Gibberellin metabolism in excised lettuce hypocotyls: Evidence for the formation of gibberellin A1 glucosyl conjugates

The properties of the water-soluble metabolites of [³H]gibberellin A₁ ([³H]GA₁) from lettuce (Lactuca sativa L.) hypocotyls were compared with those of authentic samples of gibberellin (GA) glucosyl esters and ethers. Partitioning against l-butanol at high and low pH was not an efficient method of differentiating between ester and ether conjugates of GA₁ or GA₃. Extraction into l-butanol at pH 2.5 was, however, useful as a group purification step. Gel-filtration on acrylamide indicated a mean molecular weight of ca. 600 for the polar material and high-voltage electrophoresis separated two compounds (LH 1 and LH 2) with differing charge properties. Both metabolites incorporated ¹⁴C from glucose and ³H from GA₁. Subsequent enzymatic hydrolysis of LH 1 released material with identical properties to [¹⁴C]glucose together with a second uncharacterised component. Feeding with [³H]GA₁ methyl ester greatly reduced the formation of LH 1 but not LH 2. The metabolites were provisionally identified as GA₁-glucosyl ester (LH 1) and GA₁-glucosyl ether (LH 2).Abbreviations GA gibberellin - LH1 GA₃-glucosyl ester - LH2 GA₁-glucosyl ether - HVE high voltage paper electrophoresis - TLC thin-layer chromatography     

Formation of GA20 glucosyl conjugates in seedlings ofVicia faba

[³H]GA₂₀ (1)¹, fed toVicia faba seedlings, was converted to [³H]GA₂₀ glucosyl ester (5) and [³H]GA₂₀-13-0-glucoside (6). The GA₂₀ glucosyl ester (5) was identified by HPLC-RC and by GC-MS of GA₂₀-Me formed by transesterification of (5). The [³H]GA₂₀-Me was crystallized to constant specific radioactivity with authentic GA₂₀-Me. On HPLC-RC the GA₂₀-13-0-glucoside (6) was shown to have the same retention time as an authentic sample. Subsequent enzymic hydrolysis gave a product with an HPLC retention time identical to that of authentic GA₂₀ (1).     

Metabolism of [3H]gibberellin A4 in somatic suspension cultures of anise

The native gibberellin A₄ (GA₄) was fed as [1, 2-³H]GA₄ (1.3 Ci/mmol) to anise somatic cultures maintained either at a proembryo-like stage with 2,4-dichlorophenoxyacetic acid (2,4-D), or allowed to undergo embryogenic development on a - 2,4-D medium. Proembryos, although only 20% of the dry wt of embryos, absorbed 1.4-times more [³H]GA₄/g dry wt than embryos. The [³H]GA₄ was metabolized to GA₁ and GA₈, and at least six conjugates [GA₄-glucoside (GA₄-G), GA₄ glucosyl ester (GA₄-GE), GA₁-0(3)-G, GA₁-0(13)-G, GA₁-GE and a GA₈-glucosyl conjugate]. The major metabolite was GA₄-G at each of two, 204 and 348 hr harvests (56–71 %), with GA₈-G increasing from < 1 % to 13 % with harvest time. The percentage and amount of GA₄-GE was highest at 204 hr (2% and 8 %, for embryos and proembryos, respectively), dropping to < 1 % at 348 hr, thereby indicating hydrolysis (e.g. reversible conjugation). Embryos had reduced amounts and percentages of biologically active GA₄ and GA₁, and most of their conjugates, but increased amounts and percentages of GA₈ and its conjugate(s). This finding is consistent with the hypothesis (based on present and past work) that high levels of biologically active GAs, especially GA₁, inhibit somatic embryogenesis in anise and carrot. The auxin, 2,4-D, may thus derive, at least in part, its ability to maintain the proembryo-like stage by inhibiting oxidative metabolism and conjugation of biologically active GAs.     

