Gibberellin A(1) Biosynthesis in Pisum sativum L. : II. Biological and Biochemical Consequences of the le Mutation

A comparative study of the metabolism of radiolabeled gibberellin (GA) 1, 19, and 20 in isolated vegetative tissues of isogenic Le and le pea (Pisum sativum) plants incubated in vitro with the appropriate GA substrate is described. The results of this study provide evidence that the enzymes involved in the latter stages of GA biosynthesis are spatially separated within the growing pea plant. Apical buds were not apparently involved in the production of bioactive GA₁ or its immediate precursors. The primary site of synthesis of GA₂₀ from GA₁₉ was immature leaflets and tendrils, and the synthesis of bioactive GA₁ and its inactive catabolite GA₈ occurred predominantly in stem tissue. GA₂₉, the inactive catabolite of GA₂₀, was produced to varying extents in all the tissues examined. Little or no difference was observed in the ability of corresponding Le and le tissues to metabolize radiolabeled GA₁, GA₁₉, or even GA₂₀. During a fixed period of 24 hours, stems of plants carrying the le mutation produced slightly more [³H]GA₁ (and [³H]GA₂₉) than those of Le plants. It has been concluded that the le mutation does not lie within the gene encoding the GA₂₀ 3β-hydroxylase protein.     

Internode length in Pisum

The influence of the Na and Le genes in peas on gibberellin (GA) levels and metabolism were examined by gas chromatographic-mass spectrometric analysis of extracts from a range of stem-length genotypes fed with [¹³C, ³H]GA₂₀. The substrate was metabolised to [¹³C, ³H]GA₁, [¹³C, ³H]GA₈ and [¹³C, ³H]GA₂₉ in the immature, expanding apical tissue of all genotypes carrying Le. In contrast, [¹³C, ³H]GA₂₉ and, in one line, [¹³C, ³H]GA₂₉-catabolite, were the only products detected in plants homozygous for the le gene. These results confirm that the Le gene in peas controls the 3-hydroxylation of GA₂₀ to GA₁. Qualitatively the same results were obtained irrespective of the genotype at the Na locus. In all Na lines the [¹³C, ³H]GA₂₀ metabolites were considerably diluted by endogenous [¹²C]GAs, implying that the metabolism of [¹³C, ³H]GA₂₀ mirrored that of endogenous [¹²C]GA₂₀. In contrast, the [¹³C, ³H]GA₂₀ metabolites in na lines showed no dilution with [¹²C]GAs, confirming that the na mutation prevents the production of C₁₉-GAs. Estimates of the levels of endogenous GAs in the apical tissues of Na lines, made from the ¹²C:¹³C isotope ratios and the radioactivity recovered in respective metabolites, varied between 7 and 40 ng of each GA per plant in the tissue expanded during the 5 d between treatment with [¹³C, ³H]GA₂₀ and extraction. No [¹²C]GA₁ and only traces of [¹²C]GA₈ (in one line) were detected in the two Na le lines examined. These results are discussed in relation to recent observations on dwarfism in rice and maize.Abbreviations GA_n gibberellin A_n - GC-MS gas chromatography-mass spectrometry - HPLC high-pressure liquid chromatography     

The Distribution of Gibberellins in Vegetative Tissues of Pisum sativum L. : I. Biological and Biochemical Consequences of the le Mutation

The concentrations of endogenous gibberellin (GA) 1, 5, 8, 19, 20, and 29 in the component tissues of maturing tall (Le) and dwarf (le) pea (Pisum sativum) plants have been determined. The following conclusions were drawn from the data obtained: (a) GA₂₀ and its metabolites accumulate only in the growing regions of Le and le plants; (b) the le mutation is biochemically expressed in all immature tissues of the dwarf plants; (c) the quantitative composition of the GA metabolites in the various immature tissues is variable; (d) the total GA concentration in apical buds, unexpanded leaves, and tendrils is considerably higher than in GA₁-responsive stem tissue; and (e) there is very little GA accumulation of the inactive 2β-hydroxylated GAs (GA₈ and GA₂₉) in either the mature vegetative tissues or the roots of pea plants.     

