Effects of Gabapentin on Different Neuronal Populations in the Dorsal-Root Ganglia of Rats with Streptozotocin-Induced <Emphasis Type="Italic">Diabetes Mellitus</Emphasis>

We studied the effect of gabapentin (an agent similar, in its molecular structure, to gamma-aminobutyric acid, GABA) on depolarization-evoked calcium transients in small, mid-sized, and large (diameter of the soma up to 25, 25 to 35, and 35 μm or more, respectively) neurons of the dorsal-root ganglia (DRGs) of rats with experimental streptozotocin-induced diabetes mellitus. These transients were measured using a calcium-sensitive fluorescent dye, Fura 2/AM. The amplitude of calcium transients in rats with diabetes was somewhat higher than that in healthy animals (in large and mid DRG neurons by nearly 12% and in small cells by about 8%, on average). The development of diabetes led to a dramatic increase in the total duration of such transients. In large, mid, and small DRG neurons, the values of this parameter in animals with diabetes were, respectively, about 260, 430, and 250% as compared with the norm. The duration of transients at the level of 50% amplitude (Т _0.5) in diabetes changed to a significantly smaller extent. Applications of gabapentin (25 μM) led to a decrease in the amplitude of calcium transients, their full duration, and Т _0.5. The effects of gabapentin were the strongest in large DRG neurons where the amplitude of calcium transients dropped by nearly 36%, while the total duration demonstrated a more than threefold decrease. Upon the action of gabapentin, the parameter Т _0.5 changed moderately (in all groups of DRG neurons, the decrease varied from 8 to 12%). Gabapentin-induced decreases in the amplitude of calcium transients differed in various subgroups of DRG neurons. Among neurons with mid-sized somata, the decrease in this parameter in capsaicin-positive cells was 16.3%, while that in capsaicin-negative cells reached 36.7%. The obtained data are indicative of the ability of gabapentin to normalize, to a certain extent, the parameters of diabetes-modified calcium transients in DRG neurons. This ability is more clearly pronounced in large neurons (we hypothesize that a part of such cells in animals with diabetes are, probably, abnormally involved in transmission of nociceptive influences) and also in a part of mid-sized DRG neurons participating in the formation of acute pain sensation.     

Activity of TRPV1 Channels in Primary Nociceptive Neurons of Rats: Modulation by Changes in Intracellular Calcium Level

In rat neurons of the dorsal root ganglia (DRG) with mid- (35 to 25 μm) and small-sized (less than 25 μm) somata, we studied calcium transients induced by application of capsaicin (selective agonist of TRPV1 channels) under conditions of the development of other calcium transients caused by preliminary depolarization of the plasma membrane of these neurons. The above transients in rat DRG neurons were measured using the calcium-sensitive fluorescent dye Fura 2/AM. At delays of 3, 7, and 10 sec with respect to the beginning of preliminary potassium depolarization, the amplitudes of capsaicin-induced responses were smaller, as compared with the control, on average, by 26.8, 22.1, and 4.5%, respectively, in the population of mid-sized neurons and by 35.3, 21.1, and 22.4% in small neurons. Under such conditions, we observed noticeable delays of reactions to applications of capsaicin and a certain decrease in the level of intracellular calcium at the moment of beginning of development of these reactions with respect to the corresponding values in isolated depolarization-induced transients. We conclude that excitation of primary nociceptive neurons and activation of voltage-operated calcium channels result in noticeable modulation of the activity of TRPV1 channels and change their role during pain reception.     

The Effect of Nimodipine on Calcium Homeostasis and Pain Sensitivity in Diabetic Rats

