Neurotransmitter modulation of calcium current in rat spinal cord neurons

The modulation of Ca2+ currents by neurotransmitters was studied in freshly dissociated rat spinal cord neurons, using the whole-cell patch-clamp technique. GABA, baclofen, adenosine, ATP, serotonin, norepinephrine, somatostatin, and dynorphin A inhibited the current through Ca2+ channels in a substantial fraction of cells, while substance P, vasoactive intestinal polypeptide, [D-ala2,d-leu5]-enkephalin, cholecystokinin-8 (sulfated), calcitonin gene-related peptide, angiotensin II, neurotensin, vasopressin, and thyrotropin-releasing hormone had no effect. In the case of baclofen, the inhibition is mediated, at least in part, by a GTP-binding protein. Suppression of Ca2+ current by neurotransmitters may represent a mechanism of presynaptic inhibition in the spinal cord.     

Endogenous regulator of G-protein signaling proteins modify N-type calcium channel modulation in rat sympathetic neurons.

Experiments using heterologous overexpression indicate that regulator of G-protein signaling (RGS) proteins play important roles in Gbetagamma-mediated ion channel modulation. However, the roles subserved by endogenous RGS proteins have not been extensively examined because tools for functionally inhibiting natively expressed RGS proteins are lacking. To address this void, we used a strategy in which Galpha(oA) was rendered insensitive to pertussis toxin (PTX) and RGS proteins by site-directed mutagenesis. Either PTX-insensitive (PTX-i) or both PTX- and RGS-insensitive (PTX/RGS-i) mutants of Galpha(oA) were expressed along with Gbeta(1) and Ggamma(2) subunits in rat sympathetic neurons. After overnight treatment with PTX to suppress natively expressed Galpha subunits, voltage-dependent Ca(2+) current inhibition by norepinephrine (NE) (10 microm) was reconstituted in neurons expressing either PTX-i or PTX/RGS-i Galpha(oA). When compared with neurons expressing PTX-i Galpha(oA), the steady-state concentration-response relationships for NE-induced Ca(2+) current inhibition were shifted to lower concentrations in neurons expressing PTX/RGS-i Galpha(oA). In addition to an increase in agonist potency, the expression of PTX/RGS-i Galpha(oA) dramatically retarded the current recovery after agonist removal. Interestingly, the alteration in current recovery was accompanied by a slowing in the onset of current inhibition. Together, our data suggest that endogenous RGS proteins contribute to membrane-delimited Ca(2+) channel modulation by regulating agonist potency and kinetics of G-protein-mediated signaling in neuronal cells.     

Different GTP-binding proteins mediate regulation of calcium channels by acetylcholine and noradrenaline in rat sympathetic neurons

In dissociated neurons of rat superior cervical ganglion (SCG), noradrenaline (NA) and acetylcholine (ACh) suppressed Ca2+ currents elicited by depolarizations to 0 mV from -60 mV. With GTP-gamma-S in patch electrodes, ACh and NA caused persistent inhibition of Ca2+ currents. Pretreatment of SCG cells with pertussis toxin abolished the action of ACh but not of NA. The results suggest that ACh and NA reduce the Ca2+ currents in SCG cells through different G proteins.     

Neurotransmitter phenotype-specific expression changes in developing sympathetic neurons

During late developmental phases individual sympathetic neurons undergo a switch from noradrenergic to cholinergic neurotransmission. This phenomenon of plasticity depends on target-derived signals in vivo and is triggered by neurotrophic factors in neuronal cultures. To analyze genome-wide expression differences between the two transmitter phenotypes we employed DNA microarrays. RNA expression profiles were obtained from chick paravertebral sympathetic ganglia, treated with neurotrophin 3, glial cell line-derived neurotrophic factor or ciliary neurotrophic factor, all of which stimulate cholinergic differentiation. Results were compared with the effect of nerve growth factor, which functions as a pro-noradrenergic stimulus. The gene set common to all three comparisons defined the noradrenergic and cholinergic synexpression groups. Several functional categories, such as signal transduction, G-protein-coupled signaling, cation transport, neurogenesis and synaptic transmission, were enriched in these groups. Experiments based on the prediction that some of the identified genes play a role in the neurotransmitter switch identified bone morphogenetic protein signaling as an inhibitor of cholinergic differentiation.     

