Ketamine depresses toll-like receptor 3 signaling in spinal microglia in a rat model of neuropathic pain

Reports suggest that microglia play a key role in spinal nerve ligation (SNL)-induced neuropathic pain, and toll-like receptor 3 (TLR3) has a substantial role in the activation of spinal microglia and the development of tactile allodynia after nerve injury. In addition, ketamine application could suppress microglial activation in vitro, and ketamine could inhibit proinflammatory gene expression possibly by suppressing TLR-mediated signal transduction. Therefore, the present study was designed to disclose whether intrathecal ketamine could suppress SNL-induced spinal microglial activation and exert some antiallodynic effects on neuropathic pain by suppressing TLR3 activation. Behavioral results showed that intrathecal ketamine attenuated SNL-induced mechanical allodynia, as well as spinal microglial activation, in a dose-dependent manner. Furthermore, Western blot analysis displayed that ketamine application downregulated SNL-induced phosphorylated-p38 (p-p38) expression, which was specifically expressed in spinal microglia but not in astrocytes or neurons. Besides, ketamine could reverse TLR3 agonist (polyinosine-polycytidylic acid)-induced mechanical allodynia and spinal microglia activation. It was concluded that intrathecal ketamine depresses TLR3-induced spinal microglial p-p38 mitogen-activated protein kinase pathway activation after SNL, probably contributing to the antiallodynic effect of ketamine on SNL-induced neuropathic pain.     

A potent and selective indole N-type calcium channel (Ca(v)2.2) blocker for the treatment of pain

N-type calcium channels (Ca_v2.2) have been shown to play a critical role in pain. A series of low molecular weight 2-aryl indoles were identified as potent Ca_v2.2 blockers with good in vitro and in vivo potency.     

Tyrosine phosphorylation of the N-Methyl-D-Aspartate receptor 2B subunit in spinal cord contributes to remifentanil-induced postoperative hyperalgesia: the preventive effect of ketamine

Neuropathic pain is a debilitating pain condition that occurs after nerve damage. Such pain is considered to be a reflection of the aberrant excitability of dorsal horn neurons. Emerging lines of evidence indicate that spinal microglia play a crucial role in neuronal excitability and the pathogenesis of neuropathic pain, but the mechanisms underlying neuron-microglia communications in the dorsal horn remain to be fully elucidated. A recent study has demonstrated that platelet-derived growth factor (PDGF) expressed in dorsal horn neurons contributes to neuropathic pain after nerve injury, yet how PDGF produces pain hypersensitivity remains unknown. Here we report an involvement of spinal microglia in PDGF-induced tactile allodynia. A single intrathecal delivery of PDGF B-chain homodimer (PDGF-BB) to naive rats produced a robust and long-lasting decrease in paw withdrawal threshold in a dose-dependent manner. Following PDGF administration, the immunofluorescence for phosphorylated PDGF β-receptor (p-PDGFRβ), an activated form, was markedly increased in the spinal dorsal horn. Interestingly, almost all p-PDGFRβ-positive cells were double-labeled with an antibody for the microglia marker OX-42, but not with antibodies for other markers of neurons, astrocytes and oligodendrocytes. PDGF-stimulated microglia in vivo transformed into a modest activated state in terms of their cell number and morphology. Furthermore, PDGF-BB-induced tactile allodynia was prevented by a daily intrathecal administration of minocycline, which is known to inhibit microglia activation. Moreover, in rats with an injury to the fifth lumbar spinal nerve (an animal model of neuropathic pain), the immunofluorescence for p-PDGFRβ was markedly enhanced exclusively in microglia in the ipsilateral dorsal horn. Together, our findings suggest that spinal microglia critically contribute to PDGF-induced tactile allodynia, and it is also assumed that microglial PDGF signaling may have a role in the pathogenesis of neuropathic pain.     

Neuronal CCL21 up-regulates microglia P2X4 expression and initiates neuropathic pain development

Up-regulation of P2X4 receptors in spinal cord microglia is crucial for tactile allodynia, an untreatable pathological pain reaction occurring after peripheral nerve injury. How nerve injury in the periphery leads to this microglia reaction in the dorsal horn of the spinal cord is not yet understood. It is shown here that CCL21 was rapidly expressed in injured small-sized primary sensory neurons and transported to their central terminals in the dorsal horn. Intrathecal administration of a CCL21-blocking antibody diminished tactile allodynia development in wild-type animals. Mice deficient for CCL21 did not develop any signs of tactile allodynia and failed to up-regulate microglial P2X4 receptor expression. Microglia P2X4 expression was enhanced by CCL21 application in vitro and in vivo. A single intrathecal injection of CCL21 to nerve-injured CCL21-deficient mice induced long-lasting allodynia that was undistinguishable from the wild-type response. This effect of CCL21 injection was strictly dependent on P2X4 receptor function. Since neuronal CCL21 is the earliest yet identified factor in the cascade leading to tactile allodynia, these findings may lead to a preventive therapy in neuropathic pain.     

