Project description:Among the vertebrates, teleost and urodele amphibians are capable of regenerating their central nervous system. We have used crush injury method on zebrafish spinal cord, which is a common mammalian mode of injury in spinal cord. To identify the molecular mechanisms of the underlying cellular events during regeneration of zebrafish spinal cord, we have employed high density oligonucleotide microarrays and profiled the temporal transcriptome dynamics during the entire phenomenon. A total of 3842 genes expressed differentially with significant fold changes during spinal cord regeneration. Cluster analysis revealed event specific dynamic expression of genes related to inflammation, cell death, cell migration, cell proliferation, neurogenesis, neural patterning and axonal regrowth. We have also validated the expression pattern of 14 genes (which include inflammatory regulators, cell cycle regulators, pattern forming genes and signaling molecules) by different methodologies. Spatio-temporal analysis of STAT3 expression suggested its possible function in controlling inflammation and cell proliferation. Genes involved in the proliferating neural progenitors and their dorso-ventral patterning (sox2 and dbx2) are differentially expressed. Injury induced cell proliferation is controlled by many cell cycle regulators and some of them also show their common expression in other regenerating systems like fin, heart and retina. We also reported unusual expression pattern of certain pathway genes like one carbon folate metabolism and N-glycan biosynthesis which have not been reported during regeneration of spinal cord. Genes like stat3, socs3, atf3, mmp9 and sox11, which are known to control peripheral nervous system (PNS) regeneration in mammals, are also upregulated in zebrafish spinal cord injury (SCI) thus creating PNS like environment after injury. Our study provides a comprehensive genetic blue print of diverse cellular response(s) during regeneration of zebrafish spinal cord that could be used to induce successful regeneration in mammals. The spinal cord has been injured by crushing dorso-ventrally for 1 sec with a number 5 Dumont forceps at the level of 15th/16th vertebrae. Later the wound were sealed by placing a suture. Both spinal cord injured and sham operated fish were allowed to regenerate and the progress of regeneration was observed after 1, 3, 7, 10 and 15 days of injury. Zebrafishes were anesthetized deeply for 5 minutes in 0.1% tricaine (MS222; Sigma, USA) and approximately 1mm length of spinal cord both rostrally and caudally from injury epicenter were dissected out from 50-60 fishes in each batch and pooled for RNA extraction.

Project description:Among the vertebrates, teleost and urodele amphibians are capable of regenerating their central nervous system. We have used crush injury method on zebrafish spinal cord, which is a common mammalian mode of injury in spinal cord. To identify the molecular mechanisms of the underlying cellular events during regeneration of zebrafish spinal cord, we have employed high density oligonucleotide microarrays and profiled the temporal transcriptome dynamics during the entire phenomenon. A total of 3842 genes expressed differentially with significant fold changes during spinal cord regeneration. Cluster analysis revealed event specific dynamic expression of genes related to inflammation, cell death, cell migration, cell proliferation, neurogenesis, neural patterning and axonal regrowth. We have also validated the expression pattern of 14 genes (which include inflammatory regulators, cell cycle regulators, pattern forming genes and signaling molecules) by different methodologies. Spatio-temporal analysis of STAT3 expression suggested its possible function in controlling inflammation and cell proliferation. Genes involved in the proliferating neural progenitors and their dorso-ventral patterning (sox2 and dbx2) are differentially expressed. Injury induced cell proliferation is controlled by many cell cycle regulators and some of them also show their common expression in other regenerating systems like fin, heart and retina. We also reported unusual expression pattern of certain pathway genes like one carbon folate metabolism and N-glycan biosynthesis which have not been reported during regeneration of spinal cord. Genes like stat3, socs3, atf3, mmp9 and sox11, which are known to control peripheral nervous system (PNS) regeneration in mammals, are also upregulated in zebrafish spinal cord injury (SCI) thus creating PNS like environment after injury. Our study provides a comprehensive genetic blue print of diverse cellular response(s) during regeneration of zebrafish spinal cord that could be used to induce successful regeneration in mammals.

Project description:Label-free mass spectrometry-based quantitative proteomics was applied to a larval zebrafish spinal cord injury model, which allows axon regeneration and functional recovery within two days (days post lesion; dpl) after a spinal cord transection in 3 day-old larvae (dpf). Proteomic profiling was performed of the lesion site at 1 dpl in control animals and animals with pdgfrb+ cell-specific overexpression of either zebrafish chondoradherin (chad; chad-mCherry fusion), fibromodulin a (fmoda; fmoda-mCherry fusion), lumican (lum; lum-mCherry fusion) or prolargin (prelp; prelp-mCherry fusion).

Project description:Label-free mass spectrometry-based quantitative proteomics was applied to a larval zebrafish spinal cord injury model, which allows axon regeneration and functional recovery within two days (days post lesion; dpl) after a spinal cord transection in 3 day-old larvae (dpf). Proteomic profiling of the lesion site was performed at 1 dpl and 2 dpl as well as corresponding age-matched unlesioned control tissue (4 dpf as control for 1 dpl; 5 dpf as control for 2 dpl).

Project description:Spinal cord injury (SCI) is a devastating condition resulting in permanent and irreversible deficits. Despite regeneration attempts, the neurons fail due to several dysfunctions. A number of studies have already revealed that, following SCI, microRNAs show two opposite kinds of alterations, one detrimental and one protective. However, there is still little evidence of specific microRNAs involved in axon regrowth. The aim of this project is the characterization of microRNA expression changes in sensorimotor cortex and corticospinal motor neurons, whose axons are severed by SCI.

