Estimation of the Gelatinization Temperature of Noodles from Water Sorption Curves under Temperature-Programmed Heating Conditions

Both free and conjugated brassinosteroids (BRs) in the pollen and anthers of Erythronium japonicum Decne. were investigated. As a free form of BRs, typhasterol was identified by GC-MS. Polar conjugated BRs occurred only in the anther, and non-polar con-jugated BRs occurred both in the pollen and mainly in the anther.

BR parts of acid hydrolysis of the former were identified to be teasterone (major) and castasterone (minor). Those of alkaline hydrolysis of the latter were identified to be typhasterol (major) and teasterone (minor).     

Conformation of Peracetylated Cyclodextrins

Typical brassinosteroid activity was found in the alkaline hydrolysate of the n-hexane fraction of lily pollen. Two acyl conjugates of teasterone were purified from the n-hexane fraction by HPLC and analyzed by GC-MS and/or LC-MS, resulting in the identification of teasterone esters with lauric acid and myristic acid. Syntheses of the teasterone esters are also reported. The acyl conjugates of typhasterol, castasterone, and brassinolide did not occur in lily pollen. This is the first time that acyl conjugates have ever been discovered among naturally occurring brassinosteroids.     

Arabidopsis CYP85A2 Catalyzes Lactonization Reactions in the Biosynthesis of 2-Deoxy-7-oxalactone Brassinosteroids

Brassinolide (BL), a plant 7-oxalactone-type steroid hormone, is one of the active brassinosteroids (BRs) that regulates plant growth and development. BL is biosynthesized from castasterone by the cytochrome P450 monooxygenase, CYP85A2. We showed that a Pichia pastoris transformant that synchronously expresses Arabidopsis P450 reductase gene ATR1 and P450 gene CYP85A2 converts teasterone and typhasterol to 7-oxateasterone and 7-oxatyphasterol, respectively. Thus, CYP85A2 catalyzes the lactonization reactions of not only castasterone but also teasterone and typhasterol. The two 2-deoxy-7-oxalactone-type BRs were identified in Arabidopsis plants. Although the reversible conversion between 7-oxateasterone and 7-oxatyphasterol was observed in vivo, no conversion of 7-oxatyphasterol to BL was observed. The biological activity of 7-oxatyphasterol toward Arabidopsis hypocotyl elongation was nearly the same as that of castasterone. These results suggest that a new BR biosynthetic pathway, a BR lactonization pathway, functions in Arabidopsis and plays an important role in regulating the concentration of active BRs, even though the metabolism of 7-oxatyphasterol to BL is still unknown.     

Isolation and characterization of brassinosteroids from algal cultures of Chlorella vulgaris Beijerinck (Trebouxiophyceae)

The brassinosteroids (BRs) occur ubiquitously in the plant kingdom. The occurrence of BRs has been demonstrated in almost every part of higher plants, such as pollen, flower buds, fruits, seeds, vascular cambium, leaves, shoots and roots. In this study, BRs were isolated and identified in the culture of wild-type Chlorella vulgaris. Seven BRs, including teasterone, typhasterol, 6-deoxoteasterone, 6-deoxotyphasterol, 6-deoxocastasterone, castasterone and brassinolide, were identified by GC–MS. All compounds belong to the BR biosynthetic pathway. The results suggest that early and late C6 oxidation pathways are operating in C. vulgaris. This study represents the first isolation of BRs from C. vulgaris cultures.     

6-Deoxotyphasterol and 3-Dehydro-6-deoxoteasterone,Possible Precursors to Brassinosteroidsin the Pollen of Cupressus arizonica

Two new congeners (22R,23R,24S)-22,23-dihydroxy-24-methyl-5α-cholestan-3α-ol 2 and (22R,23R,24S)-22,23-dihydroxy-24-methyl-5α-cholestan-3-one 4 that are termed 6-deoxotyphasterol and 3-dehydro-6-eoxoteasterone, respectively, occur in relatively large amounts in the mature pollen of Cupressus arizonica. GC-MS, NMR spectroscopy, the reduction of 4 to 2, and the independent formation of 2 by the reduction of typhasterol were used to identify the new compounds. In the rice lamina bioassay, 2 showed weak activity. 6-Deoxocastasterone, castasterone, typha sterol, an epicastasterone-like compound, teasterone, 28-homocastasterone, 3-dehydroteasterone, brassinolide, and dolichosterone (or 24-epibrassinolide) were also present. These brassinosteroids were identified by co-chromatography with standards after being converted for an HPLC analysis of bioactive fractions. Six other peaks have not yet been assigned. 6-Deoxotyphasterol and 3-dehydro-6-deoxoteasterone should prove useful for exploring the early stages of the biosynthetic pathway(s) to brassinosteroids.     

