Isolation and characterization of brassinosteroids from immature seeds of Camellia sinensis (O) Kuntze

Brassinosteroids play an important role in growth and development of plants. They have been reported universally in all the plants. The present study deals with the presence of these compounds in immature tea seeds. Five brassinosteroids, i.e. 6-deoxo-28-norcathasterone, 6-deoxo-28-norteasterone, 3-dehydro-6-deoxo-28-norteasterone, 6-deoxo-28-nortyphasterol and 6-deoxo-28-norcastasterone have been isolated and identified by GC–MS. The identified brassinosteroids and their derivatives are active constituents of late C-6 oxidation pathway, thereby suggesting the biosynthesis of brassinosteroids in tea seeds by late C-6 oxidation pathway.     

Biosynthesis of a cholesterol-derived brassinosteroid, 28-norcastasterone, in Arabidopsis thaliana

A metabolic study revealed that 28-norcastasterone in Arabidopsis is synthesized from cholesterol via the late C-6 oxidation pathway. On the other hand, the early C-6 oxidation pathway was found to be interrupted because cholestanol is converted to 6-oxocholestanol, but further metabolism to 28-norcathasterone was not observed. The 6-oxoBRs were found to have been produced from the respective 6-deoxoBRs administered to the enzyme solution, thus indicating that these 6-oxoBRs are supplied from the late C-6 oxidation pathway. Heterologously expressed CYP85A1 and CYP85A2 in yeast catalysed this C-6 oxidation, with CYP85A2 being much more efficient than CYP85A1. Abnormal growth of det2 and dwf4 was restored via the application of 28-norcastasterone and closer precursors. Furthermore, det2 and dwf4 could not convert cholesterol to cholestanol and cholestanol to 6-deoxo-28-norcathasterone, respectively. It is, therefore, most likely that the same enzyme system is operant in the synthesis of both 28-norcastasterone and castasterone. In the presence of S-adenosyl-L-methionine, the cell-free enzyme extract catalysed the C-24 methylation of 28-norcastasterone to castasterone, although the conversion rates of 28-norteasterone to teasterone and 28-nortyphasterol to typhasterol were much lower; this suggests that 28-norcastasterone is the primary precursor for the generation of C(28)-BRs from C(27)-BRs.     

Novel biosynthetic pathway of castasterone from cholesterol in tomato

Endogenous brassinosteroids (BRs) in tomato (Lycopersicon esculentum) seedlings are known to be composed of C27- and C28-BRs. The biosynthetic pathways of C27-BRs were examined using a cell-free enzyme solution prepared from tomato seedlings that yielded the biosynthetic sequences cholesterol --> cholestanol and 6-deoxo-28-norteasterone <--> 6-deoxo-28-nor-3-dehydroteasterone <--> 6-deoxo-28-nortyphasterol --> 6-deoxo-28-norcastasterone --> 28-norcastasterone (28-norCS). Arabidopsis CYP85A1 that was heterologously expressed in yeast mediated the conversion of 6-deoxo-28-norCS to 28-norCS. The same reaction was catalyzed by an enzyme solution from wild-type tomato but not by an extract derived from a tomato dwarf mutant with a defect in CYP85. Furthermore, exogenously applied 28-norCS restored the abnormal growth of the dwarf mutant. These findings indicate that the C-6 oxidation of 6-deoxo-28-norCS to 28-norCS in tomato seedlings is catalyzed by CYP85, just as in the conversion of 6-deoxoCS to CS. Additionally, the cell-free solution also catalyzed the C-24 methylation of 28-norCS to CS in the presence of NADPH and S-adenosylmethionine (SAM), a reaction that was clearly retarded in the absence of NADPH and SAM. Thus it seems that C27-BRs, in addition to C28-BRs, are important in the production of more active C28-BRs and CS, where a SAM-dependent sterol methyltransferase appears to biosynthetically connect C27-BRs to C28-BRs. Moreover, the tomato cell-free solution converted CS to 26-norCS and [2H6]CS to [2H3]28-norCS, suggesting that C-28 demethylation is an artifact due to an isotope effect. Although previous feeding experiments employing [2H6]CS suggested that 28-norCS was synthesized from CS in certain plant species, this is not supported in planta. Altogether, this study demonstrated for the first time, to our knowledge, that 28-norCS is not synthesized from CS but from cholesterol. In addition, CS and [2H6]CS were not converted into BL and [2H6]BL, respectively, confirming an earlier finding that the active BR in tomato seedlings is not BL but CS. In conclusion, the biosynthesis of 28-norBRs appears to play a physiologically important role in maintaining homeostatic levels of CS in tomato seedlings.     

