Project description:This study investigates the molecular changes in the bladder following spinal cord injury (SCI) in rats and the impact of inosine treatment using a multi-omics approach. We discovered the activation of PARP (Poly(ADP-ribose) polymerase) in response to SCI, a previously unrecognized phenomenon, and its attenuation with inosine treatment. SCI triggered significant DNA damage and oxidative stress pathways, whereas inosine treatment prevents DNA damage and inhibits PARP activation, offering a potential therapeutic avenue. The integrated analysis of transcriptomics and proteomics data revealed concordant regulation of multiple pathways following SCI, including EIF2 signaling and NRF2-mediated oxidative stress response, which are ameliorated by inosine treatment. These findings have relevance to human neurogenic bladder pathobiology. Pathway inhibition by inosine in the setting of SCI suggests its potential for neuroprotection in the bladder. Despite limitations, such as the focus on male rats and a lack of proteomics data from separated detrusor and mucosa, this study provides valuable insights into the molecular mechanisms underlying bladder dysfunction following SCI. It also suggests the repurposing of FDA-approved PARP inhibitors for the treatment of bladder dysfunction following spinal injury.

Project description:Spinal cord injury (SCI) evokes profound dysfunction in hollow organs such as the urinary bladder and gut. Current treatments are limited by a lack of molecular data to inform novel therapeutic avenues. Previously, we showed systemic treatment with the neuroprotective agent inosine improved bladder function following SCI in rats. This RNA-seq dataset captures global transcriptomic changes in the rat bladder at multiple time points following spinal cord injury (SCI). Full-thickness bladder tissues were collected from male Sprague Dawley rats at 2, 8, and 16 weeks post-complete T8 spinal cord transection, alongside non-injured controls.

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:LncRNAs played a crucial role in the cell growth, development and some diseases relating to central nerve system.This study suggest that with regulating the LncRNAs expression level we might design novel therapy for spinalcord injury. In this dataset, we profiled the expression pattern of LncRNAs by microarray method after spinal cord injury (SCI). Through Gene ontology and Kyoto Encyclopedia of Genes and Genomes enrichment analysis seek LncRNAs potential function in the repair of spinal cord injury. Fifteen samples were analyzed. In these sample, we divided into five groups (sham operation, 1 day post-injured, 3 days post-injured, 1 week post-injued and 3 weeks post-injured) and each group contained three mice.After RNA extraction,RNA form mice in the same group were mixed by equal mass for the preparation of microarray.Compared with spinal cord without injury, the differential expression level of LncRNAs had a few changes at 1day post-injury, reached the peak at 1 week after SCI, and subsequently declined until 3 weeks post-injury. Genes with an FDR≤0.05 and a fold-change ≥2 were selected. Subsequently we analysis the significant differential expression genes.

Project description:We have previously shown that Il1a-knockout (KO) mice exhibit rapid (at day 1) and persistent improvements in locomotion associated with reduced lesion volume compared with Il1b-KO mice and C57BL/6 controls after traumatic spinal cord injury (SCI). To investigate the mechanism by which Il1a mediates its detrimental effect, we analyzed the transcriptome of the injured spinal cord of Il1a-KO, Il1b-KO and C57BL/6 mice at 24 hours after SCI using GeneChip microarrays. Il1a-KO, Il1b-KO and C57BL/6 mice were subjected to a 50-kdyn SCI and a 6-mm spinal cord segment centered over the site of contusion extracted for RNA isolation and microarray analysis.

Project description:Traumatic spinal cord injury (SCI) may induce irreversible damage leading to severe incapacity. Molecular mechanisms underlying SCI are not fully understood, preventing the development of novel therapeutic resources. Tamoxifen has demonstrated to be a promising therapy. Our aim was to elucidate the molecular mechanisms involved in the beneficial effect of TMX administered after SCI. We use a rat model of SCI, Tamoxifen was administred intraperitoneal 30 min after injury. Four groups were organized, 1) Non-injured without TMX (Sham/TMX-), 2) Non-injured with TMX (Sham/TMX+), 3) Injured without TMX (SCI/TMX-), and 4) Injured with TMX (SCI/TMX+). From the comparison between Sham/TMX- and SCI/TMX-, 708 genes showed differential expression. Among the relevant genes Anxa1 was upregulated, this gene’s product is a promising marker of injury severity. Enriched pathways were the spinal cord injury pathway and pathways related to inflammatory response. When comparing SCI/TMX- versus SCI/TMX+, only 30 genes showed differential expression. Our results reinforce the key role of inflammatory response in SCI and Tamoxifen seem to be able to regulate this response by suppressing changes in gene expression. Our data also support the potential of previously described severity markers.

Project description:Spinal cord injury (SCI) refers to the damage to the spinal cord due to trauma, disease or degeneration, and the number of new cases is increasing yearly. The changes of cells in the area of SCI are significant to tissue injury. However, the changes in cellular composition, the trajectory of cell development and the interesting relationship of intercellular communication in the injured area are still unclear. In this study, we used single-cell RNA sequencing to evaluate almost all the cell types that make up the site of SCI in rats.

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:The goal of this study was to compare the transcriptional effects of sciatic nerve injury and spinal cord injury on lumbar dorsal root ganglion (DRG) and FACS-sorted dorsal column (DC) sensory neurons. We performed RNA-seq of whole DRG from naïve and spinal cord-injured (SCI) mice (1dpi) and compared this with previously published data for sciatic nerve transection. In order to assess changes specifically in DC neurons, we performed RNA-seq from FACS-sorted DC neurons from Thy1-YFP16 transgenic mice in naïve, sciatic nerve injured (SNI), and SCI (1 and 3dpi). We found that DC neurons alter their transcriptome after SCI, but that gene changes after SCI mostly differ from SNI. These transcriptional differences may reflect both growth promoting and growth inhibitory effects on axon regeneration after SCI.

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.