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.     

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.     

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 [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.     

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.     

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.     

Interconversion of gibberellin A5 to gibberellin 3 in seedlings of dwarf Pisum sativum

[³H]-Gibberellin A₅ ([³H]-GA₅) applied to seedlings of dark-grown dwarf pea (Pisum sativum L. cv. Meteor), was converted to two acidic compounds, GA₃ and a chromatographically similar unknown. Identification of GA₃ was made by gas-liquid radiochromatography using three stationary phases.     

Biological activities of new gibberellins A30-A35 and A35 glucoside

The plant growth-promoting activities of new gibberellins, GA₃₀, GA₃₀, GA₃₂, GA₃₃, GA₃₄, GA₃₅ and GA₃₅ glucoside were evaluated in seven bioassays. In general GA₃₀, GA₃₀, and GA₃₅ showed fairly high biological activities, whilst GA₃₃, GA₃₄ and GA₃₅ glucoside were almost inactive. GA₃₂ was highly active, behaving similarly to GA₃. It is suggested that the C-11β and C-12α hydroxyl groups have little influence on growth-promoting activity, although the C-12α hydroxyl group reduces activity in the cucumber hypocotyl assay.     

Conversion of gibberellin A14 to other gibberellins in seedlings of dwarf Pisum sativum

Gibberellin A₁₄-[17-³H] applied to seedlings of dark grown dwarf pea (Pisum sativum L. cy. Meteor) was converted to GA₁, GA₈, GA₁₈, GA₂₃, GA₂₈, and GA₃₈. The sequence of interconversion of GA₁₄→ GA₁₈ → GA₃₈ → GA₂₃ → GA₁ → GA₈ is indicated. Identifications were made by gas-liquid radiochromatography using three liquid stationary phases.     

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

The native gibberellin A₄ (GA₄), in radioactive form ([1,2-³H]GA₄, 1.06 Ci/mmol), was fed to carrot somatic cell cultures (suspension and immobilized cell systems) and its metabolism over a 48 hr period was investigated. It was found that the [³H]GA₄ was metabolized to at least two GAs, [³H]GA₁ and [³H]GA₈, six GA glucosyl conjugates, [³H]GA₁-0(3)-glucoside, [³H]GA₁-0(13)-glucoside, [³H]GA₁-glucosyl ester, [³H]GA₄-glucoside, [³H]GA₄-glucosyl ester, a [³H]GA₈ glucosyl conjugate(s) and a previously unknown [³H]GA₁ glucosyl conjugate ([³H]GA₁-0(3,13)-diglucoside-like compound). The GA₁-diglucoside-like compound was found only in extracts of cells and was present in significant amounts (33 % of total extractable radioactivity). All other metabolites were present in both cells and medium. For extracts of the medium, no differences between the suspension and immobilized cultures existed in types of [³H]GA₄ metabolites although quantitative differences were apparent.     

Gibberellin A43 and other terpenes in endosperm of Echinocystis macrocarpa

By GC-MS the following acidic constituents of the endosperm of Echinocystis macrocarpa were identified: abscisic acid and its trans,trans-isomer, 4′-dihydrophaseic acid, GA₄, GA₇, iso-GA₇, GA₂₄, GA₂₅, two isomers of GA₁₃, GA₄₃, ent-6α,7α,17-trihydroxy-16αH-kauran-19-oic acid and ent-6α,7α, 16β, 17-tetrahydroxykauran- 19-oic acid. The structures of the last three new natural products were confirmed by partial synthesis. ent-Kaurene was detected in the neutral fraction.     

Gibberellin A9 glucosyl ester in needles of Picea sitchensis

A polar gibberellin-like substance present in needles of Picea sitchensis was identified as GA₉-β-d-glucosyl ester on the basis of enzymatic hydrolysis and identification of the aglycone by GC-MS. The biological activity of the synthetic material was tested in two bioassays.     

Identification of endogenous gibberellins, and metabolism of tritiated and deuterated GA4, GA9 and GA20, in Scots pine (Pinus sylvestris) shoots

