Studies on Abscisic Acid

Methyl α-ionylideneacetates were oxidized with selenium dioxide to a mixture of methyl 3′-keto-β-ionylideneacetates and a small amount of methyl 4′-keto-α-ionylidene-acetates followed by treatment with active manganese dioxide. By a similar oxidation methyl 3′-keto-β-ionylideneacetates were prepared from methyl β-ionylidene acetates. Methyl 4′-keto-α-ionylideneacetates were obtained by oxidation of methyl α-ionylideneacetates with tert-butyl chromate. Dehydrobromination of methyl bromoionylideneacetate, obtained by bromination of methyl 2-trans-α-ionylideneacetate with N-bromosuccinimide, gave a mixture of methyl 2-trans-dehydro-β-ionylideneacetate and methyl 2-cis-dehydro-β-ionylideneacetate. The growth inhibitory activities of these sesquiterpene carboxylic acids and keto esters on rice seedlings were tested.     

Synthesis of Analogs of Optically Active α-Ionylideneacetic Acid

The Wittig reaction of (?)-α-ionone (VIa) with carbethoxymethylenetriphenylphosphorane afforded (?)-ethyl α-ionylideneacetate (VIIa). tert-Butyl chromate oxidation of the above ester (VIIa) gave (?)-ethyl 4′-keto-α-ionylideneacetate (VIlla). Selenium dioxide oxidation of (?)-α-ionone (IVa) in ethanol afforded (?)-1′-hydroxy-α-ionone (X), which reacted with car-bethoxymethylenetriphenylphosphorane to give (?)-ethyl 1′-hydroxy-α-ionylideneacetate (XI). tert-Butyl chromate oxidation of the hydroxy-ester (XI) gave (?)-ethyl abscisate (XII) and ethyl 3′-keto-β-ionylideneacetate (XIII). The sensitized photooxidation of ethyl dehydro-β-ionylideneacetate (XVI) using chlorophyll was attempted.     

Studies on Abscisic Acid

Oxidation of methvl 2-trans-β-ionylideneacetate with X-bromosuccinimide afforded methyl 2-cis and trans-3′-hydroxy-β-ionylideneacetates. NaBH₄ reduction of methyl 2-cis-3′-keto-β-ionylideneacetate and ethyl 4′-keto-α-ionylideneacetate gave methyl 2-cis-3′-hydroxy-β-ionylideneacetate and ethyl 4′-hydroxy-α-ionyiideneacetate respectively. Further, methyl 4′-methoxy-epoxy-α-ionylideneacetate was prepared by epoxidation of methyl 4′-methoxy-α-ionylideneacetate. And then methyl 4′-hydroxy-l′, 2′-dihydro-β-ionylideneacetate was synthesized from ethyl 4-keto-α-cyclogeranate. Growth inhibitory activities of the above compounds on rich seedlings were examined.     

Synthesis and Biological Activity of Methyl 3-Demethyl-Abscisate and Its Related Analogs

To elucidate the role of the methyl substituent on the side chain of abscisic acid (ABA), we synthesized (2Z,4E)-3-demethyl-α-ionylideneacetic acid (4) and its related analogs, methyl (2Z)-3-demethyl-β-ionylideneacetate 1′,2′-epoxide (9) and methyl (2Z) and (2E)-3-demethyl-abscisate (12) and (13). The biological assay of these compounds suggested that the 3-methyl group on the side chain of ABA was indispensable to biological activity.     

Studies on Abscisic Acid

Methyl α-cyclocitrylideneacetate was successively oxidized with selenium dioxide and chromium trioxide-pyridine complex to give methyl 1′-hydroxy-α-cyclocitrylideneacetate and a mixture of methyl 3′-keto-β-cyclocitrylideneacetate and methyl 4′-keto-α-cyclocitrylideneacetate. Further, oxidation of methyl α-cyclocitrylideneacetate with tert-butyl chromate afforded methyl 4′-keto-α-cyclocitrylideneacetate and methyl 1′-hydroxy-4′-keto-α-cyclocitry-lineacetate. Similarly, methyl α-cyclogeranate was oxidized to methyl 3-keto-β-cyclogeranate and methyl 4-keto-α-cyclogeranate. Methyl l′-hydroxy-4′-keto-α-cyclocitrylideneacetate, methyl l-hydroxy-4-keto-α-cyclogeranate and their related compounds did not show growth inhibitory activities on rice seedlings.     

