Project description:Time dependent-profiles in the gene expression level following lateral moderate fluid percussion injury in the rat brain We used microarray to elucidate relationship between the alteration of gene expression levels and the progression of brain damages following traumatic brain injury. To examine the levels of gene expression in the early phase of traumatic brain injury, we analyzed the gene expression at 3, 6, 12, and 48 h after trauma using the lateral moderate fluid percussion TBI model. The ratios of the gene expression level were compared between chips corresponding to the 3, 6 and 12 h fluid percussion groups and the sham group chips. On the other hand, the rations of gene expression level after 48 h FPI were compared with 48 h sham chip, because the gene expression levels of 48 h sham chip were distinct from sham group chips (3, 6 and 12 h) in the cluster and principal components analyses.
Project description:Time dependent-profiles in the gene expression level following lateral moderate fluid percussion injury in the rat brain We used microarray to elucidate relationship between the alteration of gene expression levels and the progression of brain damages following traumatic brain injury.
Project description:Injury to the adult brain induces activation of resident astrocytes, which serves as a compensatory response modulating tissue damage and recovery. However, the mechanism governing astrocyte activation and the role of reactive astrocytes remain largely unknown. Here we show that SOX2, a transcription factor critical for stem cells and brain development, is also required for injury-induced activation of adult cortical astrocytes. Genome-wide ChIP-seq analysis reveals that SOX2 binds to regulatory regions of genes associated with signaling pathways controlling reactive gliosis, such as Socs3, Nr2e1, Notch1, and Akt2. Inducible deletion of Sox2 in adult astrocytes greatly diminishes their response to traumatic injury and, most unexpectedly, restricts injury-induced cortical loss. Together, these results uncover an essential role of SOX2 in terminally differentiated cells and implicate that SOX2-dependent reactive astrocytes may be targeted for regeneration after traumatic brain injury.