Metabolism of ent-kaurenol-[17-14C], ent-kaurenal-[17-14C] and ent-kaurenoic acid-[17-14C] by germinating Hordeum distichon grains

Subcellular fractions from germinated barley embryos, chloroplast preparations and whole germinating barley grains are able to carry out the conversions ent-kaurenol → ent-kaurenal → ent-kaurenoic acid → ent-hydroxykaurenoic acid, the initial steps of the biosynthetic pathway to gibberellins. Whole grains, and chloroplasts to a slight extent, incorporate radioactivity from ent-kaurenol-[17-¹⁴C] and ent-kaurenoic acid-[17-¹⁴C] into materials with similar but distinct properties from the gibberellins GA₁, GA₃, GA₄ and GA₇.     

Preparation of biologically active substances and animal and microbial metabolites from menthols,cineoles and kauranes

Six monoterpenoids, l-menthol, l-menthyl acetate, iso-menthol, neo-menthol, 1,4-cineole and 1,8-cineole and one diterpene hydrocarbon, ent-kaurene were oxidized by meta-chloroperbenzoic acid or dry ozone to give various hydroxylated products and their structures elucidated by NMR spectroscopy. Some hydroxylated menthols showed plant growth inhibitory and strong mosquito repellent activity. Among the hydroxylated cineoles, microbial and animal metabolites of cineoles were included. From ent-kauranes, a plant growth inhibitory diterpene alcohol, (−)-16α-hydroxy kaurane was obtained along with 16α-kauran-13α-ol.     

Presence of endogenous ent-kaurene in a microsomal preparation from Cucurbita maxima L. Endosperm and implications for kinetic studies of ent-kaurene oxidase

Microsomal and soluble cell-free extracts prepared from liquid endosperm of Cucurbita maxima L. were found to contain high concentrations of endogenous ent-kaurene and ent-kaurenol by gas chromatography-mass spectrometry-chemical ionization with deuterated internal standards. Increases in the levels of ent-kaurenol, ent-kaurenoic acid, and ent-7-hydroxykaurenoic acid are correlated with a decline in the amount of endogenous ent-kaurene following a 10 min incubation of microsomes with NADPH and FAD. The rate of oxidation of radiolabeled ent-kaurene by the microsomal fraction was determined, and the need to account for endogenous substrate is shown. Endogenous ent-kaurene present in soluble extracts had the effect of diluting the [¹⁴C]ent-kaurene synthesized from [¹⁴C]mevalonic acid, resulting in reduced specific radioactivity of the product. The dilution of [¹⁴C]ent-kaurene was more pronounced in extracts with higher endogenous ent-kaurene levels or when the reactions were run in the presence of O₂ and NADPH. Evidence is presented that suggests differential metabolism of endogenous ent-kaurene and radiolabeled ent-kaurene in both microsomal and soluble extracts.Abbreviations Kaurene ent-kaur-16-ene - MVA mevalonic acid - kaurenol ent-kaur-16-en-19-ol - kaurenoic acid ent-kaur-16-en-19-oic acid - EtOAc ethyl acetate - MeOH methanol - GC-MS-CI gas chromatography-mass spectrometry-chemical ionization - 13-OH KA ent-13-hydroxykaur-16-en-19-oic acid - 7-OH kaurenoic acid ent-7-hydroxykaur-16-en-19-oic acid - kaurenal ent-kaur-16-en-19-al - Me(x) methyl ester of x - TMS(x) trimethylsilyl ether or ester of x - GA(x) gibberellin A(x)     

In Vivo Gibberellin Biosynthesis in Endosperm of Sechium edule Sw. Seeds

Biosynthesis of gibberellins (GAs) was studied in vivo in endosperms of Sechium edule Sw. Exogenous ent-[¹⁴C]kaurene was metabolized into four major products: GA₁₂, GA₄, GA₇ and 16, 17-dihydro-16-hydroxy-GA₁₅ alcohol glucoside. Other minor metabolites were also observed including ent-kaurenol and ent-kaurenal. Conversion of ent-[¹⁴C]kaurene to ent-kaurenol glucoside by endosperm cell-free preparations in the presence of UDPG was observed. However, the finding was not confirmed in in vivo studies and is probably artifactual. Overall evidence coming from the analysis of endogenous GAs and in vitro and in vivo biosynthetic studies are discussed in relation to the possible existence in the Sechium seeds of a different route, along with the known pathway, branching from ent-kaurene or ent-7-α-hydroxykaurenoic acid and this also leading to biologically active GAs.     

