Metabolism of Tritiated Gibberellin A(9) by Shoots of Dark-grown Dwarf Pea, cv. Meteor

Tritium-labeled gibberellin A₉ (³H-GA₉) was metabolized by etiolated shoots of dwarf pea (Pisum sativum cv. Meteor) to GA₂₀, GA₁₀, 2,3-dihydro-GA₃₁, and a number of highly polar, acidic GA-like substances. Identifications were made by gasliquid radiochromatography and combined gas chromatography-mass spectrometry. Kinetic studies showed that GA₃₀ and 2,3-dihydro-GA₃₁ were produced within 5 hours following ³H-GA₉ application to pea shoots. The polar GA-like substances were produced between 5 and 10 hours after ³H-GA₉ application. Levels of GA₁₀ increased with time, and since no GA₁₀ was produced during the purification procedures, GA₁₀ was, in all probability, produced from ³H-GA₉ within the plant tissue. The radioactive interconversion products produced by pea from ³H-GA₉ have chromatographic properties similar to biologically active GA-like substances present in etiolated shoots of dwarf pea. Large scale applications of ³H-GA₉ with very low specific activity to etiolated pea shoots showed that the radioactivity of the interconversion products was correlated exactly with biological activity as assayed by dwarf rice (Oryza sativa cv. Tan-ginbozu).     

Uptake and metabolism of radioactive gibberellins by barley aleurone layers

Summary When aleurone layers were treated with labeled gibberellin A₁ (³H-GA₁), gibberellin A₅ (³H-GA₅) and the methyl ester of ³H-GA₅ (³H-GA₅-ME), radioactivity was accumulated by the tissue for a period of 20–30 h. After this time, radioactivity was released into the medium. Concomitantly, ribonuclease was also liberated by the tissue. The radioactivity accumulated by aleurone layers was associated with polar metabolites of the respective GAs, and the extent of extent of accumulation was a function of the degree of GA metabolism (GA₅-ME>GA₅>GA₁). Accumulation of radioactivity was inhibited in the cold and by the metabolic poisons NaF and dinitrophenol. This was thought to be due to inbition of GA metabolism. The accumulation of ³H-GA₁ in aleurone tissue did not reach saturation when unlabeled GA₃ up to 10^-2 M was added to the incubation medium.Abbreviations GA gibberellin - GA₅ ME, gibberellin A₅ methyl ester - RNase ribonuclease     

In-vivo binding of radioactive gibberellins in dwarf pea shoots

Summary When shoots of 6-day-old, dark-grown peas were excised 30 mm below the apex and floated on a solution of radioactive gibberellin A ₁ (³H-GA₁) or radioactive gibberellin A₅ (³H-GA₅), more radioactivity accumulated in the apical part of the stem which responds to GA than in the basal, unresponsive region. The accumulation of ³H-GA₁ was, however, less pronounced than the accumulation of ³H-GA₅. GA derivatives of very low biological activity were not taken up preferentially by the apical region of the stem. Light, which lowers the responsiveness of dwarf peas to GA₁ and particularly to GA₅, also reduced the accumulation of these GAs in the apical part of the stem. Sections from the GA-responsive region were able to retain a higher level of GA₅ than sections from the non-responsive, basal region. The accumulation and retention of GA in the hormone-responsive tissue may be due to binding of the hormone to specific GA receptors.This work was supported by the United States Atomic Energy Commission under Contract AT (11-1)-1338.     

Fate of radioactive gibberellin a(1) in maturing and germinating seeds of peas and Japanese morning glory

Radioactive gibberellin A₁ (³H-GA₁) was injected into excised fruits of peas and Japanese morning glory. These were then grown in sterile culture to maturity and the label was followed in the seeds during further development and subsequent germination. During development of both pea and morning-glory seeds a large part of the radioactivity became associated with the aqueous fraction, while another part of the ³H-GA₁ was converted into 2 new, acidic, biologically active compounds, designated X₁ and X₂. A relatively small part of the neutral compounds could be converted back to ³H-GA₁, X₁, and X₂ by means of mild acid hydrolysis. During germination of pea and morning-glory seeds, part of the bound compounds was released in the form of ³H-GA₁, X₁ and X₂ while, particularly during rapid seedling growth, a further conversion of ³H-GA₁, mainly to X₁, took place. In pea seedlings, growth during the first 2 to 3 days after imbibition was not affected by Amo-1618, an inhibitor of gibberellin biosynthesis. This, in conjunction with the findings on the interconversions between free and bound ³H-GA₁ suggests that, at least in peas, early seedling growth may at least partly be regulated by gibberellins released from a bound form which was formed during seed development.     

