The Metabolism of Gibberellin A20 to Gibberellin A1 by Tall and Dwarf Mutants of Oryza sativa and Arabidopsis thaliana

The purpose of this study was to demonstrate the metabolism of gibberellin A20 (GA20) to gibberellin A1 (GA1) by tall and mutant shoots of rice (Oryza sativa L.) and Arabidopsis thaliana (L.) Heynh. The data show that the tall and dx mutant of rice and the tall and ga5 mutant of Arabidopsis metabolize GA20 to GA1. The data also show that the dy mutant of rice and the ga4 mutant of Arabidopsis block the metabolism of GA20 to GA1. [17-13C,3H]GA20 was fed to tall and the dwarf mutants, dx and dy, of rice and tall and the dwarf mutants, ga5 and ga4, of Arabidopsis. The metabolites were analyzed by high-performance liquid chromatography and full-scan gas chromatography-mass spectrometry together with Kovats retention index data. For rice, the metabolite [13C]GA, was identified from tall and dx seedlings; [13C]GA1 was not identified from the dy seedlings. [13C]GA29 was identified from tall, dx, and dy seedlings. For Arabidopsis, the metabolite [13C]GA1 was identified from tall, ga5, and ga4 plants. The amount of [13C]GA1 from ga4 plants was less than 15% of that obtained from tall and ga5 plants. [13C]GA29 was identified from tall, ga5, and ga4 plants. [13C]GA5 and [13C]GA3 were not identified from any of the six types of plant material.     

Gibberellin Biosynthesis in Maize. Metabolic Studies with GA(15), GA(24), GA(25), GA(7), and 2,3-Dehydro-GA(9)

[17-(14)C]-Labeled GA(15), GA(24), GA(25), GA(7), and 2,3-dehydro-GA(9) were separately injected into normal, dwarf-1 (d1), and dwarf-5 (d5) seedlings of maize (Zea mays L.). Purified radioactive metabolites from the plant tissues were identified by full-scan gas chromatography-mass spectrometry and Kovats retention index data. The metabolites from GA(15) were GA(44), GA(19), GA(20), GA(113), and GA(15)-15,16-ene (artifact?). GA(24) was metabolized to GA(19), GA(20), and GA(17). The metabolites from GA(25) were GA(17), GA(25) 16alpha,17-H(2)-17-OH, and HO-GA(25) (hydroxyl position not determined). GA(7) was metabolized to GA(30), GA(3), isoGA(3) (artifact?), and trace amounts of GA(7)-diene-diacid (artifact?). 2,3-Dehydro-GA(9) was metabolized to GA(5), GA(7) (trace amounts), 2,3-dehydro-GA(10) (artifact?), GA(31), and GA(62). Our results provide additional in vivo evidence of a metabolic grid in maize (i.e. pathway convergence). The grid connects members of a putative, non-early 3,13-hydroxylation branch pathway to the corresponding members of the previously documented early 13-hydroxylation branch pathway. The inability to detect the sequence GA(12) --> GA(15) --> GA(24) --> GA(9) indicates that the non-early 3,13-hydroxylation pathway probably plays a minor role in the origin of bioactive gibberellins in maize.     

Gibberellin Metabolism in Maize (The Stepwise Conversion of Gibberellin A12-Aldehyde to Gibberellin A20

The stepwise metabolism of gibberellin A12-aldehyde (GA12-aldehyde) to GA20 is demonstrated from seedling shoots of maize (Zea mays L.). The labeled substrates [13C,3H]GA12-aldehyde, [13C,3H]GA12, [14C4]GA53, [14C4/2H2]GA44, and [14C4/2H2]GA19 were fed individually to dwarf-5 vegetative shoots. Both [13C,3H]GA12-aldehyde and [13C,3H]GA12 were also added individually to normal shoots. The labeled metabolites were identified by full-scan gas chromatography-mass spectrometry and Kovats retention indices. GA12-aldehyde was metabolized to GA53-aldehyde, GA12, GA53, GA44, and GA19; GA12 was metabolized to 2[beta]-hydroxy-GA12, GA53, 2[beta]-hydroxyGA53, GA44, 2[beta]-hydroxyGA44, and GA19; GA53 was metabolized to GA44, GA19, GA20, and GA1; GA44 was metabolized to GA19; and GA19 was metabolized to GA20. These results, together with previously published data from this laboratory, document the most completely defined gibberellin pathway for the vegetative tissues of higher plants.     

