Project description:Axons fail to regenerate in the injured spinal cord, limiting motor and autonomic recovery and contributing to long-term morbidity. Endogenous inhibitors, including those on residual myelin, contribute to regeneration failure. One inhibitor, myelin-associated glycoprotein (MAG), binds to sialoglycans and other receptors on axons. MAG inhibition of axon outgrowth in some neurons is reversed by treatment with sialidase, an enzyme that hydrolyzes sialic acids and eliminates MAG-sialoglycan binding. We delivered recombinant sialidase intrathecally to rats following a spinal cord contusive injury. Sialidase (or saline solution) was infused to the injury site continuously for 2 wk and then motor behavior, autonomic physiology, and anatomic outcomes were determined 3 wk later. Sialidase treatment significantly enhanced hindlimb motor function, improved bulbospinally mediated autonomic reflexes, and increased axon sprouting. These findings validate sialoglycans as therapeutic targets and sialidase as a candidate therapy for spinal cord injury.

Project description:Excerpt from a larger study which characterized the transcriptional effects of a spinal cord contusion injury in rats. This is the data from the almost chronic contusion state (35 days) at the injury site (Thoracic 8) - where we saw significant changes in several areas, including cholesterol metabolism genes. Other spinal cord areas (rostral, caudal) and time-points (3 hours, 24 hours, 7 days and 35 days) were analyzed as well and are discussed in our paper and at www.crpf.org/microarray. Keywords = Spinal Cord Injury Keywords = chronic Keywords = thoracic Keywords = cholesterol Keywords: repeat sample

Project description:Several interventions promote axonal growth and functional recovery when initiated shortly after central nervous system injury, including blockade of myelin-derived inhibitors with soluble Nogo receptor (NgR1, RTN4R) decoy protein. We examined the efficacy of this intervention in the much more prevalent and refractory condition of chronic spinal cord injury.We eliminated the NgR1 pathway genetically in mice by conditional gene targeting starting 8 weeks after spinal hemisection injury and monitored locomotion in the open field and by video kinematics over the ensuing 4 months. In a separate pharmacological experiment, intrathecal NgR1 decoy protein administration was initiated 3 months after spinal cord contusion injury. Locomotion and raphespinal axon growth were assessed during 3 months of treatment between 4 and 6 months after contusion injury.Conditional deletion of NgR1 in the chronic state results in gradual improvement of motor function accompanied by increased density of raphespinal axons in the caudal spinal cord. In chronic rat spinal contusion, NgR1 decoy treatment from 4 to 6 months after injury results in 29% (10 of 35) of rats recovering weight-bearing status compared to 0% (0 of 29) of control rats (p < 0.05). Open field Basso, Beattie, and Bresnahan locomotor scores showed a significant improvement in the NgR-treated group relative to the control group (p < 0.005, repeated measures analysis of variance). An increase in raphespinal axon density caudal to the injury is detected in NgR1 decoy-treated animals by immunohistology and by positron emission tomography using a serotonin reuptake ligand.Antagonizing myelin-derived inhibitors signaling with NgR1 decoy augments recovery from chronic spinal cord injury.

Project description:Spontaneous remyelination occurs after spinal cord injury (SCI), but the extent of myelin repair and identity of the cells responsible remain incompletely understood and contentious. We assessed the cellular origin of new myelin by fate mapping platelet-derived growth factor receptor α (PDGFRα), Olig2+, and P0+ cells following contusion SCI in mice. Oligodendrocyte precursor cells (OPCs; PDGFRα+) produced oligodendrocytes responsible for de novo ensheathment of ∼30% of myelinated spinal axons at injury epicenter 3 months after SCI, demonstrating that these resident cells are a major contributor to oligodendrocyte regeneration. OPCs also produced the majority of myelinating Schwann cells in the injured spinal cord; invasion of peripheral myelinating (P0+) Schwann cells made only a limited contribution. These findings reveal that PDGFRα+ cells perform diverse roles in CNS repair, as multipotential progenitors that generate both classes of myelinating cells. This endogenous repair might be exploited as a therapeutic target for CNS trauma and disease.SIGNIFICANCE STATEMENT Spinal cord injury (SCI) leads to profound functional deficits, though substantial numbers of axons often survive. One possible explanation for these deficits is loss of myelin, creating conduction block at the site of injury. SCI leads to oligodendrocyte death and demyelination, and clinical trials have tested glial transplants to promote myelin repair. However, the degree and duration of myelin loss, and the extent and mechanisms of endogenous repair, have been contentious issues. Here, we use genetic fate mapping to demonstrate that spontaneous myelin repair by endogenous oligodendrocyte precursors is much more robust than previously recognized. These findings are relevant to many types of CNS pathology, raising the possibility that CNS precursors could be manipulated to repair myelin in lieu of glial transplantation.