Metabolism of [3H]gibberellin A5 in developing pharbitis nil seeds

The native gibberellin A₅ (GA₅), as [1-³H]GA₅ (3.2 Ci/mmol) was fed to seed capsules (0.58 μCi/capsule) of Pharbitis nil cv Violet at the 2-week stage of development, and its metabolism in the seeds was investigated after 43 hr. Extractable radioactivity in free GA metabolites was 38%, with 56% in GA glucosyl conjugate-like substances. Only 2.5% of the extractable radioactivity remained as [³H]GA₅. Tentative identifications, based on comparisons with authentic standards after sequential chromatography on silica gel partition column → gradient-eluted C₁₈ HPLC → isocratic-eluted C₁₈ HPLC-radiocounting (RC), showed that [³H]GA₅ was converted to at least six free GAs, GA₁, GA₃, GA₆, GA₈, GA₂₂, GA₂₉, a GA₅ methyl ester-like metabolite, and at least twelve GA glucosyl conjugate-like substances, GA₅-glucoside (GA₅-G), GA₅-glucosyl ester (GA₅-GE), GA₁-O(3)-G, GA₁-O(13)-G, GA₁-GE, GA₃-O(3)-G, GA₃-O(13)-G, GA₃-GE, GA₆-G or GE, GA₈-O(2)-G, GA₂₂-G or GE and GA₂₉-O(2)-G. After lower specific activity feeds of [1,2-³H]GA₅ (74 mCi/mmol; 0.1 μCi/capsule) at approximately the same stage of development, the presence of GA₁, GA₃, GA₅, GA₆, GA₈ and GA₂₉ was further confirmed by sequential (after C₁₈ HPLC-RC) capillary gas chromatography-selected ion monitoring (GC-SIM), using six characteristic ions. However, for GA₂₂ only a trace of the parent ion was present at the appropriate retention time.     

Metabolism of [H]Gibberellin A(5) by Immature Seeds of Apricot (Prunus armeniaca L.)

Immature seeds of apricot (Prunus armeniaca L.) were fed the native gibberellin A₅ (GA₅) as 1- and 1,2-[³H]GA₅ (5.3 Curies per millimole to 16 milliCuries per millimole) at doses (42 nanograms to 10.6 micrograms per seed) 2 to 530 times the expected endogenous level. After 4 days of incubation, seeds were extracted and free [³H]GA-like metabolites were separated from the highly H₂O-soluble [³H]metabolites. For high specific activity feeds the retention times (Rts) of radioactive peaks were compared with Rts of authentic GAs on sequential gradient-eluted → isocratic eluted reversed-phase C₁₈ high performance liquid chromatography (HPLC) -radiocounting (RC). From high substrate feeds (530 and 230 × expected endogenous levels) HPLC-RC peak groupings were subjected to capillary gas chromatography-selected ion monitoring (GC-SIM), usually six characteristic ions. The major free GA metabolites of [³H] GA₅ were identified as GA₁, GA₃, and GA₆ by GC-SIM. The major highly water soluble metabolite of [³H]GA₅ at all levels of substrate GA₅ had chromatographic characteristics similar to authentic GA₁-glucosyl ester. Expressed as a percentage of recovered radioactivity, low substrate [³H]GA₅ feeds (2 × expected endogenous level) yielded a broad spectrum of metabolites eluting at the Rts where GA₁, GA₃, GA₅ methyl ester, GA₆, GA₂₂, GA₂₉ (17, 14, 1.6, 7, 1.1, 0.5%, respectively) and GA glucosyl conjugates of GA₁, GA₃, GA₅, and GA₈ (33, 11, 1, 0.1%, respectively) elute. Metabolites were also present at Rts where GA glucosyl conjugates of GA₆ and GA₂₉ would be expected to elute (8 and 0.1%, respectively). Only 5% of the radioactivity remained as GA₅. Increasing substrate GA₅ levels increased the proportion of metabolites with HPLC Rts similar to GA₁, GA₆, and especially GA₁ glucosyl ester, primarily at the expense of metabolites with HPLC Rts similar to GA₃, GA₃-glucosyl ester, and a postulated conjugate of GA₆. There was evidence that high doses of substrate GA₅ induced new metabolites which often, but not always, differed from GA₁, GA₃, and GA₆ in HPLC Rt. These same metabolites, when analyzed by GC-SIM yielded m/e ions the same as the M⁺ and other characteristic m/e ions of the above GAs, albeit at differing GC Rt and relative intensities.     