Four new diterpenes from Sideritis serrata

Four new diterpenes have been isolated from Sideritis serata: lagascol (4, ent-8,5-friedopimar-5-ene-15S,16-diol), tobarrol (8, ent-15-beyerene-12α,17-diol), benuol (12, ent-15-beyerene-7α,17-diol) and serradiol (18, ent-16R-atis-13-ene-16,17-diol). The previously known diterpenes lagascatriol (1, ent-8,5-friedopimar-5-ene-11β,15S,16-triol), jativatriol (2, ent-15-beyerene-1β,12α,17-triol), conchitriol (3, ent-15-beyerene-7α,12α,17-triol) and sideritol (17, ent-16R-atis-13-ene-1β,16,17-triol) have also been obtained from the same source.     

Separation of Light-Induced [C]ent-Kaurene Metabolism and Light-Induced Germination in Grand Rapids Lettuce Seeds

The effect of light on the metabolism of [¹⁴C]kaurene in light-requiring lettuce seeds (Lactuca sativa L. cv Grand Rapids) was investigated. Seeds were soaked in a solution of [¹⁴C]ent-kaurene in methylene chloride with 0.01% Tween-20, dried, and incubated in 20% polyethylene glycol (PEG) to prevent seedling development. Labeled metabolites were extracted and analyzed by high performance liquid chromatography and gas chromatography-radio counting. [¹⁴C]ent-Kaurenol and [¹⁴C]ent-kaurenal were identified in seeds incubated in constant white light, while no ethyl acetate-soluble metabolites were found in seeds incubated in the dark. In time course experiments using acid scarified seeds, metabolism began after 18 hours of incubation and greatly increased after 24 hours of incubation in 20% PEG. By 48 hours, several unidentified, more polar metabolites were found. Germination was induced in seeds imbibed in 20% PEG by 4 hours of red or 4 hours of white light following 20 hours in the dark, and was fully reversed by 2 hours of far red light. However, in metabolism experiments, [¹⁴C]ent-kaurene oxidation was observed only with constant white light. These results indicate that although ent-kaurene oxidation is a light sensitive step in the biosynthesis of gibberellins in Grand Rapids lettuce seeds, ent-kaurene metabolism is not required for light-induced germination.     

Comparison ofEnt-kaurene synthetase A and B activities in cell-free extracts from young tomato fruits of wild-type andgib-1, gib-2, andgib-3 tomato plants

The nonallelicgib-1 andgib-3 tomato (Lycopersion esculentum Mill.) mutants are gibberellin deficient and exhibit a dwarfed growth habit. Previous work has shown that this dwarfed growth pattern can be reversed by the application of a number of gibberellins and their precursors, includingent-kaurene (ent-kaur-16-ene). This indicates that they are blocked in gibberellin biosynthesis at a step prior toent-kaurene metabolism. The normal accumulation of carotenoids observed in these mutants suggests a functionally normal isoprenoid pathway.Ent-kaurene is synthesized from geranylgeranyl pyrophosphate in a two-step process with copalyl pyrophosphate as an intermediate.In vitro assays using young fruit extracts from wild-type andgib-2 plants resulted in the conversion of geranylgeranyl pyrophosphate to copalyl pyrophosphate, and the conversion of copalyl pyrophosphate toentkaurene. Similar assays usinggib-1 plants indicated a reduced ability for synthesis of copalyl pyrophosphate from geranylgeranyl pyrophosphate, and thus a reducedent-kaurene synthetase A activity. Furthermore,gib-3 extracts demonstrated a reduced ability to synthesizeent-kaurene from copalyl pyrophosphate, and thus a reducedent-kaurene synthetase B activity. These results establish the enzymatic conversion of geranylgeranyl pyrophosphate to copalyl pyrophosphate, and copalyl pyrophosphate toent-kaurene, as the sites of the mutations ingib-1 andgib-3 tomatoes, respectively. We also note that tomato fruit extracts contain components which are inhibitory toent-kaurene synthesis.     

