HPLC-based methods for the identification of gibberellin conjugates: Metabolism of [3H]gibberellin A4 in seedlings of Phaseolus coccineus

A series of chromatographic and derivatization techniques has been developed for the identification of radiolabelled gibberellin (GA) conjugates. The methods are based on reversed-phase HPLC, gel permeation chromatography, anion-exchange chromatography, enzymatic hydrolysis and transesterification of conjugates, and derivatization of free GAs to methoxycoumaryl esters. The procedures have been used to identify GA₄-glucosyl ester, GA₄-3-O-glucoside, a GA₃₄-O-glucoside and GA₈-2-O-glucoside, in addition to GA₁ and GA₈, as products of [1,2-³H]GA₄ metabolism in shoots of light-grown Phaseolus coccineus seedlings.     

The endogenous gibberellins of dwarf mutants of lettuce

The gibberellin (GA) content of E-1, a tall genotype of early flowering lettuce (Lactuca sativa L.), and of three selected GA-responsive dwarfs, dwf1, dwf2, and dwf2¹, has been determined using ¹³C-labeled internal standards and gas chromatographymass spectrometry (GC-MS). In the shoots of the E-1 parent, GA₁, 3-epi-GA₁, GA₃, GA₅, GA₈, GA₁₉, GA₂₀, GA₂₉, and GA₅₃ were identified by full scan GC-MS and Kovats retention indices. Purification by immunoaffinity chromatography selective for 13-hydroxy GAs, was necessary for GA identification. Relative to the parent E-1, the concentrations of GA₁, GA₈, GA₂₀, and GA₂₉ in the shoots of dwf2 plants were reduced to about 10% and in shoots of dwf2¹ plants to less than 50%. In dwf1 the levels of GA₁, GA₈, and GA₂₉ were also reduced to less than 50% of the parent E-1, but the level of GA₂₀ was fivefold higher than in E-1. Plant height was correlated with the endogenous levels of GA₁ and GA₈.     

Identification of endogenous gibberellins in navel orange shoots

Eight gibberellins (GAs) were identified from vegetative shoots of navel orange trees (Citrus sinensis L. Osbeck cv Washington) after sequential purification by reverse-phase C₁₈ high performance liquid chromatography, Nucleosil 5N(CH₃)₂ high performance liquid chromatography, and capillary gas chromatography-mass spectrometry. GA₁, GA₁₇, GA₁₉, GA₂₀, GA₂₉, and iso-GA₃ were identified based on the full scan mass spectra and Kovats retention indices. GA₈ was tentatively identified based on the comparison of the full scan mass spectra with the published spectra. GA₄₄ was tentatively identified from the characteristic masses at the correct Kovats retention index.     

Obligate methylotroph <Emphasis Type="Italic">Methylobacillus arboreus</Emphasis> Iva<Superscript>T</Superscript> synthesizes a plant hormone,gibberellic acid GA<Subscript>3</Subscript>

An obligate methylotroph Methylobacillus arboreus Iva^Т (VKM B-2590^Т, CCUG 59684^T, DSM 23628T) is the first known aerobic methylotrophic bacterium capable of synthesis of the bioactive gibberellic acid GA₃. Primary separation and identification of gibberellic acid from the culture liquid of methanol-grown culture were carried out using thin-layer chromatography and high-performance liquid chromatography. The concentration and structure of the gibberellic acid GA₃ were determined by liquid chromatography?mass spectrometry (LC/MS). Biological activity of the isolated compound was confirmed by tests on sprouts of lettuce (Laсtuca sativa L.).     

Native gibberellins and the metabolism of [14C]gibberellin A53 and of [17-13C, 17-3H2]gibberellin A20 in tassels of Zea mays

