Histone deacetylase enzymes as potential drug targets of Neglected Tropical Diseases caused by cestodes

Cestode parasites cause neglected diseases, such as echinococcosis and cysticercosis, which represent a significant problem in human and animal health. Benzimidazoles and praziquantel are the only available drugs for chemotherapy and it is therefore important to identify new alternative drugs against cestode parasites. Histone deacetylases (HDACs) are validated drug targets for the treatment of cancer and other diseases, including neglected diseases. However, knowledge of HDACs in cestodes is very scarce. In this work, we investigated cestode HDACs as potential drug targets to develop new therapies against neglected diseases caused by cestodes. Here we showed the full repertoire of HDAC coding genes in several members of the class Cestoda. Between 6 and 7 zinc-dependent HDAC coding genes were identified in the genomes of species from Echinococcus, Taenia, Mesocestoides and Hymenolepis genera. We classified them as Class I and II HDACs and analyzed their transcriptional expression levels throughout developmental stages of Echinococcus spp. We confirmed for the first time the complete HDAC8 nucleotide sequences from Echinococcus canadensis G7 and Mesocestoides corti. Homology models for these proteins showed particular structural features which differentiate them from HDAC8 from Homo sapiens. Furthermore, we showed that Trichostatin A (TSA), a pan-HDAC inhibitor, decreases the viability of M. corti, alters its tegument and morphology and produces an increment of the total amount of acetylated proteins, including acetylated histone H4. These results suggest that HDAC from cestodes are functional and might play important roles on survival and development. The particular structural features observed in cestode HDAC8 proteins suggest that these enzymes could be selectively targeted. This report provides the basis for further studies on cestode HDAC enzymes and for discovery of new HDAC inhibitors for the treatment of neglected diseases caused by cestode parasites.

Unique pharmacological properties of serotoninergic G-protein coupled receptors from cestodes

Background

Cestodes are a diverse group of parasites, some of them being agents of neglected diseases. In cestodes, little is known about the functional properties of G protein coupled receptors (GPCRs) which have proved to be highly druggable targets in other organisms. Notably, serotoninergic G-protein coupled receptors (5-HT GPCRs) play major roles in key functions like movement, development and reproduction in parasites.

Methodology/Principal findings

Three 5-HT GPCRs from Echinococcus granulosus and Mesocestoides corti were cloned, sequenced, bioinformatically analyzed and functionally characterized. Multiple sequence alignment with other GPCRs showed the presence of seven transmembrane segments and conserved motifs but interesting differences were also observed. Phylogenetic analysis grouped these new sequences within the 5-HT7 clade of GPCRs. Molecular modeling showed a striking resemblance in the spatial localization of key residues with their mammalian counterparts. Expression analysis using available RNAseq data showed that both E. granulosus sequences are expressed in larval and adult stages. Localization studies performed in E. granulosus larvae with a fluorescent probe produced a punctiform pattern concentrated in suckers. E. granulosus and M. corti larvae showed an increase in motility in response to serotonin. Heterologous expression revealed elevated levels of cAMP production in response to 5-HT and two of the GPCRs showed extremely high sensitivity to 5-HT (picomolar range). While each of these GPCRs was activated by 5-HT, they exhibit distinct pharmacological properties (5-HT sensitivity, differential responsiveness to ligands).

Conclusions/Significance

These data provide the first functional report of GPCRs in parasitic cestodes. The serotoninergic GPCRs characterized here may represent novel druggable targets for antiparasitic intervention.

Cestode parasites are flatworms with the ability to parasitize almost every vertebrate species. Several of these parasites are etiological agents of neglected diseases prioritized by WHO, such as hydatid disease, or hydatidosis, a zoonosis caused by species of the genus Echinococcus that affects millions of people worldwide. Due to the scarcity of anthelmintic drugs available and the emergence of resistant parasites, the discovery of new anthelmintic drugs is mandatory. Neuromuscular function has been the target of commonly used drugs against parasitic diseases to impact movement, parasite development and reproduction. Here we describe three new proteins, some of them highly expressed in cestodes which could be relevant for motility. Using different approaches, the three proteins were identified as G protein coupled receptors for serotonin, an important neurotransmitter and a known modulator of cestode motility. These new receptors exhibit unique characteristics including a particular sensitivity to serotonin as well as a distinctive pharmacology, which will assist their targeting for chemotherapeutic intervention.

Inhibition of HIV-1 replication in human monocyte-derived macrophages by parasite Trypanosoma cruzi

BACKGROUND

Cells of monocyte/macrophage lineage are one of the major targets of HIV-1 infection and serve as reservoirs for viral persistence in vivo. These cells are also the target of the protozoa Trypanosoma cruzi, the causative agent of Chagas disease, being one of the most important endemic protozoonoses in Latin America. It has been demonstrated in vitro that co-infection with other pathogens can modulate HIV replication. However, no studies at cellular level have suggested an interaction between T. cruzi and HIV-1 to date.

