A high-threshold heat-activated channel in cultured rat dorsal root ganglion neurons resembles TRPV2 and is blocked by gadolinium

Heat-activated ion channels from the vanilloid-type TRP group (TRPV1-4) seem to be central for heat-sensitivity of nociceptive sensory neurons. Displaying a high-threshold (> 52 degrees C) for activation, TRPV2 was proposed to act as a sensor for intense noxious heat in mammalian sensory neurons. However, although TRPV2 is expressed in a distinct population of thinly myelinated primary afferents, a widespread expression in a variety of neuronal and non-neuronal tissues suggests a more diverse physiological role of TRPV2. In its role as a heat-sensor, TRPV2 has not been thoroughly characterized in terms of biophysical and pharmacological properties. In the present study, we demonstrate that the features of heterologously expressed rat TRPV2 closely resemble those of high-threshold heat-evoked currents in medium- and large-sized capsaicin-insensitive rat dorsal root ganglion (DRG) neurons. Both in TRPV2-expressing human embryonic kidney (HEK)293t cells and in DRGs, high-threshold heat-currents were sensitized by repeated activation and by the TRPV1-3 agonist, 2-aminoethoxydiphenyl borate (2-APB). In addition to a previously described block by ruthenium red, we identified the trivalent cations, lanthanum (La(3+)) and gadolinium (Gd(3+)) as potent blockers of TRPV2. Thus, we present a new pharmacological tool to distinguish between heat responses of TRPV2 and the closely related capsaicin-receptor, TRPV1, which is strongly sensitized by trivalent cations. We demonstrate that self-sensitization of heat-evoked currents through TRPV2 does not require extracellular calcium and that TRPV2 can be activated in cell-free membrane patches in the outside-out configuration. Taken together our results provide new evidence for a role of TRPV2 in mediating high-threshold heat responses in a subpopulation of mammalian sensory neurons.     

Opioid regulation of intracellular free calcium in cultured mouse dorsal root ganglion neurons

Opioid agonists induced an increase in the intracellular free calcium concentration ([Ca²⁺]_i) or an inhibition of K⁺ (25 mM)-stimulated increase in [Ca²⁺]_i in different subsets of mouse dorsal root ganglion (DRG) neurons. The total neuronal population was grouped into three classes according to somatic diameter and defined as small (<16 μm), intermediate (16–25 μm), or large (>25 μm) neurons. Substance P-like immunoreactivity was detected mainly in the small and intermediate neurons. The δ, κ, and μ opioid receptor agonists [D-Ser², Leu⁵]enkephalin-Thr (DSLET), U69593, and [D-Ala², MePhe⁴, Gly-ol⁵]enkephalin (DAMGO) each induced a transient increase in [Ca²⁺]_i in a small fraction (<30%) of neurons. The increases in [Ca²⁺]_i were blocked by the opioid antagonist naloxone. The dihydropyridine-sensitive calcium channel blocker nifedipine also blocked the increase in [Ca²⁺]_i induced by 1 μM DSLET. The rank order of potency (percentage of cells responding to each opioid agonist) was DSLET > U69593 > DAMGO. The opioid-induced increase in [Ca²⁺]_i was observed mainly in large neurons, with a low incidence in small and intermediate neurons. Opioid agonists also caused inhibition of K⁺-stimulated increases in [Ca²⁺]_i, which were blocked by naloxone (1 μM). Inhibition of the K⁺-stimulated increase by 1 μM DSLET or U69593 was greater in small and intermediate neurons than in large neurons. © 1996 Wiley-Liss, Inc.     