The native hormones from tassels of maize (Zea mays) were re-investigated. The previous identification by GC/SIM of GA₁, GA₈ and GA₂₉ in normal tassels was confirmed by full GC/MS scans at the correct Kovats retention indices. In tassels of dwarf-1 mutants, GA₄₄,^?GA₁₉, GA₁₇, GA₂₀ and the 16,17-dihydro, 7β,16α,17-trihydroxy derivative of ent-kaurenoic acid were identified by GC/MS. Gibberellin A₁ was not found in the mutant tassels. [¹⁴C]Gibberellin A₅₃ was fed to tassels of the dwarf-5 mutant. In the ethyl acetate-soluble acidic fraction from the feeds, [¹⁴C]GA₄₄ was identified by GC/MS; [¹⁴C]GA₁₉ and [¹⁴C]GA₂₉ were identified by GC/SIM. The GA₂₉ is probably a metabolite of the feeds because the dwarf-5 mutant is known to control the step copalyl pyrophosphate to ent-kaurene in the maize GA-biosynthetic pathway and because GA₂₉ was not identified in a control experiment. The n-butanol fractions obtained from the feeds were shown, by GC/MS, to contain [¹⁴C]GA₅₃ after hydrolysis, suggesting that conjugated [¹⁴C]GA₅₃ is a major metabolite from GA₅₃ feeds. [17-¹³C, 17-³H₂]Gibberellin A₂₀ was fed to normal, dwarf-1 and dwarf-5 tassels. In each case, analysis of the purified ethyl acetate-soluble acidic extracts by GC/MS led to the identification of [¹³C]GA₂₉ and unmetabolized [¹³C]GA₂₀ in which no ¹³C-isotope dilution was observed.     

Partial purification of gibberellin oxidases from spinach leaves

Four enzyme activities catalyzing the following oxidative steps in the gibberellin (GA) biosynthetic pathway have been extracted from spinach (Spinacia oleracea L.) leaves after exposure to 8 long days: GA₁₂ → GA₅₃ → GA₄₄ → GA₁₉ → GA₂₀. Two of these, GA₅₃ oxidase and GA₁₉ oxidase, were separable from the other two, GA₄₄ oxidase and GA₁₂ 13-hydroxylase, by anion exchange high performance liquid chromatography (HPLC). Apparent molecular weights of the four enzymes as determined by gel filtration HPLC are: GA₁₂ 13-hydroxylase, 28,400; GA₅₃ oxidase, 42,500; GA₄₄ oxidase, 38,100; GA₁₉ oxidase, 39,500. GA₄₄ oxidase was purified approximately 100-fold in 0.3% yield by a combination of ammonium sulfate fractionation, anion exchange HPLC, phenyl-Sepharose chromatography and gel filtration HPLC.     

Reversible conjugation of gibberellins in situ in maize

Gibberellins [³H]GA₄ (1.33 Curies per millimole) and [³H]GA₂₀ (2.36 Curies per millimole) were injected into the shanks of maize (Zea mays L.) cobs during rapid grain filling and mature seeds were subsequently harvested. Extracts of mature, dry seeds from 1980 feeds yielded only 20 to 30% of the ³H radioactivity in acidic, ethyl acetate-soluble form, and this was principally associated with the precursor, with lesser amounts of the major metabolite, [³H]GA₁ (putative identification based on sequential SiO₂ partition, and gradient-eluted reverse-phase C₁₈ high performance liquid chromatography [HPLC]). Most of the radioactivity in the dry seeds was associated with compounds having partition characteristics of, and co-chromatographing on, sequential SiO₂ partition and reverse-phase HPLC with glucosyl conjugates of the precursors (GA₄ or GA₂₀) and their probable major metabolite (GA₁). The majority of conjugate associated with the precursor GA₄ eluted coincidental with GA₄ glucoside. Subsequent acid or enzymic hydrolysis (β-glucosidase or cellulase) yielded the free GAs, putative identification being based on isocratic HPLC of each ³H-labeled conjugate → hydrolysis → isocratic HPLC of the ³H-labeled hydrolysate. Upon imbibition of the seeds, radioactivity associated with the conjugate fraction decreased; concomitantly, statistically significant increases in levels of free [³H]GA-like compounds were observed. Although the specific ratios of GA-like and GA-glucosyl conjugate-like substances varied substantially across years, hybrids, and even, in different plants from the same hybrid, this `reversible conjugation' (i.e. apparent conjugation during seed maturation followed by release of the GA moiety during germination), was reproducible for [³H]GA₂₀ in seed from two maize hybrids produced over 2 years.     

