Interleukin-17 sensitizes joint nociceptors to mechanical stimuli and contributes to arthritic pain through neuronal interleukin-17 receptors in rodents.

OBJECTIVE: Interleukin-17 (IL-17) is considered a proinflammatory cytokine, but whether neuronal IL-17 receptors contribute to the generation of arthritic pain is unknown. This study was undertaken to explore whether IL-17A acts on neurons, whether it sensitizes joint nociceptors, and whether neutralization of IL-17 is antinociceptive. METHODS: We recorded action potentials from rat joint nociceptors after intraarticular injection of IL-17A. We studied the expression of the IL-17A receptor in the rat dorsal root ganglia (DRG), explored the effect of IL-17A on signaling pathways in cultured rat DRG neurons, and using patch clamp recordings, monitored changes of excitability by IL-17A. We tested whether an antibody to IL-17 influences pain behaviors in mice with antigen-induced arthritis (AIA). RESULTS: A single injection of IL-17A into the rat knee joint elicited a slowly developing and long-lasting sensitization of nociceptive C fibers of the joint to mechanical stimuli, which was not attenuated by neutralizing tumor necrosis factor α or IL-6. The IL-17A receptor was visualized in most rat DRG neurons, the cell bodies of primary sensory neurons. In isolated and cultured rat DRG neurons, IL-17A caused rapid phosphorylation of protein kinase B and ERK, and it rapidly enhanced excitability. In mice with unilateral AIA in the knee, an antibody against IL-17 improved the guarding score and reduced secondary mechanical hyperalgesia at the ipsilateral paw. CONCLUSION: Our findings indicate that IL-17A has the potential to act as a pain mediator by targeting IL-17 receptors in nociceptive neurons, and these receptors are particularly involved in inflammation-evoked mechanical hyperalgesia.

The role of interleukin-1ß in arthritic pain: main involvement in thermal, but not mechanical, hyperalgesia in rat antigen-induced arthritis.

OBJECTIVE: Interleukin-1ß (IL-1ß) is considered a pronociceptive cytokine, but its role in the generation of arthritic pain is unknown. The aim of this study was to investigate the role of IL-1ß in arthritic pain and to explore the antinociceptive potential of the IL-1 receptor type I (IL-1RI) antagonist anakinra. METHODS: Antigen-induced arthritis (AIA) was induced in rats. Expression of IL-1RI in the dorsal root ganglia (DRGs) was determined, and the effects of anakinra on inflammation, pain-related behavior, and receptor expression were assessed. In cultured DRG neurons, the effect of IL-1ß on the expression of the transient receptor potential vanilloid 1 (TRPV-1) ion channel was examined. Recordings of action potentials from joint nociceptors were made after intraarticular injection of IL-1ß into the rat knee joints. RESULTS: AIA generated pronounced and persistent mechanical and thermal hyperalgesia, and IL-1RI expression in the lumbar DRGs was significantly up-regulated. Treatment with anakinra did not significantly reduce the severity of arthritis or mechanical hyperalgesia, but did result in a pronounced reduction in thermal hyperalgesia. In cultured DRG neurons, IL-1ß up-regulated the expression of TRPV-1, a major transduction molecule involved in thermal hyperalgesia. During AIA, anakinra treatment down-regulated the expression of TRPV-1, consistent with the pronounced reduction in thermal hyperalgesia. IL-1ß increased the mechanosensitivity of C-fibers of the joint, but reduced the mechanosensitivity of Aδ-fibers, thus having opposite effects on these mechanonociceptive nerve fibers. CONCLUSION: In the context of arthritic knee pain, IL-1ß and IL-1 receptors appear to be involved in thermal, rather than mechanical, hyperalgesia. Therefore, neutralization of IL-1ß may be mainly antinociceptive in disease states characterized by thermal hyperalgesia, but not in disease states mainly characterized by mechanical hyperalgesia.

Molecular effects of interleukin-1ß on dorsal root ganglion neurons: prevention of ligand-induced internalization of the bradykinin 2 receptor and downregulation of G protein-coupled receptor kinase 2.