Influence of daylength on gibberellin metabolism and stem growth in Silene armeria

Summary When radioactive gibberellin A₅ (³H-GA₅) was applied to the apices and surrounding young leaves of the long-day plant Silene armeria, it was partially converted to at least two other acidic substances. One of them was similar to GA₃ in chromatographic, but not in biological properties. The other metabolite was more polar than GA₃ and inactive in the dwarf d-5 corn assay.The rate of ³H-GA₅ conversion was influenced by the photoperiod under which Silene plants were grown. Exposure to 2 long days significantly increased ³H-GA₅ metabolism over that in control plants kept under short days. The increased conversion of ³H-GA₅ persisted for at least a few days after transferring Silene plants back from long to short days. Likewise, stem growth induced by long photoperiods continued for a considerable period of time under subsequent short days.Application of the growth retardant AMO-1618 to Silene reduced the levels of two endogenous GA-like substances, one of them with GA₅-like properties, more under long than under short days. These results indicate that long photoperiods, which induce flower formation and stem elongation in Silene, increase the turnover of endogenous gibberellins.     

Comparison of endogenous gibberellins and of the fate of applied radioactive gibberellin a(1) in a normal and a dwarf strain of Japanese morning glory

The effect of application of GA₃ on hypocotyl growth, the endogenous GAs, and the metabolism of applied ³H-GA₁ were investigated in relation to dwarfism and light-mediated growth inhibition in the normal (tall) strain Violet and the dwarf strain Kidachi of Japanese morning glory (Pharbitis nil). GA₃ applied in a wide concentration range (10⁻⁹ to 10⁻³m) to 4-day-old seedlings caused great extension of the hypocotyls in light-grown plants of both the normal and the dwarf strain. However, the dwarf strain did not attain the same length as the normal one at any given GA₃ concentration, even when saturation was reached. Dark-grown plants of the dwarf strain responded to GA₃, although relatively much less than light-grown ones; dark-grown plants of the normal strain showed no GA₃ response at all.     

Metabolism of Tritiated Gibberellin A(20) in Immature Seeds of Dwarf Pea, cv. Meteor

Tritium-labeled gibberellin A₂₀ ([³H]GA₂₀) was applied via the pedicel to immature pods and seeds of dwarf peas and three harvests were made at days 5, 10, and 23 (mature) after application. Of the five metabolites of [³H]GA₂₀, the three in highest yield were GA₂₉, an α,β-unsaturated ketone, and a compound (B), whose structure was only tentatively assigned. The metabolic sequence GA₂₀ → GA₂₉ → compound B → the ketone was indicated. The amount of [³H]GA₂₉ in both seeds and pods was highest at day 5 and declined to its lowest level at maturity. The amount of the [³H]ketone in the seed increased with time to its highest level at maturity. It is suggested that compound B and the ketone represent the major pathway of catabolism of GA₂₉, a 2β-hydroxylated GA of low biological activity, and that the ketone is not metabolized, or only slowly metabolized, during seed maturation.     

Metabolism of H-Gibberellin A(1) and H-Gibberellin A(4) by Phaseolus coccineus Seedlings

[³H]-Gibberellin A₁ (GA₁) and ³H-GA₄ were applied separately to Phaseolus coccineus seedlings grown under red light. ³H-GA₁ was converted to a compound with gas-liquid radiochromatography retention times identical to those of GA₈. ³H-GA₄ underwent conversion to at least three metabolites, none of which corresponded to GA_1-38. The rate of metabolism of ³H-GA₄ was significantly higher than that of ³H-GA₁.     

Endogenous ethylene and reversing methyl jasmonate inhibition of Amaranthus caudatus seed germination by benzyladenine or gibberellin

BA at 10^–5 M, GA₃ at 3×10^–4 M or GA₄₊₇ at 3×10^–5 M partially or largely reversed the inhibition of Amaranthus caudatus seed germination due to JA-Me. BA or GA₃ did not affect ethylene production and ACC oxidase activity in vivo in the presence of JA-Me before radicle protrusion. However, both increased ethylene production after 72 h of incubation, when the reversal of the JA-Me inhibition of seed germination was observed. AVG at 3×10^–4 M decreased ethylene production when it was applied simultaneously with BA and JA-Me or GA₃ and JA-Me, but it had no effect on seed germination. NBD almost completely reversed the stimulatory effect of BA, GA₃ or GA₄₊₇ on the germination of seeds in the presence of JA-Me. Exogenous ethylene reversed the inhibitory effect of NBD. The results indicate that action of endogenous ethylene is involved in the response of JA-Me inhibited seeds to BA or GA_s.     

