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.     

Identification of Endogenous Gibberellins and Abscisic Acid from Dormant Bulbils of Dioscorea japonica (Japanese Yam)

Four gibberelJins (GAs), GA₁₉, GA₂₀, GA₂₄, and GA₅₃, were identified by gas chromatography-mass spectrometry (GC-MS) from the dormant bulbils of Dioscorea japonica Thunb. ex Murray (Japanese yam), suggesting that two biosynthetic pathways of GAs, early 13- and non-13-hydroxylation pathways, are operating in the bulbils. Abscisic acid was also identified by GC-MS.     

Quantification of endogenous gibberellins in leaves and tubers of Chinese yam, Dioscorea opposita Thunb. cv. Tsukune during tuber enlargement

Elevengibberellins (GAs) were identified and quantified in extracts of leaves andtubers of the Chinese yam, Dioscorea opposita Thunb. cv.Tsukune by GC-MS-SIM and Kovats retention indices. Five of these gibberellinsare members of the early-13-hydroxylation pathway (GA₅₃,GA₄₄, GA₁₉, GA₂₀ and GA₁), and sixare members of the non-13-hydroxylation pathway (GA₁₂,GA₁₅, GA₂₄, GA₉, GA₃₆ andGA₄). Of these eleven, GA₄₄, GA₁₅ andGA₁ were detected for the first time in Dioscoreaopposita leaf tissues. The major biosynthetic GA pathway in leavesofChinese yam was non C-13 hydroxylation (NCH). In addition, the activeGA₄ content for all harvest dates was greater than that ofGA₁ in the leaves and tubers during tuber development. It issuggested that the higher level of GA₄ in the leaves and tubers maybe closely related to tuber enlargement.     

Quantification of GA1, GA3, GA4, GA7, GA8, GA9, GA19 and GA20; and GA20 metabolism in dormant and non-dormant beechnuts

The endogenous levels of GA₁, GA₃, GA₄, GA₇, GA₈, GA₉, GA₁₉ and GA₂₀ were determined in beech seeds (Fagus sylvatica L.) treated with different dormancy breaking treatments. Gibberellins were analysed separately in cotyledons and embryo axes. After purification of the extracts, GAs were quantified by GC-MS-selected ion monitoring (GC-MS-SIM) with deuterated GAs as internal standards. The results showed that GAs corresponding to the 13-OH pathway seemed to be involved in dormancy breaking. Strong differences in GA₁, GA₃, GA₈, GA₁₉ and GA₂₀ levels between embryo axes and cotyledons of dormant and non-dormant beechnuts were detected with less pronounced differences for GA₄, GA₇ and GA₉ levels. Both the quantitative differences between dormant and non-dormant seeds in the analysed GAs corresponding to the 13-OH pathway, and the capacity of non-dormant seeds to carry out metabolic conversions when labelled GA₂₀ was injected into the seeds, reveal a dynamic role of GAs in dormancy release.     

Endogenous Gibberellins in Aralia cordata

Eight gibberellins (GAs) were identified in extracts of buds of Aralia cordata by full scan GC/MS and by Kovats retention indices. These GAs comprised five GAs on the early-13-hydroxylation pathway [GA₁, GA₁₉, GA₂₀, GA₄₄, and GA₅₃] and three other GAs [GA₄, GA₁₅, and GA₃₇]. The major GAs were GA₁₉ and GA₄₄.     

Biosynthesis of 12α-and 13-hydroxylated gibberellins in a cell-free system from Cucurbita maxima endosperm and the identification of new endogenous gibberellins

Gibberellin (GA) biosynthesis in cell-free systems from Cucurbita maxima L. endosperm was reinvestigated using incubation conditions different from those employed in previous work. The metabolism of GA₁₂ yielded GA₁₃, GA₄₃ and 12α-hydroxyGA₄₃ as major products, GA₄, GA₃₇, GA₃₉, GA₄₆ and four unidentified compounds as minor products. The intermediates GA₁₅, GA₂₄ and GA₂₅ accumulated at low protein concentrations. The structure of the previously uncharacterised 12α-hydroxyGA₄₃ was inferred from its mass spectrum and by its formation from both GA₃₉ and GA₄₃. Gibberellin A₃₉ and 12α-hydroxyGA₄₃ were formed by a soluble 12α-hydroxylase that had not been detected before. Gibberellin A₁₂-aldehyde was metabolised to essentially the same products as GA₁₂ but with less efficiency. A new 13-hydroxylation pathway was found. Gibberellin A₅₃, formed from GA₁₂ by a microsomal oxidase, was converted by soluble 2-oxoglutarate-dependent oxidases to GA₁ GA₂₃, GA₂₈, GA₄₄, and putative 2β-hydroxyGA₂₈. Minor products were GA₁₉, GA₂₀, GA₃₈ and three unidentified GAs. Microsomal 13-hydroxylation (the formation of GA₅₃) was suppressed by the cofactors for 2-oxoglutarate-dependent enzymes. Reinvestigation of the endogenous GAs confirmed the significance of the new metabolic products. In addition to the endogenous GAs reported by Blechschmidt et al. (1984, Phytochemistry 23, 553–558), GA₁, GA₈, GA₂₅, GA₂₈, GA₃₆, GA₄₈ and 12α-hydroxyGA₄₃ were identified by full-scan capillary gas chromatography-mass spectrometry and Kovats retention indices. Thus both the 12α-hydroxylation and the 13-hydroxylation pathways found in the cell-free system operate also in vivo, giving rise to 12α-hydroxyGA₄₃ and GA₁ (or GA₈), respectively, as their end products. Evidence for endogenous GA₂₀ and GA₂₄ was also obtained but it was less conclusive due to interference.     

