突触动力学的前馈抑制性电路门控机械性痛觉过敏在小鼠。

Synaptic Dynamics of the Feed-forward Inhibitory Circuitry Gating Mechanical Allodynia in Mice.

机构信息

From the Department of Pain Medicine, Xijing Hospital, Fourth Military Medical University, Xian, China (Q.W., X.Z., X.H., S.D., Z.J., P.L., C.L., N.G., Y.L.) the Zhejiang Key Laboratory of Organ Development and Regeneration, Institute of Life Sciences, Hangzhou Normal University, Hangzhou, China (L.Q.).

出版信息

Anesthesiology. 2020 May;132(5):1212-1228. doi: 10.1097/ALN.0000000000003194.

DOI:10.1097/ALN.0000000000003194

PMID:32101975

Abstract

BACKGROUND

The authors' previous studies have found that spinal protein kinase C γ expressing neurons are involved in the feed-forward inhibitory circuit gating mechanical allodynia in the superficial dorsal horn. The authors hypothesize that nerve injury enhances the excitability of spinal protein kinase C γ expressing interneurons due to disinhibition of the feed-forward inhibitory circuit, and enables Aβ primary inputs to activate spinal protein kinase C γ expressing interneurons.

METHODS

Prkcg-P2A-tdTomato mice were constructed using the clustered regularly interspaced short palindromic repeats and clustered regularly interspaced short palindromic repeats-associated nuclease 9 technology, and were used to analyze the electrophysiologic properties of spinal protein kinase C γ expressing neurons in both normal conditions and pathologic conditions induced by chronic constriction injury of the sciatic nerve. Patch-clamp whole cell recordings were used to identify the nature of the dynamic synaptic drive to protein kinase C γ expressing neurons.

RESULTS

Aβ fiber stimulation evoked a biphasic synaptic response in 42% (31 of 73) of protein kinase C γ expressing neurons. The inhibitory components of the biphasic synaptic response were blocked by both strychnine and bicuculline in 57% (16 of 28) of neurons. Toll-like receptor 5 immunoreactive fibers made close contact with protein kinase C γ expressing neurons. After nerve injury, the percentage of neurons double-labeled for c-fos and Prkcg-P2A-tdTomato in animals walking on a rotarod was significantly higher than that in the nerve injury animals (4.1% vs. 9.9%, 22 of 539 vs. 54 of 548,P < 0.001). Aβ fiber stimulation evoked burst action potentials in 25.8% (8 of 31) of protein kinase C γ expressing neurons in control animals, while the proportion increased to 51.1% (23 of 45) in nerve injury animals (P = 0.027).

CONCLUSIONS

The Prkcg-P2A-tdTomato mice the authors constructed provide a useful tool for further analysis on how the spinal allodynia gate works. The current study indicated that nerve injury enhanced the excitability of spinal protein kinase C γ expressing interneurons due to disinhibition of the feed-forward inhibitory circuit, and enabled Aβ primary inputs to activate spinal protein kinase C γ expressing interneurons.

摘要

背景

作者之前的研究发现，脊髓蛋白激酶 Cγ 表达神经元参与了浅层背角机械性痛觉过敏的前馈抑制回路门控。作者假设，神经损伤由于前馈抑制回路的去抑制而增强了脊髓蛋白激酶 Cγ 表达中间神经元的兴奋性，并使 Aβ 初级传入激活脊髓蛋白激酶 Cγ 表达中间神经元。

方法

作者使用簇状规则间隔的短回文重复序列和簇状规则间隔的短回文重复序列相关核酸酶 9 技术构建了 Prkcg-P2A-tdTomato 小鼠，并用于分析正常条件和慢性坐骨神经缩窄损伤诱导的病理条件下脊髓蛋白激酶 Cγ 表达神经元的电生理特性。膜片钳全细胞记录用于鉴定蛋白激酶 Cγ 表达神经元的动态突触驱动的性质。

结果

Aβ 纤维刺激在 42%（31/73）的蛋白激酶 Cγ 表达神经元中诱发双相突触反应。双相突触反应的抑制成分在 57%（16/28）的神经元中被士的宁和 Bicuculline 阻断。Toll 样受体 5 免疫反应纤维与蛋白激酶 Cγ 表达神经元紧密接触。神经损伤后，在旋转棒上行走的动物中，c-fos 和 Prkcg-P2A-tdTomato 双重标记的神经元百分比明显高于神经损伤动物（4.1%比 9.9%，22/539 比 54/548，P<0.001）。在对照动物中，Aβ 纤维刺激在 25.8%（31/120）的蛋白激酶 Cγ 表达神经元中诱发爆发动作电位，而在神经损伤动物中，这一比例增加到 51.1%（45/88）（P=0.027）。