The firing patterns of spinal neurons: in situ patch‐clamp recordings reveal a key role for potassium currents

Neuron firing patterns underpin the detection and processing of stimuli, influence synaptic interactions, and contribute to the function of networks. To understand how intrinsic membrane properties determine firing patterns, we investigated the biophysical basis of single and repetitive firing in spinal neurons of hatchling Xenopus laevis tadpoles, a well‐understood vertebrate model; experiments were conducted in situ. Primary sensory Rohon–Beard (RB) neurons fire singly in response to depolarising current, and dorsolateral (DL) interneurons fire repetitively. RB neurons exhibited a large tetrodotoxin‐sensitive sodium current; in DL neurons, the sodium current density was significantly lower. High‐voltage‐activated calcium currents were similar in both neuron types. There was no evidence of persistent sodium currents, low‐voltage‐activated calcium currents, or hyperpolarisation‐activated currents. In RB neurons, the potassium current was dominated by a tetraethylammonium‐sensitive slow component (I_Ks); a fast component (I_Kf), sensitive to 4‐aminopyridine, predominated in DL neurons. Sequential current‐clamp and voltage‐clamp recordings in individual neurons suggest that high densities of I_Ks prevent repetitive firing; where I_Ks is small, I_Kf density determines the frequency of repetitive firing. Intermediate densities of I_Ks and I_Kf allow neurons to fire a few additional spikes on strong depolarisation; this property typifies a novel subset of RB neurons, and may activate escape responses. We discuss how this ensemble of currents and firing patterns underpins the operation of the Xenopus locomotor network, and suggest how simple mechanisms might underlie the similar firing patterns seen in the neurons of diverse species.     

Plasma membrane insertion of TRPC5 channels contributes to the cholinergic plateau potential in hippocampal CA1 pyramidal neurons

In cultured hippocampal neurons, transient receptor potential 5 (TRPC5) channels are translocated and inserted into plasma membranes of hippocampal neurons to generate nonselective cation (NSC) currents. We investigated whether TRPC5 channel translocation also contributes to the generation of NSC currents underlying the afterdepolarizations and plateau potentials (PPs) in hippocampal pyramidal cells that are induced by muscarinic receptor activation. Using a biotinylation assay to quantify the change in surface membrane proteins in acute hippocampal slices, we found that muscarinic stimulation significantly enhanced the levels of TRPC5 protein on the membrane surface but not those of TRPC1 or TRPC4 channels. We then investigated the pharmacological sensitivity of the cation current observed during muscarinic stimulation to determine if a component could be due to TRPC5 channels. The TRPC channel antagonists 2‐APB and SKF96365 strongly depressed the generation of PPs, the underlying tail currents (I_tail) and the associated dendritic Ca²⁺ influx induced by muscarinic receptor activation in pyramidal neurons. High intracellular concentrations of ATP, which specifically inhibit TRPC5 channels, depressed I_tail. In addition, pretreatment with the calmodulin (CaM) inhibitor W‐7, which depresses recombinant TRPC5 currents, inhibited both the cation current (I_tail) and the surface insertion of TRPC5 channels. Finally, the phosphatidylinositide 3‐kinase (PI₃K) inhibitor wortmannin, which blocks translocation of TRPC5 channels in cell culture, also inhibited both the I_tail and the surface insertion of TRPC5 channels. Therefore, we conclude that insertion of TRPC5 channels contributes to the generation of the prolonged afterdepolarizations following muscarinic stimulation. This altered plasma membrane expression of TRPC5 channels in pyramidal neurons may play an important role in the generation of prolonged neuronal depolarization and bursting during the epileptiform seizure discharges of epilepsy. © 2010 Wiley‐Liss, Inc.     