Project description:Axon regeneration in the central nervous system is severely hampered, limiting functional recovery. This is in part because of endogenous axon regeneration inhibitors that accumulate at the injury site. Therapeutic targeting of these inhibitors and their receptors may facilitate axon outgrowth and enhance recovery. A rat model of spinal cord contusion injury was used to test the effects of two bacterial enzyme therapies that target independent axon regeneration inhibitors, sialidase (Vibrio cholerae) and chondroitinase ABC (ChABC, Proteus vulgaris). The two enzymes, individually and in combination, were infused for 2 weeks via implanted osmotic pumps to the site of a moderate thoracic spinal cord contusion injury. Sialidase was completely stable, whereas ChABC retained>30% of its activity in vivo over the 2 week infusion period. Immunohistochemistry revealed that infused sialidase acted robustly throughout the spinal cord gray and white matter, whereas ChABC activity was more intense superficially. Sialidase treatment alone resulted in improved behavioral and anatomical outcomes. Rats treated exclusively with sialidase showed significantly increased hindlimb motor function, evidenced by higher Basso Beattie and Bresnahan (BBB) and BBB subscores, and fewer stepping errors on a horizontal ladder. Sialidase-treated rats also had increased serotonergic axons caudal to the injury. ChABC treatment, in contrast, did not enhance functional recovery or alter axon numbers after moderate spinal cord contusion injury, and dampened the response of sialidase in the dual enzyme treatment group. We conclude that sialidase infusion enhanced recovery from spinal cord contusion injury, and that combining sialidase with ChABC failed to improve outcomes.

Project description:Erbin has been shown to maintain the integrity of cell structure, regulate the proliferation and differentiation of cell and transconduct signals in the pathways. This study was conducted to assess the therapeutic effects of an Erbin inhibitor on spinal cord contusion in mice. Spinal contusion models of mouse were constructed and treated with an Erbin inhibitor. The experimental animals were divided into control (normal animal without any treatment), models with spinal cord injury (SIM), and models receiving Erbin inhibitor (Inhibitor). The contents of 5-hydroxytryptamine (5-HT) and reactive oxygen species (ROS) in the brain and spinal cord tissues were measured using ELISA. The expression of ERK1/2, MAPK, NF-kB and NRG1 was quantified using qRT-PCR, Western blot analysis and immunohistochemistry. Flow cytometry was used to determine the formation of macrophages. Erbin interference vector was constructed and its interference effect on the expression of these genes was characterized in cultured bone marrow cells. Spinal contusion models were successfully constructed. Administering Erbin inhibitor inhibited the expression of ERK1/2, MAPK and NF-kB and up-regulated the expression of NRG1. Flow cytometry showed that Erbin inhibitor induced the formation of a large number of macrophages, which are beneficial to the recovery of spinal cord injury. Experiments with Erbin interference vector showed similar impacts on the expression of genes at cellular level as the inhibitor did. Our work has demonstrated that the Erbin inhibitor is very effective to treat spinal cord contusion in mice. The possible mechanism of therapeutic effect is that the inhibitor suppresses the ERK1/2/MAPK and/or NF-kB/MAPK signal pathways and enhances the NRG1-ErbB signaling pathway by reducing the expression of Erbin, leading to the inhibition of apoptosis, promotion of proliferation and differentiation, and subsequent repair of the damaged spinal cord.

Project description:Previously, we and others have shown that rodent neural progenitor cells (NPCs) can support functional recovery after cervical and thoracic transection injuries. To extend these observations to a more clinically relevant model of spinal cord injury, we performed unilateral midcervical contusion injuries in Fischer 344 rats. Two-weeks later, E14-derived syngeneic spinal cord-derived multi-potent NPCs were implanted into the lesion cavity. Control animals received either no grafts or fibroblast grafts. The NPCs differentiated into all three neural lineages (neurons, astrocytes, oligodendrocytes) and robustly extended axons into the host spinal cord caudal and rostral to the lesion. Graft-derived axons grew into host gray matter and expressed synaptic proteins in juxtaposition with host neurons. Animals that received NPC grafts exhibited significant recovery of forelimb motor function compared with the two control groups (analysis of variance p < 0.05). Thus, NPC grafts improve forelimb motor outcomes after clinically relevant cervical contusion injury. These benefits are observed when grafts are placed two weeks after injury, a time point that is more clinically practical than acute interventions, allowing time for patients to stabilize medically, simplifying enrollment in clinical trials, and enhancing predictability of spontaneous improvement in control groups.