Metabolism of tritiated gibberellin a(20) in maize

After the application of 2.36 Curies per millimole [2,3-³H]gibberellin A₂₀ (GA₂₀) to 21-day-old maize (Zea mays L., hybrid CM7 × CM49) plants, etiolated maize seedlings, or maturing maize cobs, a number of ³H-metabolites were observed. The principal acidic (pH 3.0), ethyl acetate-soluble metabolite was identified as [³H]GA₁ on the basis of co-chromatography with standard [³H]GA₁ on SiO₂ partition, high resolution isocratic elution reverse phase C₁₈ high performance liquid chromatography and gas-liquid chromatography radiocounting. Two other acidic metabolites were identified similarly as [³H]GA₈ and C/D ring-rearranged [³H]GA₂₀, although gas-liquid chromatography radiocounting was not performed on these metabolites. Numerous acidic, butanol-soluble (e.g. ethyl acetate-insoluble) metabolites were observed with retention times on C₁₈ high performance liquid chromatography radiocounting similar to those of authentic glucosyl conjugates of GA₁ and GA₈, or with retention times where conjugates of GA₂₀ would be expected to elute. Conversion to [³H]GA₁ was greatest (23% of methanol extractable radioactivity) in 21-day-old maize plants. In etiolated maize seedlings, the C/D ring-rearranged [³H]GA₂₀-like metabolite was the major acidic product, while conversion to [³H]GA₁ was low.     

Biosynthetic Origin of Gibberellins A(3) and A(7) in Cell-Free Preparations from Seeds of Marah macrocarpus and Malus domestica

Cell-free preparations from seeds of Marah macrocarpus L. and Malus domestica L. catalyzed the conversion of gibberellin A₉ (GA₉) and 2,3-dehydroGA₉ to GA₇; GA₉ was also metabolized to GA₄ in a branch pathway. The preparation from Marah seeds also metabolized GA₅ to GA₃ in high yield; GA₆ was a minor product and was not metabolized to GA₃. Using substrates stereospecifically labeled with deuterium, it was shown that the metabolism of GA₅ to GA₃ and of 2,3-dehydroGA₉ to GA₇ occurs with the loss of the 1β-hydrogen. In cultures of Gibberella fujikuroi, mutant B1-41a, [1β,2β-²H₂]GA₄, was metabolized to [1,2-²H₂]GA₃ with the loss of the 1α- and 2α-hydrogens. These results provide further evidence that the biosynthetic origin of GA₃ and GA₇ in higher plants is different from that in the fungus Gibberella fujikuroi.     

Hormones of young tassels of Zea mays

The ethyl acetate-soluble acids from an aqueous methanolic extract of young tassels from Zea mays plants were fractionated by treatment with PVP, then by chromatography on a column of celite-charcoal. Methylated and trimethylsilylated fractions were analysed by GC/MS and the following compounds were identified by comparison with reference spectra: GA₁₇, GA₁₉, GA₂₀, GA₄₄, GA₅₃, ABA, phaseic acid and dihydrophaseic acid. Evidence is also presented for the presence of metabolise C of ABA and of a 16,17-dihydro-17-hydroxy-derivative of GA₅₃. In addition, the presence of small amounts of GA₁, GA₈ and GA₂₉, was indicated from a derivatized fraction analysed by capillary GC/SICM.     

Endogenous Gibberellins in Elongating Shoots of Clones of Salix dasyclados and Salix viminalis

Elongating shoots of rapidly growing clones of Salix viminalis L. (clone 683-4) and Salix dasyclados Wimm. (clone 908) harvested in early August were analyzed for endogenous gibberellins (GA). Distribution of GA-like activity, determined by Tan-ginbozu dwarf rice microdrop bioassay after reverse phase C₁₈ high performance chromatography, was similar for both species. For S. dasyclados, combined gas chromatography-selected ion monotoring (GC-SIM) yielded identifications of GA₁, GA₈, GA₁₉, GA₂₀, and GA₂₉. Identifications of GA₄ and GA₉ were also made using co-injections of known amounts of [17, 17-²H₂]GAs. By bioassay, the main activity was GA₁₉-like in both species. Gibberellin A₁, GA₁₉, and GA₂₀ concentrations were approximated by GC-SIM using co-injections of known amounts of [17,17-²H₂]GAs. Both bioassay and GC-SIM results indicated very high concentrations of GA₁₉ and GA₂₀ (about 6000 nanograms per kilogram fresh weight shoot tissue using GC-SIM: 800 ng using bioassay), compared to the concentration of GA₁ (about 130 nanograms per kilogram fresh weight using either GC-SIM or bioassay).     

