Total Synthesis of dl-Deguelin

Starting with resorcinol, the total synthesis of dl-deguelin (VI) was accomplished. In the course of this investigation, dihydrodeguelic acid (II), dihydroisodeguelic acid (X), dihydro-dehydrodeguelin (III), dehydrodeguelin (IV), dl-deguelol (V) and dihydro-β-rotenonone (XI) were prepared. But the reduction of dihydrodehydrodeguelin (III) to dihydrodeguelin (XII) resulted in failure. The preparation of dihydrodeguelol (XIIIa), its acetate (XIIIb) and dihydro-desoxy-Δ¹¹-dehydrodeguelin (XIV) was also described.     

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.     

Aromatization of 9α-hydroxy-19-norandrostenedione by Arthrobacter simplex

9α-Hydroxy-19-norandrostenedionc (9α-hydroxy-Δ⁴-estrene 3, 17-dione) (IV) was prepared by fermentation of 19-norandroslenedione with Corynespora melanis or Norcardia restriclus. When incubated with a growing culture of Arthrobacter simplex or its acetone-dried cells, IV was converted to 9α-hydroxyestronc (VII) and 9-keto-9, 10-secoestrone (VI). 9α-Hydroxyestrone undergoes spontaneous as well as enzymic dehydration to form Δ⁹⁽¹¹⁾-estrone (IX). Both VI and IX have been isolated and identified as such while VII was isolated as its 3-acetate.     

Syntheses and Biological Activities of Analogs of Abscisic Acid

Selenium dioxide oxidation of methyl α-ionylideneacetate (IIb) in ethanol afforded methyl 1′-and 4′-hydroxy-α-ionylideneacetate (IIIb and IV), methyl 3′-hydroxy-β-ionylideneacetate (V) and crude dihydroxy-ionylideneacetate (VI). The latter was oxidized with active manganese dioxide to give methyl abscisate (Ib). The growth and germination-inhibitory activity of compounds related to abscisic acid on Azuki bean seedlings and some species of seeds were examined.     

Synthesis of β-Tubanol

Synthesis of β-tubanol (VIa) was achieved by the bromination of dihydro-β-tubanol acetate (VIIb) followed by dehydrobromination and the subsequent hydrolysis. 2,2-Dimethyl-5-hydroxy-chromanone as well as its derivatives (IV) and the corresponding chromanols (V) and chromans (VII) were also prepared.     

Studies on the Microbiological Transformation of Steroids

An attempt was made to clarify how Pellicularia filamentosa f. sp. microsclerotia IFO 6298 capable of hydroxylating C₂₁-steroids at the C-19 position converts C₁₉-steroids, especially monohydroxyderivatives of androst-4-ene-3, 17-dione. Such substrates as 11β-hydroxyandrost-4-ene-3,17-dione (I), androst-4-ene-3, 11, 17-trione (II), androsta-1,4-diene-3, 17-dione (III), 11β-hydroxyandrosta-1,4-diene-3,17-dione (IV), 14α-hydroxyandrost-4-ene-3, 17-dione (V), 15α-hydroxyandrost-4-ene-3, 17-dione (VI) and 9α-hydroxyandrost-4-ene-3, 17-dione (VII) were converted by the organism. All the main and several minor products were then isolated and identified. As a result it is concluded that this organism converts I and II into 14α-hydroxyandrost-4-ene-3,11,17-trione, III and IV into 14α-hydroxyandrosta-1,4-diene-3,1l,17-trione, V into 11α 14α dihydroxyandrost-4-ene-3, 17-dione (main) and 11β, 14α-dihydroxyandrost-4-ene-3, 17-dione (minor, a tentative structure), VI into 11β, 15α-dihydroxyandrost-4-ene-3,17-dione (main) and 15α-hydroxyandrost-4-ene-3,11,17-trione (minor, a tentative structure) and VII into 9α, 14α-dihydroxyandrost-4-ene-3, 17-dione (main) and 6β, 9α-dihydroxyandrost-4-ene-3,17-dione (minor).