The critical role of spinal ceramide in the development of partial sciatic nerve ligation-induced neuropathic pain in mice

Recent observations indicate that peripheral nerve injury induces central sensitization through microglial activation and the release of inflammatory cytokines, resulting in the development of neuropathic pain. However, the underlying mechanisms of this phenomenon remain to be fully elucidated. In this study, we examined the involvement of spinal ceramide, a bioactive lipid, in the development of neuropathic pain induced by partial sciatic nerve ligation (PSL). We found that the mRNA expression levels for ceramide synthase and neutral sphingomyelinase, which are enzymes of ceramide biosynthesis, were up-regulated in the spinal cord from 3h to 1 day after PSL. The mRNA expressions of cytokines (interleukin-1β and tumor necrosis factor-α) and the microglial specific molecules (Iba-1 and CD11b) were also increased in the spinal cord after PSL. In the von Frey test, intrathecal injection of the ceramide biosynthesis inhibitors Fumonisin B1 and GW4869 at 3h and day 3 after PSL significantly attenuated PSL-induced tactile allodynia. By immunohistochemistry, microglial activation in the dorsal horn was suppressed by Fumonisin B1 and GW4869. Therefore, we conclude that spinal ceramide may play a crucial role in PSL-induced neuropathic pain through the activation of microglia.     

Pyrethroid action on calcium channels: neurotoxicological implications

Actions of cismethrin versus deltamethrin were compared using two functional attributes of rat brain synaptosomes. Both pyrethroids increased calcium influx but only deltamethrin increased Ca²⁺-dependent neurotransmitter release following K⁺-stimulated depolarization. The action of deltamethrin was stereospecific, concentration-dependent, and blocked by ω-conotoxin GVIA. These findings delineate a separate action for deltamethrin and implicate N-type rat brain Ca_v2.2 voltage-sensitive calcium channels (VSCC) as target sites that are consistent with the in vivo release of neurotransmitter caused by deltamethrin. Deltamethrin (10⁻⁷ M) reduced the peak current (approx. −47%) of heterologously expressed wild type Ca_v2.2 in a stereospecific manner. Mutation of threonine 422 to glutamic acid (T422E) in the α₁-subunit results in a channel that functions as if it were permanently phosphorylated. Deltamethrin now increased peak current (approx. +49%) of T422E Ca_v2.2 in a stereospecific manner. Collectively, these results substantiate that Ca_v2.2 is directly modified by deltamethrin but the resulting perturbation is dependent upon the phosphorylation state of Ca_v2.2. Our findings may provide a partial explanation for the different toxic syndromes produced by these structurally-distinct pyrethroids.     

Further insights into the antinociceptive potential of a peptide disrupting the N-type calcium channel–CRMP-2 signaling complex

The N-type voltage-gated calcium channel ( Ca_v2.2) has gained immense prominence in the treatment of chronic pain. While decreased channel function is ultimately anti-nociceptive, directly targeting the channel can lead to multiple adverse side effects. Targeting modulators of channel activity may facilitate improved analgesic properties associated with channel block and a broader therapeutic window. A novel interaction between Ca_v2.2 and collapsin response mediator protein 2 (CRMP-2) positively regulates channel function by increasing surface trafficking. We recently identified a CRMP-2 peptide (TAT-CBD3), which effectively blocks this interaction, reduces or completely reverses pain behavior in a number of inflammatory and neuropathic models. Importantly, TAT-CBD3 did not produce many of the typical side effects often observed with Ca_v2.2 inhibitors. Notably chronic pain mechanisms offer unique challenges as they often encompass a mix of both neuropathic and inflammatory elements, whereby inflammation likely causes damage to the neuron leading to neuropathic pain, and neuronal injury may produce inflammatory reactions. To this end, we sought to further disseminate the ability of TAT-CBD3 to alter behavioral outcomes in two additional rodent pain models. While we observed that TAT-CBD3 reversed mechanical hypersensitivity associated with a model of chronic inflammatory pain due to lysophosphotidylcholine-induced sciatic nerve focal demyelination (LPC), injury to the tibial nerve (TNI) failed to respond to drug treatment. Moreover, a single amino acid mutation within the CBD3 sequence demonstrated amplified Ca_v2.2 binding and dramatically increased efficacy in an animal model of migraine. Taken together, TAT-CBD3 potentially represents a novel class of therapeutics targeting channel regulation as opposed to the channel itself.     

