic acid is synthesized from L-tryptophan in roots of Arabidopsis thaliana

The promoter of the nit1 gene, encoding the predominantly expressed isoform of the Arabidopsis thaliana (L.) Heynh. nitrilase isoenzyme family, fused to the β-glucuronidase gene (uidA) drives β-glucuronidase expression in the root system of transgenic A. thaliana and tobacco plants. This expression pattern was shown to be controlled developmentally, suggesting that the early differentiation zone of root tips and the tissue surrounding the zone of lateral root primordia formation may constitute sites of auxin biosynthesis in plants. The root system of A. thaliana was shown to express functional nitrilase enzyme. When sterile roots were fed [²H]₅-L-tryptophan, they converted this precusor to [²H]₅-indole-3-acetonitrile and [²H]₅-indole-3-acetic acid. This latter metabolite was further metabolized into base-labile conjugates which were the predominant form of [²H]₅-indole-3-acetic acid extracted from roots. When [1-¹³C]-indole-3-acetonitrile was fed to sterile roots, it was converted to [1-¹³C]-indole-3-acetic acid which was further converted to conjugates. The results prove that the A. thaliana root system is an autonomous site of indole-3-acetic acid biosynthesis from L-tryptophan. Received: 3 February 1998 / Accepted: 17 April 1998     

Indole-3-butyric acid in plants: occurrence, synthesis, metabolism and transport

Indole-3-butyric acid (IBA) was recently identified by GC/MS analysis as an endogenous constituent of various plants. Plant tissues contained 9 ng g^?1 fresh weight of free IBA and 37 ng g^?1 fresh weight of total IBA, compared to 26 ng g^?1 and 52 ng g^?1 fresh weight of free and total indole-3-acetic acid (IAA), respectively. IBA level was found to increase during plant development, but never reached the level of IAA. It is generally assumed that the greater ability of IBA as compared with IAA to promote rooting is due to its relatively higher stability. Indeed, the concentrations of IAA and IBA in autoclaved medium were reduced by 40% and 20%, respectively, compared with filter sterilized controls. In liquid medium, IAA was more sensitive than IBA to non-biological degradation. However, in all plant tissues tested, both auxins were found to be metabolized rapidly and conjugated at the same rate with amino acids or sugar. Studies of auxin transport showed that IAA was transported faster than IBA. The velocities of some of the auxins tested were 7. 5 mm h^?1 for IAA, 6. 7 mm h^?1 for naphthaleneacetic acid (NAA) and only 3. 2 mm h^?1 for IBA. Like IAA, IBA was transported predominantly in a basipetal direction (polar transport). After application of ³H-IBA to cuttings of various plants, most of the label remained in the bases of the cuttings. Easy-to-root cultivars were found to absorb more of the auxin and transport more of it to the leaves. It has been postulated that easy-to-root, as opposed to the difficult-to-root cultivars, have the ability to hydrolyze auxin conjugates at the appropriate time to release free auxin which may promote root initiation. This theory is supported by reports on increased levels of free auxin in the bases of cuttings prior to rooting. The auxin conjugate probably acts as a ‘slow-release’ hormone in the tissues. Easy-to-root cultivars were also able to convert IBA to IAA which accumulated in the cutting bases prior to rooting. IAA conjugates, but not IBA conjugates, were subject to oxidation, and thus deactivation. The efficiency of the two auxins in root induction therefore seems to depend on the stability of their conjugates. The higher rooting promotion of IBA was also ascribed to the fact that its level remained elevated longer than that of IAA, even though IBA was metabolized in the tissue. IAA was converted to IBA by seedlings of corn and Arabidopsis. The K_m value for IBA formation was low (approximately 20 μM), indicating high affinity for the substrate. That means that small amounts of IAA (only a fraction of the total IAA in the plant tissues) can be converted to IBA. It was suggested that IBA is formed by the acetylation of IAA with acetyl-CoA in the carboxyl position via a biosynthetic pathway analogous to the primary steps of fatty acid biosynthesis, where acetyl moieties are transferred to an acceptor molecule. Incubation of the soluble enzyme fraction from Arabidopsis with ³H-IBA, IBA and UDP-glucose resulted in a product that was identified tentatively as IBA glucose (IBGIc). IBGIc was detected only during the first 30 min of incubation, showing that it might be converted rapidly to another conjugate.