Characterization of the Immune Stimulated Release of Extracellular Vesicles from Murine Cells

Abstract

Introduction: Viruses, extracellular vesicles (EVs) and endogenous retroviruses (ERVs) are types of sub-micron particles which are known to be released from a vast range of cell types, across many species. There are many medically relevant sub-micron particles which can enter healthy cells and enable the intercellular delivery of functional host-derived and foreign products, through their enclosed lipid layers. While multiple particle subsets have been identified, many of the properties, behaviors and biochemical functions have not been fully described and have yet to be characterized. Materials and Methods: CD4⁺ naïve T-cells were isolated from female C57BL6/N mice and stimulated with varying concentrations of PMA/I. In addition to concentration, the length of PMA/I activation was assessed. Supernatants and cells were harvested, filtered, and stained to be subsequently analyzed by Nanoscale Flow Cytometry, Nanoparticle Tracking Analysis and Flow Cytometry. Particle populations were quantified and sorted by size, by NTA. Labelling dye CFSE was used in conjunction with fluorescently conjugated CD81 and CD9 antibodies to separate EVs, including exosomes, from background signal. Naïve T-cell purity, viability and levels of activation were assessed by flow cytometry using CD3, CD4 and CD62L antibodies and viability staining. Results: Increasing PMA concentration led to a global increase in particles by T-cells and a specific increase in smaller particle production and were demonstrated to be significant by Welch’s T-test, when compared to non-activated and DMSO controls (p<0.0001). In addition to concentration, activation length also correlated with increases in total particle counts and a specific increase in the secretion of smaller particles in comparison to non-activated and DMSO controls (p<0.0001). Labelling techniques by NFC revealed an increased presence of CFSE-CD81 positive and CFSE-CD9 positive particles secreted by T-cells, treated for 24 hours, compared to the 0- and 12-hour timepoints. Conclusion: This work demonstrates preliminary steps and outlines methods to begin assessing discrete particle populations and subsets secreted by murine naïve T-cells. Being able to identify patterns of particle secretions by naïve T-cells, especially under immune-stimulated conditions, may be the solution to uncovering the necessary information on EV physiology, that is required to understand the roles EVs play in pathology and how these conserved pathways may lead conditions to become exacerbated. This knowledge is essential to uncovering the roles EVs play in pathophysiology, and in the development of novel rapid diagnostic tests, to screen for cancers, infections, autoimmune disorders, and numerous other pathological conditions.