METHODOLOGY/PRINCIPAL FINDINGS

By using a fully replicative wild-type virus, our study showed that T. cruzi inhibits HIV-1 antigen production by nearly 100% (p<0.001) in monocyte-derived macrophages (MDM). In different infection schemes with luciferase-reporter VSV-G or BaL pseudotyped HIV-1 and trypomastigotes, T. cruzi induced a significant reduction of luciferase level for both pseudotypes in all the infection schemes (p<0.001), T. cruzi-HIV (>99%) being stronger than HIV-T. cruzi (approximately 90% for BaL and approximately 85% for VSV-G) infection. In MDM with established HIV-1 infection, T. cruzi significantly inhibited luciferate activity (p<0.01). By quantifying R-U5 and U5-gag transcripts by real time PCR, our study showed the expression of both transcripts significantly diminished in the presence of trypomastigotes (p<0.05). Thus, T. cruzi inhibits viral post-integration steps, early post-entry steps and entry into MDM. Trypomastigotes also caused a approximately 60-70% decrease of surface CCR5 expression on MDM. Multiplication of T. cruzi inside the MDM does not seem to be required for inhibiting HIV-1 replication since soluble factors secreted by trypomastigotes have shown similar effects. Moreover, the major parasite antigen cruzipain, which is secreted by the trypomastigote form, was able to inhibit viral production in MDM over 90% (p<0.01).

CONCLUSIONS/SIGNIFICANCE

Our study showed that T. cruzi inhibits HIV-1 replication at several replication stages in macrophages, a major cell target for both pathogens.

Different Trypanosoma cruzi strains promote neuromyopathic damage mediated by distinct T lymphocyte subsets

The proliferative response of CD4 and CD8 T lymphocytes obtained from C3H/HeN mice chronically infected with Trypanosoma cruzi strains that differ in virulence, tropism and immunogenicity, was assayed against skeletal muscle, sciatic nerve and spinal cord homogenates. Although both CD4 and CD8 T lymphocytes from mice infected with the RA strain strongly proliferated against the nervous system, no response against skeletal muscle antigens was detected. CD4 and CD8 T lymphocytes from mice infected with the K-98 clone (from CA-I strain) showed low proliferative response against all the antigens assayed. To determine whether the proliferation patterns showed correlation with T cell-mediated neuromuscular damage, passive cell transfer studies were performed. Fifteen days after transfer of CD4 T cells from RA-infected donors (CD4-RA), normal syngeneic recipients displayed exclusively nervous tissue damage, such as perineural, endoneural and/or meningeal inflammatory infiltrates, with predominance of CD4 T cells. Fifteen days after transfer of CD4 T lymphocytes from mice infected with K-98 (CD4-K98), recipients showed inflammatory infiltrates only in skeletal muscle, where CD4 T lymphocytes and macrophages were predominant cells. Recipients of CD8 T cells from RA-infected mice (CD8-RA) showed lesions in both spinal cord and sciatic nerves. Higher percentages of CD8 T cells were observed in comparison with the recipients of CD4-RA or CD4-K98. In contrast, CD8 T cells from K-98-infected donors (CD8-K98) did not induce tissue damage. These results provide evidence that mice infected with T. cruzi populations that differ in their biological characteristics show diverse immune mechanisms that may be involved in the pathogenesis of peripheral nervous system damage.

Lymphocyte muscarinic cholinergic activity and PGE2 involvement in experimental Trypanosoma cruzi infection

In this paper, we demonstrated that the production of PGE2 by CD8+ T lymphocytes through muscarinic cholinergic receptor (mAChR) activation of lymphocytes from mice acutely infected with nonlethal Trypanosoma cruzi CA-1 strain could enhance resistance to infection. Treatment in vivo with either atropine or cyclooxygenase inhibitors enhanced mortality rates and parasitemia of mice infected with T. cruzi CA-1 strain. The mechanism by which CD8+ T lymphocytes released PGE2 appears to involve the activation of the cells by circulating IgG present in mice infected with T. cruzi CA-1 strain. Binding of these antibodies to mAChR on CD8+ T lymphocytes triggered the release of large amounts of PGE2. The results point to a role of serum antibodies against mAChR in the protection of T. cruzi infection. The prostanoid acting as an immunomodulator contributed to the maintenance of the chronic course of experimental Chagas disease.

