Micronucleus frequency and lipid peroxidation in <Emphasis Type="Italic">Allium sativum</Emphasis> root tip cells treated with gibberellic acid and cadmium

Gibberellic acid (GA₃) is a very potent hormone whose natural occurrence in plants controls their development. Cadmium is a particularly dangerous pollutant due to its high toxicity and great solubility in water. In this study, the effect of GA₃ on Allium sativum root tip cells was investigated in the presence of cadmium. A. sativum root tip cells were exposed to CdNO₃ (50, 100, 200 μM), GA₃ (10-3 M), both CdNO₃ and GA₃. Cytogenetic analyses were performed as micronucleus (MN) assay and mitotic index (MI). Lipid peroxidation analysis was also performed in A. sativum root tip cells for determination of membrane damage. MN exhibited a dose-dependent increase in Cd treatments in A. sativum. GA₃ significantly reduced the effect of Cd on the MN frequency. MN was observed in GA₃ and GA₃ + 50 μm Cd treatments at very low frequency. MI slightly decreased in GA₃ and GA₃ + Cd treatments. MI decreased more in high concentrations of Cd than combined GA₃ + Cd treatments. The high concentrations of cadmium induce MN, lipid peroxidation and lead to genotoxicity in A. sativum. Current work reveals that the effect of Cd on genotoxicity can be partially restored with GA₃ application.     

Expression of gibberellin mutations in fruits of Pisum sativum L.

The gibberellin (GA) economy of young pea (Pisum sativum L.) fruits was investigated using a range of mutants with altered GA biosynthesis or deactivation. The synthesis mutation lh-2 substantially reduced the content of both GA₄ and GA₁ in young seeds. Among the other synthesis mutations, ls-1, le-1 and le-3, the largest reduction in seed GA₁ content was only 1.7-fold (le-1), while GA₄ was not reduced in these mutants, and in fact accumulated in some experiments (compared with the wild type). Mutation sln appeared to block the step GA₂₀ to GA₂₉ in young pods and seeds, but not as strongly as in older seeds. Mutations ls-1, le-1 and le-3 markedly reduced pod GA₁ levels, but pod elongation was not affected. After feeds of [¹³C,³H]GA₂₀ to leaves, the pods contained ¹³C,³H-labelled GA₂₀, GA₁, GA₂₉ and GA₈₁, and the seeds, [¹³C,³H]GA₂₀ and [¹³C,³H]GA₂₉. These findings are discussed in relation to recent suggestions regarding the role and origin of GA₁ in pea fruits. Received: 6 June 1997 / Accepted: 15 July 1997     

Gibberellin formation in microorganisms

Several microorganisms possess the capacity of synthesizing gibberellins (GAs) in axenic culture. GA concentrations in the range of approximately 20 to 200 milligrams per litre of culture filtrate are produced by wild-type strains of the following fungi: Gibberella fujikuroi (GA₃, GA₄, GA₇, GA₁ and others), Sphaceloma manihoticola and other species of this genus (GA₄, GA₉ and others), Phaeosphaeria sp. (GA₁, GA₄, GA₉ and others). Neurospora crassa is capable of producing GA₃ in the range of micrograms per kilogram of mycelium. Nanogram amounts per litre of culture are present in fermentations of the bacteria Rhizobium phaseoli (GA₁, GA₄, GA₉, GA₂₀) and in Azospirillum lipoferum and A. brasilense (GA₁, GA₃). Of the high-producing organisms, G. fujikuroi and the Sphaceloma spp. appear to have an almost identical GA metabolism except that Sphaceloma is, in particular, unable to produce GA₇ and GA₁. Phaeosphaeria sp. converts GA₉ via GA₄ or GA₂₀ into GA₁, reactions not known from G. fujikuroi. Generally however, GA metabolism in these organisms appears to be very similar to the one known from higher plants. Most likely, the GAs formed play no hormonal or other immediate physiological role in the producing organism and can, thus, be regarded as secondary metabolites. On the other hand, evidence is available that GA-producing microorganisms often induce reactions in host plants which are beneficial to their growth.     

