Blue-light irradiation up-regulates the ent-kaurene synthase gene and affects the avoidance response of protonemal growth in Physcomitrella patens

Main conclusion

We report a novel physiological response to blue light in the moss Physcomitrella patens . Blue light regulates ent -kaurene biosynthesis and avoidance response to protonemal growth.

Abstract

Gibberellins (GAs) are a group of diterpene-type plant hormones biosynthesized from ent-kaurenoic acid via ent-kaurene. While the moss Physcomitrella patens has part of the GA biosynthetic pathway, from geranylgeranyl diphosphate to ent-kaurenoic acid, no GA is found in this species. Caulonemal differentiation in a P. patens mutant with a disrupted bifunctional ent-copalyl diphosphate synthase/ent-kaurene synthase (PpCPS/KS) gene is suppressed under red light, and is recovered by application of ent-kaurene and ent-kaurenoic acid. This indicates that derivatives of ent-kaurenoic acid, not GAs, might act as endogenous developmental regulators. Here, we found unique responses in the protonemal growth of P. patens under unilateral blue light, and these regulators were involved in the responses. When protonemata of the wild type were incubated under blue light, the chloronemal filaments grew in the opposite direction to the light source. Although this avoidance was not observed in the ent-kaurene deficient mutant, chloronemal growth toward a blue-light source in the mutant was suppressed by application of ent-kaurenoic acid, and the growth was rescued to that in the wild type. Expression analysis of the PpCPS/KS gene showed that the mRNA level under blue light was rapidly increased and was five times higher than under red light. These results suggest that regulators derived from ent-kaurenoic acid are strongly involved not only in the growth regulation of caulonemal differentiation under red light, but also in the light avoidance response of chloronemal growth under blue light. In particular, growth under blue light is regulated via the PpCPS/KS gene.     

Arabidopsis ent-Kaurene Oxidase Catalyzes Three Steps of Gibberellin Biosynthesis

The Arabidopsis GA3 cDNA was expressed in yeast (Saccharomyces cerevisiae) and the ability of the transformed yeast cells to metabolize ent-kaurene was tested. We show by full-scan gas chromatography-mass spectrometry that the transformed cells produce ent-kaurenoic acid, and demonstrate that the single enzyme GA3 (ent-kaurene oxidase) catalyzes the three steps of gibberellin biosynthesis from ent-kaurene to ent-kaurenoic acid.     

The P450-4 gene of Gibberella fujikuroi encodes ent-kaurene oxidase in the gibberellin biosynthesis pathway

At least five genes of the gibberellin (GA) biosynthesis pathway are clustered on chromosome 4 of Gibberella fujikuroi; these genes encode the bifunctional ent-copalyl diphosphate synthase/ent-kaurene synthase, a GA-specific geranylgeranyl diphosphate synthase, and three cytochrome P450 monooxygenases. We now describe a fourth cytochrome P450 monooxygenase gene (P450-4). Gas chromatography-mass spectrometry analysis of extracts of mycelia and culture fluid of a P450-4 knockout mutant identified ent-kaurene as the only intermediate of the GA pathway. Incubations with radiolabeled precursors showed that the metabolism of ent-kaurene, ent-kaurenol, and ent-kaurenal was blocked in the transformants, whereas ent-kaurenoic acid was metabolized efficiently to GA(4). The GA-deficient mutant strain SG139, which lacks the 30-kb GA biosynthesis gene cluster, converted ent-kaurene to ent-kaurenoic acid after transformation with P450-4. The B1-41a mutant, described as blocked between ent-kaurenal and ent-kaurenoic acid, was fully complemented by P450-4. There is a single nucleotide difference between the sequence of the B1-41a and wild-type P450-4 alleles at the 3' consensus sequence of intron 2 in the mutant, resulting in reduced levels of active protein due to a splicing defect in the mutant. These data suggest that P450-4 encodes a multifunctional ent-kaurene oxidase catalyzing all three oxidation steps between ent-kaurene and ent-kaurenoic acid.     