Antinociceptive Activity of Compounds from the Aqueous Extract of Melampodium divaricatum

A decoction prepared from the aerial parts of Melampodium divaricatum showed antinociceptive and antihyperalgesic responses when tested in the formalin model in mice. From the CH₂Cl₂ fraction of the decoction, two non-previously reported secondary metabolites, 3-O-β-D-glucopyranosyl-16α-hydroxy-ent-kaurane ( 1 ) and melampodiamide ( 2 ) [(2′R*,4′Z)-2′-hydroxy-N-[(2S*,3S*,4R*)-1,3,4-trihydroxyoctadec-2-yl]tetracos-4-enamide] were separated and characterized by spectroscopic, spectrometric, and computational techniques. The flavonoids isoquercitrin and hyperoside, which possessed noted antinociceptive properties, were obtained from the active AcOEt fraction of the decoction. The chemical composition of the essential oil of the plant was also analyzed by gas chromatography-mass spectrometry. The major constituents were (E)-caryophyllene, germacrene D, β-elemene, δ-elemene, γ-patchoulene, and 7-epi-α-selinene. Headspace solid-phase microextraction analysis detected (E)-caryophyllene as the main volatile compound of the plant.     

Acid-catalysed Reactions of Methyl β-(3,4-Dimethoxyphenyl) glycidate

Methyl trans-β-(3,4-dimethoxyphenyl)glycidate was found to rearrange to methyl 3,4-dimethoxyphenylpyruvate in high yield in DMSO, DMF or HMPT solution in the presence of boron trifluoride etherate or sulfuric acid at room temperature. It was also revealed that the glycidate, when treated with boron trifluoride in methanol at room temperature, opened at the β-position to give methyl β-(3,4-dimethoxyphenyl)-α-hydroxy-β-methoxy-propionate in 94% yield, which was a mixture of erythro and threo isomers in the ratio of 1 to 2.     

Studies on Abscisic Acid

Oxidation of 2-cis-α-ionylidene-ethanol (II) with active MnO₂ afforded a mixture of 2-cis and 2-trans-α-ionylideneacetaldehydes (III and IV). Reduction of methyl epoxy-α- and -β-ionylideneacetates (Vb, Xb XXIb and XXIIb) with LiAlH₄ gave the diols (VI, XI, XXIII and XXIV). The Wittig reaction of the hydroxyketones (XIII and XVIII) with carbethoxymethylenetriphenylphosphorane, followed by alkaline hydrolysis, yielded 5-(1′-and 2′-hydroxy-2′,6′,6′-trimethyl-1′-cyclohexyl)-3-methylpentadienoic acids (XIVa, XVa, XIXa and XXa). The reaction of α-cyclocitrylideneacetaldehyde (XXVII) and dihydro-α-ionone (XXXIII) with carbethoxymethylenetriphenylphosphorane afforded ethyl 3-demethyl-α-ionyli-deneacetate (XXVIIIb) and ethyl dihydro-α-ionylideneacetates (XXXIVb and XXXVb). Physiological activities of the above synthesized compounds on rice seedlings were examined.     

Geometrical Isomers of Monohydroperoxides Formed by Autoxidation of Methyl Linoleate

Isomeric monohydroperoxides produced from autoxidized methyl linoleate were separated into two geometrical isomers (cis-trans and trans-trans) by silver nitrate TLC. Purified monohydroperoxides were converted into hydroxy octadecadienoates. Trimethylsilyl (TMS) derivatives of these compounds (four components) were separated into three peaks in the gas chromatogram; the mixture of 9-hydroxy-cis,trans-isomer and 13-hydroxy-cis,trans-isomer, 9-hydroxy-trans,trans-isomer and 13-hydroxy-trans,trans-isomer. The trans-trans isomers became more dominant than the cis-trans isomers in the later stage of autoxidation and with the rise of temperature. At the degradation of monohydroperoxides, the decrease of trans- trans isomers was apparently slower than that of cis-trans isomers. It is proposed that cis,trans isomerization of monohydroperoxides takes place at the process of autoxidation of methyl linoleate.     