In dorsal root ganglion sections numerous small-to medium-sized neurons were found to exhibit extensive colocalization of the bradykinin receptor 2, the interleukin-1 receptor 1 and G protein-coupled receptor kinase 2. Application of bradykinin to cultured DRG neurons caused substantial internalization of the bradykinin 2 receptor which significantly reduced the responsiveness of DRG neurons to a second application of bradykinin. Such an internalization was not observed in DRG neurons which were exposed to long-term pretreatment with interleukin-1ß. The long-term incubation with interleukin-1ß on its own did neither change the proportion of neurons which expressed the bradykinin 2 receptor in the cytoplasma nor the proportion of neurons expressing the bradykinin 2 receptor in the membrane but it reduced the proportion of neurons expressing G protein-coupled receptor kinase 2, an enzyme which facilitates the internalization of G protein-coupled receptors. These results show that interleukin-1ß maintains the responsiveness of DRG neurons to bradykinin in the long-term range, and they suggest that the downregulation of G protein-coupled receptor kinase 2 could be a cellular mechanism involved in this interleukin-1ß effect.

Antinociceptive effects of tumor necrosis factor alpha neutralization in a rat model of antigen-induced arthritis: evidence of a neuronal target.

OBJECTIVE: The reduction of pain in the course of antiinflammatory therapy can result from an attenuation of the inflammatory process and/or from the neutralization of endogenous mediators of inflammation that act directly on nociceptive neurons. The purpose of this study was to investigate whether analgesic effects of the neutralization of tumor necrosis factor alpha (TNFalpha) are due to an attenuation of inflammation or whether direct neuronal effects significantly contribute to pain relief in the course of therapy. METHODS: Locomotor and pain-related behavior and histology were assessed in rats with chronic antigen-induced arthritis (AIA) in the knee joint, and the rats were treated with systemic saline, etanercept, or infliximab. The expression of TNF receptors (TNFRs) in dorsal root ganglia was measured using immunohistochemical analysis and polymerase chain reaction. Action potentials were recorded from afferent Adelta fibers and C fibers of the medial knee joint nerve, and etanercept and infliximab were injected intraarticularly into normal or inflamed knee joints (AIA or kaolin/carrageenan-induced inflammation). RESULTS: In rats with AIA, both etanercept and infliximab significantly decreased inflammation-induced locomotor and pain-related behavior, while joint swelling was only weakly attenuated and histomorphology still revealed pronounced inflammation. A large proportion of dorsal root ganglion neurons showed TNFRI- and TNFRII-like immunoreactivity. Intraarticular injection of etanercept reduced the responses of joint afferents to mechanical stimulation of the inflamed joint starting 30 minutes after injection, but had no effect on responses to mechanical stimulation of the uninflamed joint. CONCLUSION: Overall, these data show the pronounced antinociceptive effects of TNFalpha neutralization, thus suggesting that reduction of the effects of TNFalpha on pain fibers themselves significantly contributes to pain relief.

Fibroblast-like synovial cells from normal and inflamed knee joints differently affect the expression of pain-related receptors in sensory neurones: a co-culture study.

Innervation of the joint with thinly myelinated and unmyelinated sensory nerve fibres is crucial for the occurrence of joint pain. During inflammation in the joint, sensory fibres show changes in the expression of receptors that are important for the activation and sensitization of the neurones and the generation of joint pain. We recently reported that both neurokinin 1 receptors and bradykinin 2 receptors are upregulated in dorsal root ganglion (DRG) neurones (the cell bodies of sensory fibres) in the course of acute and chronic antigen-induced arthritis in the rat. In this study, we begin to address mechanisms of the interaction between fibroblast-like synovial (FLS) cells and sensory neurones by establishing a co-culture system of FLS cells and DRG neurones. The proportion of DRG neurones expressing neurokinin 1 receptor-like immunoreactivity was not altered in the co-culture with FLS cells from normal joints but was significantly upregulated using FLS cells from knee joints of rats with antigen-induced arthritis. The proportion of DRG neurones expressing bradykinin 2 receptors was slightly upregulated in the presence of FLS cells from normal joints but upregulation was more pronounced in DRG neurones co-cultured with FLS cells from acutely inflamed joints. In addition, the expression of the transient receptor potential V1 (TRPV1) receptor, which is involved in inflammation-evoked thermal hyperalgesia, was mainly upregulated by co-culturing DRG neurones with FLS cells from chronically inflamed joints. Upregulation of neurokinin 1 receptors but not of bradykinin 2 and TRPV1 receptors was also observed when only the supernatant of FLS cells from acutely inflamed joint was added to DRG neurones. Addition of indomethacin to co-cultures inhibited the effect of FLS cells from acutely inflamed joints on neurokinin 1 receptor expression, suggesting an important role for prostaglandins. Collectively, these data show that FLS cells are able to induce an upregulation of pain-related receptors in sensory neurones and, thus, they could contribute to the generation of joint pain. Importantly, the influence of FLS cells on DRG neurones is dependent on their state of activity, and soluble factors as well as direct cellular contacts are crucial for their interaction with neurones.