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)     

Kaurenolide biosynthesis in a cell-free system from Cucurbita maxima seeds

A new product obtained by incubation of [2-¹⁴C ]-mevalonic acid with a cell-free system from Cucurbita maxima endosperm was identified by GC-MS as ent-kaura-6,16-dien-19-oic acid. When this compound was reincubated with the microsomal fraction it was converted to 7β-hydroxykaurenolide and hence to 7β,12α-dihydroxykaurenolide. The dienoic acid was also obtained by incubation of ent-kaurene, ent1-kaurenol, ent-kaurenal and ent-kaurenoic acid, but not ent-7α-hydroxykaurenoic acid, with the microsomal fraction. Thus, in the C. maxima cell-free system, the kaurenolides are formed by a pathway which branches from the GA pathway at ent-kaurenoic acid and proceeds via the dienoic acid.     

Position of the metabolic block for gibberellin biosynthesis in mutant b1-41a of Gibberella fujikuroi

Mutant B1-41a, obtained by UV-irradiation of Gibberella fujikuroi strain GF-1a, does not metabolise mevalonic acid lactone (MVL), ent-kaur-16-ene, ent-kaurenol, and ent-kaurenal to gibberellins. ent-Kaur-16-ene-19-oic acid is completely metabolised to give the same gibberellins in similar concentration as unsupplemented cultures of the parent strain. It is concluded that this mutant is blocked for gibberellin synthesis at the step from ent-kaurenal to ent-kaurenoic acid. Comparison of the incorporation of MVL into GA₃ by the mutant and the parent strains indicate that the metabolic block is 97·5% effective. A method of preparing ent-kaur-16-ene, labelled at C-15 and C-17 by [²H] and [³H] is described.     

CYP701A26 is characterized as an <Emphasis Type="Italic">ent</Emphasis>-kaurene oxidase with putative involvement in maize gibberellin biosynthesis

Objectives

To characterize the ent-kaurene oxidase (KO) involved in maize (Zea mays) gibberellin (GA) biosynthesis.

Results

Two putative KO genes were identified in maize based on the homologous alignment. Biochemical characterization indicated that one of them encoded a cytochrome P450 monooxygenase (P450) CYP701A26, which reacted with ent-kaurene to form ent-kaurenoic acid, the key intermediate of GA biosynthesis. CYP701A26 showed constitutive expression in active growing tissues and no inducible expression, which led to putative designation of CYP701A26 as the ZmKO. CYP701A26 exhibited substrate promiscuity to catalyze oxidation of other labdane related diterpenes. Another maize KO homologue, CYP701A43 did not show any catalytic activities on ent-kaurene or other tested diterpenes. It exhibited inducible gene expression and might accept unknown substrates to play roles in specialized metabolism for stress response.

Conclusions

CYP701A26 was characterized to exhibit ent-kaurene oxidase activity with substrate promiscuity and might be involved in maize GA biosynthesis, and its homologue CYP701A43 did not show such function and might play roles in stress response.

     

The effect of growth retardants on phytochrome-induced lettuce seed germination

Experiments were carried out to explore the involvement of the plant hormone gibberellin (GA) in the light-induced germination of lettuce seeds. Three growth retardants known to be inhibitors of GA biosynthesis were tested for their effect on red-light-induced germination. Chlormequat chloride (CCC) and AMO-1618 had no effect, but ancymidol was strongly inhibitory. Moreover, the inhibition caused by ancymidol was completely overcome by GA₃. CCC and AMO-1618 inhibit the formation ofent-kaurene, while ancymidol blocks the oxidation ofent-kaurene toent-kaurenoic acid. Ancymidol also was found to inhibit GA-induced dark germination of lettuce seeds, and this inhibition was partially reversed by higher levels of GA. Therefore, the results suggest two possibilities for the relationship between phytochrome and GA in this system: first, the rate-limiting step in the germination of light-sensitive lettuce seeds, that which is regulated by phytochrome, is the oxidation ofent-kaurene toent-kaurenoic acid. Alternatively, red-light treatment may result in the release of active GAlike substances which, in turn, induce germination. In either case the results presented here support the view that phytochrome exerts its effect on lettuce seed germination by means of GA rather than via an independent pathway.     