Internode length inPisum: biochemical expression of thele andna mutations in the slender phenotype

Thele andna mutations in pea block GA biosynthesis and normally cause a marked reduction in internode length. However, neither of these genes influences the growth of plants carrying thecry ^s la gene combination. Plants of this genotype have long, thin internodes, pale green foliage, and abnormal flower and fruit development, collectively referred to as the slender phenotype. [¹³C,³H]Gibberellin A₂₀ is metabolized to GA₁, GA₈, and GA₂₉ in slender lines carrying the geneLe but only to GA₂₉ and GA₂₉-catabolite inle lines. Examination of¹²C:¹³C isotopic ratios showed that metabolites were strongly diluted by endogenous [¹²C]GAs inNa lines. However, little if any significant dilution was observed in a line homozygous for thena gene. These results confirm that thele andna mutations are fully expressed at the biochemical level in slender phenotypes of peas and concur with previous reports that internode elongation is entirely independent of GA levels incry ^s la (slender) plants.     

Internode Length in Pisum: Gene na May Block Gibberellin Synthesis between ent-7alpha-Hydroxykaurenoic Acid and Gibberellin A(12)-Aldehyde

The elongation response of the gibberellin (GA) deficient genotypes na, ls, and lh of peas (Pisum sativum L.) to a range of GA-precursors was examined. Plants possessing gene na did not respond to precursors in the GA biosynthetic pathway prior to GA₁₂-aldehyde. In contrast, plants possessing lh and ls responded as well as wild-type plants (dwarfed with AMO-1618) to these compounds. The results suggest that GA biosynthesis is blocked prior to ent-kaurene in the lh and ls mutants and between ent-7α-hydroxykaurenoic acid and GA₁₂-aldehyde in the na mutant. Feeds of ent-[³H]kaurenoic acid and [²H]GA₁₂-aldehyde to a range of genotypes supported the above conclusions. The na line WL1766 was shown by gas chromatography-mass spectrometry (GC-MS) to metabolize [²H]GA₁₂-aldehyde to a number of[²H]C₁₉-GAs including GA₁. However, there was no indication in na genotypes for the metabolism of ent-[³H]kaurenoic acid to these GAs. In contrast, the expanding shoot tissue of all Na genotypes examined metabolised ent-[³H]kaurenoic acid to radioactive compounds that co-chromatographed with GA₁, GA₈, GA₂₀, and GA₂₉. However, insufficient material was present for unequivocal identification of the metabolites. The radioactive profiles from HPLC of extracts of the node treated with ent-[³H]kaurenoic acid were similar for both Na and na plants and contained ent-16α,17-dihydroxykaurenoic acid and ent-6α,7α,16β,17-tetrahydroxykaurenoic acid (both characterized by GC-MS), suggesting that the metabolites arose from side branches of the main GA-biosynthetic pathway. Thus, both Na and na plants appear capable of ent-7α-hydroxylation.     

Identification of Gibberellins in Spinach and Effects of Light and Darkness on their Levels

The endogenous gibberellin (GA) content of spinach (Spinacia oleracea) was reinvestigated by combined gas chromatography-mass spectrometry analysis. The 13-hydroxy GAs: GA₅₃, GA₄₄, GA₁₉, GA₁₇, GA₂₀, GA₅, GA₁, GA₂₉, and GA₈; the non-3, 13-hydroxy GAs: GA₁₂, GA₁₅, GA₉, and GA₅₁; and the 3β-hydroxy GAs: GA₄, GA₇, and GA₃₄, were identified in spinach extracts by comparing full-scan mass spectra and Kovats retention indices with those of reference GAs. In addition, spinach plants contained GA₇-isolactone, 16,17-dihydro-17-hydroxy-GA₅₃, GA₂₉-catabolite, 3-epi-GA₁, and 10 uncharacterized GAs with mass spectra indicative of mono- and dihydroxy-GA₁₂, monohydroxy-GA₂₅, dihydroxy-GA₂₄, and dihydroxy-GA_g. The effect of light-dark conditions on the GA levels of the 13-hydroxylation pathway was studied by using labeled internal standards in selected ion monitoring mode. In short day, the GA levels were higher at the end of the light period than at the end of the dark period. Levels of GAs at the end of each short day were relatively constant. During the first supplementary light period of long day treatment, GA₅₃ and GA₁₉ declined dramatically, GA₄₄ and GA₁ decreased slightly, and GA₂₀ increased. During the subsequent high-intensity light period, the GA₂₀ level decreased and the levels of GA₅₃, GA₄₄, GA₁₉, and GA₁ increased slightly. Within 7 days after the beginning of long day treatment, similar patterns for GA₅₃ and GA₁₉ occurred. Furthermore, when these plants were transferred to darkness, an increase in the levels of GA₅₃ and GA₁₉ was observed. These results are compatible with the idea that in spinach, the flow through the GA biosynthetic pathway is much enhanced during the high-intensity light period, although GA turnover occurs also during the supplementary period of long day, both effects being responsible for the increase of GA₂₀ and GA₁ in long day.     