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.     

Gibberellin content of immature apple seeds from paclobutrazol-treated trees over three seasons

Seeds from heavily fruiting (on-year), mature untreated, and paclobutrazol-treated apple trees (Malus domestica Borkh. cv. Spartan) were sampled in mid-June 1987, mid-July 1987, and mid-July 1990. After seeds were freeze-dried, gibberellins (GAs) were extracted, purified, and fractionated via C₁₈ reversed-phase high-performance liquid chromatography (HPLC). Nine GAs (GA₁, GA₃, GA₄, GA₇, GA₈, GA₉, GA₁₉, GA₂₀, and GA₅₃) were quantified by the use of deuterated GA internal standards. Paclobutrazol trunk drench treatments reduced vegetative shoot elongation in the seasons that seeds were sampled by 55% or more. Between June 17, 1987 and July 15, 1987, the dry weight of seeds from both untreated and treated trees increased about 2.5 times and there were reductions, on a per seed basis, of GA₄ in seeds from both untreated and treated trees, of GA₇ in seeds from treated trees, and of GA₉ in seeds from untreated trees. However, GA₉ increased in seeds from treated trees. Changes in levels of some of the early-13-hydroxylation pathway GAs (GA₁₅ GA₃, GA₈, GA₁₉, GA₂₀, and GA₅₃) also occurred during the month. For mid-July harvested seeds, the pattern, with some exceptions, was that 2 years after paclobutrazol treatment (1987), levels of early-13-hydroxylation pathway GAs in seeds from treated trees were lower compared to controls but after 5 years (1990) their levels tended to increase. For the non-13-hydroxylated GAs (GA₄, GA₇, and GA₉), 2 years after paclobutrazol treatment, GA₄ levels were equal in seeds from untreated and treated trees, GA₇ decreased in seeds from treated trees compared with controls, but GA₉ levels increased. Levels of these three GAs were higher in seeds from treated trees 5 years after treatment (1990) but levels of GA₄, GA₇, and GA₉ dramatically increased in seeds from treated trees 4 years after treatment (1989), as we previously reported.     

Light effects on endogenous levels of gibberellins in photoblastic lettuce seeds

Gibberellin A₁ (GA₁), 3-epi-GA₁ GA₁₇, GA₁₉, GA₂₀, and GA₇₇ were identified by Kovats retention indices and full-scan mass spectra from gas chromatography-mass spectrometry analysis of a purified extract of mature seeds of photoblastic lettuce (Lactuca sativa L. cv. Grand Rapids). Non-13-hydroxylated GAs such as GA₄ and GA₉ were not detected even by highly sensitive radioimmunoassay. These results show that the major biosynthetic pathway of GAs in lettuce seeds is the early-13-hydroxylation pathway leading to GA₁, which is suggested to be physiologically active in lettuce seed germination. Quantification of endogenous GAs in the lettuce seeds by gas chromatography-selected ion monitoring using deuterated GAs as internal standards indicated that the endogenous level of GA₁ increased to a level about three times that of dark control 6 h after a brief red light irradiation, and that far-red light given after red light suppressed the effect of red light. The contents of GA₂₀ and GA₁₉ were not affected by the red light irradiation. Evidence is also presented that 3-epi-GA₁ is a native GA in the lettuce seeds.     

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.     