Photoperiodic control of gibberellin metabolism in spinach

[(3)H]GA(20) applied to spinach plants (Spinacia oleracea L.) was metabolized to several products. Two of these were identified by combined gasliquid chromatography-radio counting as [(3)H]GA(29) and [(3)H]3-epi-GA(1). Inasmuch as both GA(20) and GA(29) are endogenous gibberellins in spinach (Metzger, Zeevaart 1980 Plant Physiol 65: 623-626), it was concluded that the conversion of GA(20) to GA(29) is a natural process. However, 3-epi-GA(1) was not detected in extracts of spinach shoots analyzed by combined gas chromatography-mass spectrometry. This indicates that the conversion of exogenous [(3)H]GA(20) to [(3)H]3-epi-GA(1) may be an artifact.Long-day pretreatment of spinach shoots caused a 2-fold increase in the rate of [(3)H]GA(20) metabolism over the rate of metabolism in plants maintained under short-day conditions. Furthermore, [(3)H]GA(29) accumulated more rapidly under long than under short days, whereas photoperiodic treatment had no effect on the accumulation of [(3)H]3-epi-GA(1). Thus, the long-day-induced increase in the level of endogenous GA(29) in spinach shoots (Metzger, Zeevaart 1980 Plant Physiol 66: 844-846) appears to be the result of an increased capability to convert GA(20) to GA(29).     

赤霉素和光对拟南芥种子萌发和幼苗生长的影响

以拟南芥的赤霉素 (GA)缺陷型突变体ga 1,ga 2 ,ga 3和GA不敏感型突变体ga i为材料 ,研究了光和 4种GA对拟南芥种子萌发和幼苗生长影响的相互关系。结果表明 :(1)烯效唑对ga i种子萌发的抑制在光下可明显被GA恢复 ,而在黑暗中GA的作用不明显。 (2 )在光下低浓度的外源GA3 可使ga 1,ga 2和ga 3的种子萌发 ,而在黑暗中同样浓度的GA3 则难以使种子萌发。 (3)光可以降低种子萌发所需求的GA的剂量。 (4 )ga i和ga 1的幼苗的呼吸代谢有明显差异。以上结果说明 :光对拟南芥种子萌发的促进主要是提高了种子对GA反应的敏感性而不是增加GA的生物合成     

The effect of daylength on photosynthate partitioning into leaf starch and soluble sugars in a gibberellin-deficient dwarf mutant of Zea mays

The possibility that gibberellins (GAs) mediate the photoperiodic regulation of photosynthate partitioning into stored leaf carbohydrates (starch and soluble sugars) was investigated with the dwarf-5 mutant of Zea mays L., a single-gene recessive mutant with greatly reduced endogenous GA content relative to tall maize. The mutant responded to daylength as did tall maize, with higher rates of carbohydrate accumulation observed under short daylength (8.5 h of light) than under long day-length (14 h of light). Neither inhibitors of GA biosynthesis (CCC, [(2-chloroethyl) trimethylammonium chloride], ancymidol[α-cyclopropyl-α-( p -methoxy-phenyl)-5-pyrimidine methyl alcohol], and tetcyclacis [5-(4-chlorophenyl)- 3,4,5,9, 10-penta-azatetracyclo-5,4,1,0^2.6,0^8.11-dodeca-3.9-diene]) nor treatment with GAs further modified the response of partitioning to daylength even though biologically active GAs stimulated plant growth. The results indicate that photoperiodic modulation of endogenous GA titre is unlikely to be responsible for the photoperiodic response of photosynthate partitioning in Z. mays .     

Emission of ent-kaurene, a diterpenoid hydrocarbon precursor for gibberellins, into the headspace from plants

ent-Kaurene is a tetracyclic hydrocarbon precursor for gibberellins (GAs) in plants and fungi. To address whether fungal GA biosynthesis enzymes function in plants, we generated transgenic Arabidopsis plants overexpressing ent-kaurene synthase (GfCPS/KS) from a GA-producing fungus Gibberella fujikuroi. GfCPS/KS catalyzes a two-step reaction corresponding to ent-copalyl diphosphate synthase (CPS) and ent-kaurene synthase (KS) activities in plants. When GfCPS/KS was overexpressed and targeted to plastids, a range of GA-deficient phenotypes of the ga1-3 and ga2-1 mutants (defective in CPS and KS, respectively) were restored to wild type. Unexpectedly, the transgenic lines overproducing GfCPS/KS emitted the GA precursor ent-kaurene into the headspace besides its accumulation in the plant body. When co-cultivated with the ent-kaurene overproducers in a closed environment, the airborne ent-kaurene was able to fully complement the dwarf phenotype of ga1-3 and ga2-1 mutants, but not that of the ga3-1 mutant (defective in ent-kaurene oxidase). These results suggest that ent-kaurene may be efficiently metabolized into bioactive GAs in Arabidopsis when supplied as a volatile. We also provide evidence that ent-kaurene is released in the headspace of wild-type Chamaecyparis obtusa and Cryptomeria japonica plants, suggesting the occurrence of this hydrocarbon GA precursor as a volatile in nature.     

