Cellular dynamics of immune evasion during Leishmania major infection

Abstract

Abstract Concomitant immunity against intracellular parasites is dictated by the immune response and parasite escape mechanisms that prevent clearance. Infection by Leishmania major generates a strong T cell response, yet parasite clearance is incomplete and leaves a small pool of persistently infected cells. T cell behaviours are augmented by the biochemical and spatial conditions of their immediate environments, and a gap in knowledge is the cellular and molecular mechanisms that prevent complete clearance of pathogen-infected cells in the skin. We combined MP-IVM with a novel T-cell receptor transgenic mouse model, where T cells recognize the immunodominant Leishmania-glycosomal phosphoenolpyruvate carboxykinase (PEPCK) peptide, to provide insights into the spatiotemporal dynamics of anti-Leishmania T cell responses during active disease and persistent infection. We show that monocyte-derived macrophage:T cell interaction dynamics were transient at steady-state, but prolonged upon antigen recognition. PEPCK-specific T cells produced high levels of IFNg in response to peptide or infection. We also show that in vitro expanded Treg cells can suppress effector T cell functions, and that greater suppression was observed by PEPCK-specific Treg cells. Ongoing studies that address the cellular and molecular mechanisms of Treg-mediated response blunting will be presented. Intravital microscopy studies characterizing PEPCK-specific T cell migration dynamics and tissue localization within skin lesions directly in live mice will also be presented. The goal of our study is to identify barriers to overcome in order to achieve complete parasite clearance and to better describe the dynamic aspects of concomitant immunity generation.