Microbial transformation of antimalarial terpenoids

The fungal and bacterial transformation of terpenoids derived from plant essential oils, especially the sesquiterpenoid artemisinin from Artemisia annua, has produced several new candidate drugs for the treatment of malaria. Obtaining new derivatives of terpenoids, including artemisinin derivatives with increased antimalarial activity, is an important goal of research in microbial biotechnology and medicinal chemistry.     

Microbial transformations of steroids

The absolute substrate specificity was found in studying transformations of steroids by the 663 strain ofBeauveria bassiana. The presence of hydroxyl in 17α - position is critical for the direction of transformation. Pregnene steroids are above all hydroxylated in 11α-position. The 11α - derivative originated from 17α - derivatives is the main and end metabolite. Two more mutually independent reactions occur after 11α-hydroxylation of 17α-nonhydroxylated derivatives, splitting of the side chain on C₁₇ resulting in 11α - hydroxytestosterone as a main metabolite and hydroxylation in 6β -position to respective 6 β, 11 α-di-hydroxy-4-pregnene derivative. Hydroxylation in 6 β-position of androstene steroids was not found. Steroids substituted both in positions C₁₁ and C₁₇ are not transformed at all.     

Microbial transformations of cardioglycosides

Summary Penicillium vermiculatum deglycosylated lanatosid C to acetyldigoxin and Arthrobacter citreus deacetylated the latter to digoxin. Both reactions were carried out in a short time with high yields. Lanatosid A was transformed by P. vermiculatum simultaneously to acetyldigitoxin and digitoxin. A. citreus transformed lanatosid A directly to digitoxin and lanatosid C to digoxin, but the reactions took a long time and the yields were low.     

Microbial transformations of galanthamin-precursors

Summary Galanthamin is a medical important alkaloid. Its chemical synthesis gives a racemic product in low yields. Starting with a belladinderivative an enzymatic ring closure should lead exclusively to a chiral product possibly with the native structure. Although this reactions type is unknown in preparative biotransformations a large number of microorganisms were tested, unfortunately without success. On the other hand in the screen transformation products were found resulting from specific dealkylations of the subtrate. The type of metabolite formed was dependent on the fungi utilized for the transformation. Additionally two N-oxides were formed by Septomyxa affinis, one in good yield. It is possible that the chirality of this compound can direct the ring closure preferentially or exclusively to the desired stereoisomer of narwedine.     

Microbial transformations of alpha-santonin

Fungal biotransformations of alpha-santonin (1) were conducted with Mucor plumbeus (ATCC 4740), Cunninghamella bainieri (ATCC 9244), Cunninghamella echinulata (ATCC 9245), Curvularia lunata (ATCC 12017) and Rhizopus stolonifer (ATCC 10404). Rhizopus stolonifer (ATCC 10404) metabolized compound 1 to afford 3,4-epoxy-alpha-santonin (2) and 4,5-dihydro-alpha-santonin (3) while Cunninghamella bainieri (ATCC 9244), Cunninghamella echinulata (ATCC 9245) and Mucor plumbeus (ATCC 4740) were capable of metabolizing compound 1 to give a reported metabolite, 1,2-dihydro-alpha-santonin (4). The structures of these transformed metabolites were established with the aid of extensive spectroscopic studies. These fungi regiospecifically reduced the carbon-carbon double bond in ring A of alpha-santonin.     

Microbial transformations of steroids

The preparation ofΔ ^{1, 4} , 17-dione fromΔ ⁴ , 17-dione with the aid ofFusarium lateritium 403 is described, the yield being 80%, referred to the original steroid. The undesirable 1-dehydrotestololactone is formed under the given conditions only in traces. If progesterone was used as the starting steroid the yield of the undesirable 1-dehydrotestololactone is 40%, referred to the progesterone used. Dehydroepiandrosterone was not transformed by theFusarium lateritium strain to steroid metabolites. During the preparation of 1-dehydrotestosterone fromΔ ⁴ -androstene-3, 17-dione, using two successive microbial procedures (dehydrogenation of the A ring in position 1–2 and reduction of the keto group at C₁₇ giving rise to the corresponding 17β-hydroxy derivative), the isolation yield was 55–60%, referred to the starting steroid.     