Effect of photoperiod on the metabolism of deuterium-labeled gibberellin a(53) in spinach

Application of gibberellin A₅₃ (GA₅₃) to short-day (SD)-grown spinach (Spinacia oleracea L.) plants caused an increase in petiole length and leaf angle similar to that found in plants transferred to long days (LD). [²H] GA₅₃ was fed to plants in SD, LD, and in a SD to LD transition experiment, and the metabolites were identified by gas chromatography with selected ion monitoring. After 2, 4, or 6 SD, [²H]GA₅₃ was converted to [²H]GA₁₉ and [²H]GA₄₄. No other metabolites were detected. After 2 LD, only [²H] GA₂₀ was identified. In the transition experiment in which plants were given 4 SD followed by 2 LD, all three metabolites were found. The results demonstrate unequivocally that GA₁₉, GA₂₀, and GA₄₄ are metabolic products of GA₅₃, and strongly suggest that photoperiod regulates GA metabolism, in part, by controlling the conversion of GA₁₉ to GA₂₀.     

Gibberellin biosynthesis in cell-free extracts from developing Cucurbita maxima embryos and the identification of new endogenous gibberellins

Gibberellin (GA) biosynthetic pathways from GA₁₂-aldehyde, GA₁₂ and GA₅₃ were investigated in cell-free systems from developing embryos of Cucurbita maxima L. Gibberellin A₁₂-aldehyde and GA₁₂ were converted to GA₂₅, putative 12α-hydroxyGA₂₅, GA₁₃ and GA₃₉ as main products. Minor products were GA₄, GA₃₄ and, when GA₁₂ was the substrate, putative 12α-hydroxyGA₁₂. The intermediates GA₁₅ and GA₂₄ accumulated at low protein concentrations. The influence of various factors on GA₁₂ metabolism was examined. At low 2-oxoglutarate and ascorbate concentrations, or at acid pH, 3β-hydroxylated products predominated, whereas with increasing 2-oxoglutarate and ascorbate concentrations, or at neutral pH, the yield of 12α-hydroxylated GAs increased. Gibberellin A₅₃ was metabolised mainly to the C₂₀-GAs GA₄₄, GA₁₉, GA₁₇, GA₂₃ and GA₂₈, with the C₁₉-GAs GA₂₀, GA₁ and GA₈ as minor products. Only C₁₉-GAs were 2β-hydroxylated, which is a main characteristic of the embryo systems. In addition to GA₁₃, GA₂₅, GA₃₉, GA₄₃, GA₄₉, GA₅₈, GA₇₄, 12α-hydroxyGA₂₅ and GA₃₉ 3-isovalerate, which were known previously from embryos of C. maxima, GA₁, GA₄, GA₁₇, GA₂₈, GA₃₇, GA₃₈, GA₄₈, GA₈₅, 12α-hydroxyGA₃₇ and putative 12α-hydroxyGA₄₃ were identified as endogenous components by full-scan capillary gas chromatography-mass spectrometry and Kovats retention indices. Evidence for putative 2β-hydroxyGA₂₈ and GA₂₃ was also obtained but it was less conclusive because of contamination.     

Identification of Gibberellins A(1), A(5), A(29), and A(32) from Immature Seeds of Apricot (Prunus armeniaca L.)

Gibberellins (GAs) A₁, A₅, and A₂₉ were identified, and also GA₃₂ was confirmed, as endogenous GAs of immature seeds (3-4 weeks after anthesis, 0.25-0.5 gram fresh weight) of apricot (Prunus armeniaca L.) based on capillary gas chromatography (GC), retention time (Rt), and selected ion monitoring (SIM), in comparison with authentic standards. Fractions subjected to GC-SIM were purified and separated using sequential solvent partitioning → paper chromatography → reverse phase C₁₈ high performance liquid chromatography (HPLC) → bioassay on dwarf rice cv Tan-ginbozu. Two other peaks of free GA-like bioactivity (microdrop and immersion dwarf rice assays) were eluted from C₁₈ HPLC at Rts where GA_4/7 and GA₈ (or other GAs with similar structures) would elute. Also, three unidentified GA glucoside-like compounds (based on bioactivity on the immersion assay, and no bioactivity on the microdrop assay) were noted. There were very high amounts of GA₃₂ (112 ng of GA₃ equivalents per gram fresh weight), and minor amounts (0.5 ng of GA₃ equivalents) for each of GA₁ and GA₅, respectively, based on the microdrop assay.     

