BackgroundSchistosomiasis—infection with helminth parasites in the genus Schistosoma, including S. mansoni—is a widespread, devastating tropical disease affecting more than 200 million people. No vaccine is available, and praziquantel, the only drug extensively utilized, is currently administered more than 100 million people yearly. Because praziquantel resistance may develop it is essential to identify novel drug targets. Our goal was to investigate the potential of a unique, selenium-containing parasite enzyme thioredoxin glutathione reductase (TGR) as a drug target.Methods and FindingsUsing RNA interference we found that TGR is essential for parasite survival; after silencing of TGR expression, in vitro parasites died within 4 d. We also found that auranofin is an efficient inhibitor of pure TGR (K
i = 10 nM), able to kill parasites rapidly in culture at physiological concentrations (5 μM), and able to partially cure infected mice (worm burden reductions of ~60%). Furthermore, two previously used antischistosomal compounds inhibited TGR activity, suggesting that TGR is a key target during therapy with those compounds.ConclusionsCollectively, our results indicate that parasite TGR meets all the major criteria to be a key target for antischistosomal chemotherapy. To our knowledge this is the first validation of a Schistosoma drug target using a convergence of both genetic and biochemical approaches.
Gammadelta-T-lymphocytes contribute to innate immunity and are selectively activated by nonpeptide phosphorylated molecules (so-called phosphoantigens) produced by organisms responsible for causing a broad range of infectious diseases. gammadelta-T-cells are also activated by synthetic phosphoantigens and are cytotoxic to tumor cells. Here we report the synthesis, NMR characterization, and comparative biological evaluation of new pyrophosphate, phosphonate, and pyrophosphonate monoesters whose structures correspond to isosteric analogues and stereoisomers of the highly potent isoprenoid metabolite ( E)-1-hydroxy-2-methylbut-2-enyl 4-diphosphate called HDMAPP (hydroxy-dimethyl-allyl pyrophosphate). Both pyrophosphate and pyrophosphonate series elicit promising gammadelta-T-cell stimulatory responses in vitro, the pyrophosphonate ester (C-HDMAPP) being by far more stable than its parent pyrophosphate ester (HDMAPP) with improved ADMET properties and a similar pharmacodynamic profile based on in vivo studies in nonhuman primate. In both series, we found that E-stereoisomers are the most active derivatives and that Z-stereoisomers show very marginal bioactivity levels. These results indicate that the use of bioisosteric analogues of HDMAPP may represent promising new leads for immunotherapy.
Artificial synthetic molecules able to adopt well-defined stable secondary structures comparable to those found in nature ("foldamers") have considerable potential for use in a range of applications such as biomaterials, biorecognition, nanomachines and as therapeutic agents. The development of foldamers with the ability to bind and encapsulate "guest" molecules is of particular interest; as such an ability is a key step toward the development of artificial sensors, receptors and drug-delivery vectors. Although significant progress has been reported within this context, foldamer capsules reported thus far are largely restricted to organic solvent systems, and it is likely that the move to aqueous conditions will prove challenging. Toward this end, we report here structural studies into the ability of a recently reported water-soluble self-assembled foldamer helix bundle to encapsulate simple guest molecules within an internal cavity. Seven high-resolution aqueous crystal structures are reported, accompanied by molecular dynamics and high-field NMR solution data, showing for the first time that encapsulation of guests by a complex self-assembled foldamer in aqueous conditions is possible. The findings also provide ample insight for the future functional development of this system.
In order to obtain functionalized naphthoquinones, a systematic study of the Kochi-Anderson procedure for the alkylation of quinones is presented. While linear amino acids of different lengths were good substrates for this decarboxylation procedure, chiral α-amino acids were unsuccessful substrates. The best reaction conditions were evaluated with β-alanine and then applied to a series of carboxylic acids to obtain chemical diversity on the naphthoquinones. We ob-
The human protein Pontin, which belongs to the AAA+ (ATPases associated with various cellular activities) family, is overexpressed in several cancers and its silencing in vitro leads to tumour cell growth arrest and apoptosis, making it a good target for cancer therapy. In particular, high levels of expression were found in hepatic tumours for which the therapeutic arsenal is rather limited. The three-dimensional structure of Pontin has been resolved previously, revealing a hexameric assembly with one ADP molecule co-crystallized in each subunit. Using Vina, DrugScore and Xscore, structure-based virtual screening of 2200 commercial molecules was conducted into the ATP-binding site formed by a dimer of Pontin in order to prioritize the best candidates. Complementary to the in silico screening, a versatile and sensitive colorimetric assay was set up to measure the disruption of the ATPase activity of Pontin. This assay allowed the determination of inhibition curves for more than 20 top-scoring compounds, resulting in the identification of four ligands presenting an inhibition constant in the micromolar concentration range. Three of them inhibited tumour cell proliferation. The association of virtual screening and experimental assay thus proved successful for the discovery of the first small-molecule inhibitors of Pontin.
RhoGTPases are GDP/GTP molecular switches that control a wide variety of cellular processes, thereby contributing to many diseases, including cancer. As a consequence, there is great interest in the identification of small-molecule inhibitors of RhoGTPases. In the present paper, using the property of GTP-loaded RhoGTPases to bind to their effectors, we describe a miniaturized and robust assay to monitor Rac1 GTPase activation that is suitable for large-scale high-throughput screening. A pilot compound library screen revealed that the topoisomerase II poison MTX (mitoxantrone) is an inhibitor of Rac1, and also inhibits RhoA and Cdc42 in vitro. We show that MTX prevents GTP binding to RhoA/Rac1/Cdc42 in vitro. Furthermore, MTX strongly inhibits RhoGTPase-mediated F-actin (filamentous actin) reorganization and cell migration. Hence, we report a novel biochemical assay yielding the identification of RhoGTPase inhibitors and we present a proof-of-concept validation with the identification of MTX as a novel pan-RhoGTPase inhibitor.
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