Microbial transformations of steroids

Capacity to acetylate testosterone was demonstrated in the species of yeast and yeast-like organisms which simultaneously ferment lactose (Saccharomyces fragilis, S. lactis, Candida pseudotropicalis andTorulopsis sphaerica). This capacity can thus be made use of as a supplementary diagnostic test for classifying the above microorganisms. Microbial acetylation can also be employed for separating mixtures of steroid 17-hydroxy-epimers, the acetylation taking place only with the 17β-hydroxyderivative while the corresponding 17α-epimer remains intact. No acetylation of the steroid molecule with hydroxy group in the 11α, 11β, 20β and 21 positions takes place under these conditions.     

Fullerene transformations as analogues of radiolarian skeleton microevolution

The analogy in the structures of fullerenes (i.e., polyhedral molecules with only the pentagonal and hexagonal facets) and radiolarian skeletons (Heliosphaera inermis, H. tenuissima, H. actinota, H. echinoides, H. elegans; Circogonia dodecahedra; Haliomma capillaceum, Ethmosphaera siphonophora Hkl., etc.) is briefly considered. Modern chemical methods allow fullerenes to be changed to desirable forms, e.g., the most symmetrical and, therefore, stable ones. The computer algorithms (e.g., SW-transformations) divide the variety of fullerenes-isomers into the classes of equivalency. The hypothesis is stated that the transformations of fullerenes simulate the radiolarian skeleton microevolution, while the classes of equivalency are of taxonomic significance.     

Microbial transformations of 2-substituted benzothiazoles

The occurrence of benzothiazoles in the environment seems to be restricted to aquatic compartments and is mainly associated with the manufacture and use of the rubber additive 2-mercaptobenzothiazole (MBT) and its derivatives. Although data on benzothiazole biotransformations in natural environments at ppb and ppt levels are scarce, the unsubstituted benzothiazole (BT) and 2-hydroxybenzothiazole (OBT) are generally considered to be biodegradable, whereas 2-methylthiobenzothiazole is recalcitrant. The fungicide 2-thiocyanomethylthiobenzothiazole is assumed to be hydrolysed to MBT, which is then further methylated. At higher concentration levels, similar conclusions can generally be drawn. In addition, BT, MBT, 2-aminobenzothiazole and benzothiazole-2-sulphonate can be biodegraded, although side- and end-products may form. For BT and MBT, threshold concentration were reported above which inhibitory effects on biological treatment processes occur. Due to the limited availability of axenic bacterial cultures capable of benzothiazole mineralization, only the initial steps of the degradation pathways have been elucidated so far.     

Microbial transformations of tin and tin compounds

Summary The use of organotins for agricultural and industrial purposes and in the marine environment has been increasing steadily for more than 20 years. Recently, reliable methodologies have been developed to permit quantification of individual molecular species of organotins in cultures and in the environment. Particular attention has been given to methyltins which can be formed abiotically and by microorganisms, and to tributyltins which are toxic components of effective antifouling paints. In the aquatic environment tin, tributyltins and other organotins accumulate in the surface microlayer, in sediments, and on suspended particulates. Tin compounds are toxic to a variety of organisms and some aquatic organisms can bioaccumulate them. When tin compounds, particularly di-or tri-substituted tins, enter an ecosystem, a portion of the microbial population is killed. Among the survivors are organisms which can methylate inorganic or organic tins, but the relative contribution of biotic and abiotic mechanisms is not clear. While many details of methylations and demethylations need to be worked out, it is clear that transformations of tins can influence the toxicity, volatility and mobility of tin in natural ecosystems. Tributyltins can be debutylated by microorganisms, and hydroxybutyl tins may be intermediates, as they are in mammalian systems. Little is known of the potential and probable microbial transformations of other economically important organotins, but the transformations should be studied for they may have industrial and environmental importance.     