Immortalization and characterization of a nociceptive dorsal root ganglion sensory neuronal line

Development of neuroprotective strategies for peripheral neuropathies requires high-throughput drug screening assays with appropriate cell types. Currently, immortalized dorsal root ganglion (DRG) sensory neuronal cell lines that maintain nociceptive sensory neuronal properties are not available. We generated immortalized DRG neuronal lines from embryonic day 14.5 rats. Here, we show that one of the immortalized DRG neuronal lines, 50B11, has the properties of a nociceptive neuron. When differentiated in the presence of forskolin, these cells extend long neurites, express neuronal markers, and generate action potentials. They express receptors and markers of small-diameter sensory neurons and upregulate appropriate receptor populations when grown in the presence of glial cell line-derived neurotrophic factor or nerve growth factor. Furthermore, they express capsaicin receptor transient receptor potential vanilloid family-1 (TRPV-1) and respond to capsaicin with increases in intracellular calcium. In a 96-well plate format, these neurons show a decline in ATP levels when exposed to dideoxycytosine (ddC) in a proper time- and dose-dependent manner. This ddC-induced reduction in ATP levels correlates with axonal degeneration. The immortalized DRG neuronal cell line 50B11 can be used for high-throughput drug screening for neuroprotective agents for axonal degeneration and antinociceptive drugs that block TRPV-1.     

小鼠背根神经节中三个不同的钙激活氯离子通道基因家族的表达(英文)

目的在背根神经节(dorsal root ganglion,DRG)中等大小感觉神经元中可以观察到钙激活氯离子流(I_(Cl(Ca)))。在坐骨神经损伤模型中,在大多数大中神经元上诱导出类似的氯离子流。本文旨在探讨引起这个离子流的分子基础。方法使用常规的定量RT-PCR方法检测在DRG中三个基因家族的表达,这三个基因家族都具有诱导I_(Cl(Ca))的特点。结果在成年小鼠的DRG中,分别显示了在正常状态和坐骨神经损伤3天后CLCA,Bestrophin和Tweety基因家族成员的转录产物。结论mBestl和Tweety2可能在损伤诱导的DRG神经元I_(Cl(Ca))中发挥作用。     

小鼠背根神经节中三个不同的钙激活氯离子通道基因家族的表达

目的在背根神经节（dorsalrootganglion,DRG）中等大小感觉神经元中可以观察到钙激活氯离子流（ICl（Ca））。在坐骨神经损伤模型中,在大多数大中神经元上诱导出类似的氯离子流。本文旨在探讨引起这个离子流的分子基础。方法使用常规的定量RT-PCR方法检测在DRG中三个基因家族的表达,这三个基因家族都具有诱导,ICl（Ca）的特点。结果在成年小鼠的DRG中,分别显示了在正常状态和坐骨神经损伤3天后CLCA,Bestrophin和Tweety基因家族成员的转录产物。结论mBestl和Tweety2可能在损伤诱导的DRG神经元,ICl（Ca）中发挥作用。     

Effects of lysophosphatidic acid on sodium currents in rat dorsal root ganglion neurons

Lysophosphatidic acid (LPA), a simple phospholipid, induces pain. To elucidate an involvement of ion channel mechanism in the LPA-induced pain, its effects on sodium currents in rat dorsal root ganglion (DRG) neurons were investigated. LPA suppressed tetrodotoxin-sensitive (TTX-S) sodium current, but increased tetrodotoxin-resistant (TTX-R) sodium current, when currents were evoked by step depolarizations to 0 mV from a holding potential of -80 mV. In both types of currents, LPA produced a hyperpolarizing shift of both activation and inactivation voltages. LPA had a negligible effect on the maximal conductance of TTX-S current, but increased that of TTX-R current. The results suggest that the enhancement of TTX-R current may contribute to the LPA-induced pain.     

Calcium channels in the somatic membrane of the rat dorsal root ganglion neurons, effect of cAMP

Isolated rat dorsal root ganglion neurons have been perfused with potassium-free solutions containing cAMP, ATP and Mg2+ ions. In these conditions stable inward calcium currents can be recorded in the somatic membrane of all investigated cells. The kinetics of these currents can be approximated by a modified Hodgkin-Huxley equation using a square power of the m-variable; its inactivation is extremely slow. The corresponding channels pass Ba2+ ions about twice more effective than Ca2+.     