Arabidopsis CYP85A2 catalyzes lactonization reactions in the biosynthesis of 2-deoxy-7-oxalactone brassinosteroids

Brassinolide (BL), a plant 7-oxalactone-type steroid hormone, is one of the active brassinosteroids (BRs) that regulates plant growth and development. BL is biosynthesized from castasterone by the cytochrome P450 monooxygenase, CYP85A2. We showed that a Pichia pastoris transformant that synchronously expresses Arabidopsis P450 reductase gene ATR1 and P450 gene CYP85A2 converts teasterone and typhasterol to 7-oxateasterone and 7-oxatyphasterol, respectively. Thus, CYP85A2 catalyzes the lactonization reactions of not only castasterone but also teasterone and typhasterol. The two 2-deoxy-7-oxalactone-type BRs were identified in Arabidopsis plants. Although the reversible conversion between 7-oxateasterone and 7-oxatyphasterol was observed in vivo, no conversion of 7-oxatyphasterol to BL was observed. The biological activity of 7-oxatyphasterol toward Arabidopsis hypocotyl elongation was nearly the same as that of castasterone. These results suggest that a new BR biosynthetic pathway, a BR lactonization pathway, functions in Arabidopsis and plays an important role in regulating the concentration of active BRs, even though the metabolism of 7-oxatyphasterol to BL is still unknown.     

Further Evidence for the Formation in vivo of Phosphopeptide in the Intestinal Lumen from Dietary β-Casein

The occurrence of a new brassinosteroid of (22S,24R)-3β,22-dihydroxy-5α-ergostan-6-one, named cathasterone, was demonstrated by a GC-MS analysis in cultured cells of Catharanthus roseus. Its endogenous level was in the range of 2–4 ng/g fw, similar to those of brassinolide and castasterone. A feeding experiment with a deuterium-labeled substrate revealed that cathasterone was converted to teasterone and typhasterol. This is the first report of the natural occurrence of cathasterone as a brassinosteroid being the biosynthetic precursor of teasterone.     

Blockage of Brassinosteroid Biosynthesis and Sensitivity Causes Dwarfism in Garden Pea

Endogenous brassinosteroids (BRs) in the dwarf mutants lka and lkb of garden pea (Pisum sativum L.) and comparable wild-type plants were quantified by gas chromatography-selected ion monitoring using deuterated internal standards. In young shoots of the lkb mutant, the levels of brassinolide, castasterone, and 6-deoxocastasterone were 23-, 22-, and 9-fold lower, respectively, than those of wild-type plants. Applications of brassinolide, castasterone, typhasterol, 3-dehydroteasterone, and teasterone normalized internode growth of lkb seedlings. These findings indicate that the lkb plants are BR-deficient mutants, probably as a consequence of a block in the BR biosynthetic pathway prior to the production of teasterone. Young shoots of lka plants contained only 50% less brassinolide and 5 times more castasterone than the equivalent wild-type tissues. The lka seedlings were approximately 100 times less responsive to brassinolide than the lkb mutant, and application of castasterone had only a marginal effect on lka internode growth, suggesting that the lka lesion results in impaired sensitivity to BR.     

In Vivo and in Vitro Conversion of Teasterone to Typhasterol in Cultured Cells of Marchantia polymorpha

Identification by full-scan GC-MS revealed that [²H₆]-teasteronefed to suspension cultured cells of Marchantia polymorpha wasconverted to [²H₆]3-dehydroteasterone and [²H₆]typhasterol.This indicates that the cells carry out a C3-epimerization inwhich teasterone is converted to typhasterol via 3-dehydroteasterone.In vitro enzymatic conversions of teasterone to typhasterolwere also investigated. A crude cytosolic solution preparedfrom Marchantia cells catalyzed not only the dehydrogenationof teasterone to 3-dehydroteasterone but also the reductionof 3-dehydroteasterone to typhasterol. The major 4-demethysterolin cultured M. polymorpha cells was 24-methylcholesterol, theprecursor of brassinosteroids. These results suggest that enzymessimilar to those involved in the early C-6 oxidation pathwayof the brassinosteroid biosynthesis are present in the liverwort. (Received March 19, 1999; Accepted June 28, 1999)     

2,3-Epoxybrassinosteroids are intermediates in the biosynthesis of castasterone in seedlings of Secale cereale

The involvement of the 2,3-epoxybrassinosteroids secasterone and 2,3-diepisecasterone in the biosynthesis of castasterone has been demonstrated in seedlings of Secale cereale by LC-ESI-MS. Deuterated secasterone, upon administration to rye seedlings, was incorporated into castasterone and its 2beta- and 3beta-epimers. Administration of deuterated 2,3-diepisecasterone resulted in castasterone and 2-epicastasterone. A biosynthetic subpathway from typhasterol/teasterone via 2,3-epoxybrassinosteroid intermediates to castasterone is discussed.     