Modification of neuropathic pain sensation through microglial ATP receptors

Neuropathic pain that typically develops when peripheral nerves are damaged through surgery, bone compression in cancer, diabetes, or infection is a major factor causing impaired quality of life in millions of people worldwide. Recently, there has been a rapidly growing body of evidence indicating that spinal glia play a critical role in the pathogenesis of neuropathic pain. Accumulating findings also indicate that nucleotides play an important role in neuron-glia communication through P2 purinoceptors. Damaged neurons release or leak nucleotides including ATP and UTP to stimulate microglia through P2 purinoceptors expressing on microglia. It was shown in an animal model of neuropathic pain that microglial P2X₄ and P2X₇ receptors are crucial in pain signaling after peripheral nerve lesion. In this review, we describe the modification of neuropathic pain sensation through microglial P2X₄ and P2X₇, with the possibility of P2Y₆ and P2Y₁₂ involvement.     

miR-32-5p-mediated Dusp5 downregulation contributes to neuropathic pain

Previous studies have demonstrated that microRNAs (miRNAs) play important roles in the pathogenesis of neuropathic pain. In the present study, we found that miR-32-5p was significantly upregulated in rats after spinal nerve ligation (SNL), specifically in the spinal microglia of rats with SNL. Functional assays showed that knockdown of miR-32-5p greatly suppressed mechanical allodynia and heat hyperalgesia, and decreased inflammatory cytokine (IL-1β, TNF-α and IL-6) protein expression in rats after SNL. Similarly, miR-32-5p knockdown alleviated cytokine production in lipopolysaccharide (LPS)-treated spinal microglial cells, whereas its overexpression had the opposite effect. Mechanistic investigations revealed Dual-specificity phosphatase 5 (Dusp5) as a direct target of miR-32-5p, which is involved in the miR-32-5p-mediated effects on neuropathic pain and neuroinflammation. We demonstrated for the first time that miR-32-5p promotes neuroinflammation and neuropathic pain development through regulation of Dusp5. Our findings highlight a novel contribution of miR-32-5p to the process of neuropathic pain, and suggest possibilities for the development of novel therapeutic options for neuropathic pain.     

The astrocyte-targeted therapy by Bushi for the neuropathic pain in mice

Background

There is accumulating evidence that the activation of spinal glial cells, especially microglia, is a key event in the pathogenesis of neuropathic pain. However, the inhibition of microglial activation is often ineffective, especially for long-lasting persistent neuropathic pain. So far, neuropathic pain remains largely intractable and a new therapeutic strategy for the pain is still required.

Methods/Principal Findings

Using Seltzer model mice, we investigated the temporal aspect of two types of neuropathic pain behaviors, i.e., thermal hyperalgesia and mechanical allodynia, as well as that of morphological changes in spinal microglia and astrocytes by immunohistochemical studies. Firstly, we analyzed the pattern of progression in the pain behaviors, and found that the pain consisted of an “early induction phase” and subsequent “late maintenance phase”. We next analyzed the temporal changes in spinal glial cells, and found that the induction and the maintenance phase of pain were associated with the activation of microglia and astrocytes, respectively. When Bushi, a Japanese herbal medicine often used for several types of persistent pain, was administered chronically, it inhibited the maintenance phase of pain without affecting the induction phase, which was in accordance with the inhibition of astrocytic activation in the spinal cord. These analgesic effects and the inhibition of astrocytic activation by Bushi were mimicked by the intrathecal injection of fluorocitrate, an inhibitor of astrocytic activation. Finally, we tested the direct effect of Bushi on astrocytic activation, and found that Bushi suppressed the IL-1β- or IL-18-evoked ERK1/2-phosphorylation in cultured astrocytes but not the ATP-evoked p38- and ERK1/2-phosphorylation in microglia in vitro.

Conclusions

Our results indicated that the activation of spinal astrocytes was responsible for the late maintenance phase of neuropathic pain in the Seltzer model mice and, therefore, the inhibition of astrocytic activation by Bushi could be a useful therapeutic strategy for treating neuropathic pain.     