Comparison ofEnt-kaurene synthetase A and B activities in cell-free extracts from young tomato fruits of wild-type andgib-1, gib-2, andgib-3 tomato plants

The nonallelicgib-1 andgib-3 tomato (Lycopersion esculentum Mill.) mutants are gibberellin deficient and exhibit a dwarfed growth habit. Previous work has shown that this dwarfed growth pattern can be reversed by the application of a number of gibberellins and their precursors, includingent-kaurene (ent-kaur-16-ene). This indicates that they are blocked in gibberellin biosynthesis at a step prior toent-kaurene metabolism. The normal accumulation of carotenoids observed in these mutants suggests a functionally normal isoprenoid pathway.Ent-kaurene is synthesized from geranylgeranyl pyrophosphate in a two-step process with copalyl pyrophosphate as an intermediate.In vitro assays using young fruit extracts from wild-type andgib-2 plants resulted in the conversion of geranylgeranyl pyrophosphate to copalyl pyrophosphate, and the conversion of copalyl pyrophosphate toentkaurene. Similar assays usinggib-1 plants indicated a reduced ability for synthesis of copalyl pyrophosphate from geranylgeranyl pyrophosphate, and thus a reducedent-kaurene synthetase A activity. Furthermore,gib-3 extracts demonstrated a reduced ability to synthesizeent-kaurene from copalyl pyrophosphate, and thus a reducedent-kaurene synthetase B activity. These results establish the enzymatic conversion of geranylgeranyl pyrophosphate to copalyl pyrophosphate, and copalyl pyrophosphate toent-kaurene, as the sites of the mutations ingib-1 andgib-3 tomatoes, respectively. We also note that tomato fruit extracts contain components which are inhibitory toent-kaurene synthesis.     

A Step in the Biosynthesis of Gibberellins that Is Controlled by the Mutation in the Semi-Dwarf Rice Cultivar Tan-Ginbozu

Genetic analysis and a comparison of endogenous levels of gibberellinsbetween the semi-dwarf rice cultivar Tan-ginbozu and the correspondingnormal cultivar Ginbozu have confirmed that Tan-ginbozu is agibberellin deficient mutant and that the semi-dwarfism of Tan-ginbozuis controlled by a single recessive gene. A step in the biosynthesisof gibberellins that is blocked by the mutation in Tan-ginbozuhad been considered to be the synthesis of ent-kaurene or anearlier step. However, the rate of production of ent-kaureneby Tan-ginbozu was almost the same as that by Ginbozu. By contrast,accumulation of only a small amount of ent-kaurene was detectedin Tan-ginbozu, and the amount that accumulated was similarto that in Ginbozu that had been treated with 6.9 x 10^-8 M uniconazole-P(an effective inhibitor of three oxidative steps in the pathwayfrom ent-kaurene to ent-kaurenoic acid via entkaurenol and ent-kaurenal).The height of the treated Ginbozu plants was reduced to thesame as that of Tanginbozu plants. Resembling Tan-ginbozu plants,Ginbozu plants that had been treated with uniconazole-P respondedwell to ent-kaurenoic acid and slightly to ent-kaurene and ent-kaurenol.Since the growth-promoting activity of enf-kaurenal in Tan-ginbozuwas similar to that of ent-kaurene, our results suggest thatthe mutation in Tan-ginbozu blocks the three oxidative stepswhereby ent-kaurene is converted to ent-kaurenoic acid. (Received June 9, 1995; Accepted February 15, 1996)     

Metabolism of ent-Kaurene to Gibberellin A(12)-Aldehyde in Young Shoots of Normal Maize

Young shoots of normal maize (Zea mays L.) were used to determine both the stepwise metabolism of ent-kaurene to gibberellin A₁₂-aldehyde and the endogenous presence of the members in this series. Each of the five steps in the sequence was established by feeds of 17-¹³C, ³H-labeled kauranoids to cubes from the cortex of elongating internodes, to homogenates from the cortex of elongating internodes, and/or to homogenates from dark-grown seedlings. The ¹³C-metabolites were identified by Kovats retention indices (KRI) and full-scan capillary gas chromatography-mass spectrometry (GC-MS). Five substrates and the final product in this sequence were shown to be native by the isotopic dilution of 17-¹³C, ³H-labeled substrates added as internal standards to extracts obtained from elongating internodes. Evidence for the isotopic dilution was obtained by KRI and full-scan capillary GC-MS. Thus, we document the presence in young maize shoots of the metabolic steps, ent-kaurene → ent-kaurenol → ent-kaurenal → ent-kaurenoic acid → ent-7 α-hydroxykaurenoic acid → gibberellin A₁₂-aldehyde.     

