Oxidation Of Ent-kaurene Research Articles

Characterization of moss ent-kaurene oxidase (CYP701B1) using a highly purified preparation

CYP701B1 of the moss, Physcomitrella patents, might be a unique cytochrome P450 having the ent-kaurene oxidase (KO) activity occurring in nonvascular plant. Phylogenetic analysis suggested that the gene encoding CYP701B1 was diverged from a common ancestral gene encoding KO of vascular plants. CYP701B1 expressed in Phichia yeast microsomes was purified and characterized. The purified CYP701B1 catalyzed the oxidation of ent-kaurene to ent-kaurenoic acid through three successive monooxygenations, and the rate-limiting step of this oxidation might be the initial step that forms ent-kaurenol. CYP701B1 was a typical ferric low-spin cytochrome P450 and was completely moved to high-spin state upon binding with ent-kaurene, and apparent Kd of ent-kaurene estimated by the spectral change caused by this spin-state shift was 2.5 μM. The potent KO inhibitor uniconazole, an azole compound with molecular size similar to ent-kaurene, bound CYP701B1 with high affinity. However, ketoconazole, an azole compound whose molecular size is larger than ent-kaurene could not bind to CYP701B, though it binds strongly with CYP51, lanosterol 14-demethylase. The results indicated that the active site of CYP701B1 is fitted for the molecular size of ent-kaurene. The P450 monooxygenase adapted for ent-kaurene oxidation might appear in land plants before evolutionary divergence into vascular and nonvascular plants.

Regulation of the early GA biosynthesis pathway in pea.

The early steps in the gibberellin (GA) biosynthetic pathway are controlled by single copy genes or small gene families. In pea (Pisum sativum L.) there are two ent-kaurenoic acid oxidases, one expressed only in the seeds, while ent-copalyl synthesis and ent-kaurene oxidation appear to be controlled by single copy genes. None of these genes appear to show feedback regulation and the only major developmental regulation appears to be during seed development. During shoot maturation, transcript levels do not change markedly with the result that all the three genes examined are expressed in mature tissue, supporting recent findings that these tissues can synthesise GAs. It therefore appears that the regulation of bioactive GA levels are determined by the enzymes encoded by the 2-oxoglutarate-dependent dioxygenase gene families controlling the later steps in GA biosynthesis. However the early steps are nonetheless important as a clear log/linear relationship exists between elongation and the level of GA1 in a range of single and double mutants in genes controlling these steps.

Isolation and functional characterization of cytochrome P450s in Gibberellin biosynthesis pathway

Publisher Summary This chapter describes the polymerase chain reaction (PCR) strategy used to isolate cDNAs encoding ent-kaurene oxidase and a putative ent-kaurenoic acid oxidase from developing pumpkin seeds. It also describes the yeast assay used to demonstrate that CYP701A subfamily members are ent-kaurene oxidases and that CYP88A subfamily members are ent-kaurenoic acid oxidases. Gibberellin biosynthesis starts from geranylgeranyl diphosphate. Two terpene cyclases, copalyl diphosphate synthase and kaurene synthase, catalyze cyclization reactions to produce ent-kaurene. Cytochrome P450s then catalyze the oxidation of ent-kaurene to GA12. The steps of the pathway from GA12 to the bioactive GAs are catalyzed by soluble dioxygenases. One method to isolate genes encoding P450s in the GA biosynthesis pathway is to take advantage of a mutation in a gene encoding one of the pathway enzymes. The Arabidopsis ga3 mutant have been used that has a characteristic GA responsive dwarf phenotype and was thought to be impaired in ent-kaurene oxidation, to isolate the gene encoding CYP701A3, ent-kaurene oxidase.

Distinct cell-specific expression patterns of early and late gibberellin biosynthetic genes during Arabidopsis seed germination.