T-type calcium channels: heterogeneous expression in rat sensory neurons and selective modulation by phorbol esters

We report selective inhibition of low-threshold, T-type calcium channels by a phorbol ester in rat sensory neurons. Cells were exposed, either acutely or with 15-60 min preincubations, to low concentrations of phorbol 12-myristate 13-acetate, (PMA), an activator of protein kinase C; if the temperature was 29 degrees C or higher, T-type Ca current was diminished without effect on high-threshold Ca current. In untreated cells, the amplitude of T-type Ca current varies widely among neighboring sensory neurons. T channels are absent in about 25% of cells, provide a small current near threshold for the majority of cells, and are a dominant pathway for calcium entry in a small subset of neurons. The results are of interest because, by selectively inhibiting a calcium channel expressed differently among subpopulations of sensory neurons, activation of protein kinase C might selectively suppress particular sensations.     

Control of calcium current in rat sympathetic neurons by norepinephrine

Inward voltage-dependent calcium currents were recorded from clamped rat sympathetic ganglion cells using either one or two microelectrodes. Suppression of potassium current was achieved by applying tetraethylammonium (TEA) externally and TEA plus cesium internally. Peak ICa was observed at 0 mV. ICa was abolished by perfusing cadmium or low calcium medium. ICa was reduced by adding norepinephrine (1-50 micrometers). This effect was not accompanied by any major change in the voltage sensitivity or time course of the residual calcium current. It is suggested that norepinephrine acts by reducing the number of available calcium channels.     

Single calcium channels of spinal ganglion neurons in the rat

Single calcium channels in isolated dorsal root ganglion cells of the newborn rat were studied using the method of patch clamp in its cell-attached configuration. With 60 mmol/l of Ca2+ in the pipette (extracellular) solution, the amplitude of unitary Ca currents varied from 0.58 +/- 0.05 pA to 0.43 +/- 0.05 pA with a 20 mV change of the potential, which corresponds to a channel conductance of 7 +/- 0.5 pS. The distribution of the open time was monoexponential with the time constant of 0.75 ms not depending on the membrane potential. The distribution of closed time approached a biexponential time course. The fast component (approximately 0.8 ms) showed no dependence on the membrane potential, while the time constant of the slow one decreased with increasing depolarization (from 22 ms to 4 ms with a 20 mV change of the potential). Using experimentally obtained time parameters which describe single calcium channel function and assuming a three-state model of the channel, the numerical values of the rate constants of transitions between individual states were determined.     

Mercury modulation of GABA-activated chloride channels and non-specific cation channels in rat dorsal root ganglion neurons.

The effects of mercuric chloride and methylmercury chloride on the rat dorsal root ganglion neurons in primary culture were studied by the whole-cell patch clamp technique. gamma-Aminobutyric acid-induced chloride currents were augmented by mercuric chloride in a potent and efficacious manner; at concentrations of 1 and 10 microM, the current amplitude was increased to 130% and 200% of the control. Methylmercury even at 100 microM did not augment but rather decreased the GABA-induced chloride current. Both mercuric chloride and methylmercury generated slow inward currents by themselves. These currents are not mediated by the GABA-activated chloride channels or by voltage-activated sodium, potassium or calcium channels, and are likely to be due to non-specific cation channels.     