Metabolism of gibberellins A1 and A3 in fruits and shoots of Prunus avium

Isotope-labelled GA metabolites were identified by GC--MS, following HPLC fractionation of extracts derived from fruits or shoots, that had been incubated with [2H]- and [3H]- GA1 or [2H]- and [3H]- GA3. GA1 (1) was converted into GA8 (10) by developing fruits and vegetative shoots of sweet cherry (Prunus avium cv. 'Stella'), while GA3 (4) was converted into GA3-isolactone (17). Other metabolites of each GA were detected but were not identified unequivocally. These included a metabolite of GA1 (1) in fruitlets that was more polar (by reverse phase HPLC) than GA8 (10) and a metabolite of similar polarity to GA87 (6), was obtained after incubating fruitlets with GA3 (4). However, no evidence was obtained to suggest that GA87 (6) was a metabolite of GA3 (4) or that GA85 (2) was a metabolite of GA1 (1) in these tissues, under the conditions used. The pattern of metabolites obtained from vegetative tissues was similar to that from fruitlets. However, the results suggested that GA1 (1) and GA3 (4) were metabolised at a greater rate in shoots from mature trees than in shoots from seedlings, and that GA1 (1) was metabolised more rapidly than GA3 (4) in juvenile and mature shoots. We conclude from these observations that GA3 (4) is not a precursor of GA87 (6) and GA32 (5), also, that GA1 (1) is not a precursor of GA85 (2) and GA86 (3) in developing fruits or in vegetative shoots of sweet cherry.     

Characterization of mutants with reduced seed dormancy at two novel rdo loci and a further characterization of rdo1 and rdo2 in Arabidopsis

Seed dormancy and germination are complex traits that are controlled by many genes. Four mutants in Arabidopsis thaliana exhibiting a reduced dormancy phenotype, designated rdo1, rdo2, rdo3 , and rdo4, have been characterized, both genetically and physiologically. Two of these mutants, rdo1 and rdo2 , have been described before, the other two represent novel loci. The mutants mapped on chromosome 1 ( rdo3 ), chromosome 2 ( rdo2 and rdo4 ), and chromosome 3 ( rdo1 ). None of these loci has been related to dormancy before. All four mutants show pleiotropic effects in the adult plant stage, which are different for each mutant. None of the mutants is deficient in ABA. Compared to L er (wild-type), ABA sensitivity is not altered either, thereby excluding the possibility that ABA is involved in causing the reduced dormancy phenotype. The GA requirement was studied by using the GA biosynthesis inhibitor paclobutrazol, and genetically by generating double mutants with the GA-deficient mutant ga1-3 . The results obtained by these two methods were comparable for all but one mutant: rdo1 . In a GA-deficient background, rdo1 , rdo2 and rdo3 , all show sensitivity to GA between that of ga1-3 and ga1-3 aba1. However, when using paclobutrazol rdo1 exhibited the same sensitivity as rdo4 and wild-type. Analysis of double mutants among the rdo mutants revealed a very complex and inconsistent pattern.     

Pollination Increases Gibberellin Levels in Developing Ovaries of Seeded Varieties of Citrus

Reproductive and vegetative tissues of the seeded Pineapple cultivars of sweet orange (Citrus sinensis L.) contained the following C-13 hydroxylated gibberellins (GAs): GA53, GA17, GA19, GA20, GA1, GA29, and GA8, as well as GA97, 3-epi-GA1, and several uncharacterized GAs. The inclusion of 3-epi-GA1 as an endogenous substance was based on measurements of the isomerization rates of previously added [2H2]GA1. Pollination enhanced amounts of GA19, GA20, GA29, and GA8 in developing ovaries. Levels of GA1 increased from 5.0 to 9.5 ng/g dry weight during anthesis and were reduced thereafter. The amount of GA in mature pollen was very low. Emasculation reduced GA levels and caused a rapid 100% ovary abscission. This effect was partially counteracted by either pollination or application of GA3. In pollinated ovaries, repeated paclobutrazol applications decreased the amount of GA and increased ovary abscission, although the pattern of continuous decline was different from the sudden abscission induced by emasculation. The above results indicate that, in citrus, pollination increases GA levels and reduces ovary abscission and that the presence of exogenous GA3 in unpollinated ovaries also suppresses abscission. Evidence is also presented that pollination and GAs do not, as is generally assumed, suppress ovary abscission through the reactivation of cell division.     