Gibberellins (GAs) are biosynthesized through a complex pathway that involves several classes of enzymes. To predict sites of individual GA biosynthetic steps, we studied cell type-specific expression of genes encoding early and late GA biosynthetic enzymes in germinating Arabidopsis seeds. We showed that expression of two genes, AtGA3ox1 and AtGA3ox2, encoding GA 3-oxidase, which catalyzes the terminal biosynthetic step, was mainly localized in the cortex and endodermis of embryo axes in germinating seeds. Because another GA biosynthetic gene, AtKO1, coding for ent-kaurene oxidase, exhibited a similar cell-specific expression pattern, we predicted that the synthesis of bioactive GAs from ent-kaurene oxidation occurs in the same cell types during seed germination. We also showed that the cortical cells expand during germination, suggesting a spatial correlation between GA production and response. However, promoter activity of the AtCPS1 gene, responsible for the first committed step in GA biosynthesis, was detected exclusively in the embryo provasculature in germinating seeds. When the AtCPS1 cDNA was expressed only in the cortex and endodermis of non-germinating ga1-3 seeds (deficient in AtCPS1) using the AtGA3ox2 promoter, germination was not as resistant to a GA biosynthesis inhibitor as expression in the provasculature. These results suggest that the biosynthesis of GAs during seed germination takes place in two separate locations with the early step occurring in the provasculature and the later steps in the cortex and endodermis. This implies that intercellular transport of an intermediate of the GA biosynthetic pathway is required to produce bioactive GAs.

GROWTH RETARDANTS: Effects on Gibberellin Biosynthesis and Other Metabolic Pathways.

Plant growth retardants are applied in agronomic and horticultural crops to reduce unwanted longitudinal shoot growth without lowering plant productivity. Most growth retardants act by inhibiting gibberellin (GA) biosynthesis. To date, four different types of such inhibitors are known: (a) Onium compounds, such as chlormequat chloride, mepiquat chloride, chlorphonium, and AMO-1618, which block the cyclases copalyl-diphosphate synthase and ent-kaurene synthase involved in the early steps of GA metabolism. (b) Compounds with an N-containing heterocycle, e.g. ancymidol, flurprimidol, tetcyclacis, paclobutrazol, uniconazole-P, and inabenfide. These retardants block cytochrome P450-dependent monooxygenases, thereby inhibiting oxidation of ent-kaurene into ent-kaurenoic acid. (c) Structural mimics of 2-oxoglutaric acid, which is the co-substrate of dioxygenases that catalyze late steps of GA formation. Acylcyclohexanediones, e.g. prohexadione-Ca and trinexapac-ethyl and daminozide, block particularly 3ss-hydroxylation, thereby inhibiting the formation of highly active GAs from inactive precursors, and (d) 16,17-Dihydro-GA5 and related structures act most likely by mimicking the GA precursor substrate of the same dioxygenases. Enzymes, similar to the ones involved in GA biosynthesis, are also of importance in the formation of abscisic acid, ethylene, sterols, flavonoids, and other plant constituents. Changes in the levels of these compounds found after treatment with growth retardants can mostly be explained by side activities on such enzymes.

Effects of Gibberellins on Seed Germination of Phytochrome-Deficient Mutants of <italic>Arabidopsis thaliana</italic>

Experiments were carried out to explore the involvement of gibberellins (GAs) in the light-induced germination of Arabidopsis thaliana (L.) Heynh, using wild type (WT) and phytochrome-deficient mutants (phyA, phyB and phyAphyB deficient in phytochrome A, B and A plus B, respectively). Seed germination of WT and phytochrome-deficient mutants was inhibited by uniconazole (an inhibitor of an early step in biosynthesis of GA, the oxidation of ent-kaurene) and prohexadione (an inhibitor of late steps, namely, 2 beta- and 3 beta-hydroxylation). This inhibition was overcome by simultaneous application of 10(-5) M GA4. The relative activity of GAs for promoting germination of uniconazole-treated seeds was GA4 > GA1 = GA9 > GA20. The wild type and the phyA and phyB mutants had an increased response to a red light pulse in the presence of GA1, GA4, GA9, GA20 and GA24 but there were no significant differences in activity of each GA between the mutants. Therefore, neither phytochrome A nor hytochrome B appears to regulate GA biosynthesis from GA12 to GA4 during seed germination, since the conversion of GA12 to GA9 is regulated by one enzyme (GA 20-oxidase). However, GA responsiveness appears to be regulated by phytochromes other than phytochromes A and B, since the phyAphyB double mutant retains the photoreversible increased response to GAs after a red light pulse.

