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.     

Effect of Photoperiod on Metabolism of [H] Gibberellins A(1), 3-epi-A(1), and A(20) in Agrostemma githago L

To determine whether daylength influences the rate of metabolism of gibberellins (GAs) in the long-day (LD) rosette plant Agrostemma githago L., [³H]GA₂₀ and [³H]GA₁ were applied under short day (SD) and LD. Both were metabolized faster under LD than under SD. [³H]GA₂₀ was metabolized to a compound chromatographically identical to 3-epi-GA₁. [³H]GA₁ was metabolized to two acidic compounds, the major metabolite having chromatographic properties similar to, but not identical with GA₈. [³H]3-epi-GA₁ applied to plants under LD was metabolized much more slowly than was [³H]GA₁, and formed a very polar metabolite which did not partition into ethyl acetate at pH 2.5. Very polar metabolites were also formed after the feeds of [³H]GA₂₀ and [³H]GA₁. It was not possible to characterize these very polar compounds further because of their apparent instability. The results obtained suggest that in Agrostemma GA₂₀ is the precursor of 3-epi-GA₁, but there is at present no evidence indicating the precursor of GA₁.     

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 A9 with High Specific Activity

The synthesis of 2,3-(³H)-gibberellin A₉ (GA₉) with a specific activity of 47 Ci mmole^?1 is described. △^2,3GA₉ methyl ester epoxide was converted to (³H)-GA₉ methyl ester epoxide using carrier-free tritium gas. This product was de-epoxidized then hydrolysed to yield (³H)-GA₉.     

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.     

Metabolism of Tritiated Gibberellins A(4) and A(9) in Norway Spruce, Picea abies (L.) Karst. : Effects of a Cultural Treatment Known to Enhance Flowering

Shoots of mature grafted propagules of Picea abies (L.) Karst. metabolized [³H]gibberellin A₄ (GA₄) to at least 14 acidic substances, two of which were tentatively identified by gas-liquid radiochromatography as GA₂ (possibly an artifact) and GA₃₄. [³H]GA₉ was converted into a number of metabolites, one of which was chromatographically similar to, but not identical with, GA₄. Metabolism was maximally 61 and 57% over 48 hours for GA₄ and GA₉, respectively, and was correlated with the rate of change (i.e. increase followed by decrease) in endogenous GA-like substances as shoot elongation progressed. Propagules covered with a clear plastic film, a treatment which promotes flowering, metabolized [³H]GA₄ more slowly than did control plants in the open. Inasmuch as a GA_4/7 mixture can also promote flowering in P. abies, the retarded metabolism of [³H]GA₄ may reflect the manner in which trees under plastic metabolize endogenous GA-like substances. If so, then the stimulating effect of this cultural treatment on flowering may come about through an increased level of endogenous, less polar GA-like substances.     

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.     

Stem elongation and gibberellins in alpine and prairie ecotypes of Stellaria longipes

The potential for gibberellins (GAs) to control stem elongation and itsplasticity (range of phenotypic expression) was investigated inStellaria longipes grown in long warm days. Gibberellinmetabolism and sensitivity was compared between a slow-growing alpine dwarfwithlow stem elongation plasticity and a rapidly elongating, highly plastic prairieecotype. Both ecotypes elongated in response to exogenous GA₁,GA₄ or GA₉, but surprisingly, the alpine dwarf wasrelatively unresponsive to GA₃. Endogenous GA₁,GA₃, GA₄, GA₅, GA₈, GA₉and GA₂₀ were identified and quantified in stem tissue harvested atcommencement, middle and end of the period of most rapid elongation. Theconcentration of GAs which might be expected to promote shoot elongation washigher during rapid elongation than toward its end for both ecotypes. Whilethere was a trend for certain GAs (GA₃, GA₄,GA₉, GA₂₀) to be higher in stems of the alpine ecotypeduring rapid elongation, that result does not explain the slower growth of thealpine ecotype and the faster growth of the prairie ecotype under a range ofconditions. To determine if the two ecotypes metabolized GA₂₀differently, plants were fed [²H]- or[³H]-GA₂₀. The metabolic products identified included[²H₂]-GA₁, -GA₈, -GA₂₉,-GA₆₀, -3-epi-GA₁, GA₁₁₈(-1-epi-GA₆₀) and -GA₇₇. The concentration of[²H₂]-GA₁ also did not differ between the twoecotypes and metabolism of [²H₂]- or[³H]-GA₂₀ was also similar. In the same experiments thepresence of epi-GA₁, GA₂₉, GA₆₀,GA₁₁₈ and GA₇₇ was indicated, suggesting that these GAsmay also occur naturally in S. longipes, in addition tothose described above. Collectively, these results suggest that while stemelongation within ecotypes is likely regulated by GAs, differences in GAcontent, sensitivity to GAs (GA₃ excepted), or GA metabolism areunlikely to be the controlling factor in determining the differences seen ingrowth rate between the two ecotypes under the controlled environmentconditionsof this study. Nevertheless, further study is warranted especially underconditions where environmental factors may favour a GA:ethylene interaction.     