Effect of Different Gibberellins on the Growth of the Hypocotyl

It has been stated earlier that hypocotyls of different plants show different growth response to added GA₃. It was suggested that this difference may be due to the requirement of some specific gibberellin. Hence hypocotyl growth response of three groups of plants has been studied with different gibberellins: group one showing no or insignificant growth response, group two showing 150–200 per cent growth response and group three showing 300–500 per cent growth response to added GA₃. Eight gibberellins were used, viz., GA₁, GA₂, GA₃, GA₄, GA₅, GA₇, GA₈ and GA₉, to test if this varying response is connected with the requirement of some specific gibberellin. In general, the results obtained do not favour this view. Iberis amara, a plant showing no response to added GA₃, Dianthus sp., a plant showing 150 to 200 per cent response and Lactuca satwa, Antirrhinum majus and Nicotiana tabacum, plants showing 300 to 500 per cent response, were promoted by all the gibberellins tested to a similar extent as by GA₃, with the exception of GA₈ which was inactive in most of the cases.     

Callus Formation and Embryogenesis of Endosperm Tissues of Parsley Seed Cultured on Hormone-Free Medium

Archegonial differentiation in light-grown gametophytes of Lygodium japonicum was partially inhibited by exogenously applied gibberellin A₃ (GA₃) at a concentration of 10^?6M, and fully prevented at 10^?5M. The inhibitory effect was nullified by transferring the GA₃-treated samples onto fresh media omitting GA₃, so that the archegonial formation became discernible 6 days after the transplantation. The application of 10^?4M GA₃ to younger gametophytes brought about a complete inhibition of archegonial differentiation, whereas the same concentration applied to older gametophytes did not influence the process at all, indicating the timing of archegonial differentiation during the ontogeny. Activity spectrum of authentic gibberellins on the basis of concentrations inducing 50% inhibition of archegonial formation was obtained as follows: GA₄= GA₉ > GA₇ > GA₃ > GA₁= GA₅= GA₈.     

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     

Identification of gibberellin A4 in Pisum sativum L. and the effects of applied gibberellins A9, A4, A5 and A3 on the le mutant

Gibberellin A₄ (GA₄) was identified for the first time in the garden pea (Pisum sativum) L.), by gas chromatography-mass spectrometry. However, in wild-type shoots the level of GA₄ was only about 6% of the level of GA₁, and it is therefore unlikely that GA₄ plays a major role per se in the control of pea stem elongation. In shoots of the le mutant, GA₄ was not detected, while the level of GA₉ was approximately twice that found in the wild-type. The le mutation also markedly reduced the elongation response to applied GA₉. It appears, therefore, that in Pisum the le mutation blocks the 3-hydroxylation of GA₉ to GA₄, in addition to the 3-hydroxylation of GA₂₀ to GA₁. In contrast, the le mutation did not reduce the response to applied GA₅, suggesting the step GA₅ to GA₃ is not catalysed by the enzyme controlled by the Le gene. The step GA₅ to GA₃ was confirmed in peas by metabolite analysis after treatment with deuterated GA₅.     

Hormonal regulation of fruit set, parthenogenesis induction and fruit expansion in Japanese pear

The effects of applied gibberellins (GAs), GA₁, GA₃, GA₄ and GA₇ with a cytokinin, N-(2-chloro-4-pyridyl)-N′-phenylurea (CPPU) and indole-3-acetic acid (IAA) on fruit set, parthenogenesis induction and fruit expansion of a number of Rosaceae species were assessed. These included Japanese pear cv. ‘Akibae’ (self-compatible) and cv. ‘Iwate yamanashi’ (a seedless cultivar). Other Rosaceae species (Pyrus communis, Chaenomeles sinensis, Cydonia oblonga, and Malus pumila) were also investigated. GA₄, GA₇ and CPPU are very effective in inducing parthenocarpic fruit growth, whereas GA₁, GA₃ and IAA, have no ability to induce parthenogenesis in Japanese pear. GA₄- and GA₇-induced parthenocarpic fruit tended to be smaller in size, higher in flesh hardness, and showed advanced fruit ripening in comparison to pollinated fruit and to parthenocarpic fruit induced by CPPU. GA₄- and GA₇-induced parthenocarpic fruit also had an increased pedicel length and fruit shape index and also showed a slight protrusion of the calyx end. CPPU, GA₄ and GA₇ alone or combination with uniconazole were also active in inducing parthenogenesis in three other Rosaceae species, although final fruit set was extremely low. GA₁ was essentially inactive in promoting fruit expansion unlike the other bioactive GAs, whose effectiveness in promoting fruit cell expansion was as follow: GA₄ ≈ GA₇ > GA₃ > GA₁.     