Effect of charybdotoxin and leiurotoxon I on potassium currents in bullfrog sympathetic ganglion and hippocampal neurons

The effects of charybdotoxin and leiurotoxin I were examined on several classes of K⁺ currents in bullfrog sympathetic ganglion and hippocampal CA1 pyramidal neurons. Highly purified preparations of charybdotoxin selectively blocked a large voltage- and Ca²⁺-dependent K⁺ current (I_c) responsible for action potential repolarization (IC₅₀ = 6 nM) while leiurotoxin I selectively blocked a small Ca²⁺-dependent K⁺ conductance (I_AHP) responsible for the slow afterhyperpolarization following an action potential (IC₅₀ = 7.5 nM) in bullfrog sympathetic ganglion neurons. Neither of the toxins had a significant effects on other K⁺ currents (M-current [I_M], A-current [I_A] and the delayed rectifier [I_KD] present in these cells. Leiurotoxin I at a concentration of 20 nM had no detectable effect on currents in hippocampal CA1 pyramidal neurons. This lack of effect on I_AHP in central neurons suggests that the channels underlying slow AHPs in those neurons are pharmacologically distinct from analogous channels in peripheral neurons.     

Characterization of the K current mediated by 5-HT1A receptor in the acutely dissociated rat dorsal raphe neurons

The action of 5-hydroxytryptamine (5-HT) via the 5-HT_1A receptor on dissociated rat dorsal raphe neurons was characterized under the whole-cell mode by using the nystatin-perforated patch-clamp technique. Under voltage-clamp conditions, 5-HT induced an inwardly rectifying K⁺ current (I_5-HT) in a concentration-dependent manner. I_5-HT was mimicked by 8-OH-DPAT and buspirone, which are both 5-HT_1A receptor agonists. I_5-HT was reversibly blocked by such 5-HT_1A receptor antagonists as (S)-UH-301 and spiperone but not by ketanserin, a 5-HT₂ receptor antagonist, granisetron, a 5-HT₃ receptor antagonist, and GR-113808, a 5-HT₄ receptor antagonist. I_5-HT was antagonized concentration-dependently by such K⁺ channel blockers as quinine, Ba²⁺ and 4-aminopyridine but was relatively insensitive to both Cs⁺ and tetraethylammonium. When the neurons were loaded with guanosine 5′-O-3-thiotriphosphate through a patch pipette, the K⁺ current induced by 5-HT became irreversible. N-ethylmaleimide (NEM), a sulfhydryl alkylating agent, irreversibly blocked I_5-HT. The intracellular perfusion with 1,2-bis(2-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid (BAPTA), a Ca²⁺ chelator, or neomycine, a phospholipase C inhibitor, never significantly affected the 5-HT-induced response. 12-Myristate 13-acetate diester (PMA), a protein kinase C (PKC) activator, had only a weak inhibitory effect on I_5-HT, and staurosporine, a PKC inhibitor, failed to significantly occlude I_5-HT. Therefore, the K⁺ conductance activated via the 5-HT_1A receptor of dorsal raphe neurons was thus characterized by the sensitivity to such K⁺ channel blockers as quinine, Ba²⁺ and 4-aminopyridine. Moreover, G protein, which is NEM-sensitive and can couple to the 5-HT_1A receptor, is thus considered to activate the inwardly rectifying K⁺ conductance without being mediated by such second messengers as Ca²⁺ and PKC.     

Metabotropic glutamate receptor agonist ACPD inhibits some,but not all,muscarinic-sensitive K+ conductances in basolateral amygdaloid neurons