Summary 1. The pathogenesis of diabetic neuropathy is a complex phenomenon, the mechanisms of which are not fully understood. Our previous studies have shown that the intracellular calcium signaling is impaired in primary and secondary nociceptive neurons in rats with streptozotocin (STZ)-induced diabetes. Here, we investigated the effect of prolonged treatment with the L-type calcium channel blocker nimodipine on diabetes-induced changes in neuronal calcium signaling and pain sensitivity.2. Diabetes was induced in young rats (21 p.d.) by a streptozotocin injection. After 3 weeks of diabetes development, the rats were treated with nimodipine for another 3 weeks. The effect of nimodipine treatment on calcium homeostasis in nociceptive dorsal root ganglion neurons (DRG) and substantia gelatinosa (SG) neurons of the spinal cord slices was examined with fluorescent imaging technique.3. Nimodipine treatment was not able to normalize elevated resting intracellular calcium ([Ca²⁺] _i ) levels in small DRG neurons. However, it was able to restore impaired Ca²⁺ release from the ER, induced by either activation of ryanodine receptors or by receptor-independent mechanism in both DRG and SG neurons.4. The beneficiary effects of nimodipine treatment on [Ca²⁺] _i signaling were paralleled with the reversal of diabetes-induced thermal hypoalgesia and normalization of the acute phase of the response to formalin injection. Nimodipine treatment was also able to shorten the duration of the tonic phase of formalin response to the control values.5. To separate vasodilating effect of nimodipine Biessels et al., (Brain Res. 1035:86–93) from its effect on neuronal Ca²⁺ channels, a group of STZ-diabetic rats was treated with vasodilator – enalapril. Enalapril treatment also have some beneficial effect on normalizing Ca²⁺ release from the ER, however, it was far less explicit than the normalizing effect of nimodipine. Effect of enalapril treatment on nociceptive behavioral responses was also much less pronounced. It partially reversed diabetes-induced thermal hypoalgesia, but did not change the characteristics of the response to formalin injection.6. The results of this study suggest that chronic nimodipine treatment may be effective in restoring diabetes-impaired neuronal calcium homeostasis as well as reduction of diabetes-induced thermal hypoalgesia and noxious stimuli responses. The nimodipine effect is mediated through a direct neuronal action combined with some vascular mechanism.     

Spinorphin inhibits membrane depolarization- and capsaicin-induced intracellular calcium signals in rat primary nociceptive dorsal root ganglion neurons in culture

Abstract

Objective: Spinorphin is a potential endogenous antinociceptive agent although the mechanism(s) of its analgesic effect remain unknown. We conducted this study to investigate, by considering intracellular calcium concentrations as a key signal for nociceptive transmission, the effects of spinorphin on cytoplasmic Ca²⁺ ([Ca²⁺]_i) transients, evoked by high-K⁺ (30?mM) depolariasation or capsaicin, and to determine whether there were any differences in the effects of spinorphin among subpopulation of cultured rat dorsal root ganglion (DRG) neurons. Methods: DRG neurons were cultured on glass coverslips following enzymatic digestion and mechanical agitation, and loaded with the calcium sensitive dye fura-2 AM (1?µM). Intracellular calcium responses in individual DRG neurons were quantified using standard fura-2 based ratiometric calcium imaging technique. All data were analyzed by using unpaired t test, p?<?0.05 defining statistical significance. Results: Here we found that spinorphin inhibited cytoplasmic Ca²⁺ ([Ca²⁺]_i) transients, evoked by depolarization and capsaicin selectively in medium and small cultured rat DRG neurons. Spinorphin (10–300?µM) inhibited the Ca²⁺ signals in concentration dependant manner in small- and medium diameter DRG neurons. Capsaicin produced [Ca²⁺]_i responses only in small- and medium-sized DRG neurons, and pre-treatment with spinorphin significantly attenuated these [Ca²⁺]_i responses. Conclusion: Results from this study indicates that spinorphin significantly inhibits [Ca²⁺]_i signaling, which are key for the modulation of cell membrane excitability and neurotransmitter release, preferably in nociceptive subtypes of this primary sensory neurons suggesting that peripheral site is involved in the pain modulating effect of this endogenous agent.     

