The hepatitis C virus (HCV) NS5B is essential for viral RNA replication and is therefore a prime target for development of HCV replication inhibitors. Here, we report the identification of a new class of HCV NS5B inhibitors belonging to the coumestan family of phytoestrogens. Based on the in vitro NS5B RNA-dependent RNA polymerase (RdRp) inhibition in the low micromolar range by wedelolactone, a naturally occurring coumestan, we evaluated the anti-NS5B activity of four synthetic coumestan analogues bearing different patterns of substitutions in their A and D rings, and observed a good structure-activity correlation. Kinetic characterization of coumestans revealed a noncompetitive mode of inhibition with respect to nucleoside triphosphate (rNTP) substrate and a mixed mode of inhibition towards the nucleic acid template, with a major competitive component. The modified order of addition experiments with coumestans and nucleic acid substrates affected the potencies of the coumestan inhibitors. Coumestan interference at the step of NS5B–RNA binary complex formation was confirmed by cross-linking experiments. Molecular docking of coumestans within the allosteric site of NS5B yielded significant correlation between their calculated binding energies and IC50 values. Coumestans thus add to the diversifying pool of anti-NS5B agents and provide a novel scaffold for structural refinement and development of potent NS5B inhibitors.
A new pterocarpanquinone (5a) was synthesized through a palladium catalyzed oxyarylation reaction and was transformed, through electrophilic substitution reaction, into derivatives 5b-d. These compounds showed to be active against human leukemic cell lines and human lung cancer cell lines. Even multidrug resistant cells were sensitive to 5a, which presented low toxicity toward peripheral blood mononuclear cells (PBMC) cells and decreased the production of TNF-alpha by these cells. In the laboratory these pterocarpanquinones were reduced by sodium dithionite in the presence of thiophenol at physiological pH, as NAD(P)H quinone oxidoredutase-1 (NQO1) catalyzed two-electron reduction, and the resulting hydroquinone undergo structural rearrangements, leading to the formation of Michael acceptors, which were intercepted as adducts of thiophenol. These results suggest that these compounds could be activated by bioreduction.
As pterocarpanquinonas 8a-c, previamente sintetizadas em nosso laboratório, e uma série homóloga de derivados, substâncias 9a-c preparadas neste trabalho, foram avaliadas em células de câncer de mama (MCF-7) e em cultura dos parasitas Leishmania amazonensis e Plasmodium falciparum. As substâncias 8a-c foram mais potentes que 9a-c nas células tumorais e em Leishmania amazonensis. Por outro lado, 9a-c mostraram ser as mais ativas sobre o Plasmodium falciparum. Todas as substâncias estudadas foram biosseletivas, apresentando baixa citotoxicidade para linfócitos murinos frescos e linfócitos humanos ativados pelo mitógeno fitoemoaglutinina (PHA).Pterocarpanquinones 8a-c, previously synthesized in our laboratory, and an homologous series of derivatives, compounds 9a-c prepared in this work, were evaluated on breast cancer cells (MCF-7) and on the parasites Leishmania amazonensis and Plasmodium falciparum, in culture. Compounds 8a-c were more potent than 9a-c on tumor cells and Leishmania amazonensis. On the other hand, 9a-c showed to be more active on Plasmodium falciparum. All the compounds studied were bioselective, presenting negligible cytotoxicity against fresh murine lymphocytes and human lymphocytes activated by the mitogen phytohemaglutinin (PHA).Keywords: antineoplasic, antiparasitic, pterocarpans, naphtoquinones, oxa-Heck reaction, antimalarial, leishmanicide IntroductionPhytoalexins or phytotoxins are low molecular substances produced by plants in response to microorganism attacks.1 These compounds inhibit the growth of bacteria and fungi in vivo and in vitro, and their production during an infection can induce resistance to subsequent infections. It has been shown that pterocarpans, among other group of natural products, act as phytoalexins. Phaseollidin for example (1, Figure 1), is present in higher concentration in species of Colombian beans resistant to Colletotrichum lindemuthianum fungus, the causal agent of anthrachnose disease, than in species sensitive to this fungus.1 Pterocarpans present other interesting biological properties, depending on the pattern of substitution present at the A-and D-rings (Figure 1). For example, edunol (2), isolated from Harpalyce braziliana, a plant used in the northeast of Brazil as folk medicine, shows antiofidic activity in vitro and in vivo (mices).2 Pterocarpan 3, isolated from a plant of genus Erythrina, presents anti-HIV activity in vitro 3 and crotafuran B (4), isolated from Crotalaria pallida, has antiinflamatory properties in vitro. 4 In 1995, the catechol pterocarpan 5 was isolated from Petalostemon purpureus and showed to be active on KB cells, a human epidermoid carcinoma cell line.5 This compound and four new derivatives were synthesized and their toxicities in da Silva et al. 177 Vol. 20, No. 1, 2009 leukemia cell lines, including cell lines with MDR (multi drug resistant) phenotype were evaluated. 6 Cathecol 5 and its possible metabolite in vivo, ortho-quinone 6, showed to be the most active compounds. While 5 was bioselective, 6 presented high to...