Accumulation of 6-deoxocathasterone and 6-deoxocastasterone in Arabidopsis, pea and tomato is suggestive of common rate-limiting steps in brassinosteroid biosynthesis

To gain a better understanding of brassinosteroid biosynthesis, the levels of brassinosteroids and sterols related to brassinolide biosynthesis in Arabidopsis, pea, and tomato plants were quantified by gas chromatography-selected ion monitoring. In these plants, the late C-6 oxidation pathway was found to be the predominant pathway in the synthesis of castasterone. Furthermore, all these plant species had similar BR profiles, suggesting the presence of common biosynthetic control mechanisms. The especially high levels of 6-deoxocathasterone and 6-deoxocastasterone may indicate that their respective conversions to 6-deoxoteasterone and castasterone are regulated in planta and hence are important rate-limiting steps in brassinosteroid biosynthesis. Other possible rate-limiting reactions, including the conversion of campestanol to 6-deoxocathasteonre. are also discussed. Tomato differs from Arabidopsis and pea in that tomato contains 28-norcastasterone as a biologically active brassinosteroid, and that its putative precursors, cholesterol and its relatives are the major sterols.     

Synthesis and biological activity of 26-norbrassinolide, 26-norcastasterone and 26-nor-6-deoxocastasterone

26-Norbrassinolide, identified as a metabolite of brassinolide in cultured cells of the liverwort, Marchantia polymorpha, as well as 26-norcastasterone and 26-nor-6-deoxocastasterone were synthesized. Synthesis of these new brassinosteroids was conducted by employing the orthoester Claisen rearrangement and asymmetric dihydroxylation as key reactions. The modified rice lamina inclination test indicated that these three 26-norbrassinosteroids were less active than their corresponding C28 brassinosteroids. Growth-promoting activities were also examined by using the brassinosteroid-deficient, dwarf mutant lkb of garden pea (Pisum sativum L.). In this assay, 26-norbrassinolide was as effective as brassinolide and 26-norcastasterone was more effective than castasterone although 26-nor-6-deoxocastasterone was much less effective than 6-deoxocastasterone. Therefore, removal of C-26 of brassinosteroids does not necessarily reduce the biological activity. The role of C-26 removal in Marchantia cells remains unclear.     

Identification of Brassinosteroids That Appear to Be Derived from Campesterol and Cholesterol in Tomato Shoots

To obtain information about the biosynthesis of brassinosteroids(BRs) in tomato shoots, we examined endogenous BRs by gas chromatography-massspectrometry. We identified two C²⁸ BRs, namely, castasteroneand 6-deoxocastasterone, and a C²⁷ BR, 28-norcastasterone. Ourfindings suggest that the major BRs in tomato are derived fromcampesterol and cholesterol. ⁴Present address: National Research Institute of Vegetables,Ornamental Plants and Tea, 360 Kusawa, Ano, Mie, 514-23 Japan.     

28-Norcastasterone is biosynthesized from castasterone

Metabolic experiments with deuterium-labeled castasterone in seedlings of Arabidopsis thaliana, Oryza saliva and Lycopersicon esculentum, and cultured cells of Catharanthus roseus were performed, and the metabolites were analyzed by GC-MS. In all the plant species examined, [2H3]28-norcastasterone was identified as a metabolite of [26,28-2H6]castasterone, indicating that castasterone is the biosynthetic origin of 28-norcastasterone. Moreover, the natural occurrence of 28-norcastasterone and 28-nortyphasterol in seedlings of A. thaliana has been demonstrated. This is the first report of the natural occurrence of 28-nortyphasterol in plants.     