Discovery of tetrahydropyrido[4,3-d]pyrimidine derivatives for the treatment of neuropathic pain

A series of tetrahydropyridopyrimidine derivatives were synthesized and evaluated for neurotoxicity and peripheral analgesic activity followed by assessment of antiallodynic and antihyperalgesic potential in two peripheral neuropathic pain models, the chronic constriction injury (CCI) and partial sciatic nerve ligation (PSNL). Compounds (4b and 4d) exhibiting promising efficacies in four behavioral assays of allodynia and hyperalgesia (spontaneous pain, tactile allodynia, cold allodynia and mechanical hyperalgesia) were quantified for their ED₅₀ values (15.12–65.10 mg/kg). Studies carried out to assess the underlying mechanism revealed that the compounds suppressed the inflammatory component of the neuropathic pain and prevented oxidative and nitrosative stress.     

Direct evidence for the involvement of brain-derived neurotrophic factor in the development of a neuropathic pain-like state in mice

Thermal hyperalgesia and tactile allodynia induced by sciatic nerve ligation were completely suppressed by repeated intrathecal (i.t.) injection of a TrkB/Fc chimera protein, which sequesters endogenous brain-derived neurotrophic factor (BDNF). In addition, BDNF heterozygous (+/-) knockout mice exhibited a significant suppression of nerve ligation-induced thermal hyperalgesia and tactile allodynia compared with wild-type mice. After nerve ligation, BDNF-like immunoreactivity on the superficial laminae of the ipsilateral side of the spinal dorsal horn was clearly increased compared with that of the contralateral side. It should be noted that a single i.t. injection of BDNF produced a long-lasting thermal hyperalgesia and tactile allodynia in normal mice, and these responses were abolished by i.t. pre-treatment with either a Trk-dependent tyrosine kinase inhibitor K-252a or a selective protein kinase C (PKC) inhibitor Ro-32-0432. Supporting these findings, we demonstrated here for the first time that the increase in intracellular Ca2+ concentration by application of BDNF in cultured mouse spinal neurons was abolished by pre-treatment with either K-252a or Ro-32-0432. Taken together, these findings suggest that the binding of spinally released BDNF to TrkB by nerve ligation may activate PKC within the spinal cord, resulting in the development of a neuropathic pain-like state in mice.     

Suppression of inflammatory and neuropathic pain symptoms in mice lacking the N-type Ca2+ channel

The importance of voltage-dependent Ca2+ channels (VDCCs) in pain transmission has been noticed gradually, as several VDCC blockers have been shown to be effective in inhibiting this process. In particular, the N-type VDCC has attracted attention, because inhibitors of this channel are effective in various aspects of pain-related phenomena. To understand the genuine contribution of the N-type VDCC to the pain transmission system, we generated mice deficient in this channel by gene targeting. We report here that mice lacking N-type VDCCs show suppressed responses to a painful stimulus that induces inflammation and show markedly reduced symptoms of neuropathic pain, which is caused by nerve injury and is known to be difficult to treat by currently available therapeutic methods. This finding clearly demonstrates that the N-type VDCC is essential for development of neuropathic pain and, therefore, controlling the activity of this channel can be of great importance for the management of neuropathic pain.     

鞘内注射γ-氨基丁酸转运体抑制剂NO-711抑制坐骨神经慢性挤压伤大鼠神经病理性痛觉过敏

为研究γ-氨基丁酸转运体在神经病理性痛中的作用,实验用坐骨神经慢性挤压伤致神经病理性痛模型大鼠,以清醒大鼠分别对辐射热刺激和机械性触觉刺激的缩腿潜伏期和机械阈值为指标,分为NS组、N5组、N10组、N20组、N40组5组,分别在坐骨神经结扎前和结扎后第三天鞘内给予生理盐水或不同剂量的γ-氨基丁酸转运体特异性抑制剂NO-711(5、10、20、40μg),观察鞘内注射NO-711对大鼠热痛敏和触诱发痛的影响.结果表明,NO-711可显著抑制神经病理性痛大鼠的热痛觉过敏和触诱发痛(P＜0.05,P＜0.01),其抑制作用持续时间最长分别可达2 h(N40组)和4 h(N20组),其抗热痛敏作用呈剂量依赖性.坐骨神经结扎前鞘内给予不同剂量的NO-711可不同程度地延迟坐骨神经结扎所致的热痛觉过敏的发生,但不能延迟结扎所致的触诱发痛的发生.结果表明γ-氨基丁酸转运体抑制剂在神经病理性痛大鼠具有抗热痛敏和抗触诱发痛的作用.     