Endogenous gibberellins in flushing buds of three deciduous trees: Alder,aspen, and birch

Endogenous gibberellins (GAs) were extracted from flushing (expanding) vegetative buds of river alder (Alnus tenuifolia), European white birch (Betula pendula), and aspen (Populus tremuloides) and identified by gas chromatography-mass spectrometry with full scans and/or selected ion monitoring. Five 13-hydroxylated GAs were detected from the three trees: GA_{1, 8}, and ₂₀ from alder, GA_{1, 8, 19} and ₂₀ from aspen and GA_{1, 8, 19, 20}, and ₂₉ from birch. Thirteen other GAs previously detected in Salix or common in other plants were specifically investigated but not detected. The presence of GA₁, its probable precursors GA₁₉ and GA₂₀, and its probable metabolite, GA₈, suggests that the early 13-hydroxylated GA biosynthetic pathway is dominant in vegetative buds of these trees. Abundant endogenous GAs of these trees are similar to the principal GAs of willows (various Salix spp.) and poplars (various Populus spp.). This suggests similarities in the GA physiology and is consistent with a common role of GA₁ as a regulator of shoot growth in woody angiosperms.     

Gibberellins in shoots of Hordeum vulgare. A comparison between cv. Triumph and two dwarf mutants which differ in their response to gibberellin

The gibberellin (GA) content of barley (Hordeum vulgare L.) cv. Triumph was analysed by full scan gas chromatography-mass spectrometry. Developing grain contained several di-, tri-, and tetra-hydroxylated GAs, with the most abundant ones being hydroxylated at C-2, C-3, C-12β, and/or C-18. In contrast, the only GAs to be detected in shoots of 9-day old dark- and light-grown seedlings of Triumph were 13-hydroxylated C₁₉-GAs, namely GA₁, GA₈, GA₂₀, and GA₂₉, (all of which are components of the early 13-hydroxylation GA biosynthetic pathway) and GA₃. Feeds of [¹³C.³H₂GA₂₀, confirmed that GA₂₀ is a precursor of GA₁, GA₈, and GA₂₉ in barley shoots. From these results it is suggested that stem growth of barley, in common with that of several other mono- and dicotyledons, is controlled by GA,. Homozygous gal and gal lines were obtained after backcrossing to Triumph. These were then compared to Triumph with respect to their GA content and response to applied GAs and GA precursors. Shoots of the homozygous gal gal plants contained ca 6-fold less GA₁, than Triumph. These plants responded to all ent-kaurenoids and 13-hydroxylated C₂₀- and C₁₉-GAs tested. It is concluded that the gal locus impairs the GA biosynthetic pathway prior to ent-kaurene, most probably at ent-kaurene synthetase. In contrast, shoots of homozygous gal gal line contained ca 10-fold higher levels of GA, than Triumph, but failed to respond to applied GA, or GA₃. The gal locus therefore confers insensitivity to both exogenous and endogenous GAs, possibly by perturbing the reception or transduction of the GA₁ signal.     

Identification and quantitative analysis of gibberellins inCitrus

Nine gibberellins (GAs) have been identified from tissues of Valencia orange (Citrus sinensis Osbeck) using gas chromatography—mass spectrometry and gas chromatography-selected ion monitoring of high-performance liquid chromatography (HPLC)-fractionated extracts. These GAs are GA₁, GA₃, GA₈, GA₁₉, GA₂₀, GA₂₉, 3-epi-GA₁, 2-epi-GA₂₉, and iso-GA₃. Selected-ion monitoring and stable-isotope dilution assays have been used to estimate levels of some of these GAs in vegetative and reproductive tissues. GA₂₉ was found to be the most abundant GA measured. GA₁ was found in all samples examined, and there was always less 3-epi-GA₁ than GA₁. GA₂₀ was present in most extracts. Leaves of developing inflorescence shoots contained six times more GA₂₉ than did leaves of comparable vegetative shoots. Levels of GA₂₉ increased during the early stages of fruit development. GA₂₀ may be more abundant in growing fruitlets than in those about to abscise; however, there were no consistent differences in the relative amounts of the other GAs. No major differences were found between tissues of immature seeded and seedless fruit, and developing seeds did not contain high levels of any of the GAs measured. It is concluded that seed-produced GAs are not essential for normal fruit development in Valencia orange.     