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     

Endogenous Gibberellins of Pine Pollen: III. Conversion of 1,2-[H]GA(4) to Gibberellins A(1) and A(34) in Germinating Pollen of Pinus attenuata Lemm

Gibberellins A₁ and A₃₄ (possibly A₂) were found as products of metabolism of 1,2-[³H]GA₄ during germination of Pinus attenuata pollen. The conversion from GA₄ to GA₁ and GA₃₄ occurred as hydroxylations at atoms C-13 and C-2 of the ent-gibberellane skeleton, respectively. Percentage interconversion of the GA₄ absorbed was in the range of 0.15 to 0.43% for GA₁ and 1.54 to 3.22% for GA₃₄. Identifications were made on a gas-liquid chromatograph with radioactive monitoring by comparison with standards.     

Conversion of gibberellin A1 into gibberellin A3 by the mutant R-9 of Gibberella fujikuroi

A mutant R-9 of Gibberella fujikuroi has been isolated and shown to be blocked for GA₁ and GA₃ biosynthesis, but not for GA₄, G_A7 and other gibberellins. Cultures of this mutant convert low concentrations of [1,2-³H2]-GA₁ into GA₃ in a radiochemical yield of 2·7 %.     

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 [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     

On the biosynthesis of cerebrosides containing non-hydroxy acids. 1. Mass spectrometric evidence for the psychosine pathway

[1, 1, 1′, 2′, 3′, 4′, 5′, 6′, 6′-²H₉]1-O-(β-galactopyranosyl) DL-sphinganine and [4, 5-³H₂]1-O-(β-D-galactopyranosyl) D-sphinganine^∗ were prepared, and the conversion to cerebroside of a mixture of these compounds was studied with rat brain microsomes. The product was characterized by thin layer radiochromatography in several solvent systems and, as the trimethylsilyl ether derivative, by gas-liquid chromatography — mass spectrometry. The mass spectrometric analyses conclusively showed that the glycosidic bond of the substrate remained intact during the transformation to cerebroside.     

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 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.     

Inhibition of stem growth and gibberellin production in Agrostemma githago L. by the growth retardant tetcyclacis

The effects of the new growth retardant tetcyclacis (TCY) on stem growth and endogenous gibberellin (GA) levels were investigated in the long-day rosette plant Agrostemma githago. Application of TCY (10 ml of a 5·10^-5M solution daily) to the soil suppressed stem elongation in Agrostemma grown under long-day conditions. A total of 10 g GA₁ (1 g applied on alternate days) per plant overcame the growth retardation caused by TCY.Control plants and plants treated with TCY were analyzed for endogenous GAs after exposure to nine long days. The acidic extracts were fractionated by high-performance liquid chromatography. Part of each fraction was tested in the d-5 maize bioassay, while the remainder was analyzed by combined gas chromatography-selected ion monitoring. The bioassay results indicated that the GA content of plants treated with TCY was much lower than that of untreated plants. The data obtained by gas chromatography-selected ion monitoring confirmed that the levels of seven GAs present in Agrostemma were much reduced in TCY-treated plants when compared with the levels in control plants: GA₅₃ (13%), GA₄₄ (0%), GA₁₉ (1%), GA₁₇ (33%), GA₂₀ (15%), GA₁ (4%), and epi-GA₁ (13%). These results provide evidence that TCY inhibits stem growth in Agrostemma by blocking GA biosynthesis and thus lowering the levels of endogenous GAs.Abbreviations AMO-1618 2-isopropyl-4-dimethylamino-5-methylphenyl-1-piperidine-carboxylate methyl chloride - GA(s) gibberellin(s) - HPLC high-performance liquid chromatography - TCY Tetcyclacis (5-[4-chlorophenyl]-3,4,5,9,10-pentaaza-tetracyclo-5,4,1,0^2,6,0^8,11-dodeca-3,9-diene)     