The actions of the neonicotinoid imidacloprid on cholinergic neurons of Drosophila melanogaster

The neonicotinoid insecticide imidacloprid is an agonist on insect nicotinic acetylcholine receptors (nAChRs). We utilised fura-2-based calcium imaging to investigate the actions of imidacloprid on cultured GFP-tagged cholinergic neurons from the third instar larvae of the genetic model organism Drosophila melanogaster. We demonstrate dose-dependent increases in intracellular calcium ([Ca²⁺]_i) in cholinergic neurons upon application of imidacloprid (10 nM–100 μM) that are blocked by nAChR antagonists mecamylamine (10 μM) and α-bungarotoxin (α-BTX, 1 μM). When compared to other (untagged) neurons, cholinergic neurons respond to lower concentrations of imidacloprid (10–100 nM) and exhibit larger amplitude responses to higher (1–100 μM) concentrations of imidacloprid. Although imidacloprid acts via nAChRs, increases in [Ca²⁺]_i also involve voltage-gated calcium channels (VGCCs) in both groups of neurons. Thus, we demonstrate that cholinergic neurons express nAChRs that are highly sensitive to imidacloprid, and demonstrate a role for VGCCs in amplifying imidacloprid-induced increases in [Ca²⁺]_i.     

β-amyloid-induced changes in calcium homeostasis in cultured hippocampal neurons of the rat

A two-wave technique of calciometry with the use of a fluorescence dye, fura-2/AM, was applied for examination of the effect of a protein, β-amyloid (the main component of senile plaques in Alzheimer’s disease), on calcium homeostasis in cultured neurons of the rat hippocampus; β-amyloid was added to the culture medium. In most neurons, the effect of β-amyloid appeared as a more than twofold increase in the basic calcium concentration, as compared with the control (153.4 ± 11.5 and 71.7 ± 5.4 nM, respectively; P < 0.05). The characteristics of calcium transients induced by application of hyperpotassium solution also changed; the amplitude of these transients decreased, and the duration of a part corresponding to calcium release from the cell (rundown of the transient) increased. The mean amplitude of calcium transients under control conditions was 447.5 ± 20.1 nM, while after incubation in the presence of β-amyloid this index dropped to 278.4 ± 22.6 nM. Under control conditions, the decline phase of calcium transients lasted, on average, 100 ± 6 sec, while after incubation of hippocampal cell cultures in the presence of β-amyloid this phase lasted 250 ± 10 sec. Therefore, an excess of β-amyloid influences significantly calcium homeostasis in the nerve cells by disturbing functions of the calcium-controlling systems, such as voltage-operated calcium channels of the plasma membrane and calcium stores of the mitochondria and endoplasmic reticulum. Neirofiziologiya/Neurophysiology, Vol. 40, No. 1, pp. 9–12, January–February, 2008.     

Effects of mibefradil on synaptic transmission in the hippocampus and on voltage-dependent currents in isolated hippocampal and thalamic neurons of the rat

The effects of a novel anti-hypertensive drug, mibefradil, on voltage-dependent currents in isolated thalamic and hippocampal neurons, as well as on synaptic transmission in the hippocampus have been studied. Mibefradil exerted a potent inhibitory action on low-threshold calcium currents in thalamic neurons (IC₅₀=160 nM). In higher concentrations (1–20 μM), this drug blocked not only low-threshold calcium current but also voltage-dependent sodium and delayed potassium currents in pyramidal hippocampal neurons. The amplitude of population action potentials in hippocampal slices decreased by 55% in the presence of 20μM mibefradil. All of the effects of mibefradil were almost completely reversible. In our experiments, the sensitivity of low-threshold calcium channels in thalamic neurons to mibefradil was higher than that observed on other objects. The ability of mibefradil to block not only calcium currents but also other types of voltage-dependent ion conductances in hippocampal neurons may be considered an essential factor that determines the specificity of the pharmacological profile of this drug.     

Characteristics of store-operated calcium channels activated by depletion of the endoplasmic reticulum ryanodine-sensitive calcium stores in rat dorsal root ganglion neurons

In neurons of the rat dorsal root ganglia (DRG), using a patch-clamp technique in the whole-cell configuration, we studied the characteristics of calcium channels activated by depletion of the ryanodine-sensitive calcium stores of the endoplasmic reticulum. Current-voltage (I-V) relationships of these store-operated calcium channels were obtained by subtraction of the integral I-V characteristics after application of caffeine from the integral I-V characteristics of calcium channels in the control. Currents through store-operated calcium channels could be induced by application of a series of hyperpolarization current pulses to the cell under conditions of replacement of a calcium-free solution containing caffeine by a caffeine-free solution containing 2 mM Ca²⁺. In this case, the following two main conditions were abserved: Voltage-operated calcium channels were inactivated, while a gradient of the electrochemical potential for calcium ions was increased, which made easier passing of these currents through store-operated calcium channels. Therefore, we found that in DRG neurons, despite the presence of great numbers of both voltage-operated and receptor-dependent calcium channels, one more mechanism underlying the entry of calcium through store-operated channels does exist. Neirofiziologiya/Neurophysiology, Vol. 39, No. 3, pp. 195–200, May–June, 2007.     