Involvement of dihydropyridine-sensitive calcium channels in nerve growth factor-dependent neurite outgrowth by sympathetic neurons

We have used a number of pharmacological manipulations of calcium influx to alter the nerve growth factor (NGF)-elicited neurite outgrowth response of SCG neurons. Our results indicate that influx of extracellular calcium is critical to sympathetic SCG neurite outgrowth. Effective blockade of this process was produced by the inorganic calcium channel blockers Cd2+ (with an IC50 of 48 microM), Co2+ (129 microM), and Ni2+ (180 microM). More specifically, there is a significant contribution from dihydropyridine-sensitive L-type calcium channels to NGF-activated neurite outgrowth, as evidenced by the significant inhibition of neurite outgrowth by diltiazem (IC50 of 17 microM) and nifedipine (3 microM). Further, increases in calcium influx can elicit an enhanced neurite outgrowth response, as shown by the calcium channel agonist Bay K 8644 which potentiated neurite outgrowth by up to 40%.     

The role of calcium in M-current inhibition by muscarinic agonists in rat sympathetic neurons.

I have investigated the role of Ca2+ on M-current (IK(M)) inhibition by the muscarinic agonist oxo-M using the perforated patch voltage clamp technique. Oxo-M inhibited IK(M) in cultured SCG cells with an IC50 of 1.2 microM in 2 mM [Ca2+]o, and 13.1 microM in nominally Ca(2+)-free external solution. BAPTA-AM, ryanodine and thapsigargin (substances which modulate [Ca2+]i) did not affect IK(M) or the inhibitory action of oxo-M in either 2 or 0 mM extracellular Ca2+. Caffeine (10 mM) inhibited M current by approximately 30% in both 2 and 0 mM [Ca2+]o; this inhibition was not affected by [Ca2+]i modulators. Unexpectedly, the effect of oxo-M (10 microM) was enhanced after application of caffeine (10 mM) in either 2 or 0 mM [Ca2+]o. Thus, the effect of muscarinic agonists on IK(M) was blunted in Ca(2+)-free extracellular solutions, but neither oxo-M nor caffeine appeared to inhibit IK(M) through an elevation of [Ca2+]i. I suggest that resting levels of [Ca2+]i are necessary for a normal inhibition, with lower levels inducing an impairment of the inhibition of IK(M) by muscarinic agonists.     

Taurine-induced modulation of voltage-sensitive Na+ channels in rat dorsal root ganglion neurons

The physiological role of taurine, an abundant free amino acid in the neural system, is still poorly understood. The aim of this study was to investigate its effect on TTX-sensitive (TTX-S) and TTX-resistant (TTX-R) Na+ currents in enzymatically dissociated neurons from rat dorsal root ganglion (DRG) with conventional whole-cell recording manner under voltage-clamp conditions. A TTX-S Na+ current was recorded preferentially from large DRG neurons and a TTX-R Na+ current preferentially from small ones. For TTX-S Na+ channel, taurine of the concentration > or = 10 mM shifted the activation curve in the depolarizing direction and the inactivation curve in the hyperpolarizing direction. There was no change in the activation curve for TTX-R Na+ channel and the inactivation curve was shifted in the hyperpolarizing direction slightly in the presence of taurine > or = 20 mM. When the recovery kinetics was examined, the presence of taurine resulted in a slower recovery from inactivation of TTX-S currents and no change of TTX-R ones. All the effects of taurine were weakly concentration-dependent and partly recovered quite slowly after washout. Our data indicate that taurine alters the properties of Na+ currents in intact DRG neurons. These may contribute to the understanding of taurine as a natural neuroprotectant and the potential of taurine as a useful medicine for the treatment of sensory neuropathies.     

Dihydropyridine actions on calcium currents of frog sympathetic neurons.