Synthesis and Biological Properties of 2-Amino-3-fluoro-2,3-Dideoxy-D-Pentofuranosides of Natural Heterocyclic Bases

Abstract

The oxidation of methyl 5–0-benzyl-3-deoxy-3-fluoro-α-D-arabi-nofuranoside (1) with DMSO/Ac₂o afforded a ～ 2:1 mixture of 2-keto derivatives with erythro and threo configuration resulting from isomerization at C3. Successive treatment of the above mixture with MeONH₂, LiA1H₄, and S-ethyl trifluoroacetate followed by silica gel chromatography afforded methyl 5–0-benzyl-2, 3-dideoxy-3-fluoro-2-(trifluoroacetamido)-α-D-ribofuranoside (6b) and its lyxo isomer 7b in a total yield of 25% and 5%, respectively. The arabino analogue 25 was prepared from 6b. Compounds 6b, 7b and 25 were converted to the corresponding 5–0-benzoyl derivatives 8a, 9 and 26. A series of 2′-amino-2′, 3′-dideoxy-3′-fluoro-β-D-ribo- and-α-D-lyxofuranosides of natural heterocyclic bases have been synthesized starting from 8a and 9. None of the test compounds had any antiviral activity. 3′-Fluoro-2′-amino-2′, 3′-dideoxycytidine (16) was the only compound showing inhibition of murine L1210 and human Molt/4F cell proliferation (50% effective concentration: 39–42μg/m1).     

Chemical and Biological O-Demethylation of Rotenone Derivatives

3-O-Demethyl and 2,3-O,O-didemethyl derivatives of natural rotenone (5′β-rotenone), 5′α-rotenone, d-epirotenone (5′β-epirotenone) and 5′α-epirotenone are obtained upon reacting 5′β-rotenone or 5′β-epirotenone with two or three molar equivalents of boron tribromide followed by recyclization of the E-ring using sodium bicarbonate. 3-Methoxy-¹⁴C-5′β-rotenone is prepared in 16% yield by treating 3-O-demethyl-5′β-rotenone with methyl-¹⁴C iodide in the presence of alkali followed by epimerization of the ¹⁴C-5′β-epirotenone byproduct for increased yield of ¹⁴C-5′β-rotenone. 3-O-Demethylation is established as a detoxification mechanism for 5′β-rotenone or for one of its metabolites based on the expiration by mice and rats of 27% and 13%, respectively, of the administered radiocarbon as ¹⁴carbon dioxide.     

Pyromeconic Acid and Its Glucosidic Derivatives from Leaves of Erigeron annuus,and the Siderophile Activity of Pyromeconic Acid

3′-O-Caffeylerigeroside (pyromeconic acid 3-O-β-D-glucoside 3′-O-caffeyl ester) was obtained from the leaves of Erigeron annuus as a new pyromeconic acid derivative, and its structure was elucidated. Together with the γ-pyrone derivative, pyromeconic acid (3-hydroxy-4H-pyran-4-one) and its β-glucoside (erigeroside) were also isolated from the aerial parts of E. annuus. The siderophile activity of pyromeconic acid was also studied.     

New Amides from Buckwheat Seeds (Fagopyrum esculentum Moench)

Two new amino acid amides which yield in acid hydrolysis isomeric hydroxybenzylamines and amino acids have been isolated from the achenes of Fagopyrum esculentum Moench. One of them called BN-II is composed of salicylamine and allo-4-hydroxy-l-glutamic acid, and the other, BN-III, p-hydroxybenzylamine and l-glutamic acid. These coupled compounds link one another to form an amide respectively. Finally the structures of BN-II and BN-III were determined to be N⁵-(2′-hydroxybenzyl)-allo-4-hydroxy-l-glutamine and N⁵-(4′-hydroxybenzyl)-l-glutamine respectively from their chemical and spectrometry properties.     