The ELONGATED gene of Arabidopsis acts independently of light and gibberellins in the control of elongation growth

A novel elongated mutant has been isolated from EMS-mutagenized populations of the Arabidopsis thaliana ga4 mutant. After backcrossing with the Landsberg erecta ( Ler ) wild-type (WT) followed by selling, the mutant phenotype was identified in the GA4 background. Seedlings of the mutant, which has been named elg (elongated), are characterized by elongated hypocotyls and petioles, leaves that are narrow and somewhat epinastic and early flowering. Allelism tests with the hy1–hy5 mutants indicate that elg is not allelic with any of these long-hypocotyl mutants. From linkage analyses, the location of elg on chromosome 4, between cer2 and ap2 has been established. The pleiotropic phenotype of elg seedlings is suggestive of a disruption of phytochrome and/or gibberellin (GA) function. Although the elg mutant displays a light-dependent long-hypocotyl phenotype, elg seedlings retain a full range of photomorphogenic responses and the elg mutation acts additively with the photomorphogenic mutants phyB, hy1 and hy2 . This suggests that ELG acts independently of phytochrome action. The elg mutation partially suppresses the effect of GA-deficiency on elongation growth, and, although elg ga1 seedlings are more elongated than ga1 seedlings, both genotypes respond in the same way to applied GA. That applied GA and the elg mutation interact additively suggests that ELG acts independently of GA action.     

The Arabidopsis GA1 locus encodes the cyclase ent-kaurene synthetase A of gibberellin biosynthesis.

The first committed step in the gibberellin (GA) biosynthetic pathway is the conversion of geranylgeranyl pyrophosphate (GGPP) through copalyl pyrophosphate (CPP) to ent-kaurene catalyzed by ent-kaurene synthetases A and B. The ga1 mutants of Arabidopsis are gibberellin-responsive male-sterile dwarfs. Biochemical studies indicate that biosynthesis of GAs in the ga1 mutants is blocked prior to the synthesis of ent-kaurene. The GA1 locus was cloned previously using the technique of genomic subtraction. Here, we report the isolation of a nearly full-length GA1 cDNA clone from wild-type Arabidopsis. This cDNA clone encodes an active protein and is able to complement the dwarf phenotype in ga1-3 mutants by Agrobacterium-mediated transformation. In Escherichia coli cells that express both the Arabidopsis GA1 gene and the Erwinia uredovora gene encoding GGPP synthase, CPP was accumulated. This result indicates that the GA1 gene encodes the enzyme ent-kaurene synthetase A, which catalyzes the conversion of GGPP to CPP. Subcellular localization of the GA1 protein was studied using 35S-labeled GA1 protein and isolated pea chloroplasts. The results showed that the GA1 protein is imported into and processed in pea chloroplasts in vitro.     

Distinct and overlapping roles of two gibberellin 3-oxidases in Arabidopsis development

Gibberellin (GA) 3-oxidase, a class of 2-oxoglutarate-dependent dioxygenases, catalyzes the conversion of precursor GAs to their bioactive forms, thereby playing a direct role in determining the levels of bioactive GAs in plants. Gibberellin 3-oxidase in Arabidopsis is encoded by a multigene family consisting of at least four members, designated AtGA3ox1 to AtGA3ox4. It has yet to be investigated how each AtGA3ox gene contributes to optimizing bioactive GA levels during growth and development. Using quantitative real-time PCR analysis, we have shown that each AtGA3ox gene exhibits a unique organ-specific expression pattern, suggesting distinct developmental roles played by individual AtGA3ox members. To investigate the sites of synthesis of bioactive GA in plants, we generated transgenic Arabidopsis that carried AtGA3ox1-GUS and AtGA3ox2-GUS fusions. Comparisons of the GUS staining patterns of these plants with that of AtCPS-GUS from previous studies revealed the possible physical separation of the early and late stages of the GA pathway in roots. Phenotypic characterization and quantitative analysis of the endogenous GA content of ga3ox1 and ga3ox2 single and ga3ox1/ga3ox2 double mutants revealed distinct as well as overlapping roles of AtGA3ox1 and AtGA3ox2 in Arabidopsis development. Our results show that AtGA3ox1 and AtGA3ox2 are responsible for the synthesis of bioactive GAs during vegetative growth, but that they are dispensable for reproductive development. The stage-specific severe GA-deficient phenotypes of the ga3ox1/ga3ox2 mutant suggest that AtGA3ox3 and AtGA3ox4 are tightly regulated by developmental cues; AtGA3ox3 and AtGA3ox4 are not upregulated to compensate for GA deficiency during vegetative growth of the double mutant.     