The gibberellin 20-oxidase of Gibberella fujikuroi is a multifunctional monooxygenase

The genes for gibberellin (GA) biosynthesis are clustered in the fungus Gibberella fujikuroi. In addition to genes encoding a GA-specific geranylgeranyl diphosphate synthase and a bifunctional ent-copalyl diphosphate/ent-kaurene synthase, the cluster contains four cytochrome P450 monooxygenase genes (P450-1, -2, -3, -4). Recently it was shown that P450-4 and P450-1 encode multifunctional enzymes catalyzing the three oxidation steps from ent-kaurene to ent-kaurenoic acid and the four oxidation steps from ent-kaurenoic acid to GA14, respectively. Here we describe the functional analysis of the P450-2 gene by gene disruption and by expressing the gene in a mutant that lacks the entire GA biosynthesis gene cluster. Mutants in which P450-2 is inactivated by the insertion of a large piece of DNA accumulated GA14 and lacked biosynthetically more advanced metabolites, indicating that the gene encodes a 20-oxidase. This was confirmed by incubating lines containing P450-2 in the absence of the other GA biosynthesis genes with isotopically labeled substrates. The P450-2 gene product oxidized the 3beta-hydroxylated intermediate, GA14, and its non-hydroxylated analogue GA12 to GA4 and GA9, respectively. Expression of P450-2 is repressed by high amounts of nitrogen in the culture medium but is not affected by the presence of biosynthetically advanced GAs, i.e. there is no evidence for feedback regulation. The fact that the GA 20-oxidase is a cytochrome P450 monooxygenase in G. fujikuroi and not a 2-oxoglutarate-dependent dioxygenase as in plants, together with the significant differences in regulation of gene expression, are further evidence for independent evolution of the GA biosynthetic pathways in plants and fungi.     

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.     

Identification and Functional Characterization of Monofunctional ent-Copalyl Diphosphate and ent-Kaurene Synthases in White Spruce Reveal Different Patterns for Diterpene Synthase Evolution for Primary and Secondary Metabolism in Gymnosperms

