Structural basis for the function and inhibition of dihydroorotate dehydrogenase from Schistosoma mansoni.

Schistosomiasis is a serious public health problem, prevalent in tropical and subtropical areas, especially in poor communities without access to safe drinking water and adequate sanitation. Transmission has been reported in 78 countries, and its control depends on a single drug, praziquantel, which has been used over the past 30 years. Our work is focused on exploiting target-based drug discovery strategies to develop new therapeutics to treat schistosomiasis. In particular, we are interested in evaluating the enzyme dihydroorotate dehydrogenase (DHODH) as a drug target. DHODH is a flavoenzyme that catalyzes the stereospecific oxidation of (S)-dihydroorotate (DHO) to orotate during the fourth and only redox step of the de novo pyrimidine nucleotide biosynthetic pathway. Previously, we identified atovaquone, used in the treatment of malaria, and its analogues, as potent and selective inhibitors against Schistosoma mansoni DHODH (SmDHODH). In the present article, we report the first crystal structure of SmDHODH in complex with the atovaquone analogue inhibitor 2-((4-fluorophenyl)amino)-3-hydroxynaphthalene-1,4-dione (QLA). We discuss three major findings: (a) the open conformation of the active site loop and the unveiling of a novel transient druggable pocket for class 2 DHODHs; (b) the presence of a protuberant domain, only present in Schistosoma spp DHODHs, that was found to control and modulate the dynamics of the inhibitor binding site; (c) a detailed description of an unexpected binding mode for the atovaquone analogue to SmDHODH. Our findings contribute to the understanding of the catalytic mechanism performed by class 2 DHODHs and provide the molecular basis for structure-guided design of SmDHODH inhibitors. DATABASE: The structural data are available in Protein Data Bank (PDB) database under the accession code number 6UY4.

Combination of chiroptical, absorption and fluorescence spectroscopic methods reveals multiple, hydrophobicity-driven human serum albumin binding of the antimalarial atovaquone and related hydroxynaphthoquinone compounds.

High-affinity human serum albumin (HSA) binding of the C3-substituted antimalarial 2-hydroxy-1,4-naphthoquinone derivative atovaquone (ATQ) has been demonstrated and studied by circular dichroism (CD), UV/VIS absorption, fluorescence spectroscopy and affinity chromatography methods. The analysis of induced CD data generated upon HSA binding of ATQ revealed two high-affinity binding sites (K(a) ≈ 2 × 10(6) M(-1)). CD interaction studies and displacement of specific fluorescent and radioactive marker ligands indicated the contribution of both principal drug binding sites of HSA to complexation of ATQ, and also suggested the possibility of simultaneous binding of ATQ and some other drugs (e.g. warfarin, phenylbutazone, diazepam). Comparison of UV/VIS spectra of ATQ measured in aqueous solutions indicated the prevalence of the anionic species formed by dissociation of the 2-hydroxyl group. HSA binding of related natural hydroxynaphthoquinones, lapachol and lawsone also induces similar CD spectra. The much weaker binding affinity of lawsone (K(a) ≈ 10(4) M(-1)) bearing no C3 substituent highlights the importance of hydrophobic interactions in the strong HSA binding of ATQ and lapachol. Since neither drug exhibited significant binding to serum α(1)-acid glycoprotein, HSA must be the principal plasma protein for the binding and transportation of 2-hydroxy-1,4-naphthoquinone-type compounds which are ionized at physiological pH values.

Synthesis and antimalarial activity of new atovaquone derivatives.

In this paper we describe the design and synthesis of 18 derivatives of the antimicrobial atovaquone which were substituted at the 3-hydroxy group by ester and ether functions. The compounds were evaluated in vitro for their activity against the growth of Plasmodium falciparum, the malaria causing parasite. All the compounds showed potent activity, with IC(50) values in the range of 1.25-50 nM, comparable to those of atovaquone and much higher than chloroquine or quinine.

Atovaquone derivatives as potent cytotoxic and apoptosis inducing agents.

2-Piperazinyl naphthoquinones (2) and 2-piperidinyl naphthoquinones (3) were designed and synthesized as new cytotoxic and apoptosis inducing agents by utilizing the anti-parasite drug atovaquone as lead compound. Several compounds displayed significantly improved cytotoxic activities against a panel of cancer cell lines than that of atovaquone. These compounds also induced apoptosis through activating pro-apoptotic caspases 9 and 3.

Importance of using highly pure internal standards for successful liquid chromatography/tandem mass spectrometric bioanalytical assays.

Internal standards (IS) with similar physicochemical properties to the analyte provide multiple advantages in liquid chromatography/tandem mass spectrometric (LC/MS/MS) bioanalytical methods such as: reduction of the analysis run time, improvement in the intra-injection reproducibility, impact reduction of matrix and ionization effects. However, it is important to evaluate the purity of the IS prior to their use. Indeed, a minor impurity in the IS may lead to an important issue during bioanalytical method development. Stable labelled internal standards are usually appropriate IS for bioanalysis. The use of oxycodone-D3, ursodiol-D5 and atovaquone-D4 as internal standards in three different bioanalytical methods was evaluated. During oxycodone, oxymorphone and noroxycodone simultaneous quantification method development, oxymorphone was identified as a contaminant in oxycodone-D3. Since the limit of quantification for oxymorphone was very low (10 pg/mL), the presence of an even low percentage of oxymorphone in oxycodone-D3 leads to the change of the stable labelled IS for an analogue, ethylmorphine. 23-Nordeoxycholic acid was preferred to ursodiol-D5 as internal standard for the ursodiol, tauroursodiol and glycoursodiol simultaneous quantification method. Indeed, more than 7% of ursodiol was identified in the ursodiol-D5 which could not be bypassed by decreasing the IS concentration without compromising the linearity. An atovaquone-D4 reference standard revealed the non-negligible presence of atovaquone-D5 to atovaquone-D8 that has a large impact on the method validation. Therefore, atovaquone-D4 was sent for recertification since its isotopic purity was found to be much less than the isotopic purity mentioned on its certificate of analysis. Consequently, during bioanalytical method development, the purity of the IS should be scrutinized.