GC-MS identification of GA20-13-O-glucoside formed from GA20 in normal plants and dwarf-1 mutants ofZea mays L.

After feeding GA₂₀ to excised seedlings ofZea mays L. normals (N) and dwarf-1 mutants (d1), GA₂₀-13-O-glucoside (9) was identified by HPLC and by GC-MS of its permethylated derivative. The glucosylation rate of GA₂₀ was found to be higher in the dwarf-1 mutant (26%) than in the normal plant (3.6%). This article includes a GC-MS study in which diagnostic fragments from the spectra of permethylated synthetic GA glucosides have been selected that proved to be useful for the identification of permethylated GA glucosides.     

Identification of Antheridiogens in Lygodium circinnatum and Lygodium flexuosum

Antheridiogens in two species of Schizaeaceous ferns, Lygodium circinnatum and Lygodium flexuosum, were analyzed by gas chromatography-mass spectrometry. In L. circinnatum, gibberellin A73 (GA73) methyl ester (GA73-Me), which had originally been identified in L. japonicum, was identified as a principal antheridiogen, and the methyl esters of five known GAs (GA9, GA20, GA70, GA88, and 3-epi-GA88) were also identified as minor antheridiogens. In addition, four compounds corresponding to isomers of monohydroxy-GA73-Me were detected. One of these was shown to be 12[beta]-hydroxy-GA73-Me, the parent acid of which has been allocated the GA assignment GA96. The other three compounds, tentatively named X1, X2, and X3, have not been fully characterized. In L. flexuosum, GA73-Me was also identified as a major antheridiogen, with X2 being detected as a minor one. The total antheridium-formation activity in the culture medium of 7-week-old prothallia of L. circinnatum and L. flexuosum was more than 1000 times higher than that of L. japonicum. On the other hand, the response of gametophytes of the former two Lygodium ferns to GA73-Me was more than 100 times lower than that of L. japonicum.     

Gibberellin requirement for Arabidopsis seed germination is determined both by testa characteristics and embryonic abscisic acid

The mechanisms imposing a gibberellin (GA) requirement to promote the germination of dormant and non-dormant Arabidopsis seeds were analyzed using the GA-deficient mutant ga1, several seed coat pigmentation and structure mutants, and the abscisic acid (ABA)-deficient mutant aba1. Testa mutants, which exhibit reduced seed dormancy, were not resistant to GA biosynthesis inhibitors such as tetcyclacis and paclobutrazol, contrarily to what was found before for other non-dormant mutants in Arabidopsis. However, testa mutants were more sensitive to exogenous GAs than the wild-types in the presence of the inhibitors or when transferred to a GA-deficient background. The germination capacity of the ga1-1 mutant could be integrally restored, without the help of exogenous GAs, by removing the envelopes or by transferring the mutation to a tt background (tt4 and ttg1). The double mutants still required light and chilling for dormancy breaking, which may indicate that both agents can have an effect independently of GA biosynthesis. The ABA biosynthesis inhibitor norflurazon was partially efficient in releasing the dormancy of wild-type and mutant seeds. These results suggest that GAs are required to overcome the germination constraints imposed both by the seed coat and ABA-related embryo dormancy.     

Arsenic uptake, translocation and speciation in pho1 and pho2 mutants of Arabidopsis thaliana

Arsenate [As (V)] is taken up by phosphate [P (V)] transporters in the plasma membrane of roots cells, but the translocation of As from roots to shoots is not well understood. Two mutants of Arabidopsis thaliana (L.) [( pho1 , P deficient) and ( pho2 , P accumulator)], with defects in the regulation and translocation of P (V) from roots to shoots, were therefore used in this study to investigate uptake, translocation and speciation of As in roots and shoots of plants grown in soil or nutrient solution. The shoots of the pho2 mutant contained higher P concentrations, but similar or slightly higher As concentrations, in comparison with the wild type. In the pho1 mutant, the P concentration in the shoots was lower, and the As concentration was higher, in comparison with the wild type. Both pho2 and the wild type contained mainly As (III) in roots and shoot (67–90% of total As). Arsenic was likely to be translocated by a different pathway to P (V) in the pho2 and pho1 mutants . Therefore, it is suggested that As (III) is the main As species translocated from roots to shoots in Arabidopsis thaliana.