Convergent pathways of gibberellin A1 biosynthesis in Brassica

[²H, ³H]Gibberellin A₄ (GA₄) or [²H, ³H] GA₉ were applied to the shoot tips of seedlings of elongated internode (ein), a tall mutant of rapid cycling Brassica rapa. Following [²H]GA₉ application, [²H]GA₅₁, [²H]GA₂₀ and [²H]GA₄ were identified as products by GC-MS, while [²H]GA₃₄ and [²H]GA₁ were formed from [²H]GA₄. Other isotopically labelled products, including abundant putative conjugates, were also produced, but were not identified. Thus, in B. rapa, GA₁ biosynthesis involves the convergence of at least two metabolic pathways; it can be formed via GA₄ or GA₂₀, the latter of which can originate from GA₉ or from GA₁₉.     

Further studies on the metabolism of gibberellins (GAs) A9, A20 and A29 in immature seeds of Pisum sativum cv. progress No. 9

Seed maturation of Pisum sativum cv. Progress No. 9 proceeds more slowly in winter than in summer even when the parent plants are grown in greenhouse conditions with light-and heat-supplementation. For parent plants grown under summer and winter conditions the metabolism of [³H]GA₉ in cultured seeds is qualitatively different in seeds of equivalent age and qualitatively the same in seeds of equivalent weight. 13-Hydroxylation of [³H]GA₉[³H]GA₂₀ is restricted to early stages of seed development. 2-Hydroxylation of [³H]GA₉2-OH-[³H]GA₉ has only been observed at a stage of development after endogenous GA₉ has accumulated. 2-OH-GA₉ has been shown to be endogenous to pea and is named GA₅₁. H₂-GA₃₁ and its conjugate have not been shown to be present in pea and may be induced metabolites of [³H]GA₉. The metabolism of GA₂₀GA₂₉ is used to illustrate a technique of feeding [²H][³H]GAs in order to distinguish a metabolite from the same endogenous compound. The in vitro conversion of [³H]GA₂₀[³H]GA₂₉, and the virtual non-metabolism of [³H]GA₂₉ have been confirmed for seeds in intact fruits. These results are discussed in relation to the apparent absence of conjugated GAs in mature pea seeds.Abbreviations GA_n gibberellin A_n - GC gas chromatography - GC-MS combined gas chromatography-mass spectrometry - GC-RC combined gas chromatography-radio counting - Me methyl ester - R_T etention time - SICM selected ion current monitoring - TLC thin layer chromatography - TMS trimethyl silyl ether The author is née Frydman     

Effect of exo-16,17-dihydro-gibberellin A5 on gibberellin A20 metabolism in seedlings of dwarf rice (Oryza sativa L. cv. Tan-ginbozu)

Several of the 16,17-dihydro gibberellins (GAs) inhibit elongation in a variety of species. In a study of their mechanism of action we have investigated the effect of exo-16,17-dihydro-Ga₅ (diHGA₅) on the metabolism of GA₂₀ in dwarf rice (Oryza sativa cv. Tan-ginbozu). A mixture of [³H]- and [³H]-GA₂₀ (100 ng per plant) was applied in microdrops to 4 d old seedlings which were harvested 72 h later. Concurrent treatment with diHGA₅ at 100 ng or 333 ng per plant reduced GA₂₀-induced elongation of the second leaf sheath by 41–66%. There was a concomitant reduction in the amount of [²H₂]GA₁ present at harvest, measured by gas chromatography-mass spectrometry-selected ion monitoring. The [²H₂]GA₂₉ content was also reduced. There was no clear effect of diHGA₅ on the total radioactivity recovered, or on conversion of the [³H]GA₂₀ to putative [³H]GA conjugates, or on the amount of [²H₂]GA₂₀ found. No free [²H₂]GA₈ was detected. In other experiments there was little effect of diHGA₅ on elongation induced by treatment with GA₁. We conclude that diHGA₅ inhibited GA₂₀-induced elongation in dwarf rice shoots at least partly by reducing the 3-hydroxylation of GA₂₀ to GA₁.Abbreviations diHGA₅ = exo- 16, 17-dihydro-gibberellin A₅ - GA = gibberellin - GC-MS-SIM = gas chromatography-mass spectrometry-selected ion monitoring