Ergosterone-coupled Triazol molecules trigger mitochondrial dysfunction, oxidative stress, and acidocalcisomal Ca2+ release in Leishmania mexicana promastigotes.

The protozoan parasite Leishmania causes a variety of sicknesses with different clinical manifestations known as leishmaniasis. The chemotherapy currently in use is not adequate because of their side effects, resistance occurrence, and recurrences. Investigations looking for new targets or new active molecules focus mainly on the disruption of parasite specific pathways. In this sense, ergosterol biosynthesis is one of the most attractive because it does not occur in mammals. Here, we report the synthesis of ergosterone coupled molecules and the characterization of their biological activity on Leishmania mexicana promastigotes. Molecule synthesis involved three steps: ergosterone formation using Jones oxidation, synthesis of Girard reagents, and coupling reaction. All compounds were obtained in good yield and high purity. Results show that ergosterone-triazol molecules (Erg-GTr and Erg-GTr2) exhibit an antiproliferative effect in low micromolar range with a selectivity index ~10 when compared to human dermic fibroblasts. Addition of Erg-GTr or Erg-GTr2 to parasites led to a rapid [Ca2+]cyt increase and acidocalcisomes alkalinization, indicating that Ca2+ was released from this organelle. Evaluation of cell death markers revealed some apoptosis-like indicators, as phosphatidylserine exposure, DNA damage, and cytosolic vacuolization and autophagy exacerbation. Furthermore, mitochondrion hyperpolarization and superoxide production increase were detected already 6 hours after drug addition, denoting that oxidative stress is implicated in triggering the observed phenotype. Taken together our results indicate that ergosterone-triazol coupled molecules induce a regulated cell death process in the parasite and may represent starting point molecules in the search of new chemotherapeutic agents to combat leishmaniasis.

Programmed cell death in African trypanosomes.

Until recently it had generally been assumed that apoptosis and other forms of programmed cell death evolved during evolution of the metazoans to regulate growth and development in these multicellular organisms. However, recent research is adding strength to the original phenotypic observations described almost a decade ago which indicated that some parasitic protozoa may have evolved a cell death pathway analogous to the process described as apoptosis in metazoa. Here we explore the implications of a programmed cell death pathway in the African tsetse-transmitted trypanosomes.

Prostaglandin-induced programmed cell death in Trypanosoma brucei involves oxidative stress.

Recently, we reported the induction of a programmed cell death (PCD) in bloodstream forms of Trypanosoma brucei by prostaglandin D(2) (PGD(2)). As this prostanoid is readily metabolized in the presence of albumin, we were prompted to investigate if PGD(2) metabolites rather than PGD(2) itself are responsible for the observed PCD. In fact, J series metabolites, especially PGJ(2) and Delta(12)PGJ(2), were able to induce PCD more efficiently than PGD(2). However, the stable PGD(2) analog 17phenyl-trinor-PGD(2) led to the same phenotype as the natural PGD(2), indicating that the latter induces PCD as well. Interestingly, the intracellular reactive oxygen species (ROS) level increased significantly under J series metabolites treatment and, incubation with N-acetyl-L-cysteine or glutathione reduced ROS production and cell death significantly. We conclude that PGJ(2) and Delta(12)PGJ(2) formation within the serum represents a mechanism to amplify PGD(2)-induced PCD in trypanosomes via ROS production.

Prostaglandin D2 induces programmed cell death in Trypanosoma brucei bloodstream form.

African trypanosomes produce some prostanoids, especially PGD2, PGE2 and PGF2alpha (Kubata et al. 2000, J. Exp. Med. 192: 1327-1338), probably to interfere with the host's physiological response. However, addition of prostaglandin D2 (but not PGE2 or PGF2alpha) to cultured bloodstream form trypanosomes led also to a significant inhibition of cell growth. Based on morphological alterations and specific staining methods using vital dyes, necrosis and autophagy were excluded. Here, we report that in bloodstream form trypanosomes PGD2 induces an apoptosis-like programmed cell death, which includes maintenance of plasma membrane integrity, phosphatidylserine exposure, loss of mitochondrial membrane potential, nuclear chromatin condensation and DNA degradation. The use of caspase inhibitors cannot prevent the cell death, indicating that the process is caspase-independent. Based on these results, we suggest that PGD2-induced programmed cell death is part of the population density regulation as observed in infected animals.