Dihydropyridines (DHPs) generally have little effect on whole-cell calcium currents of neurons, even at concentrations far higher than those effective on muscle. Either neuronal calcium currents are much less sensitive to DHPs, or only a small proportion of the current is DHP-sensitive. We find that DHP agonists and antagonists act at low concentration on calcium currents in frog sympathetic neurons but that the effects are small even at optimal concentrations. The half-maximal dose (EC50) of the agonist Bay K 8644 is approximately 50 nM, and the effect of Bay K 8644 is blocked by 50% at approximately 300 nM nifedipine, from a holding potential of -80 mV. Nifedipine is more effective from a holding potential of -50 mV. These results suggest the presence of an L-type calcium current, with DHP sensitivity similar to L-currents in cardiac muscle. The predominant (greater than 90%) calcium current in frog sympathetic neurons is a DHP-resistant N-type current. However, high concentrations of DHPs (10 microM) partially block N-type calcium current, as well as voltage-dependent sodium and potassium currents.     

Differential distribution of voltage-gated calcium channels in dopaminergic neurons of the rat retina

We studied by immunocytochemistry and Western blots the identity and cellular distribution of voltage-gated calcium channels within dopaminergic neurons of the rat retina. The aim was to associate particular calcium channel subtypes with known activities of the neuron (e.g., transmitter release from axon terminals). Five voltage-gated calcium channels were identified: alpha1A, alpha1B, alpha1E, alpha1F, and alpha1H. All of these, except the alpha1B subtype, were found within dopaminergic perikarya. The alpha1B channels were concentrated at axon terminal rings, together with alpha1A calcium channels. In contrast, alpha1H calcium channels were most abundant in the dendrites, and alpha1F calcium channels were restricted to the perikaryon. The alpha1E calcium channel was present at such a low density that its cellular distribution beyond the perikaryon could not be determined. Our findings are consistent with the available pharmacological data indicating that alpha1A and alpha1B calcium channels control the major fraction of dopamine release in the rat retina.     

Inhibition of calcium channels in rat CA3 pyramidal neurons by a metabotropic glutamate receptor.

L-Glutamate rapidly and reversibly suppressed Ca channel current in freshly dissociated pyramidal neurons from the CA3 region of the rat hippocampus. L-Glutamate inhibition of Ca channel current could be distinguished from activation of background conductance by appropriate ionic conditions and by distinct pharmacological profiles. Ca channel inhibition by glutamate was mimicked by quisqualate, ibotenate, racem?ct-ACPD and 1S,3R-ACPD but not by kainate, AMPA, L-aspartate, NMDA, L-2-amino-4-phosphonobutyric acid, or 1R,3S-ACPD; 6-cyano-7-nitroquinoxaline-2,3-dione did not inhibit the response. All agonists inhibited a similar fraction of high-voltage-activated Ca channel current, typically approximately 30%. Concentration-response relations for the agonists were consistent with mediation by a metabotropic glutamate receptor. The stereospecific agonist 1S,3R-ACPD was especially useful since it did not activate background conductances. The fraction of Ca channel current sensitive to 1S,3R-ACPD was partially blocked by omega-conotoxin GVIA but was not sensitive to dihydropyridine antagonists or agonists. The suppression of Ca channels by 1S,3R-ACPD became irreversible when cells were dialyzed with GTP-gamma-S. 1S,3R-ACPD suppressed Ca channel currents in outside-out membrane patches but not in cell-attached patches when applied outside the patch. These results suggest that metabotropic glutamate receptors suppress the activity of N-type Ca channels in CA3 neurons by a mechanism involving G-proteins but not readily diffusible second messengers.     

Mechanism of modulation of GABA-activated current by internal calcium in rat central neurons

GABA-activated currents in Purkinje cells isolated from rat cerebellum were investigated. Increase of intracellular Ca2+ in the physiological range of concentrations caused a decrease in GABA-activated chloride currents. This effect resulted from a decrease of both the maximal values of GABA-activated currents and possibly from the affinity of GABAA receptors. Therefore, the mechanism of Ca2+ effect on GABAA receptors in central rat neurons differs from that in bullfrog sensory neurons.     

Syntaxin modulation of slow inactivation of N-type calcium channels.