The application of gibberellin A_4/7 (GA_4/7) to the stem of previous-year (1-year-old) terminal shoots of Scots pine (Pinus sylvestris) seedlings has been observed to stimulate cambial growth locally, as well as at a distance in the distal current-year terminal shoot, but the distribution and metabolic fate of the applied GA_4/7, as well as the pathway of endogenous GA biosynthesis in this species, has not been investigated. As a first step, we analysed for endogenous GAs and monitored the transport and metabolism of labelled GAs 4, 9 and 20. Endogenous GAs from the elongating current-year terminal shoot of 2-year-old seedlings were purified by column chromatography and high-performance liquid chromatography and analysed by combined gas chromatography-mass spectrometry (GC-MS). GAs 1, 3, 4, 9, 12 and 20 were identified in the stem, and GAs 1, 3 and 4 in the needles, by full-scan mass spectrometry (GAs 1, 3, 4, 9 and 12) or selected-ion monitoring (GA₂₀) and Kovats retention index. Tritiated and deuterated GA₄, GA₉ or GA₂₀ were applied around the circumference at the midpoint of the previous-year terminal shoot, and metabolites were extracted from the elongating current-year terminal shoot, the application point, and the 1-year-old needles and the cambial region above and below the application point. After purification, detection by liquid scintillation spectrometry and analysis by GC-MS, it was evident that, for each applied GA, unmetabolised [²H₂]GA and [³H]radioactivity were present in every seedling part analysed. Most of the radioactivity was retained at the application point when [³H]GA₉ and [³H]GA₂₀ were applied, whereas the largest percentage of radioactivity derived from [³H]GA₄ was recovered in the current-year terminal shoot. It was also found that [²H₂]GA₉ was converted to [²H₂]GA₂₀ and to both [²H₂]GA₄ and [²H₂]GA₁, [²H₂]GA₄ was metabolised to [²H₂]GA₁, and [²H₂]GA₂₀ was converted to [²H₂]GA₂₉. The data indicate that for Pinus sylvestris shoots (1) GAs applied laterally to the outside of the vascular system of previous-year shoots not only are absorbed and translocated extensively throughout the previous-year and current-year shoots, but also are readily metabolised, (2) the GA metabolic pathways found are closely related to the endogenous GAs identified, and (3) GA₉ metabolism follows two distinctly different routes: in one, GA₉ is converted to GA₁ through GA₄, and in the other it is converted to GA₂₀, which is then metabolised to GA₂₉. The results suggest that the late 13-hydroxylation pathway is an important route for GA biosynthesis in shoots of Pinus sylvestris, and that the stimulation of cambial growth in Scots pine by exogenous GA_4/7 may be due to its conversion to GA₁, rather than to it being active per se.     

Molecular characterisation of gibberellin 20-oxidases. Structure-function studies on recombinant enzymes and chimaeric proteins

Gibberellin (GA) 20-oxidases are multifunctional enzymes that catalyse reactions at an important branch point in the GA biosynthetic pathway. These enzymes oxidise the C-20 methyl group of a diterpene carboxylic acid precursor (e.g. GA₁₂) to form an alcohol (in our case GA₁₅-open lactone) and an aldehyde (GA₂₄). The aldehyde is either oxidised to a tricarboxylic acid (GA₂₅) or, with loss of carbon-20 and lactonisation, to a C₁₉-GA (GA₉). This branching is interesting to study, because C₁₉-GA derivatives function as plant hormones in different tissues, whereas the C₂₀-GA tricarboxylic acids have no known function. We have constructed chimaeric proteins by combining a GA 20-oxidase from immature seeds of Cucurbita maxima L., which produces mainly C-20 carboxylic acids, with a 20-oxidase from Marah macrocarpus immature seeds, which forms predominantly CC₁₉-GAs. The cDNAs encoding these two very similar 20-oxidases were digested with restriction endonucleases Van 911. Bcl 1, and Bsa WI, and six chimaeric sequences were produced by recombination of the DNA fragments. The pCM1 -construct was obtained by exchanging nt 303–809 of the Cucurbita cDNA with the homologous DNA from the March 20-oxidase. In pCM2, pCM3, pCM4, pCM5 and pCM6, nt 810–992, nt 993–end, nt 303–992, nt 810–end, and nt 311–end were exchanged, respectively. All constructs were cloned in a pUC18 vector and functionally expressed in E. coli NM522 cells. GA 20-oxidase activity was detectable in cell-lysates from the transformed E. coli, but the extent and kind of conversion depended on the construct. Highest conversion of GA₁₂was found with pCM1 and pCM3, one-tenth of this conversion was observed with pCM5 and pCM6, and one-hundredth was obtained with the hybrid proteins from pCM2 and pCM4. With pCM2 and pCM4, neither the C₁₉-end product, GA₉, nor the C₂₀-end product, GA₂₅-was formed. However, after transformation with constructs pCM1, pCM3, pCM5 or pCM6. GA₉accounted for 30, 40, 60 and 90%, respectively, of the end products formed. Thus, the segments originating from M. macrocarpus conferred upon the chimaeric proteins an increasing ability to direct the biosynthetic flow into C₁₉-GAs in this order. Although GA₂₄is the immediate precursor, much less end products were formed by using this substrate.     