A highly-sensitive rice seedling bioassay for the detection of femtomole quantities of 3?-hydroxylated gibberellins

A very sensitive and specific bioassay using prohexadione calcium [BX-112, which blocks 2β- and 3β-hydroxylation of gibberellins (GAs)] with uniconazole (which blocks oxidation of ent-kaurene, ent-kaurenol and ent-kaurenal) in a microdrop assay was developed for several rice (Oryza sativa L.) varieties, including cv. Waito-C, which is already specific to 3β-hydroxylated GAs. The sensitivity and specificity of cvs. Waito-C, Tan-ginbozu and Koshihikari to 3β-hydroxylated GAs was greatly enhanced by treatment of the seeds with a combination of 40 mM prohexadione calcium and 80 μM uniconazole. The minimum detectable doses of 3β-hydroxylated GAs (GA1, GA3, GA4 and GA7) in the three cultivars treated with both chemicals were 1 to 10 fmol (i.e. ca. 350 fg to 3.5 pg) per plant. This is equal to 30-fold more sensitive than Waito-C treated with uniconazole alone, and 30 to 1000-fold more sensitive than Waito-C with no growth retardant soak. Minimum detectable doses of 3-nonhydroxylated GAs (GA9, GA19 GA20) and GAs with very low biological activity (GA8 and GA17) were equal to or more than 1000 fmol per plant. This is about equal to the activity in Waito-C treated with uniconazole alone. Application of this assay to an extract from Raphanus sativus was compared with the data by gas chromatography/mass spectrometry (GC/MS), confirming the conclusions reached using authentic test GAs, namely that use of uniconazole plus BX-112 appreciably enhanced the detection sensitivity to fractions shown by GC/MS to contain GA1 and GA4, both 3β-hydroxylated GAs.

Ent-Kaurene Biosynthesis in Germinating Barley (Hordeum vulgare L., cv Himalaya) Caryopses and Its Relation to α-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 alpha-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. alpha-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 alpha-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 alpha-amylase in the aleurone layer.

Separation of Light-Induced [14C]ent-Kaurene Metabolism and Light-Induced Germination in Grand Rapids Lettuce Seeds

The effect of light on the metabolism of [(14)C]kaurene in light-requiring lettuce seeds (Lactuca sativa L. cv Grand Rapids) was investigated. Seeds were soaked in a solution of [(14)C]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. [(14)C]ent-Kaurenol and [(14)C]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, [(14)C]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.

Development of a New Plant Growth Regulator, Inabenfide

Inabenfide is a new plant growth regulator discovered and developed by Chugai Pharmaceutical Co. Ltd. The biggest change in rice culture in recent years in Japan has been the remarkable development in mechanization of rice-transplanting and rice harvesting. Thus, attention is being paid to development of seedling tough to withstanding mechanized transplantation and of culture techniques for preventing lodging of rice plants before harvesting. For these reasons, it has long been desired to establish good cultivation techniques or to develop plant growth regulation with the use of chemicals so that sufficiently tough seedlings and plants having good properties for mechanized harvesting can be realized. We have searched for several years to find compounds capable of regulating the growth of rice plants, and found that isonicotinanilide represented by the formula, 4′-chloro-2′-(α-hydroxybenzyl) isonicotinanilide (inabenfide, Seritard®), has excellent growth regulating activity. The treatment of inabenfide in nursery boxes strongly controlled growth of rice seedling after treatments with 0.01 to 1g per box, and resulted in good seedlings. When inabenfide was treated on rice paddies at a rate of 2.4kg per ha on either the 62nd, 52nd, 42nd, 32nd, 22nd and 12th day before heading, the resultant growth showed shorter plants and less tendency to lodge. As a result, the yield also increased, as did the number of panicles, percentage of well ripening, and 1000-Kernel weight. On the other hand, a large number of official trials carried out in Japan since 1981 have demonstrated the effective qualities of inabenfide. It is now registered for agriculture use in Japan and under developing in some countries in Southeast Asia. The action sites of inabenfide is the inhibition of oxidation of ent-Kaurene, ent-Kaurenol and ent-Kaurenal in GA biosynthesis. Inabenfide has several favourable properties: It is low in acute mammalia toxicity and fish toxicity, causes no skin and eye irritation, has no impact on usefull insects and no phytotoxicity.

