Rearrangement of unsaturated 2,4-O-benzylidenehexitol derivatives into C-glycosylbenzene derivatives.

Acetolysis of (Z)-1,3-di-O-acetyl-2,4-O-benzylidene-6-C-(2,4-dichlorophenyl)-D-xylo-he x- 5-enitol (3) afforded (E)-1,2,3,4-tetra-O-acetyl-6-C-(2,4-dichlorophenyl)-D-xylo-hex-5-enit ol and 2-C-[(R)-acetoxy(2,4-dichlorophenyl)methyl]-3,4,6-tri-O-acetyl-2-deoxy- beta-L-galacto- and -beta-L-gulo-hexopyranosylbenzene. The mechanism of this new rearrangement was studied by exchanging the substituents at C-1 and C-3 in 3 and those of the aromatic ring attached to C-6.     

Steroid derivatives

Mycobacterium flavum was used to effect the transformation of 16β-methyl-16,17-oxido-7β,11α-dihydroxypregn-4-ene-3,20-dione (I) and the final products were isolated and identified as 16β-methyl-16,17-oxido-7β,11α-dihydroxypregna-1,4-diene-3,20-dione (II) and 16β-methyl-16,17-oxido-11α-hydroxypregna-1,4,6-triene-3,20-dione (IV), and the intermediate product as 16β-methyl-16,17-oxido-11α-hydroxypregna-4,6-diene-3,20-dione (III).     

Steroid derivatives

It was found in a study of the hydroxylating capacity of one of theFungi imperfecti, the genusBeauveria, some of the species of which are able to introduce the oxygen function into position 11α of various steroid compounds, that the enzyme activity ofBeauveria globulifera gives rise both to the corresponding 11α-hydroxy-derivative and to the 5β-saturated 11α-hydroxy-compound or a 5β-saturated 7β,11α-dihydroxy-compound. The isolation and the identification of the products of biotransformation of some steroids of the pregnane and androstane series byBeauveria globulifera is described.     

Steroid derivatives

The microorganismsBacillus sphaericus, Septomyxa affinis andProactinomyces globerulus dehydrogenate 17β-hydroxy-17α-methyl-5α-androstan-3-one to corresponding 1-, or 1,4-unsaturated derivatives. However, the biotransformation of the cited compound byArthrobacter simplex andMycobacterium flavum simultaneously introduced one atom of oxygen into the 17a-position and resulted in the formation of 17β hydroxy-17α-methyl-17a-oxa-D-homo-5α-1-androsten-3-one.     

Steroid derivatives

Microbial transformation of some steroid 19-hydroxy compounds and 1(10),5-dienes, substituted by a hydroxyl group in position 3, by the action ofProactinomyces globerulus, yielded substances with aromatic A ring. Substrates with 17-keto group underwent simultaneously a partial reduction resulting in the formation of 17β-hydroxyl.     

Steroid derivatives

Biotransformation of dehydroepiandrosterone (I) and methylandrostenediol (VI) by means of the microorganismAbsidia orchidis yielded a mixture of epimeric 7-hydroxyderivatives II or VII. Microbial oxidation of these mixtures byFlavobacterium peregrinum afforded epimeric 7-hydroxyderivatives of 4-androsten-3,17-dione III and IV, or of methyltestosterone VIII and IX. The structure of these compounds was confirmed by partial synthesis.     

Steroid derivatives

The dependence of the course of hydroxylation of steroid compounds substituted differently in positions 16 and 17 was studied, using several economically important 11α-hydroxylating microorganisms. All the steroid substrates used yielded the 11α-hydroxy-derivative as the main product, with the exception of 16β-methyl-16α, 17-oxidoprogesterone, during the biotransformation of which the formation of the 11α-hydroxy-derivative was accompanied by appreciable amount of its 7β,11α-dihydroxyderivative. In the transformation achieved byBeauveria bassiana, the last-named dihydroxy-compound was formed as the main product, whereas the biotransformation carried out with the aid ofBeauveria globulifera yielded the 5-saturated analogue of 7β,11α-dihydroxy-methylepoxyprogesterone as the main product.     

Steroid derivatives

Hydroxylation of l7α-acetoxy-6-chloro-16-methylene-4,6-pregnadiene-3,20-dione (Chlorosuperlutin, I) byCunninghamella blakesleeana yielded a 15β-hydroxyderivative II. Analogous transformation of 17α-acetoxy-16-methylene-4,6-pregnadiene-3,20-dione (Superlutin, IV) included a hydroxylation in position 15β and probably also in 11β with a concomitant reduction of the 6,7-double bond.     

