Lipidomic signatures in microglial extracellular vesicles during acute inflammation: a gateway to neurological biomarkers

Extracellular vesicles (EVs) are membrane bound vesicles released from all cells throughout the body, including the central nervous system, and are known to carry both membrane-bound proteins and cargo reflective of their cell of origin. EVs show promise as neurological disease biomarkers due to their molecular makeup reflecting their parent-cell composition signature and due to their ability to cross the blood-brain barrier. To-date, the vast majority of research in this field has explored the protein profiles of EVs; however, lipids play an important role not only in the formation of EVs, but also in mediating cellular function and the pathological progression of many neurodegenerative conditions. Herein, we take a critical first step in determining the potential utility of EV lipids as biomarkers in neurological disease. In vitro we exposed BV-2 microglia to either control media or media containing lipopolysaccharides (LPS), a known pro- inflammatory stimulus, for 24 hours then isolated both the cells and their EVs and performed LC-MS/MS. For the first time, we reveal distinct lipidomic changes can differentiate resting vs. pro-inflammatory microglia and their EVs, while distinct lipids are preserved between EVs and their parent cell. Moreover, we add to current literature by demonstrating acute pro-inflammatory activation of microglia results in the activation and suppression of distinct lipidomic pathways.

Finally, we demonstrate that analysis of lipid-based relationships between parent cells and their EVs may be a useful tool to infer cellular function. This study is the first of its kind to demonstrate that lipidomic analysis can not only differentiate the functional state of cells in vitro but can also differentiate their EVs. We lay the first brick in a foundation to support future research into EV lipids as novel and exciting biomarker candidates in neurological disease.