We studied the migratory and functional characteristics of different immune cells, mainly NK cells, using an in vitro model of the blood brain barrier (BBB) and complex multiparameter flow cytometry. Different immune cells can be added into the model and it is possible to study the immune phenotype, capability to transmigrate, cytotoxicity and other functions of the cells that are capable to cross the barrier. Thus, it is possible to determine possible mechanisms that allow cells to migrate. Furthermore, our study of the immune cell compartment in blood and in cerebrospinal fluid of patients with TBE has been possible due to the collection of a small cohort of such patients that we have analysed. Additionally, we are currently studying the effect of different neurotropic viruses on the integrity of the BBB as well as on the activation of immune cells.
Here, we report that among the lymphocytic cell population, the CD56bright, a subset of NK cells, possess a high migratory capability in the presence of brain endothelial cells and the expression of cell adhesion molecules such as CD11a, CD11b and CD29 are important in the total lymphocytic migration process. The cells with higher migratory capability also seem to possess a higher cytotoxic capability as determined by the high specific target cell lysis and the association with a higher activation status determined by high expression of CD69, Granzyme A, Granzyme B and perforin.
About the study of patient samples with TBE, we are still acquiring and processing data. However, we have observed that the CD56bright NK cell population is highly increased in the CFS of TBE patients in comparison to peripheral blood, and the cells also seem to have a similar pattern of activation. Our results in vitro partially resemble the observations we have obtained in vivo and thus, the collection of more TBE patients is crucial to complete a broad picture of the immunological features during a viral infection in CNS. Furthermore, our current studies on the effect of neurotropic viruses on the BBB integrity and on immune cell activation will help us understand more the interplay between different immune components in mounting an immune response towards a viral infection in the CNS. Altogether, we have acquired insights on the migratory capabilities of different cell populations, which may add value in understanding the complex immune mobilization process between blood and tissues taking place to keep a homeostatic balance.