The biosynthesis of the tetracyclic diterpene ent-kaurene is a critical step in the general (primary) metabolism of gibberellin hormones. ent-Kaurene is formed by a two-step cyclization of geranylgeranyl diphosphate via the intermediate ent-copalyl diphosphate. In a lower land plant, the moss Physcomitrella patens, a single bifunctional diterpene synthase (diTPS) catalyzes both steps. In contrast, in angiosperms, the two consecutive cyclizations are catalyzed by two distinct monofunctional enzymes, ent-copalyl diphosphate synthase (CPS) and ent-kaurene synthase (KS). The enzyme, or enzymes, responsible for ent-kaurene biosynthesis in gymnosperms has been elusive. However, several bifunctional diTPS of specialized (secondary) metabolism have previously been characterized in gymnosperms, and all known diTPSs for resin acid biosynthesis in conifers are bifunctional. To further understand the evolution of ent-kaurene biosynthesis as well as the evolution of general and specialized diterpenoid metabolisms in gymnosperms, we set out to determine whether conifers use a single bifunctional diTPS or two monofunctional diTPSs in the ent-kaurene pathway. Using a combination of expressed sequence tag, full-length cDNA, genomic DNA, and targeted bacterial artificial chromosome sequencing, we identified two candidate CPS and KS genes from white spruce (Picea glauca) and their orthologs in Sitka spruce (Picea sitchensis). Functional characterization of the recombinant enzymes established that ent-kaurene biosynthesis in white spruce is catalyzed by two monofunctional diTPSs, PgCPS and PgKS. Comparative analysis of gene structures and enzyme functions highlights the molecular evolution of these diTPSs as conserved between gymnosperms and angiosperms. In contrast, diTPSs for specialized metabolism have evolved differently in angiosperms and gymnosperms.Conifers (Coniferophyta) are well known for producing an abundant and diverse assortment of oleoresin diterpenoids, predominantly in the form of diterpene resin acids from specialized (or secondary) metabolism, that play roles in conifer defense (Trapp and Croteau, 2001a; Keeling and Bohlmann, 2006a; Bohlmann, 2008) and are an important source of biomaterials (Bohlmann and Keeling, 2008). Several conifer diterpene synthases (diTPSs) that biosynthesize these compounds have been functionally characterized (Stofer Vogel et al., 1996; Peters et al., 2000; Martin et al., 2004; Keeling and Bohlmann, 2006b; Ro and Bohlmann, 2006). The formation of diterpene resin acids of conifer specialized metabolism parallels the formation of ent-kaurenoic acid in the biosynthesis of the gibberellin diterpenoid phytohormones (Fig. 1; Keeling and Bohlmann, 2006a; Yamaguchi, 2008). In gibberellin biosynthesis, geranylgeranyl diphosphate (GGPP) is cyclized by diTPS activity to ent-copalyl diphosphate (ent-CPP), and the ent-CPP is further cyclized by diTPS activity to ent-kaurene. A cytochrome P450 (P450)-dependent monooxygenase (CYP701) oxidizes ent-kaurene to ent-kaurenoic acid (Davidson et al., 2006), paralleling the activity of a P450 (CYP720B1) that oxidizes abietadiene to abietic acid in conifer diterpene resin acid biosynthesis (Ro et al., 2005). Other P450s further functionalize ent-kaurenoic acid to form the biologically active gibberellins. Surprisingly, no conifer diTPS involved in the general (or primary) metabolism of gibberellins has been reported to date, while metabolite profiles of gibberellins have been well characterized in conifers for their role in flowering (Moritz et al., 1990).Open in a separate windowFigure 1.Comparison of the biosynthesis of gibberellins, as it is known in angiosperm and lower plants, with the biosynthesis of diterpene resin acids in conifers, a large group of gymnosperm trees. In conifers, the formation of diterpene resin acids involves bifunctional diTPS (e.g. abietadiene synthase) for the stepwise cyclization of GGPP into diterpenes such as abietadiene via a copalyl diphosphate intermediate that moves between the two active sites of the bifunctional diTPS (Peters et al., 2001). The products of the diTPS are subsequently oxidized by P450 to the resin acids. In contrast, gibberellin biosynthesis in angiosperms requires two monofunctional diTPSs to convert GGPP into ent-kaurene, which is subsequently