Qualitative and Quantitative Analyses of Gibberellins in Vegetative Shoots of Normal, dwarf-1, dwarf-2, dwarf-3, and dwarf-5 Seedlings of Zea mays L

Gibberellins A₁₂ (GA₁₂), GA₅₃, GA₄₄, GA₁₉, GA₁₇, GA₂₀, GA₂₉, GA₁, and GA₈ have been identified from extracts of vegetative shoots of normal (wild type) maize using full scan capillary gas chromatography-mass spectrometry and Kovats retention indices. Seven of these gibberellins (GAs) have been quantified by capillary gas chromatography-selected ion monitoring using internal standards of [¹⁴C₄]GA₅₃, [¹⁴C₄]GA₄₄, [²H₂] GA₁₉, [¹³C₁]GA₂₀, [¹³C₁]GA₂₉, [¹³C₁]GA₁, and [¹³C₁]GA₈. Quantitative data from extracts of normal, dwarf-1, dwarf-2, dwarf-3, and dwarf-5 seedlings support the operation of the early 13-hydroxylation pathway in vegetative shoots of Zea mays. These data support the positions in the pathway blocked by the mutants, previously assigned by bioassay data and metabolic studies. The GA levels in dwarf-2, dwarf-3, and dwarf-5 were equal to, or less than, 2.0 nanograms per 100 grams fresh weight, showing that these mutants are blocked for steps early in the pathway. In dwarf-1, the level of GA₁ was very low (0.23 nanograms per 100 grams fresh weight) and less than 2% of that in normal shoots, while GA₂₀ and GA₂₉ accumulated to levels over 10 times those in normals; these results confirm that the dwarf-1 mutant blocks the conversion of GA₂₀ to GA₁. Since the level of GAs beyond the blocked step for each mutant is greater than zero, each mutated gene probably codes for an altered gene product, thus leading to impaired enzyme activities.     

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.     

Qualitative and Quantitative Analysis of Endogenous Gibberellins in Onion Plants and Their Effects on Bulb Development

Evidence has been reported that bulb development in onion plants (Allium cepa L.) is controlled by endogenous bulbing and anti-bulbing hormones, and that gibberellin (GA) is a candidate for anti-bulbing hormone (ABH). In this study, we identified a series of C-13-H GAs (GA₁₂, GA₁₅, GA₂₄, GA₉, GA₄, GA₃₄, and 3-epi-GA₄) and a series of C-13-OH GAs (GA₄₄, GA₂₀, GA₁ and GA₈) from the leaf sheaths including the lower part of leaf blades of onion plants (cv. Senshu-Chuko). These results suggested that two independent GA biosynthetic pathways, the early-non-hydroxylation pathway to GA₄ (active GA) and early-13-hydroxylation pathway to GA₁ (active GA), exist in onion plants. It was also suggested that GA₄ and GA₁ have almost the same ability to inhibit bulb development in onion plants induced by treatment with an inhibitor of GA biosynthesis, uniconazole-P. The endogenous levels of GA₁ and GA₄, and their direct precursors, GA₂₀ and GA₉, in leaf blades, leaf sheaths, and roots of 4-week-old bulbing and non-bulbing onion plants were measured by gas chromatography/selected ion monitoring with the corresponding [²H]labeled GAs as internal standards. In most cases, the GA levels in long-day (LD)-grown bulbing onion plants were higher than those of short-day (SD)-grown non-bulbing onion plants, but the GA₁ level in leaf blades of SD-grown onion plants was rather higher than that of LD-grown onion plants. Relationship between the endogenous GAs and bulb development in onion plants is discussed.     

Identification of gibberellins in leaf tissues of day-neutral strawberry (Fragaria × ananassa Duch.) cultivars

The endogenous gibberellins (GAs) in leaf tissues of two day-neutral cultivars (Rapella and Selva) of strawberry (Fragaria × ananassa Duch.) were analysed using combined gas chromatography -- mass spectrometry (GC-MS). Seven of the later members of the 13-hydroxylation GA biosynthetic pathway were identified, by comparison of Kovats retention indices and mass spectral data obtained for methyl ester trimethylsilyl ether derivatives, either with data obtained from authentic compounds or literature values. GA₁, GA₃, GA₈, GA₁₇, GA₁₉, GA₂₀ and GA₂₉ were detected in extracts of both cultivars.     

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.     

Comparison of the endogenous gibberellins in the shoots and roots of vernalized and non-vernalized chinese spring wheat seedlings

Endogenous gibberellins (GAs) in Chinese Spring wheat seedlings were isolated by high performance liquid chromatography (HPLC) and identified by combined capillary gas chromatography-selected ion monitoring (GC-SIM). Gibberellins A₁, A₃, A₁₉, A₂₀, A₄₄, and A₅₃ were identified in the shoots, A₁₉ and A₂₀ in the roots. The identification of these 13-hydroxylated GAs demonstrates the presence of the early-13-hydroxylation pathway in wheat seedlings. Based on peak area of total ion response of five characteristic ions by GC-SIM, the approximate levels of GAs in the shoots is GA₄₄ > GA₁₉ > GA₁ = GA₃ > GA₂₀ for the non-vernalized wheat seedlings, and GA₄₄ > GA₁₉ > GA₅₃ = GA₃ > GA₁ = GA₂₀ for the vernalized wheat seedlings. The C₂₀ GAs, GA₅₃, GA₄₄ and GA₁₉, are present in shoots of the vernalized (flowering) wheat seedlings at somewhat higher levels than that in the non-vernalized (rapidly growing) wheat seedlings. Approximate levels of the C₁₉ GAs, GA₂₀, GA₁ and GA₃ were lower in the shoots of the vernalized wheat seedlings than in the non-vernalized wheat seedlings. The conversion of GA₁₉ to GA₂₀ (C₂₀ to C₁₉ GAs) may be a rate-limiting step in the vernalized wheat seedlings.     

