Abstract
The human pathogenic amoeba Acanthamoeba castellanii (A. castellanii) causes severe diseases, including acanthamoeba keratitis and encephalitis. Pathogenicity arises from the killing of target-cells by an extracellular killing mechanism, where the crucial first step is the formation of a close contact between A. castellanii and the target-cell. This process is mediated by the glycocalix of the target-cell and mannose has been identified as key mediator. The aim of the present study was to carry out a detailed biophysical investigation of mannose-mediated adhesion of A. castellanii using force spectroscopy on single trophozoites. In detail, we studied the interaction of a mannose-coated cantilever with an A. castellanii trophozoite, as mannose is the decisive part of the cellular glycocalix in mediating pathogenicity. We observed a clear increase of the force to initiate cantilever detachment from the trophozoite with increasing contact time. This increase is also associated with an increase in the work of detachment. Furthermore, we also analyzed single rupture events during the detachment process and found that single rupture processes are associated with membrane tether formation, suggesting that the cytoskeleton is not involved in mannose binding events during the first few seconds of contact. Our study provides an experimental and conceptual basis for measuring interactions between pathogens and target-cells at different levels of complexity and as a function of interaction time, thus leading to new insights into the biophysical mechanisms of parasite pathogenicity.
Highlights
Pathogenic amoebae can cause severe and hard-to-treat infections, ranging from localized infections to life-threatening diseases, such as encephalitis [1]
As only pathogenic A. castellanii displayed adhesion to the mannose-agarose beads we conducted a further, more detailed study of the mannose dependent adhesive behavior of A. castellanii using atomic force microscope (AFM) based force spectroscopy to learn more about the binding dynamics of these parasites to mannose
Previous studies on the mannose-mediated adhesion of acanthamoebae have shown that their pathogenicity is related to the expression of an mannose-binding proteins (MBP) and to adhesion to mannose [17,18,19]
Summary
Pathogenic amoebae can cause severe and hard-to-treat infections, ranging from localized infections to life-threatening diseases, such as encephalitis [1]. Most amoeba-related diseases occur in regions with limited access to clean water resources. Swimming pools and contact lenses have been identified as sources of contamination with Acanthamoeba spp. and Naegleria spp. The genus Acanthamoeba spp. consists of species of free-living amoebae [2, 5]. There are both pathogenic acanthamoebae, such as Acanthamoeba castellanii [5] or A. culbertsoni [6], and non-pathogenic acanthamoebae like A. comandani [7]
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