Endogenous level of 28-Norcastasterone is strictly regulated in Plant Cells

A cell-free enzyme solution prepared from cultured cells ofPhaseolus vulgaris mediated C-24 methylation of 28-nor-castasterone to castasterone with the aid of S-adenosylmethionine as a co-substrate in the presence of the NADPH cofactor. This enzyme solution also catalyzed conversion of 28-norcastasterone to a demethylated 28-norcastasterone, most likely 26,28-didemethyl-castasterone, when S-adenosylmethionine was not added to the enzyme solution. Furthermore, gene expression ofArabidopsis CYP85A1 andCYP85A2 mediating the conversion of 6-deoxo-28-norcastast-erone to 28-norcastasterone was strongly inhibited by treatment of 28-norcastasterone. These results suggest that 28-norcastasterone, along with castasterone and brassinolide, is an important brassinosteroid whose endogenous level should be strictly controlled to express brassinosteroid activities in plants.     

Test-systems for immunoenzymatic determination of 6-deoxobrassinosteroids

26-Hydroxyderivatives of 6-deoxo-24-epicastasterone and 6-deoxo-28-norcastasterone were synthesized for preparation of the corresponding haptens and conjugates with horseradish peroxidase and bovine serum albumin. These preparations were further applied to a production of antisera. Test-systems for the enzyme immunoassay of phytohormones of the 6-deoxobrassinosteroid group were elaborated.     

Synthesis and bioactivity of natural and C-3 fluorinated biosynthetic precursors of 28-homobrassinolide.

In this paper we describe the synthesis of two new fluorinated brassinosteroids: (22R,23R)-22,23-dihydroxy-3alpha-fluorostigmastan-6-one and (22R,23R)-22,23-dihydroxy-3beta-fluorostigmastan-6-one. Their bioactivities were evaluated in the rice lamina inclination test and compared with that of 28-homocastasterone, 28-homotyphasterol and 28-homoteasterone, possible biosynthetic precursors of 28-homobrassinolide. Results confirmed expected similarities between the biosynthesis of 24-ethylbrassinosteroids (named as the 28-homo series) and that described for 24-methylbrassinosteroids, and also indicated that these precursors might exhibit per se activities.     

Brassinosteroids are inherently biosynthesized in the primary roots of maize, Zea mays L

GC-MS analysis revealed that primary roots of maize contain 6-deoxocathasterone, 6-deoxoteasterone and 6-deoxotyphasterol. These brassinosteroids, and the previously identified campesterol, campestanol, 6-deoxocastasterone and castasterone, in the roots are members of a biosynthetic pathway to castasterone, namely the late C-6 oxidation pathway, suggesting that its biosynthetic pathway is operative in the roots. To verify this, a cell-free enzyme extract was prepared from maize roots, and enzymatic conversions from campesterol to castasterone through the aforementioned sterols and brassinosteroids were examined. The presence for the biosynthetic sequences, campesterol-->24-methylcholest-4-en-3beta-ol-->24-methylcholest-4-en-3-one-->24-methylcholest-5 alpha-cholestan-3-one-->campestanol and 6-deoxoteasterone-->6-deoxo-3-dehydroteasterone-->6-deoxotyphasterol-->6-deoxocastasterone-->castasterone were demonstrated. These results indicate that maize roots contain a complete set of enzymes involved in the late C-6 oxidation pathway, thereby demonstrating that endogenous brassinosteroids are biosynthesized in the roots.     

Regulation of castasterone level in primary roots of maize, Zea mays

Gas chromatography–mass spectrometry analysis revealed that primary roots of maize contain 28-norcastasterone (28-norCS) and its biosynthetic precursors, cholesterol, and cholestanol, which suggests that the C₂₇-brassinosteroid (C₂₇-BR) biosynthetic pathway to generate 28-norCS is operative in the roots. A cell-free enzyme solution prepared from maize roots successfully mediated C24-methylation of 28-norCS to produce castasterone (CS) with the aid of S-adenosyl- l -methionine, which indicates that CS can be generated through C₂₇-BR biosynthesis, as well as C₂₈-BR biosynthesis, in maize roots. Enzymatic conversion study using the cell-free enzyme solution demonstrated that CS is converted into 26-norCS in the enzyme solution. Exogenously applied 28-norCS and 26-norCS showed less activity than CS in the activation of gravitropic curvature and inhibition of root elongation. Taken together, a steady-state level of CS, the active BR in maize roots, seems to be strictly controlled by complicated processes such as C₂₈- and C₂₇-BR biosynthesis and biodegradation by C26-demethylation to exert its biological activity.     