Microbial transformations of selenite by methane-oxidizing bacteria

Methane-oxidizing bacteria are well known for their role in the global methane cycle and their potential for microbial transformation of wide range of hydrocarbon and chlorinated hydrocarbon pollution. Recently, it has also emerged that methane-oxidizing bacteria interact with inorganic pollutants in the environment. Here, we report what we believe to be the first study of the interaction of pure strains of methane-oxidizing bacteria with selenite. Results indicate that the commonly used laboratory model strains of methane-oxidizing bacteria, Methylococcus capsulatus (Bath) and Methylosinus trichosporium OB3b, are both able to reduce the toxic selenite (SeO₃ ^2?) but not selenate (SeO₄ ^2?) to red spherical nanoparticulate elemental selenium (Se⁰), which was characterized via energy-dispersive X-ray spectroscopy (EDXS), X-ray absorption near-edge structure (XANES) and extended X-ray absorption fine structure (EXAFS). The cultures also produced volatile selenium-containing species, which suggests that both strains may have an additional activity that can transform either Se⁰ or selenite into volatile methylated forms of selenium. Transmission electron microscopy (TEM) measurements and experiments with the cell fractions cytoplasm, cell wall and cell membrane show that the nanoparticles are formed mainly on the cell wall. Collectively, these results are promising for the use of methane-oxidizing bacteria for bioremediation or suggest possible uses in the production of selenium nanoparticles for biotechnology.

     

Microbial transformations of steroids--I. Rare transformations of progesterone by Apiocrea chrysosperma

When Apiocrea chrysosperma is incubated with progesterone for 7 days in a peptone, yeast-extract medium, eight major metabolites are produced. Each compound has been purified and its structure determined by high-field 1D and 2D 1H nuclear magnetic resonance (NMR) spectroscopy. A clear synthetic pattern is recognisable. The products have been formed by multiple transformation reactions, usually double hydroxylations. Seven compounds are tertiary alcohols in which the hydroxyl group is located on the underside of the progesterone skeleton at either the axial 9 alpha- or the axial 14 alpha-site. One compound has hydroxyl groups at both these sites. Five metabolites are also secondary progesterone alcohols, the hydroxyl groups being at the 6 beta-, 15 alpha- or 15 beta-sites. Two compounds are monohydroxy metabolites; one is dehydrogenated in ring B and the other has lost the pregnane side-chain. The structures of the eight metabolites are 6 beta, 9 alpha-dihydroxyprogesterone; 6 beta, 14 alpha-dihydroxyprogesterone; 9 alpha, 14 alpha-dihydroxyprogesterone; 9 alpha, 15 beta-dihydroxyprogesterone, 14 alpha, 15 alpha-dihydroxyprogesterone; 14 alpha, 15 beta-dihydroxyprogesterone; 14 alpha-hydroxypregna-4,6-diene-3,20-dione and 15 alpha-hydroxyandrostene-3,17-dione. All compounds, except the last one, are biologically rare because they are not products of mammalian progesterone or androstenedione metabolism. They would be difficult to synthesise chemically. We believe that the compounds, 9 alpha, 15 beta-dihydroxyprogesterone; 14 alpha, 15 alpha-dihydroxyprogesterone and 14 alpha-hydroxypregn-4,6-diene-3,20-dione, have not been reported previously as microbial transformation products of progesterone.     

Synthetic transformations of higher terpenoids. XXVI. 16-Acetylaminomethyllabdanoids and theirs cytotoxicity

Condensation of methyl 16-aminomethyllambertianate with N-Boc-omega-amino acids leads smoothly to 16-(N-Boc-aminononan)- and 16-(N-Boc-aminoundecan)amidomethyllabdanoids. The amide of bicyclo[2.2.1]heptan-1,2-dicarbocylic acid with a labdanoid substituent was obtained under the reaction of methyl aminomethyllambertianate with bicyclo[2.2.1]hept-5-ene-2,3-dicarboxylic anhydride. Intereaction of methyl 16-aminomethyllambertianate with chloroacetyl chloride leads to methyl 16-(chloroacetylaminomethyl)lambertianate; condensation of this compound with amino acid methyl ethers the corresponding amides of methyl lambertianate was obtained. The resulting compounds are more (compared with lambertianic acid) cytotoxicity in the cell lines CEM-13, MT-4 and U-937 with an CCID50 concentration of 3.9-9.9 microM.     