In addition, the structural requirement of substrate for the 19-hydroxylation catalyzed by the organism and the influence of a hydroxyl group on steroid nucleus upon the 11β- and 14α-hydroxylations and the 11β-OH-dehydrogenation was discussed.     

Biotransformation of progesterone by suspension cultures of Digitalis purpurea cultured cells

It has been shown that the cultured cells of Digitalis purpruea are capable of transforming progesterone (I) to 5α-pregnane-3,20-dione (II), 5α-pregnan-3β-ol-20-one (III), its glucoside (IV), 5α-pregnane-3β,20α-diol (V), its glucoside (VI), 5α-pregnane-3β,20β-diol (VII), its glucoside (VIII), Δ⁴-pregnen-20α-ol-3-one (IX), its glucoside (X), Δ-pregnen-20β-ol-3-one (XI) and its glucoside (XII). 5α-Pregnan-3β-ol-20-one glucoside (IV), 5α-pregnane-3β,20α-diol glucoside (VI), 5α-pregnane-3β,20β-diol glucoside (VIII), Δ⁴-pregnen-20α-ol-3-one glucoside (X) and Δ⁴-pregnen-20β-ol-3-one glucoside (XII) have been found for the first time as new metabolises by plant tissue cultures. A scheme for the biotransformation of progesterone (I) has been proposed, and the reduction and glucosidation activities distinctly have been observed in these cultured cells.     

Metabolism of a Non-phenolic β-O-4 Lignin Substructure Model Compound by Coriolus versicolor

A non-phenolic β-O-4 lignin substructure model, 4-ethoxy-3-methoxyphenylglycerol-β-syringaldehyde ether (I), was metabolized by a ligninolytic culture of Coriolus versicolor. Based on the identification of the metabolic products (II~XI), the following reactions were found to occur in the culture; a) oxidation (III) and reduction (II) at the benzyl (Cα′) position of the substrate (I), b) β-ether cleavage to give arylglycerols (IV, V), and c) Cα-Cβ cleavage of the arylglycerols and/or arylglycerol moiety of the substrate (I). In addition, β-deoxy diol (VI) and γ-formylglycerol (VII) were obtained as degradation products from substrate (I).     

An Insecticidal Alkaloid,Cocculolidine from Cocculus trilobus DC.

An insecticidal alkaloid, cocculolidine was extracted from fresh leaves of Cocculus trilobus DC. Von Braun reaction and a novel acid catalyzed degradation showed that this alkaloid had the same skeleton with those of erythrina alkaloids. Structure (I) was finally assigned to cocculolidine, being identified as a new lactone erythrina alkaloid containing α, β-unsaturated-γ-lactone. The mass spectra of I and dihydro-β-erythroidine were also discussed.     

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.     

Metal Reduction at Low pH by a Desulfosporosinus species: Implications for the Biological Treatment of Acidic Mine Drainage

We isolated an acid-tolerant sulfate-reducing bacterium, GBSRB4.2, from coal mine-derived acidic mine drainage (AMD)-derived sediments. Sequence analysis of partial 16S rRNA gene of GBSRB4.2 revealed that it was affiliated with the genus Desulfosporosinus. GBSRB4.2 reduced sulfate, Fe(III) (hydr)oxide, Mn(IV) oxide, and U(VI) in acidic solutions (pH 4.2). Sulfate, Fe(III), and Mn(IV) but not U(VI) bioreduction led to an increase in the pH of acidic solutions and concurrent hydrolysis and precipitation of dissolved Al³⁺. Reduction of Fe(III), Mn(IV), and U(VI) in sulfate-free solutions revealed that these metals are enzymatically reduced by GBSRB4.2. GBSRB4.2 reduced U(VI) in groundwater from a radionuclide-contaminated aquifer more rapidly at pH 4.4 than at pH 7.1, possibly due to the formation of poorly bioreducible Ca-U(VI)-CO₃ complexes in the pH 7.1 groundwater.     