Syntaxin, a membrane protein vital in triggering vesicle fusion, interacts with voltage-gated N- and P/Q-type Ca(2+) channels. This biochemical association is proposed to colocalize Ca(2+) channels and presynaptic release sites, thus supporting rapid and efficient initiation of neurotransmitter release. The syntaxin channel interaction may also support a novel signaling function, to modulate Ca(2+) channels according to the state of the associated release machinery (Bezprozvanny et al., 1995; Wiser et al., 1996; see also Mastrogiacomo et al., 1994). Here we report that syntaxin 1A (syn1A) coexpressed with N-type channels in Xenopus oocytes greatly promoted slow inactivation gating, but had little or no effect on the onset of and recovery from fast inactivation. Accordingly, the effectiveness of syntaxin depended strongly on voltage protocol. Slow inactivation was found for N-type channels even in the absence of syntaxin and could be distinguished from fast inactivation on the basis of its slow kinetics, distinct voltage dependence (voltage-independent at potentials higher than the level of half-inactivation), and temperature independence (Q(10), approximately 0.8). Trains of action potential-like stimuli were more effective than steady depolarizations in stabilizing the slowly inactivated condition. Agents that stimulate protein kinase C decreased the inhibitory effect of syntaxin on N-type channels. Application of BoNtC1 to cleave syntaxin sharply attenuated the modulatory effects on Ca(2+) channel gating, consistent with structural analysis of syntaxin modulation, supporting use of this toxin to test for the impact of syntaxin on Ca(2+) influx in nerve terminals.     

N-Ethylmaleimide modulation of tetrodotoxin-sensitive and tetrodotoxin-resistant sodium channels in rat dorsal root ganglion neurons

The effects of N-ethylmaleimide (NEM), an alkylating reagent to protein sulfhydryl groups, on tetrodotoxin-sensitive (TTX-S) and tetrodotoxin-resistant (TTX-R) sodium channels in rat dorsal root ganglion (DRG) neurons were studied using the whole cell configuration of patch-clamp technique. When currents were evoked by step depolarizations to 0 mV from a holding potential of -80 mV NEM decreased the amplitude of TTX-S sodium current, but exerted little or no effect on that of TTX-R sodium current. The inhibitory effect of NEM on TTX-S sodium channel was mainly due to the shift of the steady-state inactivation curve in the hyperpolarizing direction. NEM did not affect the voltage-dependence of the activation of TTX-S sodium channel. The steady-state inactivation curve for TTX-R sodium channel was shifted by NEM in the hyperpolarizing direction as that for TTX-S sodium channel. NEM caused a change in the voltage-dependence of the activation of TTX-R sodium channel unlike TTX-S sodium channel. After NEM treatment, the amplitudes of TTX-R sodium currents at test voltages below -10 mV were increased, but those at more positive voltages were not affected. This was explained by the shift in the conductance-voltage curve for TTX-R sodium channels in the hyperpolarizing direction after NEM treatment.     

Mitochondrial participation in modulation of calcium transients in DRG neurons.

The effects of the mitochondrial Na+/Ca2+ exchange blocker tetraphenylphosphonium (TPP+) and the permeability transition blocker cyclosporinA (CysA) on the ability of mitochondria to participate in the regulation of intracellular calcium were investigated on freshly isolated mice sensory DRG neurons. The free intracellular calcium level ([Ca2+]in) was measured using indo-1 based microfluorimetry. The characteristics of depolarization-induced [Ca2+]in transients were changed in the presence of 25 microM TPP+. The amplitude of [Ca2+]in transients became decreased and the restoration of resting [Ca2+]in level speeded up in the presence of TPP+. Application of 5 microM cyclosporinA induced substantial residual elevation of [Ca2+]in after termination of depolarization. We conclude that the mitochondrial Na+/Ca2+ exchanger mechanism plays an important role in the regulation of calcium signals during neuronal activity, prolonging them by releasing Ca2+ stored during transient peak. Activation of permeability transition pores does not participate in these processes.