Function and Expression Analysis of Gibberellin Oxidases in Apple

Three cDNAs, encoding gibberellin (GA) 20-oxidase (MdGA20ox1, identical to AB037114), 3-oxidase (MdGA3ox1), and 2-oxidase (MdGA2ox1), were isolated from apple cv. Fuji (Malus x domestica). Southern blot analysis indicated that each of these genes belongs to a gene family. Standard enzyme assays show that the MdGA20ox1-MBP fusion protein can sequentially oxidize three times at C-20 position of GA₁₂ and GA₅₃ and generate GA₉ and GA₂₀; the MdGA3ox1-MBP fusion protein converts GA₂₀ and GA₉ to GA₄ and GA₁, and the MdGA2ox1-MBP fusion protein converts GA₄ and GA₁ to GA₃₄ and GA₈, respectively. In addition, we confirmed that MdGA20ox1 is strongly expressed in immature seeds and scarcely detected in other tissues, whereas MdGA3ox1 and MdGA2ox1 are mainly expressed in flowers. Therefore, all the three cDNAs are localized in reproductive tissues. Functional and expression analysis of the three GA oxidases would provide fundamental molecular information to analyze GA metabolic regulation in apple.     

Cloning,Heterologous Expression,and Enzymatic Characterization of Cathepsin L from Starfish (Asterina pectinifera)

Methyl esters of 3-epi-GA₃ and 3-epi-GA₁ were efficiently prepared from methyl esters of GA₃ and GA₁ respectively, by highly selective epimerization of the 3-hydroxyl function with a base in a low-polar aprotic medium.     

Promotive and inhibitory effects of uniconazole and prohexadione on the sprouting of bulbils of Chinese yam,Dioscorea opposita

Gibberellin A₁ (GA₁), GA₃ and GA₄ inhibited the sprouting of nondormant bulbils of Chinese yam, Dioscorea opposita, where the effectiveness of the GAs was as follows: GA₄>GA₁+GA₃. Uniconazole and prohexadione, plant growth retardants, promoted the sprouting of half-dormant bulbils. By contrast, these retardants inhibited the sprouting of nondormant bulbils. Gibberellin A₃ (GA₃) and A₄ (GA₄) which were applied to the stems of the sprouted bulbils, promoted stem elongation, but GAs applied to the bulbous parts inhibited this process. The effectiveness of the GAs on stem elongation was as follows: GA₃+GA₄ for the promotion and GA₄ > GA₃ for the inhibition. Uniconazole applied to the stem inhibited the stem elongation of the sprouted bulbils. These results suggest the possible involvement of endogenous GAs in the induction and maintenance of bulbil dormancy of D. opposita, as well as in the bulbil sprouting and subsequent stem elongation.     

The role of gibberellin biosynthesis in the control of growth and flowering in Matthiola incana

Recently, it was found that stem elongation and flowering of stock Matthiola incana (L.) R. Br. are promoted by exogenous gibberellins (GAs), including GA₄, and also by acylcyclohexanedione inhibitors of GA biosynthesis, such as prohexadione‐calcium (PCa) and trinexapac‐ethyl (TNE). Here, because it was unclear how GA biosynthetic inhibitors could promote stem elongation and flowering, their effect on GA biosynthesis has been examined by quantifying endogenous GA levels; also, the sensitivity of stem elongation and flowering to various GAs in combination with the inhibitors was examined. Stem elongation and flowering were most effectively promoted by GA₄ when combined with PCa and, next in order, by 2,2‐dimethyl‐GA₄, PCa, GA₄+TNE, TNE, GA₉+PCa and by GA₄. There was little or no promotion by GA₁, GA₃, GA₉, GA₁₃, GA₂₀ and 3‐epi‐2,2‐dimethyl‐GA₄. Both the promotive effects of the acylcyclohexanediones on stem elongation and flowering, particularly when applied with GA₄, and the fact that TNE caused a build‐up of endogenous GA₄ imply that one effect of TNE at the lower dose involved an inhibition of 2β‐hydroxylation of GA₄ rather than an inhibition of 20‐oxidation and 3β‐hydroxylation of GAs which were precursors of GA₄. Overall, these results indicate that: (1) GAs with 3β‐OH and without 13‐OH groups (e.g. GA₄) are the most important for stem elongation and flowering in M. incana; (2) growth promotion rather than inhibition can result if an acylcyclohexanedione acts predominantly to slow 2β‐hydroxylation and so slows inactivation of active gibbberellins, including GA₄. It follows that a low dose of an acylcyclohexanedione can be a ‘growth enhancer’ for any applied GA that is liable to inactivation by 2β‐hydroxylation.     