Synthesis of 3′,4′-C-Bishydroxymethyl-2′,3′,4′-trideoxy-β-L-threo-pentopyranosyl Nucleosides as Potential Inhibitors of HIV

Abstract

The synthesis of 3′,4′-bishydroxymethyl-2′,3′,4′-trideoxy pentopyranosyl derivatives of thymine, uracil, cytosine, and adenine is described. trans-(3S,4S)-Bis(methoxycarbonyl)cyclopentanone (3) was converted to 1-O-acetyl-3,4-C-bis[(tert-butyldiphenylsiloxy)methyl]-2,3,4-trideoxy-α,β-L-threo-pentopyranose (6), which was subsequently condensed with the silylated purine and pyrimidine bases.     

Ionylideneacetic Acids and Abscisic Acid Biosynthesis by Cercospora rosicola

Several compounds having the basic α-ionylideneacetic acid structure were tested in Cercospora rosicola resuspensions. At 100 μm, all the compounds inhibited abscisic acid (ABA) biosynthesis. Time studies with unlabelled and deuterated (2Z,4E)- and (2E,4E)-α-ionylideneacetic acids showed rapid conversions into both (2Z,4E)- and (2E,4E)-4′-keto-α-ionylideneacetic acids as major products. Incorporation of the label into ABA was specific for the 2Z,4E-isomer. Minor products, identified by GC-MS, were (2Z,4E)- and (2E,4E)-4′-hydroxy-α-ionylideneacetic acids and (2Z,4E)-1′-hydroxy-α-ionylideneacetic acid. The conversion to (2Z,4E)-l′-hydroxy-α-ionylideneacetic acid has not been previously reported and was specific for the 2Z,4E-isomer. A time study for the conversion of methyl esters of [²H₃]-(2Z,4E)- and [²H₃]-(2E,4E)-4′-keto-α-ionylideneacetates showed a slow introduction of the l′-hydroxyl group and specificity for 2Z,4E-isomer. Conversion of the ethyl esters of (2Z,4E)- and (2E,4E)-l′-hydroxy-α-ionylideneacetates into the ethyl esters of both ABA and (2E,4E)-ABA demonstrated that ABA can be formed by oxidation of the 4′-position after the insertion of the 1′-hydroxy group. The ethyl 1′-hydroxy acids were also isomerized to the corresponding ethyl (2Z,4E)- and ethyl (2E,4E)-3′-hydroxy-β-ionylideneacetates. Ethyl (2Z,4E)-1′-hydroxy acid also gave small amounts of ethyl l′,4′-trans-diol of ABA. These results suggest that ABA may be formed through a (2Z,4E)-1′-hydroxy-α-ionylidene-type intermediate in addition to the previously proposed route through (2Z,4E)-4′-keto-α-ionylideneacetic acid.     

Synthesis and biological properties of α-thymidine 5′-aryl phosphonates

Diethyl(N-arylaminocarbonyl)methyl phosphonates have been obtained by the reaction of diethylphosphonoacetic acid imidazolides with methyl-4-aminobenzoate or 3,5-bis(trifluoromethyl)phenylamine. Their treatment with Me₃SiBr in DMF led to a mixture of the corresponding (N-arylaminocarbonylmethyl)phosphonic acids and their monoethyl esters. After separation, they were condensed with 3′-O-acetyl-α-thymidine, which, after the removal of the acetyl protecting group, gave (α-D-thymidine-5′-yl)-[4-aminocarbonyl-, methoxycarbonyl-, or carboxy)phenylaminocarbonyl]methyl phosphonates and (α-D-thymidine-5′-yl)-[3,5-bis(trifluoromethyl)phenylaminocarbonyl]methyl phosphonate and their ethyl esters. It was shown that the compounds are stable under different conditions, low toxic (in Vero and K-562 cell cultures), and capable of penetrating into K-562 cells. Only ethyl (α-D-thymidine-5′-yl)-[4-(methoxycarbonyl)phenylaminocarbonyl]methyl phosphonate at a high concentration (200 μg/mL) inhibited in vitro the growth of the laboratory strain M. tuberculosis H37Rv.     

Cassane diterpenoids from stem bark of Erythrophleum suaveolens [(Guill. et Perr.), Brenan]

Phytochemical investigation of the stem bark of Erythrophleum suaveolens yielded four new cassane diterpenoids; 6α-hydroxy-cassamic acid, methyl ester, 4β-carbomethoxy-14-methyltotarol, 6α-hydroxy-nor-cassamine, and 8,9-dehydro-nor-cassamine, along with four known cassane diterpenoids. All structures were elucidated on the basis of one- and two-dimensional NMR, HRMS and ESIMS analysis.     

