In vitro reversion of amphotericin B resistance in Leishmania donovani by poloxamer 188

A micellar formulation of amphotericin B (AmB) solubilized with poloxamer 188 was evaluated against an AmB Leishmania donovani-resistant line. A concave isobologram showed a synergistic effect of this association against promastigotes. This result was confirmed with amastigotes since the 50% effective concentration of the new formulation was 100 times less than that of the control AmB formulation

Inhibitors of retrograde trafficking active against ricin and Shiga toxins also protect cells from several viruses, Chlamydiales and Leishmania

Medical countermeasures to treat biothreat agent infections require broad-spectrum therapeutics that do not induce agent resistance. A cell-based high-throughput screen (HTS) against ricin toxin combined with hit optimization allowed selection of a family of compounds that meet these requirements. The hit compound Retro-2 and its derivatives have been demonstrated to be safe in vivo in mice even at high doses. Moreover, Retro-2 is an inhibitor of retrograde transport that affects syntaxin-5- dependent toxins and pathogens. As a consequence, it has a broad-spectrum activity that has been demonstrated both in vitro and in vivo against ricin, Shiga toxin-producing O104:H4 enterohemorrhagic E. coli and Leishmania sp. and in vitro against Ebola, Marburg and poxviruses and Chlamydiales. An effect is anticipated on other toxins or pathogens that use retrograde trafficking and syntaxin-5. Since Retro-2 targets cell components of the host and not directly the pathogen, no selection of resistant pathogens is expected. These lead compounds need now to be developed as drugs for human use

Sitamaquine as a putative antileishmanial drug candidate: from the mechanism of action to the risk of drug resistance

Sitamaquine is a 8-aminoquinoline in development for the treatment of visceral leishmaniasis by oral route, no activity being observed on the experimental cutaneous leishmaniasis experimental models. Recent data explain how sitamaquine accumulate in Leishmania parasites, however its molecular targets remain to be identified. An advantage of sitamaquine is its short elimination half-life, preventing a rapid resistance emergence. The antileishmanial action of its metabolites is not known. The selection of a sitamaquine-resistant clone of L. donovani in laboratory and the phase II clinical trials pointing out some adverse effects such as methemoglobinemia and nephrotoxicity are considered for a further development decision

Chitinolytic activities in

Chitinolytic activities were identified in the Protozoa Trichomonas vaginalis. Overall chitinase activity assessed using chitine-azure as substrate was 10.93 ± 1.21 nmoles/min/mg prot. End nonreducing chitobiosidase (exochitinase) and chitotriosidase (endochitinase) activities were shown using p-nitrophenyl-substrates and had specific activities of 4.55 ± 0.53 and 0.47 ± 0.06 nmol/min/mg prot, Kmapp.= 1.32 mM and 5 μM and pH optimum = 7.0 and 6.1 respectively. ß-N-acetylhexosaminidase (NAHase) activity was also detected with a specific activity of 5.40 ± 0.65 nmol/min/mg prot., Kmapp = 0.656 mM and pH optimum at 7.0. No release of these enzymes into the culture medium was found. The possible role of chitinases in T. vaginalis remains to be investigated

Antiprotozoal activity of ferroquine

Ferroquine (FQ, SSR97193) is a synthetic compound currently in development for the treatment of malaria. The use of a single compound to treat several parasitoses would be very convenient for multi-infected patients and also for financial considerations. In this work, the activity of FQ was investigated on three other Protista parasites: Kinetoplastidae (Leishmania and Trypanosoma) and the cosmopolite parasite Trichomonas vaginalis. FQ exhibited a significant in vitro activity on Trypanosoma brucei brucei and Trypanosoma brucei gambiense, the agents of African trypanosomiasis in a range from 0.2 to 3.1 μM. In vivo, intraperitoneally administered FQ demonstrated a weak but significant trypanocidal activity at 100 μmol/kg, which is however higher than the maximum tolerated dose. The drop of the parasitemia of the treated mice was significantly related to the amount of injected FQ. Furthermore, this organometallic compound was responsible for a delay in the appearance of bloodstream parasites at 50 μmol/kg. However, it was not able to cure infected mice. Although no synergy was identified in vitro between FQ and pentamidine, these results justify further investigations by evaluating analogues in this chemical series

In silico analysis of a therapeutic target in Leishmania infantum: the guanosine-diphospho-D-mannose pyrophosphorylase

Leishmaniases are tropical and sub-tropical diseases for which classical drugs (i.e. antimonials) exhibit toxicity and drug resistance. Such a situation requires to find new chemical series with antileishmanial activity. This work consists in analyzing the structure of a validated target in Leishmania: the GDP-mannose pyrophosphorylase (GDP-MP), an enzyme involved in glycosylation and essential for amastigote survival. By comparing both human and L. infantum GDP-MP 3D homology models, we identified (i) a common motif of amino acids that binds to the mannose moiety of the substrate and, interestingly, (ii) a motif that is specific to the catalytic site of the parasite enzyme. This motif could then be used to design compounds that specifically inhibit the leishmanial GDP-MP, without any effect on the human homolog