Calcitonin gene-related peptide enhances TTX-resistant sodium currents in cultured dorsal root ganglion neurons from adult rats.

The neuropeptide calcitonin gene-related peptide (CGRP) binds to a subpopulation of dorsal root ganglion (DRG) neurons, elevates intracellular calcium, and causes inward currents in about 30% of lumbar DRG neurons. Using whole-cell patch clamp recordings, we found in the present study that application of CGRP to isolated and cultured DRG neurons from the adult rat enhances voltage-gated TTX-resistant (TTX-R) Na(+) inward currents in about 30% of small- to medium-sized DRG neurons. During CGRP, peak densities of Na(+) currents increased significantly. CGRP shifted the membrane conductance of the CGRP-responsive cells towards hyperpolarization without changing the slope of the peak conductance curve. The effect of CGRP was blocked by coadministration of CGRP8-37, an antagonist at the CGRP receptor. The effect of CGRP was also blocked after bath application of PKA14-22, a membrane-permeant blocker of protein kinase A, and PKC19-31, a PKC inhibitor, in the recording pipette. These data show pronounced facilitatory effects of CGRP on TTX-R Na(+) currents in DRG neurons which are mediated through CGRP receptors and intracellular pathways involving protein kinases A and C. Thus, in addition to prostaglandins, CGRP is another mediator that affects TTX-R Na(+) currents which are thought to occur mainly in nociceptive DRG neurons.

Acute and long-term effects of IL-6 on cultured dorsal root ganglion neurones from adult rat.

IL-6 contributes to pain and hyperalgesia in inflamed tissue. We have investigated short- and long-term effects of IL-6 on dorsal root ganglion (DRG) neurones. Glycoprotein 130-like immunoreactivity (the signal transduction receptor subunit) was found in almost all neurones in DRG sections and in cultured DRG neurones from adult rat. In calcium-imaging studies bath application of IL-6 caused an increase of intracellular calcium in about one-third of the DRG neurones suggesting functional IL-6 receptors in a proportion of neurones. Long-term but not short-term exposure of DRG neurones to IL-6 in vitro significantly enhanced the proportion of DRG neurones expressing neurokinin 1 receptor-like immunoreactivity from 10% to up to 40%. This up-regulation was dependent on the activation of mitogen-activated protein kinase kinase (MEK) in the neurones, suggesting that the mitogen-activated protein kinase (MAPK) pathway is important for this effects of IL-6. Calcium-imaging studies demonstrated that previous exposure of DRG neurones to IL-6 enhanced the proportion of neurones that exhibit a substance P-induced rise in intracellular calcium. These data show that IL-6 has short- and long-term effects on a proportion of DRG neurones. These effects are likely to contribute to pro-nociceptive effects of IL-6.

Expression pattern of neuronal and skeletal muscle voltage-gated Na+ channels in the developing mouse heart.