Inhibition ofEnt-kaurene oxidation by cytokinins

Cytokinins, which have some structural similarities to ancymidol, a plant growth retardant, were tested for their effects on the cell-free oxidation ofent-kaurene. Results indicate that several cytokinins inhibit this reaction in microsomal extracts of liquid endosperm from immature wild cucumber seeds. N6-cyclohexanemethyladenine was the most active (inhibiting 50% of the controlent-kaurene oxidation at 2×10−6 M). N6-isoamyladenine, N6-benzyladenine, N6-(Δ2-isopentenyl)adenine and dihydrozeatin were active at successively higher concentrations. Zeatin, kinetin, adenine, N6-benzyladenosine, and N6-(isopentenyl)adenosine were inactive in this system.

Comparative Effects of Ancymidol and Its Analogs on Growth of Peas and Ent-Kaurene Oxidation in Cell-Free Extracts of Immature Marah macrocarpus Endosperm

The plant growth retardant alpha-cyclopropyl-alpha-(4-methyoxyphenyl)-5-pyrimidine methyl alcohol (ancymidol) and a series of analogs of this substance in which one or more of the substituents were varied were tested for their comparative biological activity. The compounds were tested as inhibitors of internode elongation in peas and as inhibitors of the oxidation of ent-kaurene catalyzed by microsomal preparations from the liquid endosperm of Marah macrocarpus seeds. The relative effectiveness of a substance was generally the same as an inhibitor of the two processes. Ancymidol was the most effective. Substitution of the alcohol group of ancymidol by either methoxy or hydrogen groups reduced the activity only slightly. Substitution of the cyclopropyl group by an isopropyl moiety also had little effect on the activity. However, substitution of the cyclopropyl group with a phenyl or other aryl substituent greatly reduced the effectiveness of the analog as an inhibitor. Replacement of the 4-methoxyphenyl substituent with a similar substituent such as 4-chlorophenyl had little effect on activity, but replacement with a 2-methoxyphenyl group greatly reduced activity. Analogs in which the pyrimidyl moiety of ancymidol was modified were inactive in whole plants, but moderately active in the cell-free ent-kaurene oxidation system. The application of gibberellic acid can overcome the growth inhibitions due to treatment of the test plants with 10(-5)m or lower concentrations of the inhibitors. However, the inhibitory effects of 10(-4)m or higher concentrations of inhibitors on test plants were not overcome by the applications of exogenous gibberellic acid. These results support the idea that the effects of low concentrations of these substances on plant growth are primarily a consequence of their ability to inhibit ent-kaurene oxidation and gibberellin biosynthesis. Other modes of inhibition may operate at higher inhibitor concentrations.

Comparative Effects of Substituted Pyrimidines on Growth and Gibberellin Biosynthesis in Gibberella fujikuroi

The fungicide alpha-(2,4-dichlorophenyl)-alpha-phenyl-5-pyrimidine methyl alcohol (triarimol) and four other structural analogs of this substance, in which one or more of the substituents were varied, were tested for their comparative effects on growth and gibberellin biosynthesis in the fungus Gibberella fujikuroi. Each of the five analogs tested was capable of inhibiting growth as measured by dry weight in 5-day-old cultures. Three of them [alpha-(2-chlorophenyl)-alpha-(4-chlorophenyl)-5-pyrimidine methyl alcohol, fenarimol; alpha-(2-chlorophenyl)-alpha-(4-fluorophenyl)-5-pyrimidine methyl alcohol, nuarimol; and triarimol] were effective at appreciably lower concentrations than the other two [alpha-(4-chlorophenyl)-alpha-(1-methylethyl)-5-pyrimidine methyl alcohol, experimental compound EL 509; and alpha-cyclopropyl-alpha-(4-methoxyphenyl)-5-pyrimidine methyl alcohol, ancymidol].All five substances also inhibited gibberellin production as measured by gibberellin content of fungus filtrates. The relative effectiveness of the compounds as inhibitors of growth and gibberellin production were similar. These analogs were also shown to inhibit ent-kaurene oxidation by microsomal preparations from fungal mycelia. Thus, the site of inhibition of gibberellin biosynthesis may be the same for the fungus as the one affected by this group of substances in higher plant tissues.The structure-activity relationships between the analogs are opposite to those observed in higher plant tissues. The fungicides fenarimol, nuarimol, and triarimol, which were most effective in inhibiting growth and gibberellin biosynthesis in the fungus, were much less effective than EL 509 and ancymidol in inhibiting growth and gibberellin biosynthesis in higher plants. These results indicate that the ent-kaurene oxidase systems from the two sources have somewhat different molecular characteristics, and thus, interact differently with this group of substances.