modified by P450s. The two monofunctional diTPSs in angiosperm gibberellin biosynthesis are CPS and KS. In the lower plant P. patens, the CPS and KS activities are combined in a bifunctional diTPS similar to the bifunctional diTPS in conifer diterpene resin acid biosynthesis. Prior to this work, to our knowledge, it was not known if the formation of gibberellins in a gymnosperm involves two monofunctional diTPSs, as in angiosperms, or a bifunctional diTPS, as in gymnosperm diterpene resin acid biosynthesis and in P. patens gibberellin biosynthesis. (Figure adapted from Keeling and Bohlmann [2006a].)In the fungi Gibberella fujikuroi (Toyomasu et al., 2000) and Phaeosphaeria species L487 (Kawaide et al., 1997) and in the primitive land plant Physcomitrella patens (Bryophyta; Hayashi et al., 2006; Anterola and Shanle, 2008), the formation of ent-kaurene from GGPP is catalyzed by bifunctional diTPS enzymes. These enzymes contain two active sites. The N-terminal active site domain harbors a conserved DXDD motif and catalyzes the protonation-initiated cyclization of GGPP to ent-CPP (Prisic et al., 2007). In the C-terminal active site domain, a conserved DDXXD motif is essential for the diphosphate ionization-initiated cyclization of ent-CPP to ent-kaurene (Christianson, 2006). The presence of two active sites with their characteristic DXDD and DDXXD motifs resembles the structure of conifer bifunctional diTPSs in specialized metabolism of diterpene resin acid biosynthesis (Fig. 1), such as the grand fir (Abies grandis) abietadiene synthase (AgAS) and Norway spruce (Picea abies) levopimaradiene/abietadiene synthases (PaLAS; Peters et al., 2001; Martin et al., 2004; Keeling and Bohlmann, 2006a). In contrast, the formation of ent-kaurene from GGPP in angiosperms is catalyzed by two separate monofunctional enzymes, one with only the DXDD motif and having ent-copalyl diphosphate synthase (ent-CPS) activity and the other with only the DDXXD motif and having ent-kaurene synthase (ent-KS) activity (Yamaguchi, 2008).A previously published model for the evolution of plant diTPS (Trapp and Croteau, 2001b) suggests that genes encoding the monofunctional CPS and KS enzymes known in angiosperms originated by gene duplication and subfunctionalization (Lynch and Force, 2000) of an ancestral bifunctional CPS/KS gene that may have been similar to the gene for the CPS/KS enzyme of the moss P. patens. The same model also suggests that genes for diTPSs of gymnosperm specialized diterpene resin acid metabolism arose from duplication and subsequent neofunctionalization of an ancestral bifunctional diTPS of the gibberellin pathway (Trapp and Croteau, 2001b). The pathways to specialized oleoresin diterpenes existed in ancient plants prior to the differentiation of gymnosperms and angiosperms (Bray and Anderson, 2009). Vascular plants split from nonvascular plants approximately 500 million years ago, and angiosperms split from gymnosperms approximately 300 million years ago (Palmer et al., 2004). As there has been no report to date of genes involved in gibberellin biosynthesis in gymnosperms, it remains unresolved and cannot be predicted whether conifers have a bifunctional CPS/KS for the formation of ent-kaurene similar to the primitive land plant P. patens and paralleling the diTPSs for conifer specialized diterpene resin acid biosynthesis or whether they have separate monofunctional CPS and KS enzymes, as is the case in angiosperms.In this study, we made use of the extensive EST resources for spruce species (Pavy et al., 2005; Ralph et al., 2008), combined with isolation and sequencing of full-length cDNAs, genomic (g)DNA, and targeted bacterial artificial chromosome (BAC) clones, as well as enzyme assays with recombinant proteins to search for, and functionally characterize, possible monofunctional or bifunctional diTPS for ent-kaurene biosynthesis in a gymnosperm. In summary, we successfully isolated and characterized monofunctional ent-CPS (PgCPS) and ent-KS (PgKS) from white spruce (Picea glauca) and isolated orthologous cDNAs from Sitka spruce (Picea sitchensis). Comparison of enzyme functions and gene structures support common ancestry but different routes of evolution of monofunctional and bifunctional diTPS in conifer general and specialized metabolism, respectively.     