Metabolism of [1,2-3H]gibberellin A4 by epicotyls and cell-free preparations from Phaseolus coccineus L. seedlings

Cell-free systems were prepared from germinating seed and seedlings of Phaseolus coccineus. Gibberellin A₄ (GA₄)-metabolising activity was detected in vitro using preparations from roots, shoots and cotyledons of germinating seed, but only up to 24 h after imbibition. Cell-free preparations from cotyledons converted [³H]GA₄ to GA₁, GA₃₄, GA₄-glucosyl ester and a putative O-glucoside of GA₃₄, and, in addition converted [³H]GA₁ to GA₈. Preparations from embryo tissues contained 2-hydroxylase activity, converting [³H]GA₄ to GA₃₄ and [³H]GA₁ to GA₈.The presence of GA-metabolising enzymes was also indicated by in-vivo feeds of [³H]GA₄ to epicotyls of intact 4-d-old seedlings, which resulted in the accumulation of GA₁, GA₈, GA₃-3-O-glucoside, GA₄-glucosyl ester, GA₈-2-O-glucoside and a putative O-glucoside of GA₃₄. Gibberellin A₁ was the first metabolite detected, 15 min after application of [³H]GA₄, but after 24 h most of the label was associated with GA₈-2-O-glucoside. Over 90% of the recovered radioactivity was found in the shoot. Within the shoot, movement was preferentially acropetal, and was not dependent upon metabolism of the applied [³H]GA₄.Abbreviations DEAE diethylaminoethyl - GA_n gibberellin A_n - GPC gel permeation chromatography - HPLC-RC high performance liquid chromatography-radio counting - S-1 1000·g supernatant - UDP uridine 5-diphosphate     

Metabolism of [3H] Gibberellin A5 in Cell Suspension Cultures of Pharbitis nil

Gibberellin A₅ (GA₅), a native GA of immature seeds of Pharbitis nil, was fed to Pharbitis nil cell suspension cultures as [C-l, ³H] GA₅ (3.1 Ci/mmol), and its metabolism over a 48 hr period was investigated. Radioactivity in free GA metabolites was 13.1%, with 79.9% in GA glucosyl conjugate-like metabolites. Only 7.0% of the radioactivity remained as [³H] GA₅. Tentative identifications were based on comparison with retention times of authentic free GAs and/or glucosyl conjugates after sequential chromatography on Si gel partition column → gradient-eluted C18 HPLC-radiocounting (RC) → isocratic-eluted C18 HPLC-RC, and showed that [³H] GA₅ was converted to [³H] GA₁ (2%), [³H] GA₃ (4%), [³H] GA₆ (2%), [³H] GA₂₂ (1%) and their glucosyl conjugates, and also to [³H] GA₈ glucoside, and [³H] GA₅ glucosyl conjugates. The major conjugate-like substances were [³H] GA₁ and [³H] GA₃ glucosyl esters, at 15% and 34%, respectively, of the total extractable radioactivity.     

Metabolism of Tritiated Gibberellins in d-5 Dwarf Maize: I. In Excised Tissues and Intact Dwarf and Normal Plants

Metabolism of [³H]gibberellin A₁ ([³H]GA₁) was followed in intact seedlings and excised apices and leaf tissue of both dwarf and normal (tall) plants of d-5 maize (Zea mays L.). The three metabolites produced were tentatively identified as [³H]GA_s, [³H]GA_s-glucoside ([³H]GA_s-glu), and [³H]GA₁-X, an unknown.     

