Gabapentinoid treatment promotes corticospinal plasticity and regeneration following murine spinal cord injury
Wenjing Sun, … , Juan Peng, Andrea Tedeschi
Wenjing Sun, … , Juan Peng, Andrea Tedeschi
Published December 3, 2019
Citation Information: J Clin Invest. 2020;130(1):345-358. https://doi.org/10.1172/JCI130391.
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Research Article Neuroscience

Gabapentinoid treatment promotes corticospinal plasticity and regeneration following murine spinal cord injury

Abstract

Axon regeneration failure causes neurological deficits and long-term disability after spinal cord injury (SCI). Here, we found that the α2δ2 subunit of voltage-gated calcium channels negatively regulates axon growth and regeneration of corticospinal neurons, the cells that originate the corticospinal tract. Increased α2δ2 expression in corticospinal neurons contributed to loss of corticospinal regrowth ability during postnatal development and after SCI. In contrast, α2δ2 pharmacological blockade through gabapentin administration promoted corticospinal structural plasticity and regeneration in adulthood. Using an optogenetic strategy combined with in vivo electrophysiological recording, we demonstrated that regenerating corticospinal axons functionally integrate into spinal circuits. Mice administered gabapentin recovered upper extremity function after cervical SCI. Importantly, such recovery relies on reorganization of the corticospinal pathway, as chemogenetic silencing of injured corticospinal neurons transiently abrogated recovery. Thus, targeting α2δ2 with a clinically relevant treatment strategy aids repair of motor circuits after SCI.

Authors

Wenjing Sun, Molly J.E. Larson, Conrad M. Kiyoshi, Alexander J. Annett, William A. Stalker, Juan Peng, Andrea Tedeschi

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Figure 4

α2δ2 pharmacological blockade through GBP administration promotes functionally relevant corticospinal regeneration.

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α2δ2 pharmacological blockade through GBP administration promotes functi...
(A) In vivo recording of light-evoked LFPs using a 32-channel electrode array (vehicle n = 6 and GBP n = 6 mice). The LFP color code represents the 4 electrode shanks (B) Heatmap (z-transformed, blue to red) from A to visualize changes in corticospinal connectivity in the injured spinal cord. Each box represents averaged data from a single electrode, each column a single electrode shank (vehicle n = 6 and GBP n = 6 mice). (C) Automated tile scanning of the unsectioned adult spinal cord 4 months after C5 SCI. Corticospinal axons were labeled by injecting AAV-ChR2-eYFP into the right sensory-motor cortex. The asterisk indicates the lesion epicenter. Enclosed numbers indicate the location where multichannel electrodes arrays were inserted for in vivo recording. Scale bar: 500 μm; 50 μm (inset). R, rostral; C, caudal. (D) Quantification of C. Mean and SEM (mixed model with repeated measures using unstructured covariance matrix, *P < 0.05; **P < 0.01; NS, not significant; vehicle n = 6 and GBP n = 6 mice). (E) Schematic of the cortical stimulation paradigm. (F) c-Fos activity mapping in the injured spinal cord (vehicle n = 6 and GBP n = 5 mice). Scale bar: 200 μm. D, dorsal; V, ventral.