Chemical Constituents of a Heat-dried Chinese Mushroom,Hohenbuehelia serotina

Several compounds were isolated from a Chinese mushroom, Huangmo, the heat-dried fruiting body of Hohenbuehelia serotina. They were identified as linoleic acid (I), hexadecanoic acid (II), β-sitosterol (IV), benzoic acid (V), D-mannitol (VI), sucrose (VII), and L-rhamnose (VIII). In addition, six acidic substances were identified. (Table I). Also, ethyl linoleate, hexadecanoic acid, and 9,12-octadecadienoic acid (Z-Z) ethyl esters, IV, V, and VI were identified for the first time from this mushroom.     

Synthesis of Some New α- and β-(l→2) Linked Disaccharides Containing L-Quinovose (6-Deoxy L-Glucose)

Hepta-O-acetyl-2-0-β-l-quinovopyranosyl-α-d-glucose (VI) and hepta-O-acetyl-2-O-α-l-quinovopyranosyl-β-d-gIucose (VIII) were prepared by the coupling of 2,3,4-tri-O-acetyl-α-l-quinovopyranosyl bromide (IV) with l,3,4,6-tetra-O-acetyl-α-D-glucose (V) in the presence of mercuric cyanide and mercuric bromide in absolute acetonitrile.

Similarly, hepta-O-acetyW-O-α-l-quinovopyranosyl-α-d-galactose (X) and hepta-O-acetyl-2-O-β-L-quinovopyranosyl-α-d-galactose (XI) were prepared by the reaction of IV with 1,3,4,6-tetra-O-acetyl-α-d-galactose (IX).

Removal of the protecting groups of VI, VIII, X and XI afforded the corresponding disaccharides. On treatment with hydrogen bromide, VI, VIII, X and XI gave the corresponding acetobromo derivatives.     

Steroidal constituents of Solanum xanthocarpum

From the extract of the fruits of Solanum xanthocarpum, cycloartanol (I), cycloartenol (II), sitosterol (III), stigmasterol (IV), campesterol (V), cholesterol (VI), sitosteryl glucoside (VII), stigmasteryl glucoside (VIII), solamargine (IX), and β-solamargine (X) were identified and an isolated steroid (XI) was identical with 4α-methyl-(24R)-ethylcholest-7-en-3β-ol synthesized from carpesterol.     

Can microbially-generated hydrogen sulfide account for the rates of U(VI) reduction by a sulfate-reducing bacterium?

In situ remediation of uranium contaminated soil and groundwater is attractive because a diverse range of microbial and abiotic processes reduce soluble and mobile U(VI) to sparingly soluble and immobile U(IV). Often these processes are linked. Sulfate-reducing bacteria (SRB), for example, enzymatically reduce U(VI) to U(IV), but they also produce hydrogen sulfide that can itself reduce U(VI). This study evaluated the relative importance of these processes for Desulfovibrio aerotolerans, a SRB isolated from a U(VI)-contaminated site. For the conditions evaluated, the observed rate of SRB-mediated U(VI) reduction can be explained by the abiotic reaction of U(VI) with the microbially-generated H₂S. The presence of trace ferrous iron appeared to enhance the extent of hydrogen sulfide-mediated U(VI) reduction at 5 mM bicarbonate, but had no clear effect at 15 mM. During the hydrogen sulfide-mediated reduction of U(VI), a floc formed containing uranium and sulfur. U(VI) sequestered in the floc was not available for further reduction.     

The Preparation and Geometrical Isomerism of Substituted α-Methylthio-Cinnamic Acids

α-Methylthio-cinnamic acid and its substituted analogues (III) were synthesized from their respective β-aryl-α-thiopyruvic acids (II). In connection with the study on the tautomeric ene-thiol structure of β-aryl-α-thiopyruvic acids (II), 4-arylidenerl,3-oxathiolan-5-one (IV) were prepared from compounds II.     

Synthesis and Toxicity of Allethrin-(Z)-metabolites

(±)-trans-Allethrin-(Z)-ol (IV), (±)-trans-allethrin-(Z)-al (V) and (±)-trans-allethrin-(Z)-acid (VI), the minor components of allethrin metabolites in the insect body, were synthesized. The toxicities of newly synthesized allethrin derivatives (IV, V, VI) and of (±)-trans-allethrin-(E)-acid (Xc) to houseflies (Musca domestica L.) were examined by the injection method. And their low toxicities seem to support the hypothesis that oxidation at the isobutenyl side chain of the acid moiety of the allethrin molecule is a detoxication process in the insect body.     