Accumulation of C19-gibberellins in the gibberellin-insensitive dwarf mutantgai ofArabidopsis thaliana (L.) Heynh

The endogenous gibberellins (GAs) from shoots of the GA-insensitive mutant,gai, ofArabidopsis thaliana were analyzed and compared with the GAs from the Landsberg erecta (Ler) line. Twenty GAs were identified in Ler plants by full-scan gas chromatography-mass spectrometry (GC-MS) and Kovats retention indices (KRI's). These GAs are members of the early-13-hydroxylation pathway (GA₅₃, GA₄₄, GA₁₉, GA₁₇, GA₂₀, GA₁, GA₂₉, and GA₈), the non-3,13-hydroxylation pathway (GA₁₂, GA₁₅, GA₂₄, GA₂₅, GA₉, and GA₅₁), and the early-3-hydroxylation pathway (GA₃₇, GA₂₇, GA₃₆, GA₁₃, GA₄, and GA₃₄). The same GAs, except GA₅₃, GA₄₄, GA₃₇, and GA₂₉ were detected in thegai mutant by the same methods. In addition, extracts fromgai plants contained GA₄₁ and GA₇₁. Both lines also contained several unknown GAs. In Ler plants these were mainly hydroxy-GA₁₂ derivatives, whereas in thegai mutant hydroxy-GA₂₄, hydroxy-GA₂₅, and hydroxy-GA₉ compounds were detected. Quantification of seven GAs by GC-selected ion monitoring (SIM), using internal standards, and comparisons of the ion intensities in the SIM chromatograms of the other thirteen GAs, demonstrated that thegai mutant had reduced levels of all C₂₀-dicarboxylic acids (GA₅₃, GA₄₄, GA₁₉, GA₁₂, GA₁₅, GA₂₄, GA₃₇, GA₂₇, and GA₃₆). In contrast,gai plants had increased levels of C₂₀-tricarboxylic acid GAs (GA₁₇, GA₂₅, and GA₄₁) and of all C₁₉-GAs (GA₂₀, GA₁, GA₈, GA₉, GA₅₁, GA₄, GA₃₄, and GA₇₁) except GA₂₉. The 3β-hydroxylated GAs, GA₁ and GA₄, and their respective 2β-hydroxylated derivatives, GA₈ and GA₃₄, were the most abundant GAs found in shoots of thegai mutant. Thus, thegai mutation inArabidopsis results in a phenotype that resembles GA-deficient mutants, is insensitive to both applied and endogenous GAs, and contains low levels of C₂₀-dicarboxylic acid GAs and high levels of C₁₉-GAs. This indicates that theGAI gene controls a step beyond the synthesis of an active GA. Thegai mutant is presumably a GA-receptor mutant or a mutant with a block in the transduction pathway between the receptor and stem elongation. We thank Dr. L.N. Mander, Australian National University, Canberra, for providing [²H]gibberellins, Dr. B.O. Phinney, University of California, Los Angeles, USA for [¹³C]GA₈, and Dr. D.A. Gage, MSU-NIH Mass Spectrometry Facility (grant No. DRR00480), for advice with mass spectrometry. This work was supported by a fellowship from the Spanish Ministry of Agriculture (I.N.I.A.) to M.T., by the U.S. Department of Energy under Contract DE-ACO2-76ERO-1338, and by U.S. Department of Agriculture grant No. 88-37261-3434 to J.A.D.Z.     

Regulation of Growth in Avena (Oat) Stem Segments by Gibberellic Acid and Abscisic Acid

The purpose of this study was to analyze the nature of the interaction between gibberellic acid (GA₃) and abscisic acid (ABA) in the regulation of growth in excised Avena (oat) stem segments. Growth, compared to sucrose controls, was inhibited by ABA in the range of 10^?4 to 10^?6M. GA₃-promoted growth was also inhibited by ABA in the same concentration range. A Lineweaver-Burk analysis of the interaction between GA₃ and ABA indicated that ABA acts in a non-competitive fashion with GA₃. This same result was obtained previously with GA₃-indoleacetic acid (IAA) and GA₃-kinetin interactions with Avena stem sections. Our results indicate that ABA can inhibit GA₃-promoted growth within physiological concentrations, and that it is probably acting at a different physiological site from that for GA₃.     