Enhancement of [C]Sucrose Export from Source Leaves of Vicia faba by Gibberellic Acid

The effect of gibberellic acid (GA₃) on sucrose export from source leaves was studied in broad bean (Vicia faba L.) plants trimmed of all but one source and one sink leaf. GA₃ (10 micromolar) applied to the source leaf, enhanced export of [¹⁴C]sucrose (generated by ¹⁴CO₂ fixation) to the root and to the sink leaf. Enhanced export was observed with GA treatments as short as 35 minutes. When GA₃ was applied 24 hours prior to the ¹⁴CO₂ pulse, the enhancement of sucrose transport toward the root was abolished but transport toward the upper sink leaf was unchanged. The enhanced sucrose export was not due to increased photosynthetic rate or to changes in the starch/sucrose ratio within the source leaf; rather, GA₃ increased the proportion of sucrose exported. After a 10-min exposure to [¹⁴C]GA₃, radioactivity was found only in the source leaf. Following a 2 hour exposure to [¹⁴C]GA₃, radioactivity was distributed along the entire stem and was present in both the roots and sink leaf. Extraction and partitioning of GA metabolites by thin layer chromatography indicated that there was a decline in [¹⁴C]GA₃ in the lower stem and root, but not in the upper stem. This pattern of metabolism is consistent with the disappearance of the GA₃ effect in the lower stem with time after treatment. We conclude that in the short term, GA₃ enhances assimilate export from source leaves by increasing phloem loading. In the long term (24 hours), the effect of GA₃ is outside the source leaf. GA₃ accumulates in the apical region resulting in enhanced growth and thus greater sink strength. Conversely, GA₃ is rapidly metabolized in the lower stem thus attenuating any GA effect.     

Metabolism of gibberellin a(12)-7-aldehyde by soybean cotyledons and its use in identifying gibberellin a(7) as an endogenous gibberellin

The level of gibberellin(GA)-like material in cotyledons of soybean (Glycine max L.) was highest at mid-pod fill—about 10 nanograms GA₃ equivalents per gram fresh weight of tissue, assayed in the immersion dwarf rice bioassay. This amount is about 1000-fold less than levels in Pisum and Phaseolus seed, other legume species whose spectrum of endogenous gibberellins (GAs) is well known. The metabolism of [¹⁴C]-GA₁₂-7-aldehyde (GA₁₂ald)—the universal GA precursor—by intact, mid-pod-fill, soybean cotyledons and their cell-free extracts was investigated. In 4 hours, extracts converted GA₁₂ald to two products—[¹⁴C]GA₁₂ (42% yield) and [¹⁴C]GA₁₅ (7%). Within 5 minutes, intact embryos converted GA₁₂ald to [¹⁴C]GA₁₂ and [¹⁴C]GA₁₅ in 15% yield; 4 hour incubations afforded at least 22 products (96% total yield). The putative [¹⁴C]GA₁₂ was identified as a product of [¹⁴C]GA₁₂ald metabolism on the basis of co-chromatography with authentic GA₁₂ on a series of reversed and normal phase high pressure liquid chromatography (HPLC) and thin-layer chromatography (TLC) systems, and by a dual feed of the putative [¹⁴C]GA₁₂ and authentic [¹⁴C]GA₁₂ to cotyledons of both peas and soybeans. The [¹⁴C]GA₁₅ was identified as a metabolite of [¹⁴C]GA₁₂ald by capillary gas chromatography (GC)-mass-spectrometry-selected ion monitoring, GC-radiocounting, HPLC, and TLC. By adding the [¹⁴C] metabolites of [¹⁴C]GA₁₂ald to a different and larger extract (about 0.2 kg fresh weight of soybean reproductive tissue) and purifying endogenous substances co-chromatographing with these metabolites, at least two GA-like substances were obtained and one identified as GA₇ by GC-mass spectrometry. Since [¹⁴C]GA₉ was not found as a [¹⁴C]metabolite of [¹⁴C]GA₁₂ald, soybean embryos might have a pathway for biosynthesis of active, C-19 gibberellins like that of the cucurbits; GA₁₂ald → GA₁₂ → GA₁₅ → GA₂₄ → GA₃₆ → GA₄ → GA₇.     