Gibberellin-like Substances From Vegetative Tissue of a Conifer, Arizona Cypress

Vegetative shoots of Arizona cypress (Cupressus arizonica Greene) were found to contain an estimated 40 to 70 μg of gibberellin-like activity per kg. Based on elution patterns of silicic acid and celite partition columns, mobilities on thin layer chromatograms and specificity of the cucumber, d-3 dwarf maize, dwarf pea, and barley half seed bioassays it was possible to determine that the tissue contained at least 5 acidic, ethyl acetate-soluble gibberellin-like substances. The major one would appear to be GA₃. In addition, GA₉, GA₄, and/or GA₇-like compounds, and 2 unidentified gibberellin-like substances are present.     

Preparation of radioactive gibberellin a(1) and its metabolism in dwarf peas

Gibberellin A₁-3,4-³H was prepared by selective catalytic reduction of gibberellic acid with a mixture of tritium and hydrogen. ³H-GA₁ was applied at physiological concentrations to dwarf peas and the metabolism of the hormone was investigated. ³H-GA₁ was converted to an acidic, biologically active compound. Radioactive but biologically inactive compounds were also found in the neutral fraction and could not be converted to acidic gibberellins by hydrolysis. No attachment of gibberellin to any macromolecular fraction was evident.     

Ontogenetic variation in levels of gibberellin A1 in Pisum

The levels of the biologically active gibberellin (GA), GA₁, and of its precursor, GA₂₀, were monitored at several stages during ontogeny in the apical portions of isogenic tall (Le) and dwarf (le) peas (Pisum sativum L.) using deuterated internal standards and gas chromatography-selected ion monitoring. The levels of both GAs were relatively low on emergence and on impending apical arrest. At these early and late stages of development the internodes were substantially shorter than at intermediate stages, but were capable of large responses to applied GA₃. Tall plants generally contained 10–18 times more GA₁ and possessed internodes 2–3 times longer than dwarf plants. Further, dwarf plants contained 3–5 times more GA₂₀ than tall plants. No conclusive evidence for the presence of GA₃ or GA₅ could be obtained, even with the aid of [²H₂]GA₃ and [²H₂]GA₅ internal standards. If GA₃ and GA₅ were present in tall plants, their levels were less than 0.5% and 1.4% of the level of GA₁, respectively. Comparison of the effects of gene le on GA₁ levels and internode length with the effects of ontogeny on these variables shows that the ontogenetic variation in GA₁ content was sufficient to account for much of the observed variation in internode length within the wild-type. However, evidence was also obtained for substantial differences in the potential length of different internodes even when saturating levels of exogenous GA₃ were present.Abreviations GA_n gibberellin A_n We thank Noel Davies, Omar Hasan, Leigh Johnson, Katherine McPherson and Naomi Lawrence for technical help, Professor L. Mander (Australian National University, Canberra) for deuterated GA standards and the Australian Research Council for financial assistance.     

Similarities between gibberellins and related compounds in inducing Acid phosphatase and reducing sugar release from barley endosperm

Barley endosperm halves release acid phosphatase in response to several gibberellins and gibberellin precursors. Seed halves incubated with 10⁻⁷m GA₃ at 29° begin to release phosphatase after 11 hr and release it for another 26 hr in response to GA₃. After 37 hr, the rate of release slows to that of seed halves incubated without GA₃. GA₃ is active at 10⁻¹⁰m and maximally active at 10⁻⁷m. Comparative activity of 12 gibberellins and gibberellin precursors is GA₁ = GA₃ > GA₂ > GA₄ = GA₇ > GA₅ = GA₁₃ > GA₁₄ > GA₈ = GA₉ > (−)kaurenoic acid > (−)-kaurene. These compounds show the same order of activity and approximately the same relative activity in inducing reducing sugar release as in inducing phosphatase activity. The activity of each compound increases with its presumed position in a biosynthetic pathway leading from kaurene to GA₃. This correlation suggests that activity may be a reflection of the efficiency of conversion to an active form within the seed half.     