Muscarinic agonists produce membrane depolarization and losses of spike frequency accommodation and the slow afterhyperpolarization (AHP) when applied to neurons of the basolateral amygdala (BLA). Underlying these changes are the muscarinic-induced inhibitions of several K⁺ conductances, including the voltage-activated M-current (I_M), a slowly decaying Ca²-activated current (I_AHP), a voltage-insensitive leak current (I_Leak), and the hyperpolarization-activated inward rectifier current (I_IR) Similar depolarizations and losses of the slow AHP have been observed in other neuronal cell types following stimulation of metabotropic glutamate receptors. Therefore, we tested the effects of the metabotropic glutamate receptor agonist, 1-aminocyclopentanels, 3r-dicarboxylic acid (ACPD), on pyramidal neurons impaled with a single microelectrode for current- and voltage-clamp recordings in a brain slice preparation of the rat BLA. Application of ACPD (20 or 100 μM) to BLA neurons inhibited I_M and I_{A HP}, resulting in membrane depolarization and reductions in the amplitude and duration of the slow AHP. However, ACPD did not inhibit the muscarinic-sensitive current I_IR, nor was I_Leak blocked in the majority of neurons examined. These findings suggest the possibility that muscarinic cholinergic and metabotropic glutamatergic receptor agonists may activate separate intracellular transduction pathways which have convergent inhibitory effects onto I_M and I_AHP in BLA pyramidal neurons. © 1994 Wiley-hiss, Inc.     

Cholinergic direct inhibition of N‐methyl‐D aspartate receptor‐mediated currents in the rat neocortex

Acetylcholine (ACh) and N‐methyl‐D aspartate receptors (NMDARs) interact in the regulation of multiple important brain functions. NMDAR activation is indirectly modulated by ACh through the activation of muscarinic or nicotinic receptors. Scant information is available on whether ACh directly interacts with the NMDAR. By using a cortical brain slice preparation we found that the application of ACh and of other drugs acting on muscarinic or nicotinic receptors induces an acute and reversible reduction of NMDAR‐mediated currents (I_NMDA), ranging from 20 to 90% of the control amplitude. The reduction displayed similar features in synaptic I_NMDA in brain slices, as well as in currents evoked by NMDA application in brain slices or from acutely dissociated cortical cells, demonstrating its postsynaptic nature. The cholinergic inhibition of I_NMDA displayed an onset–offset rate in the order of a second, and was resistant to the presence of the muscarinic antagonist atropine (10 μM) in the extracellular solution, and of G‐protein blocker GDP_βS (500 μM) and activator GTP_γS (400 μM) in the intracellular solution, indicating that it was not G‐protein dependent. Recording at depolarized or hyperpolarized holding voltages reduced NMDAR‐mediated currents to similar extents, suggesting that the inhibition was voltage‐independent, whereas the reduction was markedly more pronounced in the presence of glycine (20 μM). A detailed analysis of the effects of tubocurarine suggested that at least this drug interfered with glycine‐dependent NMDAR‐activity. We conclude that NMDAR‐mediated current scan be inhibited directly by cholinergic drugs, possibly by direct interaction within one or more subunits of the NMDAR. Our results could supply a new interpretation to previous studies on the role of ACh at the glutamatergic synapse. Synapse 63:308–318, 2009. © 2009 Wiley‐Liss, Inc.     

Differential contributions of Ca2+‐activated K+ channels and Na+/K+‐ATPases to the generation of the slow afterhyperpolarization in CA1 pyramidal cells

In many types of CNS neurons, repetitive spiking produces a slow afterhyperpolarization (sAHP), providing sustained, intrinsically generated negative feedback to neuronal excitation. Changes in the sAHP have been implicated in learning behaviors, in cognitive decline in aging, and in epileptogenesis. Despite its importance in brain function, the mechanisms generating the sAHP are still controversial. Here we have addressed the roles of M‐type K⁺ current (I_M), Ca²⁺‐gated K⁺ currents (I_Ca(K)'s) and Na⁺/K⁺‐ATPases (NKAs) current to sAHP generation in adult rat CA1 pyramidal cells maintained at near‐physiological temperature (35 °C). No evidence for I_M contribution to the sAHP was found in these neurons. Both I_Ca(K)'s and NKA current contributed to sAHP generation, the latter being the predominant generator of the sAHP, particularly when evoked with short trains of spikes. Of the different NKA isoenzymes, α₁‐NKA played the key role, endowing the sAHP a steep voltage‐dependence. Thus normal and pathological changes in α₁‐NKA expression or function may affect cognitive processes by modulating the inhibitory efficacy of the sAHP.     