Leukotriene A4: Enzymatic conversion to leukotriene C4

An unstable epoxide, leukotriene A₄ (5(S)-$\text{trans}$-5,6-oxido-7,9-$\text{trans}$-11,14-$\text{cis}$-eicosatetraenoic acid), was earlier proposed to be an intermediate in the conversion of arachidonic acid into the slow reacting substance (SRS), leukotriene C₄. In the present work synthetic leukotriene A₄ was incubated with human leukocytes or murine mastocytoma cells. A lipoxygenase inhibitor, BW755C, was added in order to prevent leukotriene formation from endogenous substrate. Leukotriene C₄ and 11-$\text{trans}$-leukotriene C₄ were the main products with SRS activity. It was not established whether the 11-$\text{trans}$-compound was formed by isomerization at the leukotriene A₄ or C₄ stage.     

Gibberellin biosynthetic pathway and the physiologically active gibberellin in the shoot ofCucumis sativus L.

[²H₂]Gibberellin A₂₄ (GA₂₄) and [²H₄]-GA₉ were applied to the apices of normal-type cucumber (Cucumis sativus L. cv. Yomaki) seedlings treated with uniconazole, an inhibitor of GA biosynthesis. The metabolites from these feeds were identified by full-scan gas chromatography-mass spectrometry (GC-MS) to confirm the conversions of [²H₂]GA₂₄ to [²H₂]GA₉ and of [²H₄]GA₉ to [²H₄]GA₄. The results show that GA₄ is biosynthesized from GA₂₄ via GA₉. In a cucumber hypocotyl elongation bioassay using cv. Yomaki, prohexadione (DOCHC), an inhibitor of 2-oxoglutaratedependent dioxygenase, inhibited the hypocotyl elongation caused by application of GA₉, while DOCHC enhanced the elongation caused by application of GA₄. These results indicate that GA₄ is a physiologically active GA and that the activity of GA₉ is due to its conversion to GA₄ in cucumber shoots.     

Synthesis of GA20 glucosyl derivatives and the biological activity of some gibberellin conjugates

GA₂₀-13-0-glucoside (7a) and GA₂₀ glucosyl ester (6a), potential endogenous conjugates in maize, were synthesized chemically. The biological activities of these compounds and of nine more GA glucosyl derivatives were determined using theZea mays dwarf- 5 seedling andOryza sativa cv. Tan-ginbozu assays. The relative bioactivities of the conjugates were also calculated.     

Metabolism of gibberellin A19 is under photoperiodic control in Populus, Salix and Betula, but not in daylength-insensitive Populus overexpressing phytochrome A

Application experiments have suggested that short‐day‐induced cessation of elongation growth in trees is caused by photoperiodic regulation of the conversion of gibberellin GA₁₉ to GA₂₀. In the present study we examined further the photoperiodic control of GA metabolism in trees with focus on the conversion of GA₁₉ in Salix pentandra, hybrid aspen (Populus tremula × tremuloides) and silver birch (Betula pendula) using [17,17‐²H₂]‐GA₁₉ or unlabelled GAs in application studies. GA₂₀ and GA₁ were able to restore growth also in hybrid aspen and silver birch under short days (SD), whereas GA₁₉ had no or only a very small activity. Contrary to hybrid aspen and S. pentandra, the activity of GA₂₀ in silver birch was significantly lower than that of GA₁. Gas chromatography‐mass spectrometry (GC‐MS) analysis revealed a smaller turnover of [²H₂]‐GA₁₉ in SD than in long days (LD) in hybrid aspen. No such difference in turnover of [²H₂]‐GA₁₉ was observed in photoperiod‐insensitive hybrid aspen overexpressing PHYA. Application of unlabelled GAs to seedlings of S. pentandra, hybrid aspen and silver birch under SD followed by quantification of metabolites by GC‐MS analysis, showed that applied GA₁₉ was not readily converted to GA₂₀ and GA₁. Although the sensitivity to GAs is also known to decrease under SD, the present data are in favour of a photoperiodic regulation of the metabolism of GA₁₉in vivo in the woody species S. pentandra, hybrid aspen and silver birch. The data might also suggest that silver birch differs from S. pentandra and hybrid aspen by exhibiting a possible photoperiodic control also of the conversion of GA₂₀ to GA₁.     

Interconversion of gibberellin A20 to gibberellin A29 by etiolated seedlings and germinating seeds of dwarf Pisum sativum

Tritium labelled gibberellin A₂₀ ([³H]-GA₂₀) applied to etiolated shoots and germinating seeds of dwarf pea (Pisum sativum L. cv. Meteor) was converted to gibberellin A₂₉. Identifications were made by GLRC and GC-MS.