Abstract The contribution of antiviral resident memory T cells (TRM) to blood-brain barrier disruption has not been defined despite the implication of this lymphocyte in clinical encephalitis. We therefore evaluated the capacity of TRM cells to induce CNS vascular permeability in mice which resolved Theiler’s murine encephalomyelitis (TMEV) infection. Following TMEV infection of the brain, persistent populations of virus antigen specific resident memory T cells are induced within the brain. This population of resident memory T cells can be further reactivated at 60 dpi through administration of the cognate immunodominant virus peptide antigen, VP2, inducing blood brain barrier disruption in the process. We determined that brain resident memory T cells expand following reactivation with administered VP2 peptide. This reactivation is associated with infiltration of T cells, and inflammatory myeloid cells into the brain. Importantly, using depletion and T cell sequestrating strategies with low dose anti CD8 antibodies and FTY720, we determined that TRM induced blood-brain barrier disruption is independent of peripheral T cells. We conclude that reactivation of brain TRM cells during peptide administration occurs without dependency on peripheral responses, highlighting the importance of this cell type in inducing neuroinflammation and underlying neuropathology.