Isolation of 6-hydroxy-L-tryptophan from the fruiting body of Lyophyllum decastes for use as a tyrosinase inhibitor

ABSTRACT

Tyrosinase is the key enzyme that controls melanin formation. We found that a hot water extract of the lyophilized fruiting body of the fungus Lyophyllum decastes inhibited tyrosinase from Agaricus bisporus. The extract was fractionated by ODS column chromatography, and an active compound was obtained by purification through successive preparative HPLC using an ODS and a HILIC column. Using spectroscopic data, the compound was identified to be an uncommon amino acid, 6-hydroxytryptophan. 6-Hydroxy-L-tryptophan and 6-hydroxy-D-tryptophan were prepared through a Fenton reaction from L-tryptophan and D-tryptophan, respectively. The active compound was determined to be 6-hydroxy-L-tryptophan by comparison of their circular dichroism spectra and retention time on HPLC analysis of the N^α-(5-fluoro-2,4-dinitrophenyl)-L-leuciamide derivative with those of 6-hydroxy-L-tryptophan and 6-hydroxy-D-tryptophan. A Lineweaver–Burk plot of the enzyme reaction in the presence of 6-hydroxy-L-tryptophan indicated that this compound was a competitive inhibitor. The IC₅₀ values of 6-hydroxy-L-tryptophan was 0.23 mM.     

Limonoids and Flavonoids from the Flowers of Azadirachta indica var. siamensis,and Their Melanogenesis‐Inhibitory and Cytotoxic Activities

A new limonoid, 7‐O‐acetyl‐7‐O‐debenzoyl‐22‐hydroxy‐21‐methoxylimocinin ( 2 ), and two new flavonoids, 3′‐(3‐hydroxy‐3‐methylbutyl)naringenin ( 7 ) and 4′‐O‐methyllespedezaflavanone C ( 9 ), along with nine known compounds, including two limonoids, 1 and 3 , and seven flavonoids, 4 – 6, 8 , and 10 – 12 , were isolated from a MeOH extract of the flowers of Azadirachta indica A.Juss. var. siamensis Valeton (Siamese neem tree; Meliaceae). The structures of new compounds were elucidated on the basis of extensive spectroscopic analysis and comparison with literature data. All of these compounds were evaluated for their melanogenesis‐inhibitory activities in B16 melanoma cells induced with α‐melanocyte‐stimulating hormone (α‐MSH). Compound 2 (16.9% melanin content at 30 μM ), 6‐deacetylnimbin ( 3 ; 49.6% melanin content at 100 μM ), and kaempferide ( 10 ; 41.7% melanin content at 10 μM ) exhibited inhibitory effects with no, or almost no, toxicity to the cells (81.0–111.7% cell viability). In addition, evaluation of their cytotoxic activities against HL60, A549, AZ521, and SK‐BR‐3 human cancer cell lines, isoazadironolide ( 1 ), 4′‐O‐methyl‐8‐prenylnaringenin ( 5 ), euchrestaflavanone A ( 8 ), 9 , and 3‐methoxy‐3′‐prenylnaringenin ( 12 ) revealed potent cytotoxicities against one or more cell lines with IC₅₀ values in the range of 4.5–9.9 μM .     

Syntheses of a Neobiosamine C Derivative and Its Analogs

Methyl 2,5-di-O-p-nitrobenzoyl-β-d-ribofuranoside was prepared via methyl 2,3-O-ethoxyethylidene-β-d-ribofuranoside from d-ribose. It was condensed with 3,4,6-tri-O-acetyl-2-deoxy-2-(2′,4′-dinitroanilino)-α-d-glucopyranosyl bromide and 3,4-di-O-acetyl-2,6-dideoxy-2-(2′,4′-dinitroanilino)-6-phthalimido-α-d-glucopyranosyl bromide by a modified Königs-Knorr reaction to give neobiosamine analogs. The condensation reaction gave α-glucosides as the minor product, and the corresponding β-glucoside as the major product.