Effect of nine different gibberellins on stem elongation and flower formation in cold-requiring and photoperiodic plants grown under non-inductive conditions

Summary The effect of gibberellins A₁ through A₉ on stem elongation and flower formation in five plants was tested. The plants wereMyosotis alpestris and a biennial strain ofCentaurium minus (cold-requiring plants),Silene armeria andCrepis parviflora (long-day plants), andBryophyllum crenatum (a long-short-day plant). The two former plants were maintained on non-inductive temperatures and long days, the three latter on short days, InMyosotis, flower formation was only obtained with GA₇ and GA₁, the latter being relatively less active. InCentaurium GA₃ was the most effective, followed by GA₁, GA₄ and GA₇ and perhaps GA₅ and GA₉. InSilene, flower formations was induced only by GA₇. InCrepis, the most effective gibberellins were GA₄ and GA₇, inBryophyllum, GA₃, GA₄ and GA₇. Thus, the different gibberellins exhibited considerable differences in their activity with respect to flower induction, and different plants exhibited in this respect certain specific differences in their sensitivity to the various gibberellins. Except inCrepis, flower initiation as a result of gibberellin treatment was always preceded by substantial stem or internode elongation; however, the correlation between the effect of the different gibberellins on stem elongation and flower induction was not in all cases complete. No correlation of the flower-inducing and elongation-promoting activity with the chemical structure of the different gibberellins could be recognized.With 2 Figures in the TextWork in part supported by the National Science Foundation, grants G-16408 and G-17483.     

The effect of photoperiod on the levels of seven endogenous gibberellins in the long-day plant Agrostemma githago L.

The following seven gibberellins (GAs) have been identified by gas chromatography-mass spectrometry in shoots and leaves of the long-day plant Agrostemma githago: GA₅₃, GA₄₄, GA₁₉, GA₁₇, GA₂₀, GA₁, and 3-epi-GA₁. The levels of these compounds were measured, using selected ion monitoring, during photoperiodic induction. The levels of GA₄₄, GA₁₉, GA₁₇, and GA₂₀ all increased to a peak at eight long days (LD), followed by a decline, while the levels of GA₁ and 3-epi-GA₁ did not reach a peak until 12 LD. The level of GA₅₃ remained steady over the first 10–12 LD. Later in the LD treatment the levels of GA₅₃, GA₄₄, GA₁₉, and GA₁₇ increased again. The rate of metabolism of all GAs except GA₅₃ was higher after 12–16 LD than under short days. These data thus provide indirect evidence for an effect of photoperiodic induction on GA turnover in A. githago.Abbreviations AMO-1618 2-isopropyl-4-dimethylamino-5-methylphenyl-1-piperidine-carboxylate methyl chloride - GA(s) gibberellin(s) - GC-MS gas chromatography-mass spectrometry - HPLC high performance liquid chromatography - LD long day(s) - MeTMS trimethylsilylether of the methyl ester - SD short day(s) - SIM selected ion monitoring     

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.     

Gibberellin physiology of safflower: endogenous gibberellins and response to gibberellic acid

Endogenous gibberellins (GAs) were extracted from safflower (Carthamus tinctorius L.) stems and detected by capillary gas chromatography-mass spectrometry from which GA₁, GA₃, GA₁₉,, GA₂₀, GA₂₉, and probably, GA₄₄ were detected. The detection of these GAs suggests that the early 13-OH biosynthetic pathway is prevalent in safflower shoots. Deuterated GAs were used as internal standards and GA concentrations were determined in stems harvested at weekly intervals. GA₁ and GA₁₉ levels per stem increased but concentrations per gram dry weight decreased over time. GA₂₀ was only detected in young stem tissue.Gibberellic acid (GA₃) was also applied in field trials and both GA₃ and the GA biosynthetic inhibitor, paclobutrazol, were applied in growth chamber tests. GA₃ increased epidermal cell size, internode length, and increased internode cell number causing stem elongation. Conversely, paclobutrazol reduced stem height, internode and cell size, cell number and overall shoot weight. In field tests, GA₃ increased total stem weight, but decreased leaf weight, flower bud number and seed yield. Thus, GA₃ promoted vegetative growth at the expense of reproductive commitment. These studies collectively indicate a promotory role of GAs in the control of shoot growth in safflower, and are generally consistent with gibberellin studies of related crop plants. Author for correspondence     

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.