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.     

Genetic regulation of gibberellin deactivation in Pisum

The regulation of gibberellin (GA) deactivation was examined using the sin (slender) mutation in the garden pea (Pisum sativum L.). This mutation blocks the deactivation of GA₂₀, the precursor of the bioactive GA₁. Firstly, crosses were made to combine sin with the GA biosynthesis mutations na, lhⁱ and le-3. The combination sin na produced a novel phenotype, with long (‘slender’) basal internodes and extremely short (‘nana’) upper internodes. In contrast, the double mutant sin lhⁱ was phenotypically dwarf. The mutation sin causes an accumulation of GA₂₀ in maturing seeds, and this was unaffected by na, since the na mutation is not expressed in seeds. In contrast, lhⁱ seeds did not accumulate GA₂₀, since lhⁱ imposes an early block on GA biosynthesis. Secondly, the effects of sin on several steps in GA deactivation were investigated. In maturing seeds, the mutation sin blocks two steps in GA₂₀ metabolism, namely, GA₂₀ to GA₂₉, and GA₂₉ to GA₂₉-catabolite. In the vegetative plant, on the other hand, sin blocked the step GA₂₀ to GA₂₉, but not GA₂₉ to GA₂₉-catabolite; the steps GA₂₀ to GA₈₁ and GA₂₀ to GA₁ were also not impaired in this mutant. It is clear that the effects of sin, like those of na, are strongly organ-specific. The presence of separate enzymes for the steps GA₂₀ to GA₂₉ and GA₂₉ to GA₂₉-catabolite was suggested by the observation that GA₈ inhibited the latter step, but not the former, and by the inability of GA₂₀ and GA₂₉ to inhibit each other's metabolism. It is suggested that the Sin gene may be a regulatory gene controlling the expression of two structural genes involved in GA deactivation.     

Distribution of endogenous gibberellins in vegetative and reproductive organs of Brassica

Recognizing the physiological diversity of different plant organs, studies were conducted to investigate the distribution of endogenous gibberellins (GAs) in Brassica (canola or oilseed rape). GA₁ and its biosynthetic precursors, GA₂₀ and GA₁₉, were extracted, chromatographically purified, and quantified by gas-chromatography-selected ion monitoring (GC-SIM), using [²H₂]GAs as internal standards. In young (vegetative) B. napus cv. Westar plants, GA concentrations were lowest in the roots, increased acropetally along the shoot axis, and were highest in the shoot tips. GA concentrations were high but variable in leaves. GA₁ concentrations also increased acropetally along the plant axis in reproductive plants. During early silique filling, GA₁ concentrations were highest in siliques and progressively lower in flowers, inflorescence stalks (peduncles plus pedicels), stem, leaves, and roots. Concentrations of GA₁₉ and GA₂₀ showed similar patterns of distribution except in leaves, in which concentrations were higher, but variable. Immature siliques were qualitatively rich in endogenous GAs and GA₁, GA₃, GA₄, GA₈, GA₉, GA₁₇, GA₁₉, GA₂₀, GA₂₄, GA₂₉, GA₃₄, GA₅₁, and GA₅₃ were identified by GC-SIM. In whole siliques, GA₁₉, GA₂₀, GA₁, and GA₈ concentrations declined during maturation due to declining levels in the maturing seeds; their concentrations in the silique coats remained relatively constant and low. These studies demonstrate that GAs are differentially distributed in _Brassica with a general pattern of acropetally increasing concentration in shoots and high concentration in actively growing and developing organs.     

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).     

