Hosseini Marjan, Parviz Mohsen, Shabanzadeh Alireza P, Zamani Elham
Department of Physiology, School of Medicine, Tehran University of Medical Sciences, Tehran, Iran.
Asian Spine J. 2021 Apr;15(2):200-206. doi: 10.31616/asj.2019.0367. Epub 2020 May 29.
In this study, we decided to change the activity of periaqueductal gray (PAG)'s metabotropic glutamate receptors subtype 8 (mGluR8) by means of its specific agonist, (S)-3,4-dicarboxyphenylglycine (DCPG), and by knock downing it with mGluR8 siRNA. We then evaluated the changes in animal pain threshold levels in the face of painful thermal stimuli (thermal hyperalgesia).
Although several mechanisms have been examined for central neuropathic pain, researchers have so far failed to find the precise mechanism for the development and progression of this type of pain. Hyperalgesia is one of the most important complications of central neuropathic pain and there is not a consensus among researchers about the exact cause of this complication. In this study, we investigated the effect of activation of the PAG region mGluR8 on the threshold of pain response to thermal noxious stimulus in rats and measured mGluR8 expression.
Spinal cord injury (SCI) produces an decrease in mGluR2/3 expression in the injured and vehicle-treated groups compared to normal levels, APDC and L-AP4 treated groups had higher expression levels of mGluR2/3. These findings suggesting that the level of mGluR expression after SCI may modulate nociceptive responses.
Male Wistar rats were randomly assigned to five groups (n=10 per group). The clip compression injury model was used to induce chronic central neuropathic pain. Three weeks after SCI, DCPG, siRNA, or normal saline were administered to the intra-ventrolateral PAG region. Withdrawal threshold to the noxious thermal stimulus (e.g., heat hyperalgesia) was assessed through the tail-flick test. In order to assure involvement of this receptor, pain responses were compared with mice that received GRM8 siRNA.
We found that the mGluR8 agonist DCPG increased lead to an increased expression of mGluR8 in the PAG region. We also found that SCI can decrease the threshold of response to painful thermal stimuli; however, activation of mGluR8 with DCPG agonist did not significantly improve the tail-flick response.
The results revealed that activation of mGluR8 in PAG is not capable of improving the thermal hyperalgesia threshold. Based on the decreased expression of mGluR8 after SCI induced by clip compression injury and its significant increase after treatment of siRNA against mGluR8, this method might still hold promise as an effective treatment of neuropathic pain. It can be concluded that increased expression of mGluR8 is due to the fact that DCPG prevents the death of neurons that express these receptors.
在本研究中,我们决定通过中脑导水管周围灰质(PAG)的代谢型谷氨酸受体8(mGluR8)的特异性激动剂(S)-3,4-二羧基苯基甘氨酸(DCPG)以及用mGluR8小干扰RNA(siRNA)敲低该受体,来改变其活性。然后我们评估了动物在面对疼痛性热刺激(热痛觉过敏)时疼痛阈值水平的变化。
尽管已经对中枢神经性疼痛的几种机制进行了研究,但研究人员至今仍未找到这种类型疼痛发生和进展的确切机制。痛觉过敏是中枢神经性疼痛最重要的并发症之一,研究人员对于该并发症的确切原因尚未达成共识。在本研究中,我们研究了激活PAG区域的mGluR8对大鼠对热伤害性刺激的疼痛反应阈值的影响,并检测了mGluR8的表达。
与正常水平相比,脊髓损伤(SCI)导致损伤组和给予赋形剂组的mGluR2/3表达降低,给予APDC和L-AP4治疗的组mGluR2/3表达水平更高。这些发现表明SCI后mGluR的表达水平可能调节伤害性反应。
将雄性Wistar大鼠随机分为五组(每组n = 10)。采用夹压损伤模型诱导慢性中枢神经性疼痛。SCI后三周,将DCPG、siRNA或生理盐水注入腹外侧PAG区域。通过甩尾试验评估对伤害性热刺激的撤针阈值(如热痛觉过敏)。为确保该受体的参与,将疼痛反应与接受GRM8 siRNA的小鼠进行比较。
我们发现mGluR8激动剂DCPG导致PAG区域mGluR8表达增加。我们还发现SCI可降低对疼痛性热刺激的反应阈值;然而,用DCPG激动剂激活mGluR8并未显著改善甩尾反应。
结果显示激活PAG中的mGluR8不能提高热痛觉过敏阈值。基于夹压损伤诱导的SCI后mGluR8表达降低以及针对mGluR8的siRNA治疗后其显著增加,该方法可能仍有望成为治疗神经性疼痛的有效方法。可以得出结论,mGluR8表达增加是因为DCPG可防止表达这些受体的神经元死亡。
