Cortical astrocytes rewire somatosensory cortical circuits for peripheral neuropathic pain
Sun Kwang Kim, … , Schuichi Koizumi, Junichi Nabekura
Sun Kwang Kim, … , Schuichi Koizumi, Junichi Nabekura
Published April 11, 2016
Citation Information: J Clin Invest. 2016;126(5):1983-1997. https://doi.org/10.1172/JCI82859.
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Research Article

Cortical astrocytes rewire somatosensory cortical circuits for peripheral neuropathic pain

Abstract

Long-term treatments to ameliorate peripheral neuropathic pain that includes mechanical allodynia are limited. While glial activation and altered nociceptive transmission within the spinal cord are associated with the pathogenesis of mechanical allodynia, changes in cortical circuits also accompany peripheral nerve injury and may represent additional therapeutic targets. Dendritic spine plasticity in the S1 cortex appears within days following nerve injury; however, the underlying cellular mechanisms of this plasticity and whether it has a causal relationship to allodynia remain unsolved. Furthermore, it is not known whether glial activation occurs within the S1 cortex following injury or whether it contributes to this S1 synaptic plasticity. Using in vivo 2-photon imaging with genetic and pharmacological manipulations of murine models, we have shown that sciatic nerve ligation induces a re-emergence of immature metabotropic glutamate receptor 5 (mGluR5) signaling in S1 astroglia, which elicits spontaneous somatic Ca2+ transients, synaptogenic thrombospondin 1 (TSP-1) release, and synapse formation. This S1 astrocyte reactivation was evident only during the first week after injury and correlated with the temporal changes in S1 extracellular glutamate levels and dendritic spine turnover. Blocking the astrocytic mGluR5-signaling pathway suppressed mechanical allodynia, while activating this pathway in the absence of any peripheral injury induced long-lasting (>1 month) allodynia. We conclude that reawakened astrocytes are a key trigger for S1 circuit rewiring and that this contributes to neuropathic mechanical allodynia.

Authors

Sun Kwang Kim, Hideaki Hayashi, Tatsuya Ishikawa, Keisuke Shibata, Eiji Shigetomi, Youichi Shinozaki, Hiroyuki Inada, Seung Eon Roh, Sang Jeong Kim, Gihyun Lee, Hyunsu Bae, Andrew J. Moorhouse, Katsuhiko Mikoshiba, Yugo Fukazawa, Schuichi Koizumi, Junichi Nabekura

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Figure 2

Activation of S1 astrocytic Ca2+ induces spine turnover.

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Activation of S1 astrocytic Ca2+ induces spine turnover. (A) Photolysis ...
(A) Photolysis of caged Ca2+ (DMNP-EDTA) within an astrocyte soma was done by 730-nm 2-photon laser stimulation (10 mW, 50-ms duration, Tornado mode, Olympus). This brief uncaging induced a prolonged (≥1 minute) astrocytic Ca2+ transient (solid arrowheads; yellow) approximately 20 seconds after the stimulation. Simultaneous imaging (0.5 Hz, 900-nm 2-photon laser scanning) was done after dye loading (Ca2+ dye [OGB-1–AM, green] and astrocyte marker [SR101, red]) in a naive mouse. Note that the unstimulated astrocytes (open arrowheads) show no Ca2+ changes. Scale bar: 10 μm. (B) Timeline of the experimental protocol for in vivo 2-photon Ca2+ uncaging (from DMNP-EDTA) and repeated dendrite (Dend) imaging. (C) Left: Z-projection images of apical dendrites (green, GFP) and astrocytes (red, SR101). Scale bar: 10 μm. Yellow oval in lower rotated image indicates the focal point for in vivo intra-astrocyte 2-photon Ca2+ uncaging. Center and right: Magnified dendrite images before (0 minutes) and 90 minutes after Ca2+ uncaging. Repeated astrocytic Ca2+ uncaging (5-minute intervals) induced spine formation and elimination in adjacent dendritic segments (blue squares), but not in more remote dendritic segments (upper left of center and right images). Scale bar: 3 μm.