Photoreactivity of indirubin derivatives

Twenty-nine analogs of indirubin, an isomer of indigo, have been synthesized to optimize its promising kinase inhibitory scaffold. These compounds being also pigmented, have been tested for their photoreactivity. Absorption maxima were between 485 nm and 560 nm. Addition of fetal calf serum induced fluorescence and time dependent absorption modifications. Appropriate illumination induced Reactive Oxygen Species (ROS) production for nineteen compounds out of twenty-nine. The relationship between fluorescence and ROS production is discussed. Six compounds showed an important toxicity on F98 cells, a murine glioma cell line. Three of these were found to be also phototoxic, as four other non-toxic compounds. All but one phototoxic compounds were detected as ROS producers by in vitro tests. Photoreactivity assessment is important to anticipate adverse reactions for compounds that might be clinically developed. The experimental assay was found to be the only way to evaluate the photoreactivity of this family of compounds since no predictive criteria on structures could be found. Combining the vascular tumor growth inhibition induced by kinase inhibitors with the massive local blood flow arrest following photodynamic treatment may be an efficient anti-cancer strategy. These data could orientate further syntheses of either non-photoreactive compounds or compounds displaying both kinase inhibitory activity and strong phototoxicity.     

Acetolysis of disaccharide derivatives

The acetolysis of aldobi-itols and aldobionic acids containing α- and β-(1→2), χ-and β-(1→4), and β-(1→6) linkages has been studied. Cleavage of the (1→4)- and (1→6)-linked derivatives occurred more slowly than for the parent disaccharides. The reverse situation was found for (1→2)-linked aldobi-itols and methyl esters of aldobionic acids.     

Dicarboxylatodirhodium derivatives of polyoxotungstates

Salts of the new complexes [PW₁₁O₃₉{Rh₂(O₂CR)₂}]⁵⁻; R = Prⁿ (1), CH₂Cl (2), CH₂OH (3), o-C₆H₄OH (4), p-C₆H₄OH (5), and [XW₁₁O₃₉{Rh₂(p-O₂CC₆H₄OH)₂}]⁶⁻; X = Si (6), Ge (7) have been prepared in good yield and characterized by elemental analysis, multinuclear NMR spectroscopy, and structural crystallography of the cesium salts of anions 1 and 5 with chloride ions in axial positions of the dirhodium moiety. The incorporation of the dirhodium group into the Keggin structure significantly increases the hydrolytic kinetic stability of the polyoxotungstates at pH 7–8.5, a result that has implications for the use of such complexes for imaging and for phase determination in structural studies of large biomolecules. Based on NMR studies, the axial sites of the dirhodium moiety of the polytungstate anions are accessible to ligation by molecules such as cysteine, methionine, and isonicotinic acid.     

Biocenversion of cyclohexene derivatives

Summary Bioconversion of new methylcyclohexene derivatives with bulky side chains ending in aromatic or heteroaromatic rings by Streptomyces natalensis and Mycobacterium smegmatis results in monohydroxylation of the cyclohexene ring. Further oxidation of the hydroxyl group into a keto group is effected only with M. smegmatis. The synthesis of the substrates and proof of the structure of the products is given in detail.     

Synthesis of tunicaminyluracil derivatives

A tunicaminyluracil derivative, which is a key component of the tunicamycin nucleoside antibiotics, was synthesized using a samarium diiodide (SmI2) mediated aldol reaction and intramolecular Pummerer reaction as the key steps. The alpha-phenylthio ketone 11, the precursor of the samarium enolate, was prepared from D-galactose. Treatment of 11 with SmI2 at -40 degrees C resulted in complete conversion to the corresponding samarium enolate, and subsequent addition of uridine 5'-aldehyde 12 afforded the desired aldol products 13a,b. Compound 13a was converted to the sulfoxide 15 by a sequential diastereoselective reduction of the ketone and an oxidation with mCPBA. Activation of 15 with Tf2O provided the desired cyclized compound 17. In this reaction, the aldol product 13a was also obtained as a consequence of a competitive intramolecular version of DMSO-oxidation via a 7-membered ring intermediate. Compound 18 or 19 are ready for use as a glycosyl donor in glycosylations to provide a range of analogues as potential glycosyltransferase inhibitors as well as related natural products.