ATP-induced calcium signalling in acinar cells of the submandibular salivary gland

To study changes in the cytoplasmic Ca²⁺ concentration ([Ca²⁺]_i) and the total amount of calcium in cells, we used, respectively, the fluorescent dye fura 2/AM and the metallochrome dye arsenazo III. The total amount of calcium in acinar cells after their incubation in calcium-free ATP-containing extracellular solution decreased. The action of ATP induced a dose-dependent increase in the [Ca²⁺]_i; the EC₅₀ was, on average, 130 ± ± 36 μM. Calcium transients induced by ATP demonstrated no desensitization. Against the background of a blocker of ionotropic P2X receptors, pyridoxal phosphate-6-azophenyl-2′,4′-disulfonic acid, we observed a decrease in the ATP-induced calcium transients by 72%. In addition, these transients were reduced by 65% in the calcium-free milieu, while after thapsigargin-induced exhaustion of the endoplasmic reticulum store they disappeared. This is indicative of the involvement of metabotropic P2Y receptors in the formation of the above calcium transients. Therefore, P2X and P2Y receptors participate in ATP-induced calcium signalling in acinar cells of the submandibular salivary gland; activation of these channels results in a rise in the [Ca²⁺]_i. The P2X receptors to a higher extent contribute to the formation of calcium signals; the P2Y-determined increase in the [Ca²⁺]_i is smaller (equal to about 35%). Therefore, the functionally active ligand-operated ionotropic P2Y receptors and metabotropic G protein-related P2Y receptors do exist in acinar cells of the submandibular salivary gland and play an important role in the control of functioning of this gland. Neirofiziologiya/Neurophysiology, Vol. 37, Nos. 5/6, pp. 395–402, September–December, 2005.     

Induction of Long-Term Depression of Synaptic Transmission in a Co-Culture of DRG and Spinal Dorsal Horn Neurons of Rats

In a co-culture of dissociated neurons of lumbar dorsal root ganglia (DRG) and spinal dorsal horn (DH) neurons of newborn rats, we examined peculiarities of induction of long-term depression (LTD) of synaptic transmission through synapses formed by primary afferents on DH neurons. Induction of LTD was provided by low-frequency (5 sec⁻¹) microstimulation of single DRG neurons. Ion currents were simultaneously recorded in pre- and post-synaptic cells using a dual whole-cell path-clamp technique. Parameters of evoked excitatory and inhibitory postsynaptic currents (eEPSCs and eIPSCs, respectively) initiated in DH neurons by intracellular stimulation of DRG neurons were analyzed. Monosynaptic eEPSC mediated by activation of AMPA receptors demonstrated no sensitivity to blockers of NMDA and kainate receptors (20 μM D_L-AP5 and 10 μM SIM 2081, respectively), but were entirely blocked upon applications of 10 μM DNQX. Monosynaptic glycinergic eIPSCs found in some of the DH neurons were blocked by 1 μM strychnine and were insensitive to 10 μM bicuculline and blockers of glutamatergic neurotransmission, D_L-AP5 and DNQX. Long-lasting (360 sec) low-frequency stimulation of DRG neurons did not affect the amplitude of glycineinduced eIPSCs in DH neurons. At the same time, such stimulation of DRG neurons evoked a drop in the amplitude of AMPA-activated eEPSCs in DH neurons to 41.6 ± 2.5%, on average, as compared with the analogous index in the control. This effect lasted at least 20 min after stimulation. Long-term depression of glutamatergic transmission in DH neurons was observed at the holding potential of −70 mV and did not change after applications of 10 μM bicuculline and 1 μM strychnine. The LTD intensity depended on the duration of low-frequency stimulation of primary afferent neurons. Sequential stimulation of DRG neurons lasting 120, 160, 200, and 240 sec resulted in decreases in the eEPSC amplitude in DH neurons to 85.6 ± 3.9, 62.7 ± 4.3, 51.8 ± 3.5, and 41.6 ±2.5% with respect to control values. Our findings show that use-dependent induction of homosynaptic LTD of glutamatergic transmission is possible at the level of a separate pair of synaptically connected DRG and DH neurons under co-culturing conditions. Such LTD of glutamatergic synaptic transmission mostly mediated by activation of AMPA receptors depends on the duration of activation of a presynaptic DRG neuron and does not need depolarization of a postsynaptic DH neuron.     