Structure of Ovarian Asterosaponin-1 in the Starfish Asterias amurensis

Cultured crown gall cells of Catharanthus roseus Don (Vinca rosea L.) was found to contain brassinosteroids. These were identified as brassinolide and castasterone by GC/MS. This is the first conclusive identification of endogenous brassinosteroids in cultured cells.     

Biosynthesis and metabolism of brassinosteroids

Natural brassinosteroids so far identified from various plant species include biosynthetic congeners of brassinolide, such as cathasterone, teasterone, 3-dehydroteasterone, typhasterol and castasterone as well as another series of 6-deoxoteasterone, 3-dehydro-6-deoxoteasterone, 6-deoxotyphasterol and 6-deoxocastasterone. Using cell culture system of Catharanthus roseus , the outlines of biosynthetic pathways of brassinolide, via plant sterol of campesterol, have now been demonstrated. There are two pathways, named early C6-oxidation pathway and late C6-oxidation pathway, both of which would be operating in wide varieties of plants. Metabolic studies with various plant systems revealed multiple paths of metabolism such as hydroxylation, epimerization, side chain cleavage, reduction and conjugation with glucose and fatty acids. Recent progress of biosynthesis and metabolism of brassinosteroids is described.     

Biosynthesis of brassinolide from teasterone via typhasterol and castasterone in cultured cells of Catharanthus roseus

The biosynthesis of brassinolide (BL) in crown gall and nontransformed cells of Catharanthus roseus in which BL, castasterone (CS), typhasterol (TY), and teasterone (TE) are endogenous was investigated using deuterated TY and TE as substrates. The metabolites were analyzed by gas chromatography-mass spectrometry (GC-MS) and/or GC-selected ion monitoring (SIM). It was found that these cells converted TY to CS and BL, as well as TE to TY and CS. Because the pathway from CS to BL in the cells has already been confirmed, a biosynthetic sequence of TE TY CS BL was established. Reversible conversion between TE and TY was observed.Biosynthesis of brassinosteroids in Catharanthus roseus. Part III. Part II of this series: Suzuki et al. (1993).     

Biosynthesis of 2,3-epoxybrassinosteroids in seedlings of Secale cereale

Two new brassinosteroids, (22R,23R,24S)-22,23-dihydroxy-24-methyl-5alpha-cholest-2-en-6-one (secasterol) and (22R,23R,24S)-22,23-dihydroxy-2alpha,3alpha-epoxy-24-methyl-5alpha-cholest-6-one (2,3-diepisecasterone) have been identified together with a known 2,3-epoxybrassinosteroid, secasterone, in seedlings of Secale cereale. Deuterated secasterol, teasterone, and typhasterol, upon administration to rye seedlings, were incorporated into secasterone and 2,3-diepisecasterone, indicating a biosynthetic route via teasterone/typhasterol to secasterol to 2,3-epoxybrassinosteroids.     

Usefulness of Glucokinase from Bacillus stearothermophilus for the Enzymatic Measurement of Magnesium in Human Serum

(22R,23R,24S)-3α,5-Cyclo-22,23-diacetoxy-5a-ergostan-6-one (2b) is a new key intermediate of some naturally occurring brassinosteroids such as brassinolide (la), castasterone (lb), teasterone (lc) and typhasterol (Id). The cycloketone 2b was prepared in 10 steps via (22R,23R,24S)-6p- benzyloxy-3a,5-cyclo-22,23-dihydroxy-5a-ergostane (5) from stigmasterol. 2b was treated with a catalytic amount of /7-toluenesulfonic acid and sodium bromide to give an enone (7b), which was oxidized with osmium tetroxide and derived to give a 2a,3a-acetonide (8b). 8b was easily separated from its isomer by the use of silica gel column chromatography. 8b was oxidized with tri- fluoroperacetic acid and deacetylated to give la. 8b was deacetylated and deacetonized to give lb. 2b was treated with dilute sulfuric acid in acetic acid to give a 3/^-acetate (10). 10 was treated with sodium hydroxide to give lc. 2b was treated with hydrobromic acid to give a 3/i-bromide (12), which was treated with silver acetate to give a 3a-acetate (13). 13 was treated with sodium hydroxide to give Id.     