Effects of free fatty acids on sodium currents in rat dorsal root ganglion neurons

Free fatty acids (FFAs), especially polyunsaturated fatty acids (PUFAs), are potent modulators of muscle-type sodium channels. It is not known if they also modulate sodium channels of sensory neurons. In this study, we investigated the effects of FFAs on the fast tetrodotoxin-sensitive (fTTX-S) and the slow tetrodotoxin-resistant (sTTX-R) sodium currents in rat dorsal root ganglion neurons. At a holding potential of -80 mV, PUFAs potently inhibited fTTX-S current, but monounsaturated fatty acids (MUFAs) and saturated fatty acids (SFAs) to a lesser extent. All FFAs initially increased sTTX-R current, and then decreased it slightly. PUFAs and MUFAs produced a hyperpolarizing shift of the steady-state inactivation voltage for both types of sodium currents. The shift generally increased with the number of unsaturated bonds. FFAs did not change the maximum amplitude of fTTX-S current, but increased that of sTTX-R current. Most FFAs shifted the activation voltage for fTTX-S current in the hyperpolarizing direction, which was not dependent on the degree of unsaturation. MUFAs and SFAs shifted the activation voltage for sTTX-R current in the hyperpolarizing direction, but PUFAs were without effect. The modulation of sodium currents by FFAs, especially PUFAs, may have considerable impact on the excitability of sensory neurons.     

Sphingosine‐1‐phosphate induces Ca2+ signaling and CXCL1 release via TRPC6 channel in astrocytes

A biologically active lipid, sphingosine‐1‐phosphate (S1P) is highly abundant in blood, and plays an important role in regulating the growth, survival, and migration of many cells. Binding of the endogenous ligand S1P results in activation of various signaling pathways via G protein‐coupled receptors, some of which generates Ca²⁺ mobilization. In astrocytes, S1P is reported to evoke Ca²⁺ signaling, proliferation, and migration; however, the precise mechanisms underlying such responses in astrocytes remain to be elucidated. Transient receptor potential canonical (TRPC) channels are Ca²⁺‐permeable cation channels expressed in astrocytes and involved in Ca²⁺ influx after receptor stimulation. In this study, we investigated the involvement of TRPC channels in S1P‐induced cellular responses. In Ca²⁺ imaging experiments, S1P at 1 μM elicited a transient increase in intracellular Ca²⁺ in astrocytes, followed by sustained elevation. The sustained Ca²⁺ response was markedly suppressed by S1P₂ receptor antagonist JTE013, S1P₃ receptor antagonist CAY10444, or non‐selective TRPC channel inhibitor Pyr2. Additionally, S1P increased chemokine CXCL1 mRNA expression and release, which were suppressed by TRPC inhibitor, inhibition of Ca²⁺ mobilization, MAPK pathway inhibitors, or knockdown of the TRPC channel isoform TRPC6. Taken together, these results demonstrate that S1P induces Ca²⁺ signaling in astrocytes via G_q‐coupled receptors S1P₂ and S1P₃, followed by Ca²⁺ influx through TRPC6 that could activate MAPK signaling, which leads to increased secretion of the proinflammatory or neuroprotective chemokine CXCL1.     

Spontaneous hyperpolarizations at the membrane of cultured mouse dorsal root ganglion cells

Intracellular recordings from cultured mouse dorsal root (sensory) ganglion cells revealed the presence of spontaneous hyperpolarizing potentials in over half of the cells. The potentials were resistant to tetrodotoxin and under voltage clamp were replaced by fluctuations in outward current. The power spectral density plots of these current fluctuations were predominantly of the Lorentzian type. These events may play an important role in the functioning of some sensory nerve cells.     