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 influence of dwarfing interstocks on the distribution and metabolism of xylem-applied [h]gibberellin a(4) in apple

The influence of an interstock of the dwarfing cultivar M9 and the nondwarfing cultivar MM115 on the distribution and metabolism of labeled gibberellic acid A₄ ([³H]GA₄) of high specific radioactivity (5.18 × 10¹⁰ becquerel per millimole) applied to the xylem of the rootstock in grafted apple (Malus × domestica Borkh.) trees was compared. Free [³H] GA-like metabolites of [³H]GA₄, including putative GA₁, GA₂, GA₃, and GA₃₄, as well as various ³H-putative GA glucosyl conjugates were detected in stem segments from both cultivars. M9 interstocks reduced the total uptake of [³H]GA₄ and decreased the proportion of ³H metabolites transported to the shoots and leaves of scions. The M9 interstock tissue and adjacent rootstock and scion tissue retained a much greater amount and a higher proportion of the label than did comparable tissue of the nondwarfing MM115 interstock. In addition, the amount and proportion of free [³H]GAs was higher, and the proportion of putative [³H]GA glucosyl conjugates lower, in M9 interstocks compared to MM115. These effects of the dwarfing interstock on GA distribution and metabolism indicate a significant role for GAs in any satisfactory explanation of the dwarfing mechanism in apple.     

Heterosis and the metabolism of gibberellin A20 in sorghum

The correlation between gibberellin (GA) metabolism and growth rate was investigated using two Sorghum bicolor inbred lines, Hegari and AT×623, and their heterotic F₁ hybrid. Previous studies have demonstrated that this hybrid is taller and has substantially greater shoot dry weights and leaf areas than either parental inbred. [³H]GA₂₀ was applied to the leaf whorl of seedlings and after 24 hours, plants were harvested and separated into roots, shoot cylinders containing the apical meristems, and leaf blades. Chromatographic analyses of metabolites indicated the conversions of [³H]GA₂₀ to [³H]GA_{1,8 and 29}. The conversion of [²H]GA₂₀ to [²H]GA₁ was demonstrated by gas chromatography-selected ion monitoring (GC-SIM). Putative glucosyl conjugates of all of the [³H]GAs were also produced and GA₈ was identified by GC-SIM following enzymic cleavage of the putative [³H]GA₈ glucosyl conjugate fraction. Comparing the genotypes, [³H]GA₂₀ metabolism was more rapid in the shoot cylinders of the hybrid than in the shoot cylinders from inbreds. In the hybrid samples, there was a three-fold increase in the putative conjugate(s) of [³H]GA₁ which was the principal metabolite, and increased production of [³H]GA₈ and the putative conjugates of [³H]GA₂₉ and [³H]GA₈. Conversely, levels of the remaining precursor, [³H]GA₂₀, and its putative conjugate(s) were reduced in the hybrid. The rate of GA₂₀ metabolism was thus positively correlated with growth rate across these sorghum genotypes. This correlation supports a promotive role of GA in the regulation of shoot growth and in the expression of heterosis (hybrid vigor) in sorghum.     

The transport and metabolism of gibberellins A1 and A5 in excised segments from internodes of Phaseolus coccineus

Jacobs, W. P., Beall, F. D. and Pharis, R. P. 1988. The transport and metabolism of gibberellins A₁ and A₅ in excised segments from internodes of Phaseolus coccineus. -Physiol. Plant. 72: 529–534. The transport and metabolism of gibberellins (GAs) ([³H]-GA, and [³H]-GA₅) of high specific radioactivity were investigated in excised segments from young internodes of Phaseolus coccineus L. Both GA₁ and GA₅ are native to this species and present in shoot tissue. The segments, 5.1 mm long, were incubated for 6 h in the horizontal position with agar donor blocks containing the [³H]-GA on the morphological apical or basal ends and with plain agar receiver blocks on the opposite end. At the end of incubation, the individual agar blocks were analyzed immediately for total radioactivity, or both blocks and intervening tissue were frozen and freeze-dried for later chromatographic analysis. The movement of both [³H]-GA, and [³H]-GA₅ was found to be consistently without polarity. However, approximately 5-fold more [³H]-GA, than [³H]-GA₅ was transported through the Phaseolus segments into receivers when equal amounts were in the donors. The extractable radioactivity from receiver blocks was primarily that of the donor GA. No putative GA conjugates were found in any class of receivers, but more GA metabolites were found in the free acid fraction from acropetal than basipetal receivers. Chromatographic analysis by reversed phase C₁₈ high performance liquid chromatography of the tissue segments showed that [³H]-GA, was metabolized more than [³H]-GA₅. Tissue adjacent to receiver blocks contained not only the precursor GA from the donor, but also polar ‘free GA metabolites’ and putative GA glucosyl conjugates. These results provide evidence that GA., which is the known ‘effector’ GA for elongation in shoot tissue of several species, is more effectively transported than GA₅ (a known precursor of GA₁) or than GA₁s more polar metabolites.     

