A feed-forward spinal cord glycinergic neural circuit gates mechanical allodynia
Yan Lu, Hailong Dong, Yandong Gao, Yuanyuan Gong, Yingna Ren, Nan Gu, Shudi Zhou, Nan Xia, Yan-Yan Sun, Ru-Rong Ji, Lize Xiong
Yan Lu, Hailong Dong, Yandong Gao, Yuanyuan Gong, Yingna Ren, Nan Gu, Shudi Zhou, Nan Xia, Yan-Yan Sun, Ru-Rong Ji, Lize Xiong
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Research Article Neuroscience

A feed-forward spinal cord glycinergic neural circuit gates mechanical allodynia

Abstract

Neuropathic pain is characterized by mechanical allodynia induced by low-threshold myelinated Aβ-fiber activation. The original gate theory of pain proposes that inhibitory interneurons in the lamina II of the spinal dorsal horn (DH) act as “gate control” units for preventing the interaction between innocuous and nociceptive signals. However, our understanding of the neuronal circuits underlying pain signaling and modulation in the spinal DH is incomplete. Using a rat model, we have shown that the convergence of glycinergic inhibitory and excitatory Aβ-fiber inputs onto PKCγ+ neurons in the superficial DH forms a feed-forward inhibitory circuit that prevents Aβ input from activating the nociceptive pathway. This feed-forward inhibition was suppressed following peripheral nerve injury or glycine blockage, leading to inappropriate induction of action potential outputs in the nociceptive pathway by Aβ-fiber stimulation. Furthermore, spinal blockage of glycinergic synaptic transmission in vivo induced marked mechanical allodynia. Our findings identify a glycinergic feed-forward inhibitory circuit that functions as a gate control to separate the innocuous mechanoreceptive pathway and the nociceptive pathway in the spinal DH. Disruption of this glycinergic inhibitory circuit after peripheral nerve injury has the potential to elicit mechanical allodynia, a cardinal symptom of neuropathic pain.

Authors

Yan Lu, Hailong Dong, Yandong Gao, Yuanyuan Gong, Yingna Ren, Nan Gu, Shudi Zhou, Nan Xia, Yan-Yan Sun, Ru-Rong Ji, Lize Xiong

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Figure 4

The feed-forward inhibition is impaired after spinal nerve injury.

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The feed-forward inhibition is impaired after spinal nerve injury. (A) G...
(A) Gly unitary inhibitory connection between Gly and PKCγ+ neurons recorded from a SNL rat. (B) Confocal images show 30-μm-thick optical stacks of the recorded neuronal pair. Arrows indicate the PKCγ+ cell, and an arrowhead indicates putative axon. Insets show 1-μm-thick optical stacks of the PKCγ+ cell. Scale bar: 100 μm. (C) AP patterns of the recorded neurons. (D) Schematic diagram of the feed-forward inhibitory circuit. (E) DR stimulation evokes Aβ-fiber EPSPs in both Gly and PKCγ+ neurons. The amplitudes of the evoked EPSPs in Gly neurons were significantly smaller than those recorded in naive rats. The polysynaptic inhibitory components revealed in the naive slices almost completely disappeared after SNL. (F) Repetitive DR stimulation (20 Hz) indicates the evoked EPSPs are monosynaptic. Arrows indicate the stimulus artifacts. (G) DR stimulation at C-fiber strength fails to recruit additional Aδ- or C-fiber inputs to PKCγ and Gly neurons.