糖尿病早期大鼠背根神经节中的差异表达基因

目的研究糖尿病早期大鼠背根神经节（dorsal root ganglion,DRG）中基因的差异表达,探索糖尿病神经病变相关基因。方法一次性腹腔注射链脲菌素（streptozotocin,STZ）制备糖尿病模型大鼠,于造模成功后第2周,测量其感觉神经传导速度（sensory nerve conduction velocities,SNCV）,然后运用银染差异显示逆转录聚合酶链反应法（differential display polymerase chain reaction,DD—PCR）从糖尿病模型组与对照组大鼠的DRG中获得两者差异表达的cDNA片段,并进行反杂交筛选、克隆测序、DNA序列检索分析与Northern印迹验证。结果糖尿病模型大鼠建模2周时,其SNCV与对照组相比显著下降（P〈0．05）。银染差异显示并经克隆获得7个差异片段,一个为上调基因,其余为下调基因。经GenBank查询,仅其中的上调基因的cDNA序列与6-丙酮酰四氢喋呤合酶基因（6-pyruvoyl—tetrahydropterin synthase,序列号BC059140）高度同源,其它差异表达片段未检出与已知基因有同源性。结论这些在糖尿病早期背根神经节中差异表达的基因可能参与了糖尿病神经病变的发生发展。     

Distinct cellular expression and subcellular localization of Kv2 voltage-gated K+ channel subtypes in dorsal root ganglion neurons conserved between mice and humans

The distinct organization of Kv2 voltage-gated potassium channels on and near the cell body of brain neurons enables their regulation of action potentials and specialized membrane contact sites. Somatosensory neurons have a pseudounipolar morphology and transmit action potentials from peripheral nerve endings through axons that bifurcate to the spinal cord and the cell body within ganglia including the dorsal root ganglia (DRG). Kv2 channels regulate action potentials in somatosensory neurons, yet little is known about where Kv2 channels are located. Here, we define the cellular and subcellular localization of the Kv2 paralogs, Kv2.1 and Kv2.2, in DRG somatosensory neurons with a panel of antibodies, cell markers, and genetically modified mice. We find that relative to spinal cord neurons, DRG neurons have similar levels of detectable Kv2.1 and higher levels of Kv2.2. In older mice, detectable Kv2.2 remains similar, while detectable Kv2.1 decreases. Both Kv2 subtypes adopt clustered subcellular patterns that are distinct from central neurons. Most DRG neurons co-express Kv2.1 and Kv2.2, although neuron subpopulations show preferential expression of Kv2.1 or Kv2.2. We find that Kv2 protein expression and subcellular localization are similar between mouse and human DRG neurons. We conclude that the organization of both Kv2 channels is consistent with physiological roles in the somata and stem axons of DRG neurons. The general prevalence of Kv2.2 in DRG as compared to central neurons and the enrichment of Kv2.2 relative to detectable Kv2.1 in older mice, proprioceptors, and axons suggest more widespread roles for Kv2.2 in DRG neurons.     

Spontaneous voltage and current fluctuations in tissue cultured mouse dorsal root ganglion cells

Fetal mouse dorsal root ganglion (DRG) neurons were maintained in primary dissociated cell culture for periods of 7 days to 3 months. Intracellular recordings from these cells revealed the presence of spontaneous subthreshold potentials in 101/177 neurons studied. When measured at the resting membrane potential, these spontaneous voltage events took two forms: (a) high frequency potential fluctuations several millivolts in peak-to-peak amplitude and (b) small, discrete hyperpolarizations. Neurons exhibiting either type of event were designated as 'active' DRG cells. No spontaneous potentials were seen in DRG cells hyperpolarized to membrane voltages more negative than -64 +/- 11.5 mV (n = 5 cells). Under voltage-clamp conditions, the subthreshold potentials of active DRG cells were replaced by fluctuations in outward current. The power spectral density, S(f) of these current fluctuations was approximated by an equation of the form S(f) = (S(o)/[1 + (f/fc) alpha] where 2 less than or equal to a less than or equal to 3 and the half-power frequency fc = 11.3 +/- 3.1 Hz at 23 degrees C (n = 17 cells). The spontaneous voltage fluctuations of active DRG cells were abolished in Ca2+-free saline, and of the divalent metal cations Sr2+, Mg2+, Ba2+, Co2+ and Mn2+, only Sr2+ could substitute for Ca2+ in the maintenance of this activity. Tetraethylammonium ions (1-10 mM) reversibly blocked the spontaneous potentials, while caffeine (10 mM) increased the frequency of these events. The spontaneous voltage fluctuations were not dependent on the presence of spinal cord neurons in the culture plate, and they were also observed in cultured DRG cells derived from adult mice.     