PGE2 involvement in experimental infection with Trypanosoma cruzi subpopulations

PGE2 involvement in experimental Trypanosoma cruzi infection depends on the lethal capacity of the parasite subpopulation used. Mice acutely infected with non-lethal K98 displayed an enhancement in PGE2 serum levels during the acute period, while those infected with lethal T. cruzi subpopulations (RA or K98-2) showed levels not different from normal mice. The enhancement detected in K98 group could be related both to an increased number of CD8+ T cell number and to enhanced PGE2 release per cell by CD8+; values of PGE2 release by adherent cells were not altered in this group. Treatment with cyclooxygenase inhibitors enhanced mortality rates of mice infected with K98, and administration of 16,16-dimethyl PGE2 (dPGE) reversed this effect. However, mice infected with RA did not reduce their mortality rates by administration of diverse doses of dPGE. These findings suggest that PGE2 could play a role in resistance in mice infected with K98.

In vivo macrophage function in experimental infection with Trypanosoma cruzi subpopulations

The macrophage function was investigated in mice infected with Trypanosoma cruzi. Two subpopulations of the parasite were utilized, RA and K98. Strain RA is efficiently internalized by macrophages and is lethal for mice, and clone K98 is poorly phagocytosed by macrophages and is not lethal. Treatment with silica enhanced parasitemia and mortality in mice infected with both parasite subpopulations. Parasitemia kinetics, however, were affected only in mice infected with RA, which suggests that macrophage effector mechanisms may play a more relevant role in this experimental group than in mice infected with K98. Resistance to Salmonella typhimurium infection and bactericidal activity of macrophages depended upon the T. cruzi subpopulation utilized and the infection period. Infection with K98 induced only a trend towards enhanced resistance to bacterial challenge during both the acute and chronic phases, whereas a significantly enhanced bactericidal activity of spleen and liver phagocytes was observed. Mice acutely infected with RA showed significantly enhanced susceptibility to S. typhimurium infection and lower bactericidal activity. Mice surviving infection with this aggressive strain, however, showed significantly enhanced resistance and bactericidal activities. Mice acutely infected with the RA strain displayed a dissociation between macrophage capacities to control S. typhimurium and T. cruzi. A similar phenomenon was also observed in other parasitoses (schistosomiasis, African trypanosomiasis). This fact may be due to differences in the lethal mechanisms through which macrophages control these parasites and S. typhimurium.

Induction of macrophage activation and opsonizing antibodies by Trypanosoma cruzi subpopulations

Macrophage activation and production of opsonizing antibodies were studied in mice either infected with a lethal and reticulotropic Trypanosoma cruzi strain, RA, or with a non lethal and myotropic strain, CA-I, as well as with a clone, K98 (derived from CA-I), similar to the parental strain. Measurement of macrophage respiratory burst by chemiluminescence disclosed that T. cruzi infection induced an enhancement of the respiratory burst, no matter the parasite subpopulation employed. But, while in mice surviving RA infection the respiratory burst was higher than during the acute period and parasitaemia was efficiently controlled, in mice infected with K98 enhanced respiratory burst coexisted with measurable levels of parasitaemia either at acute or chronic infection periods. Macrophage activation was also proved by enhanced trypanocidal activity in macrophages derived from mice infected with any of the parasite subpopulations. Sera from RA mice opsonized and lysed T. cruzi bloodstream forms efficiently, whereas sera from CA-I or K98 mice neither lysed nor opsonized this parasite stage. All three subpopulations assayed here showed IgG bound to their membranes in vivo and similar capping kinetics, but only antibodies bound to RA parasites invariably triggered lysis. Therefore, the role played by macrophage activation in resistance and control of Pm levels is related to some features of each T. cruzi subpopulation, such as its capacity to invade macrophages and to elicit opsonizing antibodies.

[Trypanosoma cruzi: induction of changes in the peripheral nervous system in different strains of mice]

This study has been designed to find an easy method to evaluate the motor unit alterations induced during experimental T. cruzi infections. Different mouse strains infected with three strains of T. cruzi were used to perform conventional needle electromyography, in one of the lower limb hamstring muscles; amplitude, duration and number of phases of single motor unit potentials were measured. The following parasite strain to mouse strain relationship was investigated, in mice inoculated intraperitoneally with bloodstream forms of T. cruzi: Tulahuen and C3H/HeN, C57Bl, Balb/c, Swiss; CA-I and C3H/HeN, Rockland, NIH; RA and C3H/HeN, Rockland. T. cruzi-induced denervating alterations were found in both C3H/HeN and C57Bl mice infected with the Tulahuen strain, as well as in C3H/HeN mice inoculated with the CA-I strain. Moreover, CA-I trypomastigotes could produce primary muscle changes in C3H/HeN and NIH mice. The technique employed in this investigation proved to be an easy and adequate way to detect changes within the motor unit during T. cruzi infection in mice.