1. Regenerating Lost Neurons After Spinal Cord Injury
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2. Regrowing Severed Axons to Restore Motor Function |
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Motor function deficits after spinal cord injury are primarily due to disruption of rostro-caudal axonal connections. We are using profiling approaches, strategies to visualize neuronal connections in situ and regeneration assays to pinpoint signals required for regeneration of axon tracts severed after injury. While exploring how axons spontaneously regenerate and navigate the injury environment in zebrafish, we keep an eye open on how to use our discoveries in platforms to enhance regenerative capacity in adult mammals. |
3. Elucidating Evolutionarily Conserved Spinal Cord Regeneration Responses
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Our previous studies identified some zebrafish injury-responsive chromatin regions (regeneration enhancers) functionally conserved in mouse. Notably, for some of these zebrafish enhancers recognition and function are conserved in neonatal mice, able to regrow axons after spinal cord injury as the zebrafish, but not in adult mice undergoing scarring. We are using this knowledge to identify conserved mechanisms of spinal cord regeneration across species, whose re-establishment in adult mammals would possibly boost regeneration. |