Abstract
A major goal of spinal cord injury research is to develop a path to endogenous regeneration. This approach has been heavily informed by animal models of natural regeneration. An unresolved question is whether these models rebuild the spinal cord by exclusively accessing developmental mechanisms of neuron differentiation. To address this question, we contrasted single-cell gene expression during regeneration with stage-matched controls in the conditionally regenerative frog Xenopus tropicalis . We generated an expanded atlas of neuronal diversity, annotating several neurons in Xenopus for the first time. From this atlas, we found that the neuron composition of the developing and regenerating spinal cord differ. So do the strategies employed, which favor waves of cell-type specific neuron morphogenesis, proliferation, and proliferative neurogenesis during regeneration. Low levels of early neurogenesis are then compensated by movement of post-mitotic neurons. Our work highlights the use of distinct developmental versus regenerative paths to heal post-injury.
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Abstract
A major goal of spinal cord injury research is to develop a path to endogenous regeneration. This approach has been heavily informed by animal models of natural regeneration. An unresolved question is whether these models rebuild the spinal cord by exclusively accessing developmental mechanisms of neuron differentiation. To address this question, we contrasted single-cell gene expression during regeneration with stage-matched controls in the conditionally regenerative frog Xenopus tropicalis. We generated an expanded atlas of neuronal diversity, annotating several neurons in Xenopus for the first time. From this atlas, we found that the neuron composition of the developing and regenerating spinal cord differ. So do the strategies employed, which favor waves of cell-type specific neuron morphogenesis, proliferation, and proliferative neurogenesis during regeneration. Low levels of early neurogenesis are then compensated by movement of post-mitotic neurons. Our work highlights the use of distinct developmental versus regenerative paths to heal post-injury.
Competing Interest Statement
The authors have declared no competing interest.
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