The biosynthesis of the gibberellin precursorent-kaurene in cell-free extracts and the endogenous gibberellins of Japanese morning glory in relation to seed development

The endogenous levels of gibberellins (GAs) determined by a combined HPLC-bioassay procedure and the formation ofent-kaurene, an immediate GA precursor, in cell-free extracts were studied in relation to seed development inPharbitis nil Choisy cv. Violet. Three biologically active GA fractions were obtained, tentatively identified as GA₃, GA₅/ GA₂₀, and a GA fraction, possibly GA₁₉ and/or GA₄₄, which all increased in activity during early seed development and subsequently declined during maturation of the seeds. The total endogenous GA level reached its maximum at 19 days after anthesis, just before the seeds had attained their maximum fresh weight at about 23 days after anthesis. Similarly, theent-kaurene synthesizing capacity showed a rapid increase during the period of rapid growth of the seeds, followed by a decline during maturation. A direct relationship between the endogenous GA levels and theent-kaurene synthesizing capacity of a particular tissue was indicated.     

Diterpenoids of Halimium viscosum

From the neutral fraction of the hexane extract of Halimium viscosum the following components were isolated; 7-labdene-3β,l5-diol, 15-acetoxy-7-labden-3β-ol and a new diterpene-lactone with a rearranged ent-labdane skeleton, 13S-ent-9, 1-friedo-labd-1(10)-en-15-acetoxy-2R,18-olide. From the non-saponifiable part, beside 7-labdene-3β, 15-diol and 7, 13E-labdadiene-3β, 15-diol, the new diterpene 8(17)-labdene-3β, 7α, 15-triol was extracted. The structures were elucidated by spectroscopic methods, correlations or synthesis.     

Biosynthesis of ent-kaurene in cell-free extracts of Pisum sativum shoot tips

Soluble enzyme preparations from pea shoot tips incorporated mevalonic acid-2-¹⁴C into ent-kaurene-¹⁴C, squalene-¹⁴C and other products. The assay for either ent-kaurene or squalene is quite direct; both products can be obtained apparently free of radioactive contaminants by TLC on silica gel G in hexane. The enzyme system is dependent upon added ATP and Mn²⁺ or Mg²⁺, with Mn²⁺ being a more effective activator than Mg²⁺ under the experimental conditions. Reduced pyridine nucleotide had no effect on ent-kaurene production but stimulated squalene synthesis. The accumulation of both ent-kaurene and squalene was stimulated by dithiothreitol and carbon monoxide and was reduced by the addition of particulate cell components. AMO-1618 inhibited ent-kaurene production and had no effect on the synthesis of squalene. Enzyme extracts from shoot tips are much less active in ent-kaurene synthesis than extracts from the cotyledons of immature seeds on either a fresh weight or protein basis.     

Inhibition of gibberellin biosynthesis by paclobutrazol in cell-free homogenates ofCucurbita maxima endosperm andMalus pumila embryos

The plant growth retardant paclobutrazol, (PP333) (2RS, 3RS)-1-(4-chlorophenyl)-4,4-dimethyl-2-(1,2,4-triazol-1-yl)pentan-3-ol, inhibits specifically the three steps in the oxidation of the gibberellin-precursorent-kaurene toent-kaurenoic acid in a cell-free system fromCucurbita maxima endosperm. The KI₅₀ for this inhibition is 2×10^?8 M. The KI₅₀ values for the separated2S, 3S, and2R, 3R enantiomers of paclobutrazol in this system are 2×10^?8 M and 7×10^?7 M, respectively. A cell-free preparation from immatureMalus pumila embryos convertsent-kaurene to gibberellin A₉, whereas no conversion occurs in a similar preparation fromMalus endosperm. The conversion ofent-kaurene by the embryo preparation is inhibited by paclobutrazol with KI₅₀ values for the2S,3S and2R,3R enantiomers of 2×10^?8 M and 6×10^?8 M, respectively.     

