Ready-to-use qPCR for detection of Cyclospora cayetanensis or Trypanosoma cruzi in food matrices.

Foodborne outbreaks caused by parasites have long been a public health issue. Among the available contamination detection methods, qPCR is one of the most sensitive and specific. However, it can be cumbersome and error-prone, if used by unexperienced users. Moreover, qPCR reagents usually require freezer temperatures for transportation and storage. We present a gelified reaction format that allows the reagents to be stored at 2-8 °C for up to 90 days without losing performance. The gelification process eliminates most operator mistakes during reaction setup, and renders the qPCR plates ready-to-use. The new reaction makeup was evaluated using artificially contaminated samples of distinct food matrices for sensitivity, specificity, repeatability, reproducibility, and stability. Samples consisted of cilantro leaves and raspberry fruits spiked with Cyclospora cayetanensis oocysts, as well as açai pulp and sugarcane juice tainted with Trypanosoma cruzi trypomastigotes. No significant difference between the gelified and the non-gelified qPCR was found. Our results suggest that gelifying the assay may help to achieve more reproducible qPCR data across laboratories, thus supporting surveillance actions. (170 words).

Proof of Concept for a Portable Platform for Molecular Diagnosis of Tropical Diseases: On-Chip Ready-to-Use Real-Time Quantitative PCR for Detection of Trypanosoma cruzi or Plasmodium spp.

Although molecular diagnostics is well established in clinical laboratories, its full potential has not been extended to field settings. Typically, diagnostic real-time quantitative PCR (qPCR) reagents require temperature-controlled transportation and storage. Furthermore, thermocyclers are bulky and fragile, requiring good infrastructure for optimal operation. These major hurdles strongly limit use of molecular-based tests in low-resource scenarios. Herein, Trypanosoma cruzi or Plasmodium spp. DNA were detected with qPCR using commercial equipment (ABI7500 instrument) and a prototype platform comprising a portable device and a silicon chip, named Q3-Plus. In addition, a ready-to-use reaction format, where all qPCR reagents are stored on plate or on chip, was compared with the traditional freezer-stored format. No significant differences were observed in detecting T. cruzi or Plasmodium spp. DNA between thermocyclers, as well as between reagents' formats, for storage periods of up to 28 days (at 2°C to 8°C or 21°C to 23°C, respectively). When challenged with patients' samples, the Q3-Plus system performed as efficiently as the standard equipment for Plasmodium spp. DNA detection, showing it to be a valuable solution to malaria point-of-care diagnostics. Detection of T. cruzi DNA in chronic patients' samples using the Q3-Plus system yielded approximately 50% efficiency relative to the ABI7500. These results are essential to support future endeavors to bring molecular diagnostics to the point of care, where most needed.

Profiling the Trypanosoma cruzi phosphoproteome.

Protein phosphorylation is a reversible post-translational modification essential for the regulation of several signal transduction pathways and biological processes in the living cell. Therefore, the identification of protein phosphorylation sites is crucial to understand cell signaling control at the molecular level. Based on mass spectrometry, recent studies have reported the large-scale mapping of phosphorylation sites in various eukaryotes and prokaryotes. However, little is known about the impact of phosphorylation in protozoan parasites. To in depth characterize the phosphoproteome of Trypanosoma cruzi, a parasite of the Kinetoplastida class, protein samples from cells at different phases of the metacyclogenesis--differentiation process of the parasites from non-infective epimastigotes to infective metacyclic trypomastigotes--were enriched for phosphopeptides using TiO(2) chromatography and analyzed on an LTQ-Orbitrap mass spectrometer. In total, 1,671 proteins were identified, including 753 phosphoproteins, containing a total of 2,572 phosphorylation sites. The distribution of phosphorylated residues was 2,162 (84.1%) on serine, 384 (14.9%) on threonine and 26 (1.0%) on tyrosine. Here, we also report several consensus phosphorylation sequence motifs and as some of these conserved groups have enriched biological functions, we can infer the regulation by protein kinases of this functions. To our knowledge, our phosphoproteome is the most comprehensive dataset identified until now for Kinetoplastida species. Here we also were able to extract biological information and infer groups of sites phosphorylated by the same protein kinase. To make our data accessible to the scientific community, we uploaded our study to the data repositories PHOSIDA, Proteome Commons and TriTrypDB enabling researchers to access information about the phosphorylation sites identified here.

Trypanosoma cruzi infection induces a global host cell response in cardiomyocytes.

Chagas' disease, caused by the hemoflagellate protozoan Trypanosoma cruzi, affects millions of people in South and Central America. Chronic chagasic cardiomyopathy, the most devastating manifestation of this disease, occurs in approximately one-third of infected individuals. Events associated with the parasite's tropism for and invasion of cardiomyocytes have been the focus of intense investigation in recent years. In the present study, we use murine microarrays to investigate the cellular response caused by invasion of primary murine cardiomyocytes by T. cruzi trypomastigotes. These studies identified 353 murine genes that were differentially expressed during the early stages of invasion and infection of these cells. Genes associated with the immune response, inflammation, cytoskeleton organization, cell-cell and cell-matrix interactions, apoptosis, cell cycle, and oxidative stress are among those affected during the infection. Our data indicate that T. cruzi induces broad modulations of the host cell machinery in ways that provide insight into how the parasite survives, replicates, and persists in the infected host and ultimately defines the clinical outcome of the infection.