Project description:CD8+ T cells that were found accumulated in the spinal cord preceding (aged) and following a spinal cord injury disrupt wound healing. We isolated spinal cord cells of the aged mice who were treated with IgG or anti-CD8 monoclonal antibody following spinal cord injury and transcriptionally profiled them by doing single cell RNAseq to identify what cells were affected after depleting CD8+ T cells.

Project description:CD8+ T cells were found accumulated in the spinal cord preceding (aged) and following spinal cord injury. We used single cell TCR sequencing to analyze the clonality of T cells in the spinal cord and discovered that CD8+ T cells exhibit age and injury-dependent clonal expansion.

Project description:In homeostasis, because of the blood-brain barrier, immune cells rarely infiltrate the central nervous system (CNS). However, after spinal cord injury (SCI), many cells, including both myeloid and T cells, infiltrate the spinal cord. However, the role immune cells play in SCI remains controversial. We are curious whether after SCI there are self-peptides that are released and sensed by T cells that then modulate response to CNS injury.

Project description:Summary: Spinal cord injury (SCI) is a damage to the spinal cord induced by trauma or disease resulting in a loss of mobility or feeling. SCI is characterized by a primary mechanical injury followed by a secondary injury in which several molecular events are altered in the spinal cord often resulting in loss of neuronal function. Analysis of the areas directly (spinal cord) and indirectly (raphe and sensorimotor cortex) affected by injury will help understanding mechanisms of SCI. Hypothesis: Areas of the brain primarily affected by spinal cord injury are the Raphe and the Sensorimotor cortex thus gene expression profiling these two areas might contribute understanding the mechanisms of spinal cord injury. Specific Aim: The project aims at finding significantly altered genes in the Raphe and Sensorimotor cortex following an induced moderate spinal cord injury in T9.

Project description:Summary: Spinal cord injury (SCI) is a damage to the spinal cord induced by trauma or disease resulting in a loss of mobility or feeling. SCI is characterized by a primary mechanical injury followed by a secondary injury in which several molecular events are altered in the spinal cord often resulting in loss of neuronal function. Hypothesis: Spinal cord injury (SCI) induces a cascade of molecular events including the activation of genes associated with transcription factors, inflammation, oxidative stress, ionic imbalance, apoptosis and neuroregeneration which suggests the existance of endogenous reparative attempts. However, not all mechanisms following SCI are well known. Specific Aim: The goal of this project is to analyze the molecular events following spinal cord injury 1 cm above, below, and at the site of injury (T9), aiming at finding potential new targets to improve recovery and therapy.

Project description:Traumatic spinal cord injury (SCI) is a debilitating central nervous system (CNS) pathology that lacks effective restorative treatments. The mechanisms of tissue recovery after SCI are dysregulated in comparison to normal wound healing, leading to a chronic wound state, rather than a return to homeostasis. While this state is characterized by persistent inflammation driven by CNS resident microglia (MG) and infiltrating myeloid cells, the precise roles of myeloid cell subsets after SCI remains unclear. In particular, upon crossing the blood-brain barrier, tissue infiltrating monocyte-derived macrophages (MCd) take on the morphology of MG, and upregulate canonical MG markers2, making the two populations practically indistinguishable. Here, we first employed a Cx3cr1-CreERT2 mouse model to label Cx3cr1+ cells for FACS isolation. Then we utilized fate-mapping approach (see methods) to investigate the ontology and temporal dynamics of Cx3cr1+ spinal cord MG (RFP+/YFP+) and Cx3cr1+ infiltrating myeloid cells (RFP-/YFP+) via FACS isolation and single-cell RNA sequencing (scRNAseq) in a mouse model of thoracic contusion SCI. Useful Links: Github repository (https://github.com/regan-hamel/SCI_2020)

Project description:Summary: Spinal cord injury (SCI) is a damage to the spinal cord induced by trauma or disease resulting in a loss of mobility or feeling. SCI is characterized by a primary mechanical injury followed by a secondary injury in which several molecular events are altered in the spinal cord often resulting in loss of neuronal function. Analysis of the areas directly (spinal cord) and indirectly (raphe and sensorimotor cortex) affected by injury will help understanding mechanisms of SCI. Hypothesis: Areas of the brain primarily affected by spinal cord injury are the Raphe and the Sensorimotor cortex thus gene expression profiling these two areas might contribute understanding the mechanisms of spinal cord injury. Specific Aim: The project aims at finding significantly altered genes in the Raphe and Sensorimotor cortex following an induced moderate spinal cord injury in T9. Keywords: other

Project description:The aneurysm clip impact-compression model of spinal cord injury (SCI) in animals mimics the primary mechanism of SCI in human, i.e. acute impact and persisting compression; and its histo-pathological and behavioural outcomes are extensively similar to the human SCI. In order to understand the distinct molecular events underlying this injury model, an analysis of global gene expression of the acute, subacute and chronic stages of a moderate to severe injury to the rat spinal cord was conducted using a microarray gene chip approach. Rat thoracic spinal cord (T7) was injured using aneurysm clip impact-compression injury model and the epicenter area of injured spinal cord was isolated for RNA extraction and processing and hybridization on Affymetrix GeneChip arrays.

Project description:Summary: Spinal cord injury (SCI) is a damage to the spinal cord induced by trauma or desease resulting in a loss of mobility or feeling. SCI is characterized by a primary mechanical injury followed by a secondary injury in which several molecular events are altered in the spinal cord often resulting in loss of neuronal function. Hypothesis: Spinal cord injury (SCI) induces a cascade of molecular events including the activation of genes associated with transcription factors, inflammation, oxidative stress, ionic imbalance, apoptosis and neuroregeneration which suggests the existance of endogenous reparative attempts. However, not all mechanisms following SCI are well known. Specific Aim: The goal of this project is to analyze the molecular events following spinal cord injury 1 cm above, below, and at the site of injury (T9), aiming at finding potential new targets to improve recovery and therapy. Keywords: other

Project description:We conducted snRNAseq of mouse astrocytes after traumatic spinal cord injury (SCI). These data reveal transcriptomic similarities and differences among astrocytes in healthy spinal cord and after spinal cord injury.