Antitumor studies. Part 1: design, synthesis, antitumor activity, and AutoDock study of 2-deoxo-2-phenyl-5-deazaflavins and 2-deoxo-2-phenylflavin-5-oxides as a new class of antitumor agents

Novel 2-deoxo-2-phenyl-5-deazaflavins and 2-deoxo-2-phenylflavin-5-oxides were prepared as a new class of antitumor agents and showed significant antitumor activities against NCI-H 460, HCT 116, A 431, CCRF-HSB-2, andKB cell lines. In vivo investigation, 2-deoxo-10-methyl-2-phenyl-5-deazaflavin exhibited the effective antitumor activity against A 431 human adenocarcinoma cells transplanted subcutaneously into nude mouse. Furthermore, AutoDock study has been done by binding of the flavin analogs into PTK pp60(c-src), where a good correlation between their IC(50) and AutoDock binding free energy was exhibited. In particular, 2-deoxo-2-phenylflavin-5-oxides exhibited the highest potential binding affinity within the binding pocket of PTK.     

Castasterone Can be Biosynthesized from 28-homodolichosterone in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

We recently demonstrated the biosynthesis of 24-ethylidene brassinosteroids in Arabidopsis thaliana. To determine the physiological role of biosynthesis of 24-ethylidene brassinosteroids, metabolism of 28-homodolichosterone as the end product of 24-ethylidene brassinosteroids biosynthesis was examined by a crude enzyme solution prepared from A. thaliana. In wild-type plants, dolichosterone and castasterone were identified as enzyme products on GC-MS analysis. In a mutant where DWARF1 was overexpressed (35S-DWF1), the conversion rate of 28-homodolichosterone to castasterone was significantly increased. These results indicate that conversion of 28-homodolichosterone to castasterone is mediated by dolichosterone in Arabidopsis. In the root growth assay, inhibitory activity was enhanced in the order of castasterone > dolichosterone > 28-homodolichosterone, demonstrating that conversion of 28-homodolichosterone to castasterone via dolichosterone is a biosynthetic reaction that increases BR activity in Arabidopsis. Compared to Arabidopsis grown under dark conditions, light-grown Arabidopsis showed up-regulated DWARF1 expression, resulting in an increased conversion rate of 28-homodolichosterone to castasterone, suggesting that light is an important regulatory factor for the biosynthetic connection of 24-ethylidene brassinosteroids and 24-methyl brassinosteroids in A. thaliana. Consequently, 24-ethylidene brassinosteroids biosynthesis to generate 28-homodolichosterone is a lightregulated alternative route for synthesis of the biologically-active BRs, castasterone and brassinolide in Arabidopsis plants.     

Synthesis, characterization and reactions of 2-deoxo-5-deazaalloxazines

5-Deazaflavins and their homologues have been known as potential riboflavin antagonists, bioreductives, and compounds with potent antitumor activity. 2-Amino-4-methylquinoline-3-carbonitrile (2) was prepared as unreported starting material for several interesting 2-deoxo-5-deazalloxazine derivatives. Cyclization of 2 using formamide afforded the 2,4-deoxo-5-deazaalloxazine derivative 7, which was subjected to deamination with nitrous acid to give the 2-deoxo-5-deazaalloxazine (8). The compound 8 was also obtained via 13 by treating the latter with refluxing formic acid or formamide and used as a precursor for synthesis of several 2-deoxo-5-deazaalloxazines 18, 19, 20, 21 and 22. The pharmacological and biological properties of these compounds are still under investigation.     