Synthetic transformations of higher terpenoids. XXVI. 16-acetylaminomethyllabdanoids and their cytotoxicity

Coupling of methyl 16-aminomethyllambertianate with N-Boc-protected ω-amino acids resulted in 16-(N-Boc-aminononan)- and 16-(N-Boc-aminoundecan)amidomethyllabdanoids. Interaction of methyl aminomethyllambertianate with bicyclo[2.2.1]hept-5-en-2,3-dicarboxylic acid anhydride led to the amide of bicyclo[2.2.1]heptan-1,2-dicarboxylic acid with a labdanoid substituent. Reaction of methyl 16-aminomethyllambertianate with chloroacetyl chloride resulted in methyl 16-(chloroacetylaminomethyl)lambertianate; coupling of the latter with methyl esters of amino acids gave the corresponding amides of methyl lambertianate. The compounds obtained were more cytotoxic toward CEM-13, MT-4, and U-937 tumor cell lines as compared with lambertianic acid; the dose inhibiting tumor cell viability by 50% (CCID₅₀) of the more active compounds was 3.9–9.9 μM.     

Microbial transformations of antimicrobial quinolones and related drugs

The quinolones are an important group of synthetic antimicrobial drugs used for treating bacterial diseases of humans and animals. Microorganisms transform antimicrobial quinolones (including fluoroquinolones) and the pharmacologically related naphthyridones, pyranoacridones, and cinnolones to a variety of metabolites. The biotransformation processes involve hydroxylation of methyl groups; hydroxylation of aliphatic and aromatic rings; oxidation of alcohols and amines; reduction of carboxyl groups; removal of methyl, carboxyl, fluoro, and cyano groups; addition of formyl, acetyl, nitrosyl, and cyclopentenone groups; and cleavage of aliphatic and aromatic rings. Most of these reactions greatly reduce or eliminate the antimicrobial activity of the quinolones.     

Microbial steroid transformations: current state and prospects

Studies of steroid modifications catalyzed by microbial whole cells represent a well-established research area in white biotechnology. Still, advances over the last decade in genetic and metabolic engineering, whole-cell biocatalysis in non-conventional media, and process monitoring raised research in this field to a new level. This review summarizes the data on microbial steroid conversion obtained since 2003. The key reactions of structural steroid functionalization by microorganisms are highlighted including sterol side-chain degradation, hydroxylation at various positions of the steroid core, and redox reactions. We also describe methods for enhancement of bioprocess productivity, selectivity of target reactions, and application of microbial transformations for production of valuable pharmaceutical ingredients and precursors. Challenges and prospects of whole-cell biocatalysis applications in steroid industry are discussed.     

Microbial transformations of chalcones to produce food sweetener derivatives

Biotransformations of two substrates: chalcone (1) and 2′-hydroxychalcone (4) were carried out using four yeast strains and five filamentous fungi cultures. Substrate 1 was effectively hydrogenated in all of tested yeast cultures (80–99% of substrate conversion after 1 h of biotransformation) affording dihydrochalcone 2. In the cultures of filamentous fungi the reaction was much slower, however, Chaetomium sp. gave product 2 in 97% yield. After 12 h of incubation a reduction of dihydrochalcone 2 to alcohol 3 was additionally observed. After 3 days of biotransformation in the culture of Rhodotorula rubra product (S)-3 was obtained with 75% ee (enantiomeric excess) and 99% of conversion. Also after a 3-day biotransformation using the strain Fusarium culmorum product (R)-3 was obtained with 98% ee and 97% of conversion. In most of the tested strains a change in enantiomeric excess of compound 3 during the biotransformation process was noticed. In the culture of Rhodotorula glutinis after 3 h of transformation alcohol (R)-3 was formed with 47% ee and 31% of substrate conversion, whereas after 6 days the (S)-3 enantiomer was obtained with 99% ee and 91% of conversion. In the case of 2′-hydroxychalcone (4), the hydrogenation proceeded much slower and led to 2′-hydroxydihydrochalcone (5) – in the culture of Yarrowia lipolytica 97% of conversion was observed after 3 days. In all cultures of the tested strains no products of 2′-hydroxydihydrochalcone reduction were detected.