Translocation and Intracellular Distribution of Tritiated Gibberellin A3

The localization of tritium-radioactivity in dwarf kidney bean plants (Phaseolus vulgaris) of ³H-gibberellm A₃(³H-GA₃) applied in a large quantity was investigated in advance of the study on GA₃ metabolism in this plant. Immediately after the application of ³H-GA₃, the radioactivity was distributed uniformly in the top of this plant; no further transportation of the radioactivity into the growing apical region from mature leaves and stems was the observed as the growth stage proceeded. An investigation on the intracellular localization of the radioactivity demonstrated that most part of the radioactivity was found in the cellular soluble fraction, while no radioactivity was detected in such subcellular particles as nuclei, mitochondria and microsomes. Examinations of the occurrence of GA₃ bound with such macromolecules as RNA and protein gave negative results.     

THE INDEPENDENT ACTION OF MORPHACTINS AND GIBBERELLIC ACID ON HIGHER PLANTS

The comparative activity of three morphactins, n-butyl-9-hydroxyfluorene-9-carboxylate (IT 3233), 9-hydroxy-fluorene-9-carboxylicacid (IT 3235) and methyl-2-chloro-9-hydroxy fluorene-9-carboxylate(IT 3456) on the action of gibberellic acid (GA₃) were examinedutilizing dwarf pea (Progress No. 9), dwarf corn (strain d-5),CCC dwarfed Alaska pea, and embryoless barley half-seeds. When applied either prior to or simultaneously with GA₃ themorphactins were without effect in reducing the response ofthe dwarf peas to the gibberellin. In fact IT 3233 and IT 3235in combination with GA₃ produced taller plants than the GA₃controls. Similar results were observed using CCC dwarfed Alaskapeas. The morphactins did, however, produce several morphologicaleffects on the peas. In addition, they were effective in breakingapical dominance in the peas. The morphactins were also withouteffect on the dwarf corn bioassay and no morphological changeswere observed. In the embryoless barley half-seeds the morphactins did notinhibit the response of the tissue to the GA₃. Also, the morphactinsdid not exhibit gibberellin-like properties. The results suggest that morphactins do not compete with gibberellinfor similar sites of action. ¹Published with the approval of the Director of the MichiganAgricultural Experiment Station as Journal Article Number 3917.     

Possible control of gibberellin-induced release of temperature-dependent primary dormancy in seeds of celery (Apium graveolens L.) by transmembrane ion fluxes

The temperature-dependent primary dormancy of cv Florida 683 celery seeds in darkness was broken by GA_4/7 (2 × 10^-4 M) alone but other growth regulators such as BA, ethephon or daminozide were necessary to break dormancy of cv Lathom Blanching seeds in the presence of GA_4/7 at this concentration. Although AgNO₃ partially inhibited both the ethephon- and BA- induced germination of cv Lathom Blanching seeds in the presence of GA_4/7 in the dark it did not affect the promotive action of daminozide. Ethephon did not overcome the inhibitory action of high concentrations of AgNO₃ in the light. The ethylene synthesis inhibitor aminoethoxyvinylglycine (AVG) did not inhibit the germination of cv Lathom Blanching seeds induced by growth regulators in the dark or in the absence of growth regulators in the light. Fusicoccin (FC) did not break celery seed dormancy unless applied in the presence of GA_4/7. Germination of cv Lathom Blanching celery seeds treated with GA_4/7 at 16°C in the dark was inhibited by the K⁺ ionophore benzo-18-crown-C-6 (18-C-6) and in the presence of Ca²⁺ by the Ca²⁺ ionophore A23187; the 18-C-6 inhibition was reversed by BA.It is concluded that the involvement of gibberellin in celery seed dormancy is not dependent on endogenous ethylene and is directly or indirectly controlled through the action of other hormones on transmembrane ion fluxes.     

The identification and metabolism of GA9 and its metabolites in seed coats and shoots of pea,line G2