Block of Voltage-dependent Calcium Channel by the Green Mamba Toxin Calcicludine

A number of peptide toxins derived from marine snails and various spiders have been shown to potently inhibit voltage-dependent calcium channels. Here, we describe the effect of calcicludine, a 60 amino-acid peptide isolated from the venom of the green mamba (Dendroaspis angusticeps), on transiently expressed high voltage-activated calcium channels. Upon application of calcicludine, L-type (α_{1 C} ) calcium channels underwent a rapid, irreversible decrease in peak current amplitude with no change in current kinetics, or any apparent voltage-dependence. However, even at saturating toxin concentrations, block was always incomplete with a maximum inhibition of 58%, indicating either partial pore block, or an effect on channel gating. Block nonetheless was of high affinity with an IC₅₀ value of 88 nm. Three other types of high voltage activated channels tested (α_{1 A} , α_{1 B} , and α_{1 E} ) exhibited a diametrically different response to calcicludine. First, the maximal inhibition observed was around 10%, furthermore, the voltage-dependence of channel activation was shifted slightly towards more negative potentials. Thus, at relatively hyperpolarized test potentials, calcicludine actually upregulated current activity of (N-type) α_{1 B} channels by as much as 50%. Finally, the use of several chimeric channels combining the major transmembrane domains of α_{1 C} and α_{1 E} revealed that calcicludine block of L-type calcium channels involves interactions with multiple structural domains. Overall, calcicludine is a potent and selective inhibitor of neuronal L-type channels with a unique mode of action. Received: 22 September 1999/Revised: 1 December 1999     

Inhibition of ATP-Induced Ca<Superscript>2+</Superscript> Influx by Corticosterone in Dorsal Root Ganglion Neurons

In addition to the classic genomic effects, it is well known that glucocorticoids also have rapid, nongenomic effects on neurons. In the present study, the effect of corticosterone (CORT) on ATP-induced Ca²⁺ mobilization in cultured dorsal root ganglion (DRG) neurons were detected with confocal laser scanning microscopy using fluo-4/AM as a calcium fluorescent indicator that could monitor real-time alterations of intracellular calcium concentration ([Ca²⁺]i). ATP, an algesic agent, caused [Ca²⁺]i increase in DRG neurons by activation of P2X receptor. Pretreatment with CORT (1 nM–1 μM for 5 min) inhibited ATP-induced [Ca²⁺]i increase in DRG neurons. The rapid inhibition of ATP-induced Ca²⁺ response by CORT was concentration-dependent, reversible and could be blocked by glucocorticoid receptor antagonist RU38486 (10 μM). Furthermore, the inhibitory effect of CORT was abolished by protein kinase A inhibitor H89 (10 μM), but was not influenced by protein kinase C inhibitor Chelerythrine chloride (10 μM). On the other hand, membrane-impermeable bovine serum albumin-conjugated corticosterone had no effect on ATP-induced [Ca²⁺]i transients. These observations suggest that a nongenomic pathways may be involved in the effect of CORT on ATP-induced [Ca²⁺]i transients in cultured DRG neurons.     

