Disulfiram and dithiocarbamate analogues demonstrate promising antischistosomal effects.

Schistosomiasis is a neglected tropical disease with more than 200 million new infections per year. It is caused by parasites of the genus Schistosoma and can lead to death if left untreated. Currently, only two drugs are available to combat schistosomiasis: praziquantel and, to a limited extent, oxamniquine. However, the intensive use of these two drugs leads to an increased probability of the emergence of resistance. Thus, the search for new active substances and their targeted development are mandatory. In this study the substance class of "dithiocarbamates" and their potential as antischistosomal agents is highlighted. These compounds are derived from the basic structure of the human aldehyde dehydrogenase inhibitor disulfiram (tetraethylthiuram disulfide, DSF) and its metabolites. Our compounds revealed promising activity (in vitro) against adults of Schistosoma mansoni, such as the reduction of egg production, pairing stability, vitality, and motility. Moreover, tegument damage as well as gut dilatations or even the death of the parasite were observed. We performed detailed structure-activity relationship studies on both sides of the dithiocarbamate core leading to a library of approximately 300 derivatives (116 derivatives shown here). Starting with 100 µm we improved antischistosomal activity down to 25 µm by substitution of the single bonded sulfur atom for example with different benzyl moieties and integration of the two residues on the nitrogen atom into a cyclic structure like piperazine. Its derivatization at the 4-nitrogen with a sulfonyl group or an acyl group led to the most active derivatives of this study which were active at 10 µm. In light of this SAR study, we identified 17 derivatives that significantly reduced motility and induced several other phenotypes at 25 µm, and importantly five of them have antischistosomal activity also at 10 µm. These derivatives were found to be non-cytotoxic in two human cell lines at 100 µm. Therefore, dithiocarbamates seem to be interesting new candidates for further antischistosomal drug development.

Molecular basis for hycanthone drug action in schistosome parasites.

Hycanthone (HYC) is a retired drug formerly used to treat schistosomiasis caused by infection from Schistosoma mansoni and S. haematobium. Resistance to HYC was first observed in S. mansoni laboratory strains and in patients in the 1970s and the use of this drug was subsequently discontinued with the substitution of praziquantel (PZQ) as the single antischistosomal drug in the worldwide formulary. In endemic regions, multiple organizations have partnered with the World Health Organization to deliver PZQ for morbidity control and prevention. While the monotherapy reduces the disease burden, additional drugs are needed to use in combination with PZQ to stay ahead of potential drug resistance. HYC will not be reintroduced into the schistosomiasis drug formulary as a combination drug because it was shown to have adverse properties including mutagenic, teratogenic and carcinogenic activities. Oxamniquine (OXA) was used to treat S. mansoni infection in Brazil during the brief period of HYC use, until the 1990s. Its antischistosomal efficacy has been shown to work through the same mechanism as HYC and it does not possess the undesirable properties linked to HYC. OXA demonstrates cross-resistance in Schistosoma strains with HYC resistance and both are prodrugs requiring metabolic activation in the worm to toxic sulfated forms. The target activating enzyme has been identified as a sulfotransferase enzyme and is currently used as the basis for a structure-guided drug design program. Here, we characterize the sulfotransferases from S. mansoni and S. haematobium in complexes with HYC to compare and contrast with OXA-bound sulfotransferase crystal structures. Although HYC is discontinued for antischistosomal treatment, it can serve as a resource for design of derivative compounds without contraindication.

Medicinal chemistry of antischistosomal drugs: Praziquantel and oxamniquine.

Neglected tropical diseases (NTDs) are a group of diseases that, besides prevailing in poverty conditions, contribute to the maintenance of social inequality, being a strong barrier to a country development. Schistosomiasis, a NTD, is a tropical and subtropical disease caused by the trematode Schistosoma mansoni (Africa, Middle East, Caribbean, Brazil, Venezuela, Suriname), japonicum (China, Indonesia, the Philippines), mekongi (several districts of Cambodia and the Lao People's Democratic Republic), intercalatum and guianensis (areas of tropical rainforests in Central Africa) and hematobium (Middle East Africa, Corsica, France) whose adult forms inhabit the mesenteric vessels of the host, while the intermediate forms are found in the aquatic gastropod snails of the genus Biomphalaria. Currently, praziquantel (PZQ) is the first line drug chosen for the treatment of schistosomiasis according to the World Health Organization (WHO) Model List of Essential Medicines, 2015. PZQ chemotherapy is considered to be the most important development for decades in the treatment of schistosomiasis. Beside the PZQ, oxamniquine (OXA) has been first described in 1969 and launched in Brazil by Pfizer under the name of Mansil® for oral administration. It has a lower cost when compared to PZQ, being active in the intestinal and hepatosplenic infections caused exclusively by S. mansoni, single species in Brazil. Both PZQ and OXA have limitations, as low efficacy in the treatment of acute schistosomiasis, low activity against S. mansoni in immature stages and resistance or tolerance, which is the reason why further research are still necessary for the development of a second generation of antischistosomal drugs. For the development of new PZQ analogs, three main strategies can be adopted: (a) synthesis and evaluation of PZQ analogues; (b) rational design of new pharmacophores; (c) discovery of new active compounds from screening programs on a large scale. Such (b) approach is difficult as the target of PZQ still unknown, the synthesis of new active analogues is possible from delineation of structure-activity relationships for PZQ. Thus, we proposed for a review article an accurate analysis of PZQ and OXA medicinal properties and uses, focusing on the pharmacochemical aspects of both drugs through 178 bibliographic references. The mechanisms of action will be discussed, with the latest information available in the literature (for the first time in the case of the oxamniquine). Cases of resistance are also discussed. As both drugs are available as a racemic mixture the biological impact of their stereochemistry to activity and side effects are reviewed. The results obtained for the combination of PZQ and artemisinin derivatives against immature worms are also introduced in the discussion. Using the information about more than 200 PZQ new derivatives synthetized during almost 35years since its discovery, a deep structure-activity relationship (SAR) is also proposed in this study.

Physiochemical interactions of praziquantel, oxamniquine and tablet excipients.

A differential scanning calorimetry and infrared spectrophotometry study of potential interactions between oxamniquine and praziquantel, two synergistic anti-parasitic drugs, indicated that they did not interact on fusion. Mixtures of the two drugs with each of nine common pharmaceutical excipients (Ac-Di-Sol, Avicel, Crospovidone, calcium phosphate, magnesium stearate, starch, lactose, PEG 6000, stearic acid) appeared to interact only with stearic acid. These results suggested that a combination solid dosage form was feasible.