In the mammalian heart, a variety of voltage-gated Na(+) channel transcripts and proteins have been detected. However, little quantitative information is available on the abundance of each transcript during development, or the contribution of TTX-sensitive Na(+) channels to the cardiac sodium current (I(Na)). Using competitive and real-time RT-PCR we investigated the transcription of six Na(+) channels (Na(v)1.1-Na(v)1.6) and the beta1 subunit during mouse heart development. Na(v)1.5 was predominantly expressed in the adult heart, whereas the splice variant Na(v)1.5a was the major Na(+) channel isoform in embryonic hearts. The TTX-resistant Na(+) channel transcripts (Na(v)1.5 and Na(v)1.5a) increased 1.7-fold during postnatal development. Transcripts encoding TTX-sensitive Na(+) channels (Na(v)1.1-Na(v)1.4) and the beta1 subunit gradually increased up to fourfold from postnatal day (P)1 to P126, while the Na(v)1.6 transcript level remained low and constant over the same period. In adults, TTX-sensitive channel mRNA accounted for 30-40% of the channel pool in whole-heart preparations (Na(v)1.3 > Na(v)1.4 > Na(v)1.2 >> Na(v)1.1 approximately Na(v)1.6), and 16% in mRNA from isolated cardiomyocytes (Na(v)1.4 > Na(v)1.3 > Na(v)1.2 > Na(v)1.1 > Na(v)1.6). Confocal immunofluorescence on ventricular myocytes suggested that Na(v)1.1 and Na(v)1.2 were localized at the intercalated disks and in the t tubules. Na(v)1.3 labelling predominantly produced a diffuse but strong intracellular signal. Na(v)1.6 fluorescence was detected only along the Z lines. Electrophysiological recordings showed that TTX-sensitive and TTX-resistant Na(+) channels, respectively, accounted for 8% and 92% of the I(Na) in adult ventricular cardiomyocytes. Our data suggest that neuronal and skeletal muscle Na(+) channels contribute to the action potential of cardiomyocytes in the adult mammalian heart.

The proportion of TRPV1 protein-positive lumbar DRG neurones does not increase in the course of acute and chronic antigen-induced arthritis in the knee joint of the rat.

The TRPV1 receptor, previously called VR1 receptor, is a non-selective cation channel gated by capsaicin, noxious heat, protons and anandamide. The TRPV1 receptor is essential for the development of thermal hyperalgesia. The present study investigated whether the proportion of neurones with TRPV1 receptor increases in lumbar DRG neurones in the course of an antigen-induced arthritis (AIA) of one knee joint in the rat. In control rats 38.1+/-2.3% of the neurones from sections of the L1-L5 ganglia showed TRPV1-like immunoreactivity. Neither in the acute (3 days) nor chronic phase (21 days) of AIA in the knee joint the proportion of TRPV1-like immunoreactive profiles showed significant changes. Thus AIA in the knee joint is not associated with an up-regulation of the TRPV1 receptor in the lumbar DRG neurones.

Mechanisms of pain in arthritis.

Inflammation in the joint causes peripheral sensitization (increase of sensitivity of nociceptive primary afferent neurons) and central sensitization (hyperexcitability of nociceptive neurons in the central nervous system). The processes of sensitization are thought to be the basis of arthritic pain that appears as spontaneous pain (joints at rest) and hyperalgesia (augmented pain response on noxious stimulation and pain on normally nonpainful stimulation). Sensitization also facilitates efferent neuronal processes through which the nervous system influences the inflammatory process. Peripheral sensitization is produced by the action of inflammatory mediators such as bradykinin, prostaglandins, neuropeptides, and cytokines which activate corresponding receptors in proportions of nerve fibers. In addition, the expression of receptors, for example, bradykinin and neurokinin 1 receptors, is upregulated during inflammation. The development of hyperexcitability of spinal cord neurons is produced by various transmitter/receptor systems that constitute and modulate synaptic activation of the neurons. The key transmitter is glutamate that activates N-methyl-d-aspartate (NMDA) and non-NMDA receptors on spinal cord neurons. Blockade of these receptors prevents and reduces central sensitization. Excitatory neuropeptides (substance P and calcitonin gene-related peptide) further central sensitization. Central sensitization also is facilitated by mediators that have complex actions (e.g., prostaglandin E(2)). Spinal PGE(2) binds to receptors at presynaptic endings of primary afferent neurons (thus influencing synaptic release) and to receptors on postsynaptic spinal cord neurons. The administration of PGE(2) to the spinal cord surface produces changes of responsiveness of spinal neurons similar to peripheral inflammation, and spinal indomethacin to the spinal cord attenuates development of hyperexcitability significantly.