Gibberellins and Stem Growth as Related to Photoperiod in Silene armeria L

Stem growth and flowering in the long-day plant Silene armeria L. are induced by exposure to a minimum of 3 to 6 long days (LD). Stem growth continues in subsequent short days (SD), albeit at a reduced rate. The growth retardant tetcyclacis inhibited stem elongation induced by LD, but had no effect on flowering. This indicates that photoperiodic control of stem growth in Silene is mediated by gibberellins (GA). The objective of this study was to analyze the effects of photoperiod on the levels and distribution of endogenous GAs in Silene and to determine the nature of the photoperiodic after-effect on stem growth in this plant. The GAs identified in extracts from Silene by full-scan combined gas chromatography-mass spectrometry (GC-MS), GA₁₂, GA₅₃, GA₄₄, GA₁₇, GA₁₉, GA₂₀, GA₁, GA₂₉, and GA₈, are members of the early 13-hydroxylation pathway. All of these GAs were present in plants under SD as well as under LD conditions. The GA₅₃ level was highest in plants in SD, and decreased in plants transferred to LD conditions. By contrast, GA₁₉, GA₂₀, and GA₁ initially increased in plants transferred to LD, and then declined. Likewise, when Silene plants were returned from LD to SD, there was an increase in GA₅₃, and a decrease in GA₁₉, GA₂₀, and GA₁ which ultimately reached levels similar to those found in plants kept in SD. Thus, measurements of GA levels in whole shoots of Silene as well as in individual parts of the plant suggest that the photoperiod modulates GA metabolism mainly through the rate of conversion of GA₅₃. As a result of LD induction, GA₁ accumulates at its highest level in shoot tips which, in turn, results in stem elongation. In addition, LD also appear to increase the sensitivity of the tissue to GA, and this effect is presumably responsible for the photoperiodic after-effect on stem elongation in Silene.     

Gibberellins, Endogenous and Applied, in Relation to Flower Induction in the Long-Day Plant Lolium temulentum

Changes in endogenous gibberellin-like substances (GAs) and related compounds in the shoot apices of Lolium temulentum during and after flower induction by one long day was examined for plants grown in three consecutive years. The total GA level in the shoot apical tissue was high (up to 42 micrograms per gram dry weight, or 3 × 10⁻⁵ molar GA₃ equivalents), increasing several-fold on the day after the long day and then declining. Of the many GA-like substances present, the putative polyhydroxylated components—with HPLC retention times between those of GA₈ (three hydroxyls) and GA₃₂ (four hydroxyls), and accounting for about a quarter of the total GA activity—were most consistent and striking in their changes. Their level in the apices increased 3- to 5-fold on the day after the long day and then subsided. When various GAs were applied to plants in noninductive short days, flower initiation was induced by several, most notably by GA₃₂, GA₅, 2,2-dimethyl GA₄, GA₃, and GA₇. GA₃₂ was most like one long day in eliciting a strong flowering response while having little effect on stem growth, whereas GA₁ had the opposite effect. It is suggested that highly hydroxylated C-19 GAs may play a central role in the induction of flowering in this long-day plant.     

Gibberellins in Leaves of Alstroemeria hybrida: Identification and Quantification in Relation to Leaf Age

In alstroemeria (Alstroemeria hybrida), leaf senescence is retarded effectively by the application of gibberellins (GAs). To study the role of endogenous GAs in leaf senescence, the GA content was analyzed by combined gas chromatography and mass spectrometry. Five 13-hydroxy GAs (GA₁₉, GA₂₀, GA₁, GA₈, and GA₂₉) and three non-13-hydroxy GAs (GA₉ and GA₄) were identified in leaf extracts by comparing Kováts retention indices (KRIs) and full scan mass sprectra with those of reference GAs. In addition, GA₁₅, GA₄₄, GA₂₄, and GA₃₄ were tentatively identified by comparing selected ion monitoring results and KRIs with those of reference GAs. A number of GAs were detected in conjugated form as well. Concentrations of GAs in alstroemeria changed with the development of leaves. The proportion of biologically active GA₁ and GA₄ decreased with progressive senescence and the fraction of conjugated GAs increased. Received May 26, 1997; accepted August 12, 1997     

Implication of Gibberellins in Head Smut (Sporisorium reilianum) of Sorghum bicolor

The head smut fungus, Sporisorium reilianum ([Kuhn] Landon and Fullerton), was shown to reduce plant height in infected Sorghum bicolor ([L.] Moench) plants. The major reductions occurred in the internodes nearest the panicle and were more severe in naturally infected than in inoculated plants. Less affected plants developed reproductively sterile panicles, and eventually smutted panicles developed phyllodied growths which progressed into leafy shoots. Extracts of smutted, sterile, and healthy (control) panicles of field-grown plants exhibited gibberellin (GA)-like activity in the dwarf rice bioassay. When extracts were purified and assayed with deuterium-labeled GA standards by gas chromatography-mass spectrometry-selected ion monitoring (GC-MS-SIM), GA₁, GA₃, GA₁₉, GA₂₀, and GA₅₃ were detected based on coelution with the standards, identical Kovats retention index values, and matching ion masses and relative abundances for three major ions. In addition, based on published Kovats retention index values, ion masses, and relative abundance values, GA₄, GA₇, GA₈, GA₁₄, GA₂₉, and GA₄₄ were tentatively identified. Quantitative analysis revealed that panicles of healthy control plants contained from 60 to 100% higher total concentrations of GAs than panicles of smutted plants. These comparisons were most striking for the early 13-hydroxylation pathway precursors GA₅₃, GA₄₄, and GA₁₉ but not for GA₂₀. Extracts of S. reilianum sporidia and culture medium exhibited GA-like bioactivity, and GA₁ and GA₃ were detected based on GC-MS-SIM assay with ²H-labeled internal standards. Quantitative analysis of these GAs showed increasing concentrations from 4 to 7 to 10 days of culture and a decline at 20 days. This is the first GC-MS-SIM detection of GAs in a non-Ascomycete fungus, and the disease symptoms and quantitative data suggested that fungal infection may interfere with biosynthesis of GAs by the host plant.     

