Nasopharyngeal aspirate cytokine levels 1 yr after severe respiratory syncytial virus infection

Respiratory syncytial virus (RSV) infection is an important cause of recurrent wheezing in infants. Nevertheless, the link between RSV infection and wheezing has yet to be elucidated at the molecular level. Here, we present a preliminary study on the evolution of the immune response in the respiratory tract at long‐term after RSV infection. Twenty‐seven immune mediators were profiled in nasopharyngeal aspirates (NPAs) obtained from 20 children hospitalized due to a severe infection by RSV at discharge from hospital and again 1 yr later. The same mediators were profiled in parallel in NPAs from 12 healthy controls. In the year following discharge, 85% (17/20) of children of the RSV group suffered at least one episode of wheezing documented by the pediatrician. On the contrary, wheezing episodes were observed only in 25% (3/12) of children in the control group. While most of the mediators profiled returned to normal levels by 1 yr after discharge from hospital, RSV children showed a persistent nasal hyper‐secretion of VEGF, G‐CSF, IL‐10, IL‐6, IFN‐γ, IL‐7 and IL‐13. In previous works VEGF, IL‐10 and IFN‐γ have been put in relation with the pathogenesis of post‐virus induced asthma. G‐CSF, IL‐6, IL‐7 and IL‐13 are increased in respiratory and plasma samples of asthmatic patients. Here, we evidence for the first time a persistent elevation of these mediators as late as 1 yr after severe RSV disease resolution, reinforcing their possible implication in the pathogenesis of wheezing.     

Propulsion of African trypanosomes is driven by bihelical waves with alternating chirality separated by kinks

Trypanosoma brucei, a parasitic protist with a single flagellum, is the causative agent of African sleeping sickness. Propulsion of T. brucei was long believed to be by a drill-like, helical motion. Using millisecond differential interference-contrast microscopy and analyzing image sequences of cultured procyclic-form and bloodstream-form parasites, as well as bloodstream-form cells in infected mouse blood, we find that, instead, motility of T. brucei is by the propagation of kinks, separating left-handed and right-handed helical waves. Kink-driven motility, previously encountered in prokaryotes, permits T. brucei a helical propagation mechanism while avoiding the large viscous drag associated with a net rotation of the broad end of its tapering body. Our study demonstrates that millisecond differential interference-contrast microscopy can be a useful tool for uncovering important short-time features of microorganism locomotion.     

Immune detection of acetylcholinesterase in subcellular compartments of Trypanosoma evansi

Trypanosoma evansi is a worldwide distributed hemoparasite with a strong economic impact in veterinary activities. Despite widespread knowledge about the etiology of the disease caused by T. evansi, there are few detailed studies about the metabolism of this parasite. The aim of this study was to determine the presence of Acetylcholinesterase (AChE) in T. evansi through a strategy of subcellular localization and confocal microscopy. The localization of the AChE by differential and isopycnic centrifugation strategy showed that this enzyme has a predominant localization in the glycosome, similar to hexokinase, and it is not present in either the cytosol or the plasma membrane. This study shows novel data that help to understand the non-neuronal role of AChE in the Trypanosomatidae family.     

Export of RNA silencing from C. elegans tissues does not require the RNA channel SID-1

Double-stranded RNA (dsRNA) triggers RNA interference (RNAi) to silence genes of matching sequence. In some animals this experimentally induced silencing is transported between cells, and studies in the nematode Caenorhabditis elegans have shown that the dsRNA channel SID-1 is required for the import of such transported silencing signals. Gene silencing can also be triggered by endogenously expressed RNAi triggers, but it is unknown whether such silencing is transported between cells. Here, we show that, in C. elegans, SID-1 is required for efficient silencing of multicopy transgenes, indicating that mobile silencing signals contribute to transgene silencing. Further, most tissues can transport silencing initiated by the tissue-specific transgenic expression of RNAi triggers to other tissues, consistent with expressed RNAi triggers generating mobile silencing signals. Whereas the import of silencing signals requires SID-1, we found that mobile silencing signals generated by transgene-expressed RNAi triggers are exported to other tissues through a SID-1-independent mechanism. Furthermore, when RNAi triggers are expressed in ingested Escherichia coli, silencing signals can be transported to internal tissues from the gut lumen across gut cells that lack SID-1. Thus, C. elegans can transport endogenous and exogenous RNA silencing signals between many different tissues via at least 2 SID-1 independent export pathways.