Gibberellin precursor is involved in spore germination in the moss Physcomitrella patens

Gibberellins are ent-kaurene derived phytohormones that are involved in seed germination, stem elongation, and flower induction in seed plants, as well as in antheridia formation and spore germination in ferns. Although ubiquitous in vascular plants, the occurrence and potential function(s) of gibberellins in bryophytes have not yet been resolved. To determine the potential role of gibberellin and/or gibberellin-like compounds in mosses, the effect of AMO-1618 on spores of Physcomitrella patens (Hedw.) B.S.G. was tested. AMO-1618, which inhibited ent-kaurene and gibberellin biosynthesis in angiosperms, also inhibited the bifunctional copalyl diphosphate synthase (E.C. 5.5.1.13)/ent-kaurene synthase (E.C. 4.2.3.19) of P. patens. AMO-1618 also caused a decrease in spore germination rates of P. patens, and this inhibitory effect was less pronounced in the presence of ent-kaurene. These results suggest that ent-kaurene biosynthesis is required by P. patens spores to germinate, implying the presence of gibberellin-like phytohormones in mosses.     

Kaurene and kaurenol biosynthesis in cell-free system of Phaseolus coccineus suspensor

It is shown that suspensor tissue of Phaseolus coccineus can biosynthesize ent-kaur-16-ene and ent-kaur-16-en-19β-ol, two key precursors in the biosynthesis of gibberellins.     

4β,19-Epoxy-norkaurene and other diterpenes from Mikania banisteriae

The aerial parts of Mikania banisterae afforded four new diterpenes, ent-kaur-16-en-18-al, 18-acetoxy-ent-kaurene, 18-hydroxy-16α,17-epoxy-ent-kaurane and 4β-19-epoxy-18-nor-ent-kaurene.     

Gibberellin biosynthesis in a cell-free system from immature seeds of Pisum sativum

A cell-free system from immature pea seeds converts ¹⁴C-labelled $\text{ent}$-kaurene to $\text{ent}$-kaurenol, $\text{ent}$-kaurenal, $\text{ent}$-kaurenoic acid, $\text{ent}$-7α-hydroxykaurenoic acid, and gibberellin A₁₂-aldehyde. The latter becomes converted further to 13-hydroxygibberellin A₁₂, gibberellin A44, gibberellin A₁₂-alcohol, and several unidentified products. Thus the biosynthesis of gibberellins $\text{via ent}$-kaurene is now established for a member of the $\text{Leguminosae}$. It is the first time that 13-hydroxylation of gibberellins has been observed in a cell-free system and that gibberellin A₁₂-alcohol has been obtained in any biological system.     

Gibberellin estimation and biosynthesis in germinating Hordeum distichon

Gibberellic acid (GA₃) and 13-deoxy-gibberellic acid (GA₇) were identified in extracts of germinating barley as their ¹⁴C-methyl esters. The maximal level of GA₃ was estimated by an isotopic dilution procedure to be 1·5 ng per grain. Germinating barley incorporated 2-¹⁴C-mevalonic acid into several terpenes, whose specific radioactivities were measured, but incorporation into GA₃ could not be detected. Cell-free embryo extracts from germinating barley converted 2-¹⁴C-mevalonic acid into isopentenol, dimethylallyl alcohol, farnesol and squalene, while ¹⁴C-isopentenyl pyrophosphate was incorporated into geraniol, farnesol, geranylgeraniol and squalene. There was no detectable incorporation into the gibberellin intermediate ent-kaurene.     

Apparent endogenous circadian rhythm inent-kaurene biosynthesis

Net synthesis of [¹⁴C]ent-kaurene from [¹⁴C]2-mevalonic acid was assayed in cell-free enzyme extracts prepared from Alaska pea (Pisum sativum L.) seedlings throughout 44 h of a regimen consisting of a 16-h day and an 8-h night. Activities generally followed an upward trend during the dark period and a downward trend during the photoperiod. Activity was also assayed in enzyme extracts prepared at intervals during a 12-h photoperiod and a following, continuous 36-h dark period after entrainment of plants to a regimen of 12-h days and 12-h nights.Ent-kaurene synthesis activity again followed an upward trend in enzyme extracts prepared during what would have been the entrainment dark period, and a downward trend during the entrainment photoperiod. The apparent endogenous rhythm ofent-kaurene biosynthesis may have implications for the regulation of gibberellin biosynthesis.