Gibberellins in Embryo-Suspensor of Phaseolus coccineus Seeds at the Heart Stage of Embryo Development

Gibberellins (GAs) in suspensors and embryos of Phaseolus coccineus seeds at the heart stage of embryo development were analyzed by combined gas chromatography-mass spectrometry (GC-MS). From the suspensor four C₁₉-GAs, GA₁, GA₄, GA₅, GA₆, and one C₂₀ GA, GA₄₄, were identified. From the embryo, five C₁₉-GAs GA₁, GA₄, GA₅, GA₆, GA₆₀ and two C₂₀ GAs, GA₁₉ and GA₄₄ were identified. The data, in relation to previous results, suggest a dependence of the embryo on the suspensor during early stages of development.     

Gibberellins in apical shoot meristems of flowering and vegetative sugarcane

Gibberellins A₁, A₃, iso-A₃, A₄, A₁₉, A₂₀, and A₃₆ were identified by gas chromatography-selected ion monitoring in apices of sugarcane (Saccharum spp. hybrids). Flowering apices (i.e., 2–4 cm panicle) contained 8–9 times more (estimated by bioassay) endogenous gibberellins A and iso-GA₃ (ratio of 1:6:8, respectively; in total 51 ng g^–1 fresh weight) than vegetative apices (6.4 ng g^–1 fresh weight). Vegetative apices contained small but significant levels of GA₁₉, which could not be detected in flowering apices; vegetative apices also contained approximately four times more of a GA₃₆-like substance than flowering apices. Since the two apex types developed under the same photoperiod, the increased levels of GA and iso-GA₃ and the reduced levels of GA₁₉ and GA₃₆-like substances are correlated with the flowering state rather than with photoperiod or photoperiod changes per se. Since there were relatively high levels of C₁₉ GAs along with low levels of C₂₀ GAs in flowering apices, and since the converse is true in vegetative apices, metabolism of C₂₀ to C₁₉ GAs may be enhanced in flowering apices.Mention of a trademark, proprietary product, or vendor does not constitute a guarantee or warranty of the product by U.S. Department of Agriculture and does not imply its approval to the exclusion of other products or vendors that may also be suitable.     

The roles and interactions of ethylene with gibberellins in the far-red enriched light-mediated growth of <Emphasis Type="Italic">Solanum lycopersicum</Emphasis> seedlings

Wild type (WT) tomato seedlings responded to a low red to far-red (R/FR) ratio with increased stem elongation, similar leaflet area expansion and lower shoot ethylene levels. The levels of endogenous growth-active GA₁ and its immediate precursor GA₂₀ were decreased by low R/FR ratio, whereas the levels of GA₁ catabolite, GA₈, increased. To examine the interaction of ethylene with GAs in regulating tomato shoot growth under low R/FR ratio, transgenic (T) seedlings bearing Le-ACS2 and Le-ACS4 antisense mRNA were utilized. Low R/FR ratio increased stem elongation and decreased ethylene levels in T tomato shoots, as it did in WT shoots. However, T stems were significantly taller than the WT stems under low R/FR ratio. Leaflet areas were significantly larger for T, than WT seedlings under both R/FR ratios. Low R/FR ratio did not decrease endogenous levels of GA₁ and GA₂₀ in T shoots, but did increase GA₈ levels, which were higher than in WT shoots. These results, and hormone/inhibitor application studies, showed that in tomato shoots subjected to low R/FR ratio, GAs play a growth-promotive role in stem elongation, whereas ethylene is growth-inhibitory. Further, these results may imply that decreasing ethylene production under low R/FR ratio causes increases in stem elongation and GA levels.