Biosynthesis of gibberellins A12, A15, A24, A36, and A37 by a cell-free system from Cucurbita maxima

GA₁₂-aldehyde obtained from mevalonate via ent-kaurene, ent-kaurenol, ent-kaurenoic acid and ent-7α-hydroxykaurenoic acid in a cell-free system from immature seeds of Cucurbita maxima was converted to GA₁₂ by the same system. When Mn²⁺ was omitted from the system GA₁₂-aldehyde and GA₁₂ were converted further to several products. Among these GA₁₅, GA₂₄, GA₃₆ and GA₃₇ were conclusively identified by GC-MS. With the exception of GA₃₇ these GAs have not previously been found in higher plants. Another biosynthetic pathway led from ent-7α-hydroxykaurenoic acid to very polar products via what was tentatively identified as ent-6α, 7α-dihydroxykaurenoic acid. An unidentified component with an MS resembling that of a dihydroxykaurenolide was also obtained from incubations with mevalonate.     

Dwarf mutants ofBrassica: Responses to applied gibberellins and gibberellin content

Eight rapid-cyclingBrassica genotypes differing in height were treated with gibberellins (GAs) by syringe application to the shoot tip. The height of two genotypes ofBrassica napus, Bn5-2 and Bn5-8, andB. rapa mutants,dwarf 1 (dwf1) anddwarf 2 (dwf2), was unaffected by exogenous GA₃ at dosages up to 0.1 μg/plant, a level which increased shoot elongation of normal genotypes. Thus, these dwarf mutants are “GA-insensitive.” In contrast to theB. napus dwarfs, twoB. rapa mutants,rosette (ros), anddormant (dor), elongated following GA₃ application. The dwarfros was most sensitive, responding to applications as low as 1 ng GA₃/plant. Furthermore,ros also responded to GA₁ and some of its precursors with decreasing efficacy: GA₃>ent-kaurenoic acid ≥GA₁>GA₂₀≥GA₁₉=GA₄₄≥GA₅₃. Endogenous GAs were measured by gas chromatography-selected ion monitoring using [²H₂]GA internal standards for calibration, from shoots of the GA-insensitive genotypes Bn5-2, Bn5-8 which contained theB. napus mutantdwarf 1, and from a normal genotype Bn5-1. Concentrations of GA₁ and GA₂₀ averaged 3.2- and 4.6-fold higher, respectively, and GA₁₉ levels also tended to be higher in the dwarfs than in the normal genotype.     

In Vitro Gibberellin A(1) Binding in Zea mays L

The first and second leaf sheaths of Zea mays L. cv Golden Jubilee were extracted and the extract centrifuged at 100,000g to yield a supernatant or cytosol fraction. Binding of [³H]gibberellin A₁ (GA₁) to a soluble macromolecular component present in the cytosol was demonstrated at 4°C by Sephadex G-200 chromatography. The binding component was of high molecular weight (HMW) and greater than 500 kilodaltons. The HMW component was shown to be a protein and the ³H-activity bound to this protein was largely [³H]GA₁ and not a metabolite. Binding was pH sensitive but only a small percentage (20%) appeared to be exchangeable on addition of unlabeled GA₁. Both biologically active and inactive GAs and non-GAs were able to inhibit GA₁ binding. [³H]GA₁ binding to an intermediate molecular weight (IMW) fraction (40-100 kilodaltons) was also detected, provided cytosol was first desalted using Sephadex G-200 chromatography. Gel filtration studies suggest that the HMW binding component is an aggregate derived from the IMW fraction. The HMW binding fraction can be separated into two components using anion exchange chromatography.     

Influence of photoperiod on seed development in the genetic line of peas G2 and its relation to changes in endogenous gibberellins measured by combined gas chromatography — Mass spectrometry

When apical senescence in the genetic line of peas G2 was prevented by short days fruit development was also found to be retarded. The levels of GA₂₀ and GA₂₉ in cotyledons and pods grown under long or short days were measured by gas chromatography — mass spectrometry multiple ion monitoring using extracts derivatised with deuterated trimethylsilyl groups as internal standards. The levels of GA₂₀ but not GA₂₉, were increased by short days. Conventional gas chromatography — mass spectrometry showed that relative to GA₂₉ the levels of GA₁₉, the other GA identified in G2 cotyledons, were also increased in short days. The levels of GA₂₀ in the pods were highest during the main phase of pod growth early in fruit development.Abbreviations GA_n gibberellin A_n - GC/MS gas chromatography — mass spectrometry - MIM multiple ion monitoring - Me methyl ester - SIM single ion monitoring - TIC total ion current - TMS trimethylsilyl ether - TLC thin layer chromatography - TTLC instant thin layer chromatography