Subunit Regulation of the Human Brain α1E Calcium Channel

The α₁ subunit coding for the human brain type E calcium channel (Schneider et al., 1994) was expressed in Xenopus oocytes in the absence, and in combination with auxiliary α₂δ and β subunits. α_1E channels directed with the expression of Ba²⁺ whole-cell currents that completely inactivated after a 2-sec membrane pulse. Coexpression of α_1E with α_2bδ shifted the peak current by +10 mV but had no significant effect on whole-cell current inactivation. Coexpression of α_1E with β_2a shifted the peak current relationship by −10 mV, and strongly reduced Ba²⁺ current inactivation. This slower rate of inactivation explains that a sizable fraction (40 ± 10%, n= 8) of the Ba²⁺ current failed to inactivate completely after a 5-sec prepulse. Coinjection with both the cardiac/brain β_2a and the neuronal α_2bδ subunits increased by ≈10-fold whole-cell Ba²⁺ currents although coinjection with either β_2a or α_2bδ alone failed to significantly increase α_1E peak currents. Coexpression with β_2a and α_2bδ yielded Ba²⁺ currents with inactivation kinetics similar to the β_2a induced currents, indicating that the neuronal α_2bδ subunit has little effect on α_1E inactivation kinetics. The subunit specificity of the changes in current properties were analyzed for all four β subunit genes. The slower inactivation was unique to α_1E/β_2a currents. Coexpression with β_1a, β_1b, β₃, and β₄, yielded faster-inactivating Ba²⁺ currents than currents recorded from the α_1E subunit alone. Furthermore, α_1E/α_2bδ/β_1a; α_1E/α_2bδ/β_1b; α_1E/α_2bδ/β₃; α_1E/α_2bδ/β₄ channels elicited whole-cell currents with steady-state inactivation curves shifted in the hyperpolarized direction. The β subunit-induced changes in the properties of α_1E channel were comparable to modulation effects reported for α_1C and α_1A channels with β₃≈β_1b > β_1a≈β₄≫β_2a inducing fastest to slowest rate of whole-cell inactivation. Received: 27 March 1997/Revised: 10 July 1997     

Properties of the caffeine-sensitive intracellular calcium stores in mammalian neurons

Using indo-1- and fura-2-based microfluorometry for measuring the cytoplasmic free calcium concentration ([Ca²⁺] _in ), the properties of caffeine-induced Ca²⁺ release from internal stores were studied in rat cultured central and peripheral neurons, including dorsal root ganglion (DRG) neurons, neurons from then. cuneatus, CA1 and CA3 hippocampal regions, and pyramidal neocortical neurons. Under resting conditions, the Ca²⁺ content of internal stores in DRG neurons was high enough to produce caffeine-triggered [Ca²⁺] _in transients. Prolonged exposure of caffeine depleted the caffeine-sensitive stores of releasable Ca²⁺; the degree of this depletion depended on caffeine concentration. The depletion of the caffeine-sensitive internal stores to some extent was linked to calcium extrusion via La³⁺-sensitive plasmalemmal Ca²⁺-ATPases. Caffeine-induced Ca²⁺ release deprived internal stores in DRG neurons, but they refilled themselves spontaneously within 10 min. Pharmacological manipulation with caffeine-sensitive stores interferred with the depolarization-induced [Ca²⁺] _in transients. In the presence of low caffeine concentration (0.5–1.0 mM) in the extracellular solution, the rate of rise of the depolarization-triggered [Ca²⁺] _in transients significantly increased (by a factor of 2.15 ± 0.29) suggesting the occurrence of Ca²⁺-induced Ca²⁺ release. When the caffeine-sensitive stores were emptied by prolonged application of caffeine, the amplitude and rate of rise of the depolarization-induced [Ca²⁺] _in transients decreased. These findings suggest the involvement of internal caffeine-sensitive calcium stores in generation of calcium signal in sensory neurons. In contrast, in all types of central neurons tested the resting Ca²⁺ content of internal stores was low, but the stores could be charged by transmembrane Ca²⁺ entry through voltage-operated calcium channels. After charging, the stores in central neurons spontaneously lost releasable calcium content and within 10 min they became completely empty again. We suggest that internal Ca²⁺ stores in peripheral and central neurons, although having similar pharmacological characteristics, handle Ca²⁺ ions in a different manner. Calcium stores in sensory neurons are continuously filled by releasable calcium and after discharging they can be spontaneously refilled, whereas in central neurons internal calcium stores can be charged by releasable calcium only transiently. Caffeine-evoked [Ca²⁺] _in transients in all types of neurons were effectively blocked by 10 mM ryanodine, 5 mM procaine, 10 mM dantrolene, or 0.5 mM Ba²⁺, thus sharing the basic properties of the Ca²⁺-induced Ca²⁺ release from endoplasmic reticulum.Neirofiziologiya/Neurophysiology, Vol. 26, No. 1, pp. 16–25, January–February, 1994.     