Cell differentiation and infectivity of Leishmania mexicana are inhibited in a strain resistant to an ABC-transporter blocker.

We analysed whether markers of cell differentiation and infectivity differed when compared to the parental sensitive strain [NR(Gs)] in an in vitro selected Leishmania strain [NR(Gr)] resistant to Glibenclamide, an ATP-binding-cassette (ABC)-transporter blocker. The data show that the cell body area was larger in NR(Gr) compared to NR(Gs) and that functional characters associated with an infective metacyclic phenotype, such as resistance to the lytic effect of the alternative complement pathway and expression of the Meta-1 protein, were reduced. The infectivity of NR(Gr) to J774.1 macrophages was also significantly reduced. These results suggest that resistance in Leishmania against Glibenclamide, a general blocker of P-glycoproteins, could produce functional modifications that may be relevant for Leishmania differentiation, infectivity and survival.

Molecular pharmacology of chemo-resistant leishmania

Infectious diseases leishmaniosis among them, constitute a leading cause of death world wide, especially in the developing world, where they remain as an important cause of concern and has become a serious problem because of the everyday enhanced risk of co infection with HIV and the increasing frequency of resistance development of the parasites to the drug agents. Emergence of drug resistance is usually associated with changes in the expression of an specific membrane P-glycoprotein, but also includes physiological responses with high complexity. In the present review we summarize results which emphasize that the comprehesion of the molecular pharmacology of drug-resistant phenotype must include, as a way for identifying new strategies for the control of the disease, the understanding of the multiple biochemical and functional parasite mechanisms involved

Experimental leishmaniasis: the glibenclamide-triggered decrease in parasite growth correlates with changes in macrophage features.

Previous studies from our laboratories revealed the susceptibility of Leishmania sp. to glibenclamide (GLIB), a potassium channel blocker which selectively interacts with adenosine-binding-cassette transporters. In the present work, we analyzed whether the drug sensitivity of intracellular amastigotes correlates with changes in macrophage features that are related to their function as antigen-presenting cells. We provide evidence that in BALB/c murine macrophages, GLIB induced a decrease in the interferon-gamma-stimulated expression of major histocompatibility complex class II molecules and the co-stimulatory molecule CD86 (B7-2). Furthermore, it caused a decrease in the interleukin-1 secretion by macrophages. The data indicate that the treatment with GLIB inhibits the Th2 development and polarizes macrophage functions towards the induction of a protective Th1 response.

Changes in the infectivity, pyruvate kinase activity, acid phosphatase activity and P-glycoprotein expression in glibenclamide-resistant Leishmania mexicana.

We previously demonstrated susceptibility of Leishmania sp. to glibenclamide, a K+ -ATP transport blocker which interacts with members of the superfamily of adenosine 5' triphosphate-binding cassette transporters. In order to characterize the molecular differences between a sensitive Leishmania strain, NR(Gs), and an experimentally selected glibenclamide-resistant strain, NR(Gr), specific biochemical and functional parameters have been evaluated both in the wild type and in the resistant strain. Most noteworthy, NR(Gr) exhibit an increased expression of P-glycoprotein and a decreased activity of functional key enzymes such as acid phosphatase, a prominent virulent factor of the parasite, and pyruvate kinase, a key control enzyme for both carbohydrate and protein metabolism. The specific biochemical, metabolic and functional changes observed in the resistant strain correlated with a reduced infectivity of stationary phase NR(Gr) in J774 macrophages and suggested a mechanism to overcome the effect of glibenclamide.