Expression and localization of insulin receptor in rat dorsal root ganglion and spinal cord

The expression and localization of the insulin receptor (IR) was examined in rat dorsal root ganglia (DRG) and spinal cord using Western blotting, in situ hybridization and immunocytochemistry. Western blotting showed that the molecular weight of the IR beta subunit was higher in PNS than that found in CNS. Both IR mRNA and protein expressions were highest in small-sized sensory DRG neurons and myelinated sensory root fibers expressed higher levels of IR protein than myelinated anterior root fibers. In the spinal cord, IR immunoreactive neurons were present in lateral lamina V and in lamina X, suggesting the presence of IR in nociceptive pathways. Electronmicroscopy of DRGs revealed a polarized localization of the IR in abaxonal Schwann cell membranes, outer mesaxons in close vicinity to tight junctions of both myelinating and non-myelinating Schwann cells and to plasma membranes of sensory neurons. From these findings, we speculate that insulin may play a role in sensory fibers involved in nociceptive function often perturbed in diabetic neuropathy. The high expression of IR localizing to tight junctions of dorsal root mesaxons of DRGs may suggest a regulatory role on barrier functions compensating for the lack of a blood-nerve barrier in dorsal root ganglia. This is consistent with the colocalization of IR with tight junctions of the paranodal barrier and endoneurial endothelial cells in peripheral nerve.     

Differential expression of alpha1-adrenoceptor subtype mRNAs in the dorsal root ganglion after spinal nerve ligation

In spinal nerve ligated Lewis strain neuropathic rats, pain behaviors and the rate of ectopic discharges of injured sensory neurons were significantly reduced by systemic injection of phentolamine. A pharmacological study indicated that this adrenergic dependency was mediated by alpha(1)-adrenoceptors (alpha(1)-AR). The development of adrenergic sensitivity in injured sensory neurons might have resulted from changes in adrenoceptor expression as a consequence of changed expression of adrenoceptor genes. This possibility was examined by determining the changes in the mRNA expression of 3 subtypes of alpha(1)-ARs, alpha(1a)-, alpha(1b)-, and alpha(1d)-ARs, in the dorsal root ganglia (DRG) after spinal nerve ligation. The L4 and L5 spinal nerves were tightly ligated in Lewis rats. One week later, the L4 and L5 DRG were collected and RNase protection assay (RPA) and in situ hybridization were performed. In the DRG of unoperated rats, a moderate amount of alpha(1a)-AR mRNA was present while the amount of either alpha(1b)-AR or alpha(1d)-AR mRNA was small. After spinal nerve ligation, there was a significant increase in the amount of alpha(1b)-AR mRNA in the nerve ligated DRG as measured by RPA. The amount of alpha(1a)-AR mRNA was decreased to 20% of the normal level while that of alpha(1d)-AR mRNA did not change. The in situ hybridization study showed that the number of alpha(1b)-AR mRNA positive neurons increased in spinal nerve ligated DRG, confirming the results of RPA study. These data suggest that the up-regulated expression of alpha(1b)-AR mRNA in axotomized DRG neurons may play an important role in the development of adrenergic sensitivity in injured sensory neurons and thus contribute to the sympathetically maintained pain in spinal nerve ligated neuropathic Lewis rats.     

The maturation-dependent change in fibronectin receptor density of mouse dorsal root ganglion neurons

The maturation-dependent change in fibronectin receptor density of mouse dorsal root ganglion neurons were investigated by an immuno-cytofluorometric method. The receptor density showed a drastic decrease around birth and a smaller change after birth.