In vitro characterization of Trypanosoma cruzi infection dynamics in skeletal and cardiac myotubes models suggests a potential cell-to-cell transmission in mediating cardiac pathology.

Chagas disease predominantly affects the heart, esophagus, and colon in its chronic phase. However, the precise infection mechanisms of the causal agent Trypanosoma cruzi in these tissue types remain incompletely understood. This study investigated T. cruzi infection dynamics in skeletal (SM) and cardiac myotubes (CM) differentiated from H9c2(2-1) myoblasts (control). SM and CM were generated using 1% fetal bovine serum (FBS) without or with retinoic acid, respectively. Initial invasion efficiencies and numbers of released parasites were equivalent between undifferentiated and differentiated cells (~0.3-0.6%). Concomitantly, parasite motility patterns were similar across cell lines. However, CM demonstrated significantly higher infection kinetics over time, reaching 13.26% infected cells versus 3.12% for SM and 3.70% for myoblasts at later stages. Cellular automata modeling suggested an enhanced role for cell-to-cell transmission in driving the heightened parasitism observed in CM. The increased late-stage susceptibility of CM, potentially mediated by cell-to-cell transfer mechanisms of the parasite, aligns with reported clinical tropism patterns. The myotube infection models provide novel insights into Chagas disease pathogenesis that are not fully attainable through in vivo examination alone. Expanding knowledge in this area could aid therapeutic development for this neglected illness.

Trypanosoma cruzi: multiple actin isovariants are observed along different developmental stages.

The expression and biological role of actin during the Trypanosoma cruzi life cycle remains largely unknown. Polyclonal antibodies against a recombinant T. cruzi actin protein were used to confirm its expression in epimastigotes, trypomastigotes, and amastigotes. Although the overall levels of expression were similar, clear differences in the subcellular distribution of actin among the developmental stages were identified. The existence of five actin variants in each developmental stage with distinct patterns of expression were uncovered by immunoblotting of protein extracts separated 2D-SDS gels. The isoelectric points of the actin variants in epimastigotes ranged from 4.45 to 4.9, whereas they ranged from 4.9 to 5.24 in trypomastigotes and amastigotes. To determine if the actin variants found could represent previously unidentified actins, we performed a genomic survey of the T.cruzi GeneDB database and found 12 independent loci encoding for a diverse group of actins and actin-like proteins that are conserved among trypanosomatids.

Cellular analysis of host cell infection by different developmental stages of Trypanosoma cruzi.

Trypanosoma cruzi is an obligate intracellular parasite that infects phagocytic and non-phagocytic mammalian cells by a complex process that appears to involve several discrete steps. Even though the infection process was described many years ago, the molecular mechanisms involved remain poorly understood. As fluorescent proteins have proven to be excellent tools for live-cell imaging, we used EGFP- and DsRed1-1-transfected trypomastigotes, amastigotes and epimastigotes to study the infection process in living cells. Contrary to what has been reported, our results showed that epimastigotes are as infective as trypomastigotes and amastigotes. Besides, differences in replication, differentiation and parasite release times were observed among the stages. Our results suggest that the different developmental stages use distinct attachment and invasion mechanisms. We propose that fluorescent-based plasmid expression systems are good models for studying the infection process of intracellular microorganisms and could offers insights about the molecular mechanisms involved.

Gamma-glutamylcysteine synthetase and tryparedoxin 1 exert high control on the antioxidant system in Trypanosoma cruzi contributing to drug resistance and infectivity.

Trypanothione (T(SH)2) is the main antioxidant metabolite for peroxide reduction in Trypanosoma cruzi; therefore, its metabolism has attracted attention for therapeutic intervention against Chagas disease. To validate drug targets within the T(SH)2 metabolism, the strategies and methods of Metabolic Control Analysis and kinetic modeling of the metabolic pathway were used here, to identify the steps that mainly control the pathway fluxes and which could be appropriate sites for therapeutic intervention. For that purpose, gamma-glutamylcysteine synthetase (γECS), trypanothione synthetase (TryS), trypanothione reductase (TryR) and the tryparedoxin cytosolic isoform 1 (TXN1) were separately overexpressed to different levels in T. cruzi epimastigotes and their degrees of control on the pathway flux as well as their effect on drug resistance and infectivity determined. Both experimental in vivo as well as in silico analyses indicated that γECS and TryS control T(SH)2 synthesis by 60-74% and 15-31%, respectively. γECS overexpression prompted up to a 3.5-fold increase in T(SH)2 concentration, whereas TryS overexpression did not render an increase in T(SH)2 levels as a consequence of high T(SH)2 degradation. The peroxide reduction flux was controlled for 64-73% by TXN1, 17-20% by TXNPx and 11-16% by TryR. TXN1 and TryR overexpression increased H2O2 resistance, whereas TXN1 overexpression increased resistance to the benznidazole plus buthionine sulfoximine combination. γECS overexpression led to an increase in infectivity capacity whereas that of TXN increased trypomastigote bursting. The present data suggested that inhibition of high controlling enzymes such as γECS and TXN1 in the T(SH)2 antioxidant pathway may compromise the parasite's viability and infectivity.

Los productos alternativos de LYT1 de Trypanosoma cruzi tienen un patrón de localización diferencial / The alternative products of Trypanosoma cruzi LYT1 have different localization patterns

LYT1 is a molecule with lytic activity under acidic conditions that, as genetically demonstrated, participates in the infection and stage transition of T. cruzi. The differing functions of this protein result from alternative trans-splicing, resulting in proteins that contain either a secretion and nuclear sequence (LYT1s) or the nuclear sequence alone (LYT1n). To determine the localization of different LYT1 products, transgenic parasites expressing LYT1s or LYT1n fused to the enhanced green fluorescence sequence were analyzed. LYT1s-EGFP localized to the flagellum, vacuoles, membrane and regions of the nucleus and kinetoplast; LYT1n-EGFP localized to the nucleus and kinetoplast, and occasionally in vacuoles. These results show that even though different LYT1 products localize to the same sites, they are also found in different intracellular organelles and microenvironments, which could influence their multifunctional behavior.

LYT1 es una molécula con actividad lítica en condiciones ácidas, que según se demostró genéticamente, participa en el proceso de infección y transición de estadio de T. cruzi. Su diferente funcionalidad es resultado de la producción de dos proteínas, obtenidas por trans-empalme alternativo, que contienen una secuencia de secreción y una nuclear (LYT1s) o únicamente la secuencia nuclear (LYT1n). Para evaluar la localización de los diferentes productos de LYT1, se analizaron parásitos transgénicos que expresan la secuencia de LYT1s o LYT1n fusionada con la secuencia de la verde fluorescente. LYT1s-EGFP se localiza en flagelo, vacuolas, membrana y región del núcleo y cinetoplasto; mientras que, LYT1n-EGFP se localiza en la región del núcleo y cinetoplasto, y ocasionalmente en vesículas. Estos resultados muestran que aún cuando los distintos productos de LYT1 comparten algunos sitios de localización, también se encuentran en distintos organelos y microambientes intracelulares que podrían influir en su comportamiento multifuncional.