Project description:Spinal cord injury (SCI) is medically and socioeconomically debilitating. Currently, there is a paucity of effective therapies that promote regeneration at the injury site, and limited understanding of mechanisms that can be utilized to therapeutically manipulate spinal cord plasticity. MicroRNAs (miRNAs) constitute novel targets for therapeutic intervention to promote repair and regeneration. Microarray comparisons of the injury sites of contused and sham rat spinal cords, harvested 4 and 14 days following SCI, showed that 32 miRNAs, including miR124, miR129, and miR1, were significantly down-regulated, whereas SNORD2, a translation-initiation factor, was induced. Additionally, three miRNAs including miR21 were significantly induced, indicating adaptive induction of an anti-apoptotic response in the injured cord. Validation of miRNA expression by qRT-PCR and in situ hybridization assays revealed that the influence of SCI on miRNA expression persists up to 14 days and expands both anteriorly and caudally beyond the lesion site. Specifically, changes in miR129-2 and miR146a expression significantly explained the variability in initial injury severity, suggesting that these specific miRNAs may serve as biomarkers and therapeutic targets for SCI. Moreover, the pattern of miRNA changes coincided spatially and temporally with the appearance of SOX2, nestin, and REST immunoreactivity, suggesting that aberrant expression of these miRNAs may not only reflect the emergence of stem cell niches, but also the reemergence in surviving neurons of a pre-neuronal phenotype. Finally, bioinformatics analysis of validated miRNA-targeted genes indicates that miRNA dysregulation may explain apoptosis susceptibility and aberrant cell cycle associated with a loss of neuronal identity, which underlies the pathogenesis of secondary SCI.

Project description:Long noncoding RNAs (LncRNAs) play a crucial role in cell growth, development, and various diseases related to the central nervous system. However, LncRNA differential expression profiles in spinal cord injury are yet to be reported. In this study, we profiled the expression pattern of LncRNAs using a microarray method in a contusion spinal cord injury (SCI) mouse model. Compared with a spinal cord without injury, few changes in LncRNA expression levels were noted 1 day after injury. The differential changes in LncRNA expression peaked 1 week after SCI and subsequently declined until 3 weeks after injury. Quantitative real-time polymerase chain reaction (qRT-PCR) was used to validate the reliability of the microarray, demonstrating that the results were reliable. Gene ontology (GO) analysis indicated that differentially expressed mRNAs were involved in transport, cell adhesion, ion transport, and metabolic processes, among others. Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analysis showed that the neuroactive ligand-receptor interaction, the PI3K-Akt signaling pathway, and focal adhesions were potentially implicated in SCI pathology. We constructed a dynamic LncRNA-mRNA network containing 264 LncRNAs and 949 mRNAs to elucidate the interactions between the LncRNAs and mRNAs. Overall, the results from this study indicate for the first time that LncRNAs are differentially expressed in a contusion SCI mouse model.

Project description:Spinal cord injury (SCI) is an insult to the spinal cord resulting in a change, either temporary or permanent, in its normal motor or sensory function, but the mechanism of neuron loss after spinal cord injury is still unclear. Long non-coding RNAs (lncRNAs) can play an important role in regulating cell physiological activities through competitively binding to miRNAs. However, there is still a lack of research on the effect of lncRNAs on SCI. In this study, we selected SCI gene expression data and miRNA expression data from the NCBI database for differential expression analysis, and predicted miRNA target genes. Subsequently, biological analysis of gene expression and miRNA changes was performed on a rat SCI model. The results showed that the expression level of lncRNA-MEG increased significantly in rat SCI model. Subsequently, we found that lncRNA-MEG can promote the expression level of PDCD4 by inhibiting miR-21-5p, which leads to neuronal cell apoptosis. Furthermore, knocking down of lncRNA-MEG with shRNA can reverse the effect of miR-21-5p and inhibit the effect of PDCD4 to reduce the expression of apoptosis-related proteins. Furthermore, we found lncRNA-MEG can regulate PDCD4 expression through miR-21-5p by targeting 3'UTR of PDCD4 in the OGD cell model. In summary, we first discovered lncRNA-MEG regulates neuronal cell apoptosis through miR-21-5p by targeting PDCD4 in SCI.