Increased 5-HT3-mediated signalling in pelvic afferent neurons from mice deficient in P2X2 and/or P2X3 receptor subunits

Extracellular ATP and 5-hydroxytryptamine (5-HT) are both involved in visceral sensory pathways by interacting with P2X and 5-HT₃ receptors, respectively. We have investigated the changes in P2X and 5-HT₃-mediated signalling in pelvic afferent neurons in mice deficient in P2X₂ and/or P2X₃ subunits by whole-cell recording of L₆–S₂ dorsal root ganglion (DRG) neurons and by multi-unit recording of pelvic afferents of the colorectum. In wildtype DRG neurons, ATP evoked transient, sustained or mixed (biphasic) inward currents. Transient currents were absent in P2X₃ ^−/− neurons, whereas sustained currents were absent in P2X₂ ^−/− DRG neurons. Neither transient nor sustained currents were observed following application of ATP or α,β-methylene ATP (α,β-meATP) in P2X₂/P2X₃ ^Dbl−/− DRG neurons. 5-HT was found to induce a fast inward current in 63% of DRG neurons from wildtype mice, which was blocked by tropisetron, a 5-HT₃ receptor antagonist. The percentage of DRG neurons responding to 5-HT was significantly increased in P2X ₂ ^−/−, P2X₃ ^−/− and P2X₂/P2X₃ ^Dbl−/− mice, and the amplitude of 5-HT response was significantly increased in P2X₂/P2X₃ ^Dbl−/− mice. The pelvic afferent response to colorectal distension was attenuated in P2X₂/P2X₃ ^Dbl−/− mice, but the response to serosal application of 5-HT was enhanced. Furthermore, tropisetron resulted in a greater reduction in pelvic afferent responses to colorectal distension in the P2X₂/P2X₃ ^Dbl−/− preparations. These data suggest that P2X receptors containing the P2X₂ and/or P2X₃ subunits mediate purinergic activation of colorectal afferents and that 5-HT signalling in pelvic afferent neurons is up-regulated in mice lacking P2X₂ or P2X₃ receptor genes. This effect is more pronounced when both subunits are absent.     

Dissimilar Roles of the Mitochondria in the Modulation of Intracellular Calcium Signals in Primary and Secondary Nociceptive Neurons

The role of different Ca²⁺-regulated mechanisms in the generation of cytosolic Ca²⁺ transients during neuronal excitation was compared in isolated primary and secondary nociceptive neurons of the rat. Application of carbonyl cyanide m-chlorophenylhydrazone (CCCP) significantly increased the peak amplitude of depolarization-induced transients in dorsal root ganglion (DRG) neurons in contrast to what was observed in spinal dorsal horn (DH) neurons. Application of CCCP immediately after termination of depolarization induced in DRG neurons massive Ca²⁺ release from the mitochondria into the cytosol. Application of CCCP immediately after termination of depolarization elicited a small Ca²⁺ release in DH neurons, which became more intense when application of the agent was delayed.     

Effects of nitric oxide and hypoxia on low-and high-voltage activated calcium currents in murine DRG neurons

The effects of a nitric oxide (NO)-containing aqueous solution (authentic NO) and hypoxia on low-and high-voltage activated calcium currents (I _Ca,lva andI _Ca,hva , respectively; in the latter transient and sustained portions were differentiated) were studied in enzymatically dispersed medium-sized neuronal somata from the murine dorsal root ganglia (DRG). Authentic NO (10 μM) was found to decrease the mean peak amplitude ofI _Ca,lva , from 3.5±0.3 to 1.2±0.2 nA (n=11,p<0.001), as well as the amplitudes of transient and sustainedI _Ca,hva components from 4.5±0.1 to 2.7±0.2 nA and form 2.8±0.2 to 1.7±0.2 nA (n=11;P<0.001), respectively. This NO-induced suppression was reversible and was removed by 1-min-long washout. At the same time, medium-sized DRG neurons demonstrated relatively low sensitivity to hypoxia (P_O2=20–25 mm Hg): decreases of both types ofI _Ca under hypoxic condition were not statistically significant (n=11;p>0.05). The data strongly suggest that NO is capable of reversibly suppressing both types of calcium channels in murine DRG neurons and of modulating in this way their excitability. It seems likely that this ability is based on a direct effect of NO on the corresponding channels and not on NO participation in the induction of hypoxic effects. Yet, a hypothesis that NO is a messenger of hypoxic damage to neural cells still should be suggested.     