Interaction between uranium and the cytochrome c 3 of Desulfovibrio desulfuricans strain G20

Cytochrome c₃ of Desulfovibrio desulfuricans strain G20 is an electron carrier for uranium (VI) reduction. When D. desulfuricans G20 was grown in medium containing a non-lethal concentration of uranyl acetate (1 mM), the rate at which the cells reduced U(VI) was decreased compared to cells grown in the absence of uranium. Western analysis did not detect cytochrome c₃ in periplasmic extracts from cells grown in the presence of uranium. The expression of this predominant tetraheme cytochrome was not detectably altered by uranium during growth of the cells as monitored through a translational fusion of the gene encoding cytochrome c₃ (cycA) to lacZ. Instead, cytochrome c₃ protein was found tightly associated with insoluble U(IV), uraninite, after the periplasmic contents of cells were harvested by a pH shift. The association of cytochrome c₃ with U(IV) was interpreted to be non-specific, since pure cytochrome c₃ adsorbed to other insoluble metal oxides, including cupric oxide (CuO), ferric oxide (Fe₂O₃), and commercially available U(IV) oxide.An erratum to this article can be found at     

Purification and characterization of dihydroorotase fromPseudomonas putida

Dihydroorotase was purified to homogeneity fromPseudomonas putida. The relative molecular mass of the native enzyme was 82 kDa and the enzyme consisted of two identical subunits with a relative molecular mass of 41 kDa. The enzyme only hydrolyzed dihydro-l-orotate and its methyl ester, and the reactions were reversible. The apparentK _m andV _max values for dihydro-l-orotate hydrolysis (at pH 7.4) were 0.081 mM and 18 μmol min⁻¹ mg⁻¹, respectively; and those forN-carbamoyl-dl-aspartate (at pH 6.0) were 2.2 mM and 68 μmol min⁻¹ mg⁻¹, respectively. The enzyme was inhibited by metal ion chelators and activated by Zn²⁺. However, excessive Zn²⁺ was inhibitory. The enzyme was inhibited by sulfhydryl reagents, and competitively inhibited byN-carbamoylamino acids such asN-carbamoylglycine, with aK _i value of 2.7 mM. The enzyme was also inhibited noncompetitively by pyrimidine-metabolism intermediates such as dihydrouracil and orotate, with aK _i value of 3.4 and 0.75 mM, respectively, suggesting that the enzyme activity is regulated by pyrimidine-metabolism intermediates and that dihydroorotase plays a role in the control of pyrimidine biosynthesis.     

Resonance Raman as a direct probe for the catalytic mechanism of molybdenum oxotransferases

 Recent studies of human sulfite oxidase and Rhodobacter sphaeroides DMSO reductase have demonstrated the ability of resonance Raman to probe in detail the coordination environment of the Mo active sites in oxotransferases via Mo=O, Mo-S(dithiolene), Mo-S(Cys) or Mo-O(Ser), dithiolene chelate ring and bound substrate vibrations. Furthermore, the ability to monitor the catalytically exchangeable oxo group via isotopic labeling affords direct mechanistic information and structures for the catalytically competent Mo(IV) and Mo(VI) species. The results clearly demonstrate that sulfite oxidase cycles between cis–di-oxo-Mo(VI) and mono-oxo-Mo(IV) states during catalytic turnover, whereas DMSO reductase cycles between mono-oxo-Mo(VI) and des-oxo-Mo(IV) states. In the case of DMSO reductase, ¹⁸O-labeling experiments have provided the first direct evidence for an oxygen atom transfer mechanism involving an Mo=O species. Of particular importance is that the active-site structures and detailed mechanism of DMSO reductase in solution, as determined by resonance Raman spectroscopy, are quite different to those reported or deduced in the three X-ray crystallographic studies of DMSO reductases from Rhodobacter species. Received: 16 June 1997 / Accepted: 20 August 1997