Identification of Castasterone, 6-Deoxocastasterone, Typhasterol and 6-Deoxotyphasterol from the Shoots of Arabidopsis thaliana

Endogenous brassinosteroids in the shoots of Arabidopsis thalianawere investigated. Castasterone, 6-deoxocastasterone, typhasteroland 6-deoxotyphasterol were identified by GC-MS. The co-occurrenceof 6-deoxo-brassinosteroids and 6-oxo-brassinosteroids suggeststhat there are both early and late C6-oxidation pathways ofbrassinosteroids in A. thaliana. (Received September 17, 1996; Accepted October 11, 1996)     

Quantitative determination of 9-deoxo-16,16-dimethyl-9-methylene-PGE2 in human plasma by GC-MS,RIA and HPLC

Comparisons were made of 9-deoxo-16,16-dimethyl-9-methylene-PGE₂ levels in plasma determined by three assay methods. Plasma samples from Rhesus monkeys treated with 200 μg/kg 9-deoxo-16,16-dimethyl-9-methylene-PGE₂ intravenously were analyzed by radioimmunoassay (RIA) and by high pressure liquid chromatography (HPLC). In a second experiment known amounts of 11β-³H-9-deoxo-16,16-dimethyl-9-methylene-PGE₂ were added to human plasma at several concentration levels. The samples were analyzed by RIA, HPLC and gas chromatography-mass spectrometry (GC-MS). A limited number of comparisons have been made between RIA and GC-MS analysis of plasma samples from human subjects treated with 9-deoxo-16, 16-dimethyl-9-methylene-PGE₂. The results indicated that the three assay methods generally give comparable estimations of 9-deoxo-16,16-dimethyl-9-methylene-PGE₂ content in plasma.     

Brassinolide and [26, 28-2H6]brassinolide are differently demethylated by loss of C-26 and C-28, respectively, in Marchantia polymorpha

Metabolism of brassinolide in Marchantia polymorpha was investigated by use of in vivo suspension cultured cells. GC-MS analysis of metabolites derived from non-labelled brassinolide and [26, 28-2H6] brassinolide revealed that brassinolide was converted to 26-norbrassinolide while [26, 28-2H6]brassinolide to [26-2H3]28-norbrassinolide. It seems that Marchantia cells recognized [26, 28-2H6]brassinolide as a xenobiotic rather than brassinolide and deteriums attached to C-28 significantly affect demethylation reaction due to isotopic effect. Thus, demethylation of brassinolide in planta seems to proceed by loss of C-26 rather than C-28. The present finding is the first evidence for demethylation metabolism of brassinosteroids. The biological activity of 26-norbrassinolide was 10-fold reduced as shown by the rice lamina inclination test. However, because of its high biological activity, it remains difficult to conclude whether or not C-26 demethylation serves as an important deactivation process of brassinolide.     

Metabolic changes in fruits of the tomato dx mutant

The tomato DWARF cytochrome P450 protein catalyzes the C-6 oxidation of 6-deoxo-castasterone to castasterone. The d(x) mutant does not produce a functional DWARF enzyme, and d(x) shoots display severe symptoms of brassinosteroid-deficiency. However, fruits express the CYP85A3 protein which compensates for the deficiency of the DWARF protein and produce bioactive brassinosteroids. Here, we report on the metabolic characterization of d(x) fruits. Fruit size, fresh weight, and pigment content were not altered. However, d(x) fruits showed reduced dry mass content. Levels of starch and various sugars were reduced, amino acid levels were elevated. BR application to d(x) leaves partially normalized dry mass content, sugar and amino acid levels in d(x) fruits. The data demonstrate that brassinosteroid in shoots is required for fruit development in tomato.     

Isolation and Characterization of Brassinosteroids from Leaves of Camellia sinensis (L.) O. Kuntze

Brassinosteroids are of ubiquitous occurrence in plants and elicit a wide spectrum of physiological responses. In our study, brassinosteroids were isolated and identified in topmost dormant leaves of tea plants. Six brassinosteriods, i.e. 6-deoxocastasterone, 24-epibrassinolide,3-dehydroteasterone, typhasterol, 3-deoxotyphasterol and 28-homodolicholide, were isolated and identified by GC–MS. All the brassinosteroids identified belong to important components of early and late C6 oxidation pathways proposed for brassinosteroids biosynthesis in plants. It suggests that both pathways are operating in tea to produce brassinolide, the most active brassinosteroid biologically.