The chemical reactivity of safrole, eugenol, piperonal, vanillin and derivates toward ozone, aluminium chloride, brominating agents and butyl lithium was investigated. The synthesis of naturally occuring anthraquinones, furonaphthoquinones, naphthoquinones, lignans and pterocarpans from these easily available staring materials is also discussed.
Pterocarpanquinones (1a-e) and the aza-pterocarpanquinone (2) were synthesized through palladium catalyzed oxyarylation and azaarylation of conjugate olefins, and showed antineoplasic effect on leukemic cell lines (K562 and HL-60) as well as colon cancer (HCT-8), gliobastoma (SF-295) and melanoma (MDA-MB435) cell lines. Some derivatives were prepared (3-8) and evaluated, allowing establishing the structural requirements for the antineoplasic activity in each series. Compound 1a showed the best selectivity index in special for leukemic cells while 2 showed to be more bioselective for HCT-8, SF-295 and MDA-MB435 cells. Pterocarpanquinones 1a and 1c-e, as well as 8 were the most active on amastigote form of Leishmania amazonensis in culture. Compounds 1a, 1c and 8 showed the best selectivity index.
These results demonstrate that the molecular hybridization of a naphthoquinone core to pterocarpan yielded a novel antileishmanial compound that was locally and orally active in an experimental cutaneous leishmaniasis model.
Leishmaniasis affects mainly low-income populations in tropical regions. Radical innovation in drug discovery is time-consuming and expensive, imposing severe restrictions on the ability to launch new chemical entities for the treatment of neglected diseases. Drug repositioning is an attractive strategy for addressing a specific demand more easily. In this project, we have evaluated the antileishmanial activities of 30 drugs currently in clinical use for various morbidities. Ezetimibe, clinically used to reduce intestinal cholesterol absorption in dyslipidemic patients, killed Leishmania amazonensis promastigotes with a 50% inhibitory concentration (IC 50 ) of 30 M. Morphological analysis revealed that ezetimibe caused the parasites to become rounded, with multiple nuclei and flagella. Analysis by gas chromatography (GC)-mass spectrometry (MS) showed that promastigotes treated with ezetimibe had smaller amounts of C-14-demethylated sterols, and accumulated more cholesterol and lanosterol, than untreated promastigotes. We then evaluated the combination of ezetimibe with well-known antileishmanial azoles. The fractional inhibitory concentration index (FICI) indicated synergy when ezetimibe was combined with ketoconazole or miconazole. The activity of ezetimibe against intracellular amastigotes was confirmed, with an IC 50 of 20 M, and ezetimibe reduced the IC 90 s of ketoconazole and miconazole from 11.3 and 11.5 M to 4.14 and 8.25 M, respectively. Subsequently, we confirmed the activity of ezetimibe in vivo, showing that it decreased lesion development and parasite loads in murine cutaneous leishmaniasis. We concluded that ezetimibe has promising antileishmanial activity and should be considered in combination with azoles in further preclinical and clinical studies.
Acute myeloid leukemia (AML) is a challenging neoplasm that despite therapeutic advances requires efforts to overcome the multidrug resistance (MDR) phenotype, the major cause of relapse. The pterocarpanquinone LQB-118 is a new compound that induces apoptosis in leukemia cells. The objective of this work was to analyze the role of LQB-118 in inhibiting the inhibitor of apoptosis proteins (IAPs), XIAP and survivin, as well as in modulating the subcellular localization of NFκB, in comparison with idarubicin. LQB- 118 was more effective in inducing apoptosis than idarubicin in both AML Kasumi-1 cell line and cells from patients despite their MDR phenotype. LQB-118-induced apoptosis was accompanied by a marked inhibition of IAPs, and cytoplasmatic NFκB subcellular localization. On the other hand, idarubicin increased the IAPs expression and translocated NFκB to the nucleus. The inhibition profile of survivin induced by LQB-118 was comparable to the survivin inhibition profile when we investigated the efficiency of survivin-small interfering RNA (siRNA) treatment. LQB-118 as well as survivin-siRNA contributed similarly to the increase in apoptosis rate of Kasumi-1 cells. The data indicated that there is a functional interaction between the survivin, XIAP and NFκB, which appears to be involved in idarubicin resistance of Kasumi-1 cells. The efficacy of LQB-118 to induce cell death through inhibiting survivin suggests that this IAP may be involved in the chemoresistance phenotype in AML cells. Our findings suggest that LQB-118 might be a promising therapeutic approach for AML patients through survivin downregulation.
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