A short-term method to evaluate anti-leishmania drugs by inhibition of stage differentiation in Leishmania mexicana using flow cytometry.

Leishmaniasis is a vector-borne neglected tropical disease caused by the Leishmania spp. Parasite. The disease is transmitted to humans and animals by the bite of infected female sandflies during the ingestion of bloodmeal. Because current drug treatments induce toxicity and parasite resistance, there is an urgent need to evaluate new drugs. Most therapeutics target the differentiation of promastigotes to amastigotes, which is necessary to maintain Leishmania infection. However, in vitro assays are laborious, time-consuming, and depend on the experience of the technician. In this study, we aimed to establish a short-term method to assess the differentiation status of Leishmania mexicana (L. mexicana) using flow cytometry. Here, we showed that flow cytometry provides a rapid means to quantify parasite differentiation in cell culture as reliably as light microscopy. Interestingly, we found using flow cytometry that miltefosine reduced promastigote-to-amastigote differentiation of L. mexicana. We conclude that flow cytometry provides a means to rapidly assay the efficacy of small molecules or natural compounds as potential anti-leishmanials.

Mining Trypanosoma cruzi Genome Sequences for Antigen Discovery and Vaccine Development.

A large number of studies have demonstrated that Trypanosoma cruzi can be controlled by vaccines in animal models, but the identification of effective vaccine antigens represents one of the most critical steps in vaccine development. Thus, only a limited diversity of parasite antigens has been empirically tested as vaccine candidates. More recently, genome-to-vaccine approaches, based principally on T-cell epitope prediction, have emerged as powerful strategies to accelerate vaccine development. In parallel, the increased availability of extensive genomic information on multiple T. cruzi strains offers a major resource for data mining and antigen identification. We present here some of the key strategies for T. cruzi genome mining for antigen discovery and vaccine development.

Molecular Genotyping of Trypanosoma cruzi by Next-Generation Sequencing of the Mini-Exon Gene Reveals Infections With Multiple Parasite Discrete Typing Units in Chagasic Patients From Yucatan, Mexico.

The diversity of Trypanosoma cruzi parasites infecting humans is still poorly understood. We used deep sequencing to analyze this diversity in chagasic patients from Mexico. Such information is crucial to understand transmission cycles and to identify determinants of epidemiological and clinical characteristics of the infection. We analyzed parasite mini-exon spliced-leader sequences following amplification of blood DNA by polymerase chain reaction and deep sequencing. Chagasic patients presented a diverse assemblage of parasite haplotypes covering TcI, TcII, TcV, and TcVI discrete typing units, with a mean (±SEM) of 3.9 ± 0.7 haplotypes/patient, and 47% harbored infections with multiple discrete typing units. Most parasite haplotypes from patients were identical or similar to those for Triatoma dimidiata from the same region, confirming their local circulation. Infection with multiple T. cruzi strains may influence serological diagnostic test results and disease progression in patients and should be taken into account to evaluate associations between parasite diversity and clinical aspects of T. cruzi infections.

From genome screening to creation of vaccine against Trypanosoma cruzi by use of immunoinformatics.

Chagas disease is caused by the protozoan parasite Trypanosoma cruzi, and activation of CD8(+) T cells is crucial for a protective immune response. Therefore, the identification of antigens with major histocompatibility complex class I epitopes is a crucial step for vaccine development against T. cruzi. Our aim was to identify novel antigens and epitopes by immunoinformatics analysis of the parasite proteome (12 969 proteins) and to validate their immunotherapeutic potential in infected mice. We identified 172 predicted epitopes, using NetMHC and RANKPEP. The corresponding protein sequences were reanalyzed to generate a consensus prediction, and 26 epitopes were selected for in vivo validation. The interferon γ (IFN-γ) recall response of splenocytes from T. cruzi-infected mice confirmed that 10 of 26 epitopes (38%) induced IFN-γ production. The immunotherapeutic potential of a mixture of all 10 peptides was evaluated in infected mice. The therapeutic vaccine was able to control T. cruzi infection, as evidenced by reduced parasitemia, cardiac tissue inflammation, and parasite burden and increased survival. These findings illustrate the benefits of this approach for the rapid development of a vaccine against pathogens with large genomes. The identified peptides and the proteins from which they are derived are excellent candidates for the development of a vaccine against T. cruzi.