Studies on lipidomimetic derivatives of α-difluoromethylornithine (DFMO) to enhance the bioavailability in a

DFMO, a trypanostatic drug, presents a satisfactory intestinal absorption but its elimination from the blood is rapid so that high doses are necessary to obtain a therapeutic effect. In this study, we propose a strategy to enhance the bioavailability of DFMO by using lipidomimetic derivatives. Three lipidomimetic DFMO derivatives called ODFMO, S-DFMO and Chol-DFMO were designed to reach easily the plasma and to be cleaved preferentially by plasma esterases progressively liberating free DFMO. Chol-DFMO only could be cleaved partially whereas the other compounds appeared to be stable in a reconstituted intestinal medium and mouse plasma. Nevertheless, the use of DFMO derivatives in T. b. brucei experimental chemotherapy appeared as an interesting approach. Thus, ODFMO was trypanocidal in vitro whereas DFMO, the active principle, was only trypanostatic. Nevertheless, this compound did not release DFMO in mouse blood as expected and acted therefore not as a prodrug. Oral treatment using low doses of compound O-DFMO was able to cure 40 % mice while the active principle (eflornithine) administered at 50 fold higher molarity failed to cure any mice. This indicates that compound ODFMO acts by a specific mechanism which remains to be investigated. S-DFMO was less active and Chol-DFMO had no in vitro activity but released small amounts of DFMO in mice, however, too slight to obtain a therapeutic effect

In vivo antileishmanial action of Ir-(COD)-pentamidine tetraphenylborate on Leishmania donovani and Leishmania major mouse models

lr-(COD)-pentamidine tetraphenylborate which has previously been studied on promastigote forms of Leishmania, was investigated for its antileishmanial properties compared with pentamidine used as reference compound. In vitro, the iridium complex had the same IC50 value on intracellular forms of Leishmania as pentamidine (15 μM). In vivo, the compound could not be injected intravenously due to the DMSO excipient so that the treatments were performed intraperitoneally or subcutaneously. On the L. donovani LV9 /Balb/C mouse model, the iridium complex was not toxic after intraperitoneal treatment at 232 mg/kg/day x 5 or 147 μmoles/ kg/day x 5, whereas all the mice died within five days when treated at the same dose with pentamidine isethionate. However, only 23 % of parasite suppression was observed with the iridium complex. On a L. major MON 74/Balb/C mouse model, susceptible to intravenously administered pentamidine at 6.7 μmoles/ kg/day x 5 (54 % of parasite suppression), the iridium complex exhibited 32 % of parasite suppression after a treatment at 76 μmoles/ kg/day x 5 administered subcutaneously. This slight activity is of interest since pentamidine isethionate is not active under these conditions. Transmission electron microscopy of amastigotes from infected and treated mice show aggregation of ribosomal material, distension of the nuclear membrane and kDNA depolymerization. The mechanism of action therefore involves several targets: membranes, ribosomes and kDNA. According to our results, the Iridium complex is a suitable candidate to be encapsulated in drug carriers such as liposomes or nanoparticles

antileishmanial action of Ir-(COD)-pentamidine tetraphenylborate on

lr-(COD)-pentamidine tetraphenylborate which has previously been studied on promastigote forms of Leishmania, was investigated for its antileishmanial properties compared with pentamidine used as reference compound. In vitro, the iridium complex had the same IC50 value on intracellular forms of Leishmania as pentamidine (15 μM). In vivo, the compound could not be injected intravenously due to the DMSO excipient so that the treatments were performed intraperitoneally or subcutaneously. On the L. donovani LV9 /Balb/C mouse model, the iridium complex was not toxic after intraperitoneal treatment at 232 mg/kg/day x 5 or 147 μmoles/ kg/day x 5, whereas all the mice died within five days when treated at the same dose with pentamidine isethionate. However, only 23 % of parasite suppression was observed with the iridium complex. On a L. major MON 74/Balb/C mouse model, susceptible to intravenously administered pentamidine at 6.7 μmoles/ kg/day x 5 (54 % of parasite suppression), the iridium complex exhibited 32 % of parasite suppression after a treatment at 76 μmoles/ kg/day x 5 administered subcutaneously. This slight activity is of interest since pentamidine isethionate is not active under these conditions. Transmission electron microscopy of amastigotes from infected and treated mice show aggregation of ribosomal material, distension of the nuclear membrane and kDNA depolymerization. The mechanism of action therefore involves several targets: membranes, ribosomes and kDNA. According to our results, the Iridium complex is a suitable candidate to be encapsulated in drug carriers such as liposomes or nanoparticles

In vitro reversion of amphotericin B resistance in Leishmania donovani by poloxamer 188

A micellar formulation of amphotericin B (AmB) solubilized with poloxamer 188 was evaluated against an AmB Leishmania donovani-resistant line. A concave isobologram showed a synergistic effect of this association against promastigotes. This result was confirmed with amastigotes since the 50% effective concentration of the new formulation was 100 times less than that of the control AmB formulation