Understanding LTP in pain pathways

Background

Small neurons of the dorsal root ganglion (DRG) express five of the nine known voltage-gated sodium channels. Each channel has unique biophysical characteristics which determine how it contributes to the generation of action potentials (AP). To better understand how AP amplitude is maintained in nociceptive DRG neurons and their centrally projecting axons, which are subjected to depolarization within the dorsal horn, we investigated the dependence of AP amplitude on membrane potential, and how that dependence is altered by the presence or absence of sodium channel Na_v1.8.

Results

In small neurons cultured from wild type (WT) adult mouse DRG, AP amplitude decreases as the membrane potential is depolarized from -90 mV to -30 mV. The decrease in amplitude is best fit by two Boltzmann equations, having V_1/2 values of -73 and -37 mV. These values are similar to the V_1/2 values for steady-state fast inactivation of tetrodotoxin-sensitive (TTX-s) sodium channels, and the tetrodotoxin-resistant (TTX-r) Na_v1.8 sodium channel, respectively. Addition of TTX eliminates the more hyperpolarized V_1/2 component and leads to increasing AP amplitude for holding potentials of -90 to -60 mV. This increase is substantially reduced by the addition of potassium channel blockers. In neurons from Na_v1.8(-/-) mice, the voltage-dependent decrease in AP amplitude is characterized by a single Boltzmann equation with a V_1/2 value of -55 mV, suggesting a shift in the steady-state fast inactivation properties of TTX-s sodium channels. Transfection of Na_v1.8(-/-) DRG neurons with DNA encoding Na_v1.8 results in a membrane potential-dependent decrease in AP amplitude that recapitulates WT properties.

Conclusion

We conclude that the presence of Na_v1.8 allows AP amplitude to be maintained in DRG neurons and their centrally projecting axons even when depolarized within the dorsal horn.     

Assessment of TTX-s and TTX-r Action Potential Conduction along Neurites of NGF and GDNF Cultured Porcine DRG Somata

Nine isoforms of voltage-gated sodium channels (NaV) have been characterized and in excitable tissues they are responsible for the initiation and conduction of action potentials. For primary afferent neurons residing in dorsal root ganglia (DRG), individual neurons may express multiple NaV isoforms extending the neuron’s functional capabilities. Since expression of NaV isoforms can be differentially regulated by neurotrophic factors we have examined the functional consequences of exposure to either nerve growth factor (NGF) or glial cell line-derived neurotrophic factor (GDNF) on action potential conduction in outgrowing cultured porcine neurites of DRG neurons. Calcium signals were recorded using the exogenous intensity based calcium indicator Fluo-8®, AM. In 94 neurons, calcium signals were conducted along neurites in response to electrical stimulation of the soma. At an image acquisition rate of 25 Hz it was possible to discern calcium transients in response to individual electrical stimuli. The peak amplitude of electrically-evoked calcium signals was limited by the ability of the neuron to follow the stimulus frequency. The stimulus frequency required to evoke a half-maximal calcium response was approximately 3 Hz at room temperature. In 13 of 14 (93%) NGF-responsive neurites, TTX-r NaV isoforms alone were sufficient to support propagated signals. In contrast, calcium signals mediated by TTX-r NaVs were evident in only 4 of 11 (36%) neurites from somata cultured in GDNF. This establishes a basis for assessing action potential signaling using calcium imaging techniques in individual cultured neurites and suggests that, in the pig, afferent nociceptor classes relying on the functional properties of TTX-r NaV isoforms, such as cold-nociceptors, most probably derive from NGF-responsive DRG neurons.