[³H]gibberellin A₉ was applied to shoots or seed parts of G2 pea to produce radiolabeled metabolites. These were used as markers during purification for the recovery of endogenous GA₉ and its naturally occurring metabolites. GA₉ and its metabolites were purified by HPLC, derivatized and examined by GC-MS. Endogenous GA₉, GA₂₀, GA₂₉ and GA₅₁ were identified in pea shoots and seed coats. GA₅₁-catabolite and GA₂₉-catabolite were also detected in seed coats. GA₇₀ was detected in seed coats following the application of 1 g of GA₉. Applied [³H]GA₉ was metabolized through both the 13-hydroxylation and 2-hydroxylation pathways. Labeled metabolites were tentatively identified on the basis of co-chromatography on HPLC with endogenous compounds identified by GC-MS. In shoots [³H]GA₅₁ and [³H]GA₅₁-catabolite were the predominant metabolites after 6 hrs, but by 24 hrs there was little of these metabolites remaining, while [³H]GA₂₉-catabolite and an unidentified metabolite predominated. In seed coats [³H]GA₅₁ was the initial product, later followed by [³H]GA₅₁-catabolite and an unidentified metabolite (different from that in shoots), with lesser amounts of [³H]GA₂₀, [³H]GA₂₉ and [³H]GA₂₉-catabolite. [³H]GA₇₀ was a very minor product in both cases. [³H]GA₉ was not metabolized by pea cotyledons.Edited by T.J. Gianfagna.Author for correspondence     

Effect of gibberellic acid and uniconazol on embryo abortion in the stenospermocarpic grape cultivars Emperatriz and Perlon

Hypothesizing that seed abortion in stenospermocarpic grapes (Vitis vinifera L.) is caused by high gibberellin levels in the seed during the first stages of its development, we studied the effect of gibberellic acid GA₃ and uniconazol (a GAs biosynthesis inhibitor) on this phenomenon. In vitro germination was analyzed in the seedless cultivars Emperatriz and Perlon, which were treated with 60 and 120 mg.^-l 1 uniconazol (5 and 15 days before bloom) and 100 mg.^-l 1 GA₃ (5 days after bloom). In addition, endogenous levels of free gibberellins in flowers and seeds of Emperatriz and Perlon were compared with their seedeed progenitor Emperador. Clusters were harvested at bloom and 20 days after bloom for gibberellin analysis and at commercial maturity for in vitro culture of the seeds. Considerable gibberellin activity was found in the three cultivars, but only small differences were detected between the seedless and the seeded genotypes. Exogenous applications of GA₃ had a deleterious effect on seed growth and on in vitro germination. Uniconazol also inhibited in vitro germination, though not affecting the total number of germinating embryos plus those rescued from non-germinating seeds. In conclusion, gibberellins do not appear to be directly involved in seed abortion of the stenospermocarpic cultivars Emperatriz and Perlon, although their participation in a more complex scenario should not be rejected, taking into account that in Perlon germination rates are positively correlated with the number of clusters per plant. Treatments with growth regulators also modified berry number per cluster, berry weight and rachis morphology. Finally, the plant source was a determinant affecting germination rates in vitro.     

Use of an Acylcyclohexanedione Growth Retardant, LAB 198 999, to Determine Whether Gibberellin A(20) Has Biological Activity per se in Dark-Grown Dwarf (le) Seedlings of Pisum sativum

Dwarf (le⁵⁸³⁹) seedlings of Pisum sativum respond to gibberellin A₂₀ (GA₂₀) in the dark, although the same dosage of GA₂₀ applied to light-grown le⁵⁸³⁹ seedlings elicits no growth response. The acylcyclohexanedione growth retardant, LAB 198 999, which is known to inhibit gibberellin oxidation and in particular 3β-hydroxylation such as the conversion of GA₂₀ to GA₁, also inhibits the growth response of dark-grown dwarf (le⁵⁸³⁹) seedlings to GA₂₀. Thus, the biological activity of GA₂₀ in the dark appears to be a consequence of its conversion to GA₁, even though it is known from studies with light-grown seedlings that the le mutation reduces the conversion of GA₂₀ to GA₁.     

The biological activity of fluorogibberellins

Summary The biological activities of gibberellin A₉ (GA₉), gibberellin A₁₂ (GA₁₂) and monofluoro-analogues (F-GA₉ and F-GA₁₂), substituted in the 1 -methyl group, were compared in the barley endosperm, cucumber hypocotyl, lettuce hypocotyl, Meteor dwarf pea, dwarf-5 maize and Rumex leaf disc assays. In most cases the fluorosubstituted compounds had a potency similar to, or less than, the relevant unmodified gibberellin but, in the lettuce assay, F-GA₉ was approximately 5 times more active than GA₉ up to a dose rate of 10^-1 g.A 27–30% mixture of fluorogibberellin A₃ (F-GA₃) in GA₃ had a lower activity than 100% GA₃ in the barley endosperm, lettuce hypocotyl and dwarf maize assays. This suggested that pure F-GA₃ may be a competitive inhibitor of GA₃ action. The findings are discussed in the context of the structure/activity relationships of the gibberellins.