Isolation and Characterization of the Gibberellin Biosynthetic Gene Cluster in Sphaceloma manihoticola

Gibberellins (GAs) are tetracyclic diterpenoid phytohormones that were first identified as secondary metabolites of the fungus Fusarium fujikuroi (teleomorph, Gibberella fujikuroi). GAs were also found in the cassava pathogen Sphaceloma manihoticola, but the spectrum of GAs differed from that in F. fujikuroi. In contrast to F. fujikuroi, the GA biosynthetic pathway has not been studied in detail in S. manihoticola, and none of the GA biosynthetic genes have been cloned from the species. Here, we present the identification of the GA biosynthetic gene cluster from S. manihoticola consisting of five genes encoding a bifunctional ent-copalyl/ent-kaurene synthase (CPS/KS), a pathway-specific geranylgeranyl diphosphate synthase (GGS2), and three cytochrome P450 monooxygenases. The functions of all of the genes were analyzed either by a gene replacement approach or by complementing the corresponding F. fujikuroi mutants. The cluster organization and gene functions are similar to those in F. fujikuroi. However, the two border genes in the Fusarium cluster encoding the GA₄ desaturase (DES) and the 13-hydroxylase (P450-3) are absent in the S. manihoticola GA gene cluster, consistent with the spectrum of GAs produced by this fungus. The close similarity between the two GA gene clusters, the identical gene functions, and the conserved intron positions suggest a common evolutionary origin despite the distant relatedness of the two fungi.     

Deletions in the Gibberellin Biosynthesis Gene Cluster of Gibberella fujikuroi by Restriction Enzyme-Mediated Integration and Conventional Transformation-Mediated Mutagenesis

We induced mutants of Gibberella fujikuroi deficient in gibberellin (GA) biosynthesis by transformation-mediated mutagenesis with the vector pAN7-1. We recovered 24 GA-defective mutants in one of nine transformation experiments performed without the addition of a restriction enzyme. Each mutant had a similar Southern blot pattern, suggesting the integration of the vector into the same site. The addition of a restriction enzyme by restriction enzyme-mediated integration (REMI) significantly increased the transformation rate and the rate of single-copy integration events. Of 1,600 REMI transformants, two produced no GAs. Both mutants had multiple copies of the vector pAN7-1 and one had a Southern blot pattern similar to those of the 24 conventionally transformed GA-deficient mutants. Biochemical analysis of the two REMI mutants confirmed that they cannot produce ent-kaurene, the first specific intermediate of the GA pathway. Feeding the radioactively labelled precursors ent-kaurene and GA₁₂-aldehyde followed by high-performance liquid chromatography and gas chromatography-mass spectrometry analysis showed that neither of these intermediates was converted to GAs in the mutants. Southern blot analysis and pulsed-field gel electrophoresis of the transformants using the bifunctional ent-copalyl diphosphate/ent-kaurene synthase gene (cps/ks) and the flanking regions as probes revealed a large deletion in the GA-deficient REMI transformants and in the GA-deficient transformants obtained by conventional insertional transformation. We conclude that transformation procedures with and without the addition of restriction enzymes can lead to insertion-mediated mutations and to deletions and chromosome translocations.     

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.     

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.     

Plant growth regulation with triazoles of the dioxanyl type

The plant growth retarding activities of several dioxanylalkyl and dioxanylalkenyl triazoles were determined in seedlings of barley, rice, and oilseed rape. Out of these groups some substances proved to be among the most efficient growth retardants known. The compound 1-(4-trifluormethyl)-2-(1,2,4-triazolyl-(1))-3-(5-methyl-1,3-dioxan-5-yl)-propen-3-ol was investigated more closely. Shoot growth is reduced more intensively than root growth by this compound. At lower dosages root growth may even be stimulated. The action of this retardant can be antagonized by gibberellin A₃ and byent-kaurenoic acid. It is suggested that its main biochemical action is to block the reactions that lead froment-kaurene toent-kaurenoic acid in the course of gibberellin biosynthesis.     