Plasticity and emerging role of BKCa channels in nociceptive control in neuropathic pain

Large‐conductance Ca²⁺‐activated K⁺ (BK_Ca, MaxiK) channels are important for the regulation of neuronal excitability. Peripheral nerve injury causes plasticity of primary afferent neurons and spinal dorsal horn neurons, leading to central sensitization and neuropathic pain. However, little is known about changes in the BK_Ca channels in the dorsal root ganglion (DRG) and spinal dorsal horn and their role in the control of nociception in neuropathic pain. Here we show that L5 and L6 spinal nerve ligation in rats resulted in a substantial reduction in both the mRNA and protein levels of BK_Ca channels in the DRG but not in the spinal cord. Nerve injury primarily reduced the BK_Ca channel immunoreactivity in small‐ and medium‐sized DRG neurons. Furthermore, although the BK_Ca channel immunoreactivity was decreased in the lateral dorsal horn, there was an increase in the BK_Ca channel immunoreactivity present on dorsal horn neurons near the dorsal root entry zone. Blocking the BK_Ca channel with iberiotoxin at the spinal level significantly reduced the mechanical nociceptive withdrawal threshold in control and nerve‐injured rats. Intrathecal injection of the BK_Ca channel opener [1,3‐dihydro‐1‐[2‐hydroxy‐5‐(trifluoromethyl)phenyl]‐5‐(trifluoromethyl)‐2H‐benzimidazol‐2‐one] dose dependently reversed allodynia and hyperalgesia in nerve‐ligated rats but it had no significant effect on nociception in control rats. Our study provides novel information that nerve injury suppresses BK_Ca channel expression in the DRG and induces a redistribution of BK_Ca channels in the spinal dorsal horn. BK_Ca channels are increasingly involved in the control of sensory input in neuropathic pain and may represent a new target for neuropathic pain treatment.     

Spinal Astrocytic Activation Contributes to Mechanical Allodynia in a Rat Chemotherapy-Induced Neuropathic Pain Model

Chemotherapy-induced neuropathic pain (CNP) is the major dose-limiting factor in cancer chemotherapy. However, the neural mechanisms underlying CNP remain enigmatic. Accumulating evidence implicates the involvement of spinal glia in some neuropathic pain models. In this study, using a vincristine-evoked CNP rat model with obvious mechanical allodynia, we found that spinal astrocyte rather than microglia was dramatically activated. The mechanical allodynia was dose-dependently attenuated by intrathecal administratration of L-α-aminoadipate (astrocytic specific inhibitor); whereas minocycline (microglial specific inhibitor) had no such effect, indicating that spinal astrocytic activation contributes to allodynia in CNP rat. Furthermore, oxidative stress mediated the development of spinal astrocytic activation, and activated astrocytes dramatically increased interleukin-1β expression which induced N-methyl-D-aspartic acid receptor (NMDAR) phosphorylation in spinal neurons to strengthen pain transmission. Taken together, our findings suggest that spinal activated astrocytes may be a crucial component of the pathophysiology of CNP and “Astrocyte-Cytokine-NMDAR-neuron” pathway may be one detailed neural mechanisms underlying CNP. Thus, inhibiting spinal astrocytic activation may represent a novel therapeutic strategy for treating CNP.     

Molecular and immunohistochemical studies in expression of voltage-dependent Ca2+ channels in dorsal root ganglia from streptozotocin-induced diabetic mice

We have recently demonstrated that intrathecal injection of a selective P/Q-type blocker of the voltage-dependent Ca(2+) channels (VDCCs) significantly inhibited the mechanical hyperalgesia in streptozotocin (STZ)-induced diabetic mice, its antinociceptive effect being greater than in controls. In this study, to further clarify the underlying mechanism of the STZ-induced hyperalgesia, we investigated the expression level of the VDCC alpha1A and alpha1B subunits in the dorsal root ganglia (DRGs) and the dorsal spinal cord under this hyperalgesia. Real-time PCR analysis showed mRNA expression of alpha1A (P/Q-type), but not alpha1B (N-type), was significantly increased in the DRGs from the STZ-induced diabetic mice. On the other hand, gene expression of both alpha1 subunits was not changed in the dorsal part of the spinal cord. In diabetic DRG neurons, the number of large nerve cells was significantly reduced, whereas small neurons were significantly increased. Immunohistochemical study demonstrated the alpha1A-positive neurons, but not alpha1B-positive neurons, increased significantly greater in diabetic DRGs than in control in all cell size. These results indicate that an alteration in expression of P/Q-type VDCCs, especially in the small and medium-diameter primary afferent fibers, in pain pathways ascending input to the spinal cord may be involved in hypersensitivity in STZ-induced diabetes.