Abstract
BackgroundBrain inflammation is a key cause of cognitive decline after central nervous system (CNS) infections. A thorough understanding of immune responses to CNS infection is essential for developing anti-inflammatory interventions that improve outcomes. Tissue-resident memory T cells (TRM) are non-recirculating memory T cells that provide surveillance of previously infected tissues. However, in addition to protecting the brain against reinfection, brain TRM can contribute to post-infectious neuroinflammation. We hypothesized that accumulation of CD8+TRM in the brain could be reduced by inhibiting microRNA (miR)-155, a microRNA that influences development of cytotoxic CD8+ T lymphocytes during infection.MethodsC57BL/6J mice were infected by intraperitoneal injection with a lethal inoculum of Listeria monocytogenes (Lm) then treated with antibiotics. Flow cytometry was used to quantify specific populations of brain leukocytes 28–29 days (d) post-infection (p.i.). To test the degree to which miR-155 altered leukocyte influxes into the brain, infected mice were injected with a miR-155 inhibitor or locked nucleic acid (LNA) scramble control 2d, 4d, 6d, and 8d p.i. along with antibiotic treatment. Bacterial loads in spleen and liver and body weights were measured up to 7d p.i. Brain leukocytes were analyzed 14d and 28d p.i. Confirmatory studies were performed in mutated mice lacking miR-155 (miR-155−/−)ResultsLm infection significantly increased the numbers of brain CD3+CD8+ lymphocytes at 28d p.i. These cells were extravascular, and displayed markers characteristic of TRM, with the predominant phenotype of CD44+CD62L-CD69+CX3CR1−. Further analysis showed that > 75% of brain TRM also expressed CD49a, PD-1, Ly6C, CD103, and CD127. Mice injected with miR-155 inhibitor lost less weight through 7d p.i. than did control mice, whereas bacterial loads in brain, liver, and spleen were not different from controls. By 28d p.i., the numbers of brain CD8+ TRM cells were significantly decreased in mice treated with the inhibitor compared with controls. Similarly, miR-155−/− mice showed significantly reduced numbers of brain CD8+TRM cells by 28d p.i.ConclusionsBrain CD8+ TRM populations are established during neuroinvasive Lm infection. Accumulation of brain CD8+ TRM cells is reduced by blocking miR-155 and in miR-155−/− mice, indicating that this molecule has a critical role in development of these specialized cells. Administering anti-miR-155 during infection could provide a novel avenue for reducing post-infectious neuroinflammation.
Highlights
Brain inflammation is a key cause of cognitive decline after central nervous system (CNS) infections
Accumulation of brain CD8+ T resident memory cells (TRM) cells is reduced by blocking miR-155 and in miR-155−/− mice, indicating that this molecule has a critical role in development of these specialized cells
Prior studies demonstrated that brain TRM (BTRM) promoted rapid clearance of ovalbuminexpressing Listeria monocytogenes (Lm) that were inoculated intracranially into mice previously injected with ovalbumin-pulsed dendritic cells [11]
Summary
Brain inflammation is a key cause of cognitive decline after central nervous system (CNS) infections. Leukocytes recruited to the infected CNS are a key source of pro-inflammatory mediators, such as IFN-γ and TNF, as well as chemokines that recruit additional cells and amplify the inflammatory response. These proinflammatory mediators activate microglia and facilitate pathogen removal, and negatively affect cognitive function and can cause mood disorders in survivors [7]. A recently described population of T lymphocytes, T resident memory cells (TRM), establish longlived populations within infected tissues to provide immune surveillance and rapid pathogen removal in the case of re-infection [9]. Recent studies show that BTRM can be generated during peripheral viral and bacterial infections, and promote pathogen clearance from the brain [13]
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