The LS locus of pea encodes the gibberellin biosynthesis enzyme ent-kaurene synthase A

Gibberellins (GAs) are hormones required for several aspects of plant development, including internode elongation and seed development in pea (Pisum sativum L.). The first committed step in the GA biosynthesis pathway is the conversion of geranylgeranyl diphosphate (GGDP) to ent-kaurene via copalyl diphosphate (CDP). These two reactions are catalyzed by the cyclases ent-kaurene synthase A (KSA) and ent-kaurene synthase B (KSB), respectively. Previous genetic and biochemical analysis of the GA-responsive ls-1 mutant of pea suggested that GA levels are reduced in a developmental- and organ-specific manner due to reduced GA biosynthesis. Analysis of cell-free enzyme preparations from WT and ls-1 embryos at contact point reveals that ls-1 reduces the activity of KSA but not KSB. To characterize the ls-1 mutation in more detail, a cDNA coding for a pea KSA was cloned and shown to be encoded by the LS locus. The ls-1 mutation results from an intronic G to A substitution that causes impaired RNA splicing. To determine the activity of the KSAs encoded by the LS and ls-1 alleles, a new in vitro assay for combined KSA and KSB activity has been developed using the KSB gene of pumpkin. Using recombinant WT KSA and KSB fusion proteins, GGDP is converted to ent-kaurene in vitro. Based on the sequence of RT-PCR products, three different truncated KSA proteins are predicted to exist in ls-1 plants. The most abundant mutant KSA protein does not possess detectable activity in vitro. Nevertheless, the ls-1 allele is not null and is able to encode at least a partially functional KSA since a more severe ls allele has been identified. The ls-1 mutation has played a key role in identifying a role for GAs in pea seed development in the first few days after fertilization, but not in older seeds. KSA expression in seeds is developmentally regulated and parallels overall GA biosynthesis, suggesting that KSA expression may play an important role in the regulation of GA biosynthesis and seed development.     

ent-Kaurene Biosynthesis in Germinating Barley (Hordeum vulgare L., cv Himalaya) Caryopses and Its Relation to alpha-Amylase Production

ent-Kaurene biosynthesis as a prerequisite for gibberellin (GA) biosynthesis was studied in germinating Hordeum vulgare L., cv Himalaya caryopses and correlated, in time, with the appearance of α-amylase activity. The rate of ent-kaurene biosynthesis was estimated by inhibiting its further metabolism with plant growth retardants (triapenthenol or tetcyclacis) and measuring its accumulation by isotope dilution using combined gas chromatographymass spectrometry. In the inhibitor-treated caryopses, ent-kaurene accumulation began approximately 24 hours after imbibition and proceeded at a rate of about 1 to 2 picomoles per hour per caryopsis, depending on the batch of seeds. In the absence of inhibitor, ent-kaurene did not accumulate, indicating that it is normally turned over rapidly, presumably to further intermediates of the GA biosynthesis pathway and eventually to GAs. ent-Kaurene accumulation occurred almost exclusively in the shoot, which is, therefore, probably the site of biosynthesis. α-Amylase production began between 30 and 36 hours after imbibition and, thus, correlated well with de novo GA biosynthesis, as estimated from ent-kaurene accumulation. However, inhibition of ent-kaurene oxidation by plant growth retardants did not reduce the α-amylase production significantly, although it did reduce shoot elongation. We conclude that ent-kaurene is produced in the shoot and is continuously converted to GA, which is essential for normal shoot elongation, but not for the production of α-amylase in the aleurone layer.     

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.     

Gibberellin biosynthesis in bacteria: Separate ent-copalyl diphosphate and ent-kaurene synthases in Bradyrhizobium japonicum

Gibberellins are ent-kaurene-derived diterpenoid phytohormones produced by plants, fungi, and bacteria. The distinct gibberellin biosynthetic pathways in plants and fungi are known, but not that in bacteria. Plants typically use two diterpene synthases to form ent-kaurene, while fungi use only a single bifunctional diterpene synthase. We demonstrate here that Bradyrhizobium japonicum encodes separate ent-copalyl diphosphate and ent-kaurene synthases. These are found in an operon whose enzymatic composition indicates that gibberellin biosynthesis in bacteria represents a third independently assembled pathway relative to plants and fungi. Nevertheless, sequence comparisons also suggest potential homology between diterpene synthases from bacteria, plants, and fungi.