Metabolism of Tritiated Gibberellins in d-5 Dward Maize: II. [H]Gibberellin A(1), [H]Gibberellin A(3), and Related Compounds

After 30 minutes of incubation of young leaf sections of d-5 maize (Zea mays L.) in [³H]gibberellin A₁ ([³H]GA₁), the metabolite [³H]GA₈ was present in significant amounts, with a second metabolite, [³H]GA₈-glucose ([³H]GA₈-glu), appearing soon after. A third [³H]GA₁ metabolite, the polar uncharacterized conjugate [³H]GA₁-X, took more than 1 hour to appear. The protein synthesis inhibitor cycloheximide inhibited the production of all [³H]GA₁ metabolites, indicating a possible protein synthesis requirement for [³H]GA₁ metabolism.     

Biological activity of some synthetic gibberellin glucosyl esters

Four gibberellin (GA₁, GA₃, GA₄ and GA₃₇) glucosyl esters were synthesized and found to be as active as their respective free acids in the rice seedling bioassay. The rapid hydrolysis of the glucosyl esters in rice seedlings was demonstrated by feeding experiments with glucosyl esters of [³H]GA₁ and [³H]GA₄.     

Formation of GA20 glucosyl conjugates in seedlings ofVicia faba

[³H]GA₂₀ (1)¹, fed toVicia faba seedlings, was converted to [³H]GA₂₀ glucosyl ester (5) and [³H]GA₂₀-13-0-glucoside (6). The GA₂₀ glucosyl ester (5) was identified by HPLC-RC and by GC-MS of GA₂₀-Me formed by transesterification of (5). The [³H]GA₂₀-Me was crystallized to constant specific radioactivity with authentic GA₂₀-Me. On HPLC-RC the GA₂₀-13-0-glucoside (6) was shown to have the same retention time as an authentic sample. Subsequent enzymic hydrolysis gave a product with an HPLC retention time identical to that of authentic GA₂₀ (1).     

Interconversion of gibberellin A1 to gibberellin A8 in seedlings of dwarf Oryza sativa

[³H]Gibberellin A₁ ([³H]GA₁)applied to seedlings of dwarf rice (Oryza sativa L. cv. Tanginbozu) was metabolized to GA₈. Identification of GA₈, was made by gas-liquid radiochromatography using three liquid stationary phases.     

Lack of influence of photoperiod on the metabolism of gibberellin A20 in Salix pentandra