Hormonal Profile in Vegetative and Floral Buds of Azalea: Levels of Polyamines, Gibberellins, and Cytokinins

The floral transition includes a complex system of factors that interact and involve various biochemical signals, including plant growth regulators. The physiological signals involved in the control of the floral transition have been sparsely studied and mainly in plant species whose genetics are poorly known. In this work, the role of polyamines, gibberellins, and cytokinins was investigated by analyzing their endogenous content in vegetative and floral buds of azalea. The results showed that there is a clear distinction between floral and vegetative buds with respect to the levels of these plant hormones, with floral buds containing higher amounts of conjugated polyamines, gibberellins (GAs) from the non-13-hydroxylation pathway (GA₉, GA₇, and GA₄), and cytokinins (particularly isopentenyl-type species), and vegetative buds containing higher amounts of free polyamines and gibberellins from the early 13-hydroxylation pathway and fewer cytokinins. In conclusion, there is a specific pattern of endogenous hormone profiles in both vegetative and floral bud development in azalea, which may be relevant for future research on the control of flowering by exogenous hormone applications.     

Developing Inflorescences of Male and Female <Emphasis Type="Italic">Rumex acetosa</Emphasis> L. Show Differences in Gibberellin Content

Rumex acetosa L. (common sorrel) is a dioecious perennial in the family Polygonaceae. Gibberellins (GAs) of the early 13-hydroxylation pathway and the putative early 3, 13-hydroxylation pathway were previously identified in young R. acetosa inflorescences by GC-MS. In this investigation to examine the GA content of individual inflorescences ELISAs were used for quantitative analysis. Significant differences were revealed between the sexes in the GA content of young inflorescences, and GC-SRM was used to validate the observed trends. Males had higher levels of the 3, 13-hydroxylated C₂₀-GA GA₁₈ and the 2, 13-hydroxylated C₁₉-GA GA₂₉, whereas females had higher levels of the 13-hydroxylated C₂₀-GAs GA₅₃ and GA₁₉. It is suggested that the conversion from C₂₀-GAs to C₁₉-GAs is under tighter control in the inflorescences of females compared to male plants and therefore there is accumulation of the C₂₀-GAs in the females. Results from flowering bioassays using authentic GAs indicate that differences in GA content between the sexes are unlikely to be a consequence of sex determination.     

Gibberellins and the photoperiodic control of leaf growth in Poa pratensis

The role of gibberellins (GAs) in photoperiodic control of leaf elongation in Poa pratensis was studied by both application of exogenous GAs and analysis of endogenous GAs. Leaf elongation was strongly increased under long day (LD, 24 h) conditions at both 9 and 21°C, leaf length at 9°C LD being similar to that in plants grown in short days (SD, 8 h) at 21°C. However, even at 21°C leaf elongation was enhanced by LD. Exogenous GA₁ could completely compensate for LD at both 9 and 21°C. Gibberellins A₂₀, A₁₉ and A₄₄ could also partly replace LD, but they were significantly less active than GA₁, GA₅₃ was inactive when applied to plants grown at 9°C in SD and exhibited only marginal activity at 9°C LD and 21°C SD. The total level of GAs of the early 13-hydroxylation pathway (A₅₃, A₄₄, A₁₉, A₂₀ and A₁) increased rapidly when plants were transferred from SD to LD at 9°C. After transfer from 9 to 21°C, there was an increase in GA levels at both LD and SD, followed by a decrease under LD conditions. In all cases, GA₁₉ was the predominant GA, accounting for 60 to 80% of the analysed GAs. Levels of the bioactive GA₁ were low and increased transiently by LD four days after transfer from SD to LD. At both temperatures, the ratio GA₁₉ to GA₂₀ and GA₂₀ to GA₁ at 9°C was enhanced by LD compared with SD. Taken together, these results support the hypothesis that photoperiodic regulation of leaf elongation in Poa pratensis is GA-mediated, and they indicate a photoperiodic control of oxidation of GA₅₃ to GA₄₄ and GA₁₉ to GA₂₀, and perhaps also of 3β-hydroxylation of GA₂₀ to GA₁.     

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.