Vitrosin: a member of the collagen class

Vitrosin, a fibrous protein obtained from the vitreous humor of the eye in the form of an indefinitely long fibril about 100 to 150 A in diameter, has been identified as a member of the collagen class of proteins. It is characterized by the collagen wide-angle x-ray diffraction pattern, and axial periodicity of about 640 A determined by electron microscopy and small-angle x-ray diffraction, an amino acid pattern characteristic of collagen as determined by paper chromatography, and a hydroxyproline and glycine content also typical of collagen. The glycine-hydroxyproline ratio is somewhat lower than that for most vertebrate collagens.     

Selective targeting of breast cancer cells through ROS-mediated mechanisms potentiates the lethality of paclitaxel by a novel diterpene, gelomulide K

Defects in apoptotic pathways confer resistance to tubulin-binding agents via downregulation of caspases or overexpression of antiapoptotic factors, urging the need for novel agents acting on an alternative pathway. The purpose of this study was to investigate whether induction of ROS can induce caspase-independent cell death in breast cancer cells and thereby enhance the activity of paclitaxel. Here, we report that gelomulide K acts as a caspase-independent cell death-inducing agent that synergizes with paclitaxel in breast cancer cells and has low toxicity in normal cells. Treatment with gelomulide K induced PARP-1 hyperactivation, AIF nuclear translocation, and cytoprotective autophagy. These effects were associated with increased ROS production and a decrease in cellular GSH levels in cancer cells. Furthermore, pretreatment with NAC, a precursor of intracellular GSH, effectively abrogated gelomulide K-induced caspase-independent cell death and autophagy, suggesting that ROS-mediated downstream signaling is essential to the anticancer effects of gelomulide K. Additionally, in a xenograft model, gelomulide K induced PARP-1 activation and reduced tumor growth. In terms of structure-activity relationships, analysis not only showed a correlation between ROS levels and drug activity but also highlighted the importance of the 8,14-epoxy group. Taken together, our results show that enhancement of paclitaxel activity can be achieved with gelomulide K and that the structurally relevant pharmacophore provides important insight into the development of new caspase-independent cell death-inducing agents.     

Microbial hydroxylation and reduction of the diterpene psiadin

Microbial bioconversion studies conducted on the diterpene psiadin have revealed that it was metabolized by Aspergillus niger (NRRL 2295) to give 2alpha-hydroxydeoxopsiadin, Cunninghamella blakesleeana (ATCC 8688a) to give 11beta-hydroxypsiadin, and Cylindrocephalum aureum (ATCC 12720), Gongronella butleri (ATCC 22822), Kloeckera africana (ATCC 20111), and Kluyveromyces marxianus var. lactis (ATCC 2628) to yield 7alpha-hydroxypsiadin. Their structures have been established on the basis of spectral data. The structure and relative stereochemistry of 7alpha-hydroxypsiadin was confirmed by single-crystal X-ray analysis.     

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--IV. 6,7-Dehydrogenation; a new class of fungal steroid transformation product

Microbial steroid dehydrogenation is quite common. The reaction seems to occur mainly in bacteria and usually results in hydrogen abstraction from positions C(1)-C(2) and/or C(4)-C(5) with occasional aromatisation of ring A. We have screened large numbers of fungal cultures for their ability to monohydroxylate steroids at unusual sites and in the course of our investigations we have identified seven fungal strains capable of dehydrogenating ring B of progesterone and androstenedione at positions C(6)-C(7). Microbiological dehydrogenation at this site seems not to have been reported previously. The structures of the metabolites isolated from progesterone, and the producing fungi, are: 6-dehydroprogesterone (Botryodiplodia theobromae), 11 alpha-hydroxy-6-dehydroprogesterone (Botryosphaerica obtusa, Mucor racemosus and Nigrospora sphaerica), 12 alpha-, 15 beta- and 16 alpha-hydroxy-6-dehydroprogesterones (B. obtusa) and 14 alpha-hydroxy-6-dehydroprogesterone (Apiocrea chrysosperma) [1]. From androstenedione we isolated 6-dehydroandrostenedione (Absidia coerulea and Curvularia lunata) and 6-dehydrotestosterone (C. lunata).     

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 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.     

Salvidorol, a nor-abietane diterpene with a rare carbon skeleton and two abietane diterpene derivatives from Salvia dorrii

Salvidorol (1), a irregular nor-abietane-type diterpene, was isolated from the aerial parts of Salvia dorrii, in addition to two epimeric abietane diterpenes (2 and 3). This is the first report of a nor-diterpene with an irregular skeleton. The structures were established by high-field NMR techniques ((1)H-(1)H COSY, DEPT, HMQC, HMBC, NOESY and HRMS) and in case of 2 was confirmed by X-ray analysis.     

Microbial hydroxylation of natural drimenic lactones.

Incubation of confertifolin and isodrimenin with Mucor plumbeus, Aspergillus niger or Rhizopus arrhizus gave in good yields the corresponding 3 beta-hydroxy derivatives. From isodrimenin, the known natural 7 alpha-hydroxy derivative (futronolide) was also obtained and its structure was definitely established by X-ray crystallographic study of its acetate derivative.     

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.     

Sesquiterpene lactones and the diterpene 5-epi-icetexone affect the intracellular and extracellular stages of Trypanosoma cruzi

Chagas disease is a major health problem in Latin America and is caused by the parasitic protozoan Trypanosoma cruzi. Although many drugs have been used to alleviate the disease, these have been ineffective in the chronic phase and have also presented numerous side effects on patients. In this study we tested the effect of three sesquiterpene lactones (dehydroleucodine, helenalin and mexicanin) and a diterpene (5-epi-icetexone) on parasites (Y-strain) grown in host cells. At 48h of treatment, the number of amastigotes inside the cells was lower than in the controls. This effect was observable at concentrations of 1.5-3.8μM, which are of low cytotoxicity to host cells. In addition, the compounds caused a decrease in the percentage of infected cells. The treatments also reduced the presence of trypomastigotes in the extracellular medium. In all cases, helenalin was the most potent. The number of parasites per cell at 24h indicates the occurrence of multiple infection, which would also be affected by the compounds. However, we should not discard an effect on the proliferation and survival of parasites within the host cells. On the other hand, an additional effect on the differentiation of parasites and/or the survival of extracellular trypomastigotes might be possible. We conclude that these compounds are very effective against T. cruzi possibly by multiple mechanisms.     

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 7,2-dimethylbenz[a]anthracene.

Microbial transformations of 7,12-dimethylbenz[a]anthracene, a carcinogenic polycyclic aromatic hydrocarbon, in cultures of Pseudomonas aeruginosa and Penicillium notatum were studied by high performance liquid chromatographic separation of metabolic fractions followed by gas chromatographic-mass spectrometric analysis of the metabolites. Two methyl-hydroxylated metabolites were identified in each of the incubations. The metabolic activation of the polycyclic aromatic hydrocarbon suggests a possible involvement of microorganisms in environmental carcinogenesis.     

Reflections of a member of the bicentennial class on the Bicentennial Symposium

This perspective piece explores what it means to be a first-year medical student at Yale School of Medicine during its bicentennial year. At first, it seemed like a hefty burden to bear. However, upon listening to Dr. Eric Kandel speak at the Bicentennial Symposium at Yale on April 28, 2011, it became clear what it means to be a part of the future of science and medicine at Yale.     

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.