The influence of photoperiod on the metabolism of GA₂₀ in Salix pentandra was studied by feeding [³H]-GA₂₀ to seedlings which had been grown previously under long day (LD) or short day (SD) conditions. After 48 h in LD or SD, metabolites were separated on sequential, silica gel partition columns and reversed-phase C₁₈ HPLC. The principal metabolite co-chromatographed with [³H]-GA₁ and this conversion was confirmed by feeding [²H]-GA₂₀, which was converted to [²H]-GA₁ as identified by gas chromatography-selected ion monitoring. Chromatographic evidence also indicated the minor conversion of [³H]-GA₂₀ to [³H]-GA₈ (via [³H]-GA₁) and trace conversion to [³H]-GA₂₉ (GAs A_1.8,20.29 are native in Salix). Ethyl acetate-insoluble [³H] metabolites were formed and could be cleaved by cellulase to release putative [³H]-GA₂₀ and [³H]-GA₁ suggesting the conversion to glucosyl conjugates of these GAs. Metabolism of [³H]-GA₂₀ was slightly more rapid in plants previously grown under LD than SD, an effect which reflected the generally increased shoot growth under LD. However, altering the photoperiod after [³H]-GA₂₀ addition had only a slight effect on the metabolism of [³H]-GA₂₀ in Salix seedlings. This indicates that the conversion of GA₂₀ to GA₁ is not a controlling step in the photoperiodic regulation of growth cessation in Salix.     

Gibberellins and Gravitropism in Maize Shoots : Endogenous Gibberellin-Like Substances and Movement and Metabolism of [3H]Gibberellin A20

[³H]Gibberellin A₂₀ (GA₂₀) of high specific radioactivity (49.9 gigabecquerel per millimole) was applied equilaterally in a ring of microdrops to the internodal pulvinus of shoots of 3-week-old gravistimulated and vertical normal maize (Zea mays L.), and to a pleiogravitropic (prostrate) maize mutant, lazy (la). All plants converted the [³H]GA₂₀ to [³H]GA₁⁻ and [³H]GA₂₉-like metabolites as well as to several metabolites with the partitioning and chromatographic behavior of glucosyl conjugates of [³H]GA₁, [³H]GA₂₉, and [³H]GA₈. The tentative identification of these putative [³H]GA glucosyl conjugates was further supported by the release of the free [³H]GA moiety after cleavage with cellulase. Within 12 hours of the [³H]GA₂₀ feed, there was a significantly higher proportion of total radioactivity in lower than in upper halves of internode and leaf sheath pulvini in gravistimulated normal maize. Further, there was a significantly higher proportion of putative free GA metabolites of [³H]GA₂₀, especially [³H]GA₁, in the lower halves of normal maize relative to upper halves. The differential localization of the metabolites between upper and lower halves was not apparent in the pleiogravitropic mutant, la. Endogenous GA-like substances were also examined in gravistimulated maize shoots. Forty-eight hours after gravistimulation of 3-week-old maize seedlings, endogenous free GA-like substances in upper and lower leaf sheath and internode pulvini halves were extracted, chromatographed, and bioassayed using the `Tanginbozu' dwarf rice microdrop assay. Lower halves contained consistently higher total levels of GA-like activity. The qualitative elution profile of GA-like substances differed consistently, upper halves containing principally a GA₂₀-like substance and lower halves containing mainly GA₁-like and GA₁₉-like substances. Gibberellins A₁ (10 nanograms per gram) and A₂₀ (5 nanograms per gram) were identified from these lower leaf sheath pulvini by capillary gas chromatography-selected ion monitoring. Results from all of these experiments are consistent with a role for GAs in the differential shoot growth that follows gravitropism, although the results do not eliminate the possibility that the redistribution of GAs results from the gravitropic response.     

The synthesis of [3H]gibberellin A3 and [3H]gibberellin A1 by the palladium-catalyzed actions of carrier-free tritium on gibberellin A3

Reaction of gibberellin A₃ (GA₃) with carrier-free tritium gas and 5% palladium on calcium carbonate as catalyst gave a complex mixture of products, several of which were isolated and identified. Three of the purified products are the radioactive forms of naturally occurring gibberellins: [³H]GA₃ (1), [³H]GA₁ (2) and [³H]tetrahydro GA₃ (4). Another substance was isolated and tentatively identified as [³H]16,17-dihydro GA₃ (3). GLC was used to determine the specific activities of 1 and 2. [³H]GA₃ likely arises from palladium catalysed nonspecific exchange of GA₃ alkane hydrogen atoms with tritium. [³H]GA₁ is also exchange labeled but most of its radioactivity is due to tritium addition to the C-1,2 olefinic bond of GA₃.     

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.