Biosynthetic pathways of brassinolide in Arabidopsis

Our previous studies on the endogenous brassinosteroids (BRs) in Arabidopsis have provided suggestive evidence for the operation of the early C6-oxidation and the late C6-oxidation pathways, leading to brassinolide (BL) in Arabidopsis. However, to date the in vivo operation of these pathways has not been fully confirmed in this species. This paper describes metabolic studies using deuterium-labeled BRs in wild-type and BR-insensitive mutant (bri1) seedlings to establish the intermediates of the biosynthetic pathway of BL in Arabidopsis. The first evidence for the conversion of campestanol to 6-deoxocathasterone and the conversion of 6-deoxocathasterone to 6-deoxoteasterone is provided. The later biosynthetic steps (6-deoxoteasterone --> 3-dehydro-6-deoxoteasterone --> 6-deoxotyphasterol --> 6-deoxocastasterone --> 6alpha-hydroxycastasterone --> castasterone --> BL) were demonstrated by stepwise metabolic experiments. Therefore, these studies complete the documentation of the late C6-oxidation pathway. The biosynthetic sequence involved in the early C6-oxidation pathway (teasterone --> 3-dehydroteasterone --> typhasterol --> castasterone --> BL) was also demonstrated. These results show that both the early and late C6-oxidation pathways are functional in Arabidopsis. In addition we report two new observations: the presence of a new branch in the pathway, C6 oxidation of 6-deoxotyphasterol to typhasterol, and increased metabolic flow in BR-insensitive mutants.     

Endogenous brassinosteroids in microalgae exposed to salt and low temperature stress

Brassinosteroids are part of the hormonal network that regulates growth processes and stress responses in plants. There is evidence for a similar hormonal network in microalgae. In the present study, six microalgae (Chlorococcum ellipsoideum, Gyoerffyana humicola, Nautococcus mamillatus, Acutodesmus acuminatus, Protococcus viridis and Chlorella vulgaris) were subjected to salt and low temperature stress with the addition of 36 g l^–1 NaCl and transfer from 25°C to 15°C. There was a rapid response to salt stress with the brassinosteroid content (mainly castasterone with lower amounts of brassinolide, homocastasterone and typhasterol) increasing within 30 min of the salt treatment and remaining at these elevated levels after 7 h. The decrease in temperature had little effect on the brassinosteroid content. This was the first study to show that endogenous brassinosteroids increase in response to abiotic stress in a number of microalgae species.     

Structure of Smith Degradation Resistant Moiety of Extracellular Glucomannan of Candida utilis

From immature seed of Phaseolus vulgaris, a new brassinosteroid, 6-deoxodihydrohomo- dolichosterone, as well as dolichosterone and brassinolide have been identified in addition to 6-deoxodihydrodolichosterone, 6-deoxodihydrocastasterone, castasterone and dolicholide which had already been reported therein. Extensive GC/MS analysis revealed that the number of brassinosteroids fully or partially characterized from the seed totals thirty, including unknown brassinosteroids.     

Ceramide in Rice Grain

A rice lamina inclination test that is simple and specific for brassinosteroids was used as a micro-quantitative bioassay for brassinolide 1 and its 6-keto congener, castasterone 2, in the concentration range of 5 x 10^–5 /ig/ml to 5 x 10^–3μg/ml, when uniform seedlings of the rice cultivars Arborio J-l and Nihonbare were selected. A phytohormone, indole-3-acetic acid (IAA), showed similar activity in this bioassay. Its lowest effective concentration, however, was 50 /ig/μl, about five orders of magnitude greater than that of brassinolide. Other phytohormones, abscisic acid (ABA) and the cytokinins kinetin and A⁶-benzyladenine, inhibited the lamina inclination of rice seedlings. The addition of a cytokinin reduced the promoting effect of brassinolide. Thus, the rice lamina inclination test can be used both as a micro-quantitative bioassay for brassinosteroids and as a method for detecting antibrassinolide compouds.     

Biosynthesis of brassinolide from castasterone in cultured cells of Catharanthus roseus

Feeding experiments with tritium- and deuterium-labeled castasterone (CS) were conducted with three cell lines of Catharanthus roseus, including crown gall cells and nontransformed cells. In all three cell lines, the conversion of CS to brassinolide (BL) was observed and unequivocally confirmed by gas chromatography/mass spectrometry (GC/MS). This is the first conclusive evidence that CS is the biosynthetic precursor of BL.Biosynthesis of brassinosteroids in Catharanthus roseus. Part II. Part I of this series: Yokota et al. (1990a).