Project description:Spinal cord injury (SCI) is a devastating condition resulting in permanent and irreversible deficits. Despite regeneration attempts, the neurons fail due to several dysfunctions. A number of studies have already revealed that, following SCI, microRNAs show two opposite kinds of alterations, one detrimental and one protective. However, there is still little evidence of specific microRNAs involved in axon regrowth. The aim of this project is the characterization of microRNA expression changes in sensorimotor cortex and corticospinal motor neurons, whose axons are severed by SCI.

Project description:Spinal cord injury (SCI) results in loss of neurons, oligodendrocytes and myelin sheaths, all of which are not efficiently restored. The scarcity of oligodendrocytes in the lesion site impairs remyelination of spared fibres, which leaves axons denuded, impedes signal transduction and contributes to permanent functional deficits. In contrast to mammals, zebrafish can functionally regenerate the spinal cord. Yet, little is known about oligodendroglial lineage biology and remyelination capacity after SCI in a regeneration-permissive context. Here, we report that in adult zebrafish, SCI results in axonal, oligodendrocyte and myelin sheath loss. We find that OPCs, the oligodendorocyte progenitor cells, survive the injury, enter a reactive state, proliferate and differentiate into oligodendrocytes. Concomitantly, the oligodendrocyte population is re-established to pre-injury levels within two weeks.Transcriptional profiling revealed that reactive OPCs upregulate the expression of several myelination-related genes. Interestingly, global reduction of axonal tracts and partial re-myelination, relative to pre-injury levels, persist at later stages of regeneration, yet suffices for functional recovery. Taken together, these findings imply that in the zebrafish spinal cord, OPCs replace lost oligodendrocytes and, thus, re-establish myelination during regeneration.

Project description:Spinal cord injury (SCI) results in loss of neurons, oligodendrocytes and myelin sheaths, all of which are not efficiently restored. The scarcity of oligodendrocytes in the lesion site impairs remyelination of spared fibres, which leaves axons denuded, impedes signal transduction and contributes to permanent functional deficits. In contrast to mammals, zebrafish can functionally regenerate the spinal cord. Yet, little is known about oligodendroglial lineage biology and remyelination capacity after SCI in a regeneration-permissive context. Here, we report that in adult zebrafish, SCI results in axonal, oligodendrocyte and myelin sheath loss. We find that OPCs, the oligodendorocyte progenitor cells, survive the injury, enter a reactive state, proliferate and differentiate into oligodendrocytes. Concomitantly, the oligodendrocyte population is re-established to pre-injury levels within two weeks.Transcriptional profiling revealed that reactive OPCs upregulate the expression of several myelination-related genes. Interestingly, global reduction of axonal tracts and partial re-myelination, relative to pre-injury levels, persist at later stages of regeneration, yet suffices for functional recovery. Taken together, these findings imply that in the zebrafish spinal cord, OPCs replace lost oligodendrocytes and, thus, re-establish myelination during regeneration.

Project description:The lamprey is a vertebrate that, unlike mammals, achieves spontaneous recovery after spinal cord transection. Despite anatomical, physiological, and behavioral data on spinal cord regeneration in lamprey, the molecular mechanisms underlying this capacity are largely unknown. To address this, we used RNA-Seq to obtain transcriptional profiles from uninjured animals and at 10 time points ranging from 6 hours to 12 weeks post injury. Overall, 4208 (spinal cord) and 3788 (brain) transcripts are differentially expressed (DE). Complex intraspinal and supraspinal responses were induced acutely and occurred even at chronic phases of recovery. Leveraging functional data for mammalian homologs of DE genes (via Enrichr) permitted identification of enriched conserved genes and pathways. These included genes and pathways induced after mammalian peripheral nerve injury, such as those associated with regeneration, immune function, cell growth, proliferation and cell death. For example, ATF3, a transcription factor implicated in mammalian peripheral nerve regeneration, is highly expressed and enriched in lamprey spinal cord and brain after SCI. Other homologs of regeneration-associated genes that are differentially expressed after SCI include members of the WNT, HDAC, SOX, SMAD, KLF, and JUN families. This study provides the first comprehensive view of transcriptional responses during successful anatomical and functional recovery from spinal cord injury in lamprey, and reveals unexpectedly large changes in transcription in the brain, which is quite distant from the spinal lesion site. Gene expression patterns associated with functional recovery in lamprey may be useful in guiding studies aimed at modulating mammalian responses to SCI.

Project description:Neonatal spinal cord tissues exhibit remarkable regenerative capabilities compared to adult tissues following injury. Although some cellular signaling pathways involved in the process have been identified, the specific role of extracellular matrix (ECM) responsible for neonatal spinal cord regeneration has remained elusive. Here we revealed that early developmental spinal cord contained a higher abundance of ECM proteins associated with neural development and axon growth but fewer inhibitory proteoglycans compared to adult spinal cord. Decellularized spinal cord ECM from neonatal (DNSCM) and adult (DASCM) rabbits preserve the major difference of native spinal cord tissues in both stages. Compared to DASCM, DNSCM promoted proliferation, migration, and neuronal differentiation of neural progenitor cells (NPCs), as well as facilitated the long-distance axonal outgrowth and axon regeneration of spinal cord organoids. Pleiotrophin (PTN) and Tenascin (TNC) in DNSCM were identified as contributors to the remarkable neural regeneration ability. Furthermore, DNSCM demonstrated superior performance when used as a delivery vehicle for NPCs and organoids in rats with spinal cord injury (SCI). It suggests that ECM cues derived from different development stage might contribute to the distinct regeneration ability of spinal cord.