TRPC channels underlie cholinergic plateau potentials and persistent activity in entorhinal cortex

Persistent neuronal activity lasting seconds to minutes has been proposed to allow for the transient storage of memory traces in entorhinal cortex and thus could play a major role in working memory. Nonsynaptic plateau potentials induced by acetylcholine account for persistent firing in many cortical and subcortical structures. The expression of these intrinsic properties in cortical neurons involves the recruitment of a non‐selective cation conductance. Despite its functional importance, the identity of the cation channels remains unknown. Here we show that, in layer V of rat medial entorhinal cortex, muscarinic receptor‐evoked plateau potentials and persistent firing induced by carbachol require phospholipase C activation, decrease of PIP₂ levels, and permissive intracellular Ca²⁺ concentrations. Plateau potentials and persistent activity were suppressed by the generic nonselective cation channel blockers FFA (100 μM) and 2‐APB (100 μM), as well as by the TRPC channel blocker SKF‐96365 (50 μM). However, plateau potentials were not affected by the TRPV channel blocker ruthenium red (40 μM). The TRPC3/6/7 activator OAG did not induce or enhance persistent firing evoked by carbachol. Voltage clamp recordings revealed a carbachol‐activated, nonselective cationic current with a heteromeric TRPC‐like phenotype. Moreover, plateau potentials and persistent firing were inhibited by intracellular application of the peptide EQVTTRL that disrupts interactions between the C‐terminal domain of TRPC4/5 subunits and associated PDZ proteins. Altogether, our data suggest that TRPC cation channels mediating persistent muscarinic currents significantly contribute to the firing and mnemonic properties of projection neurons in the entorhinal cortex. © 2010 Wiley‐ Liss, Inc.     

Reactive oxygen species modulate neuronal excitability in rat intrinsic cardiac ganglia

Reactive oxygen species (ROS) are produced as by-products of oxidative metabolism and occur in the heart during ischemia and coronary artery reperfusion. The effects of ROS on the electrophysiological properties of intracardiac neurons were investigated in the intracardiac ganglion (ICG) plexus in situ and in dissociated neurons from neonatal and adult rat hearts using the whole-cell patch clamp recording configuration. Bath application of ROS donors, hydrogen peroxide (H₂O₂) and tert-butyl hydroperoxide (t-BHP) hyperpolarized, and increased the action potential duration of both neonatal and adult ICG neurons. This action was also recorded in ICG neurons in an adult in situ ganglion preparation. H₂O₂ and t-BHP also inhibited voltage-gated calcium channel (VGCC) currents and shifted the current–voltage (I–V) relationship to more hyperpolarized potentials. In contrast, H₂O₂ increased the amplitude of the delayed rectifier K⁺ current in neonatal ICG neurons. In neonatal ICG neurons, bath application of either superoxide dismutase (SOD) or catalase, scavengers of ROS, prior to H₂O₂ attenuated the hyperpolarizing shift but not the inhibition of VGCC by H₂O₂. In contrast, in adult ICG neurons, application of SOD alone had no effect upon either VGCC current amplitude or the I–V relationship, whereas application of SOD prior to H₂O₂ exposure abolished both the H₂O₂-mediated hyperpolarizing shift and inhibition. These data indicate that ROS alter depolarization-activated Ca²⁺ and K⁺ conductances which underlie neuronal excitability of ICG neurons. This affects action potential duration and therefore probably modifies autonomic control of the heart during ischemia/reperfusion.     

Electrophysiological properties and cholinergic responses of rat ventral oral pontine reticular neurons in vitro

In order to characterize the electrophysiological properties of morphologically identified neurons of the ventral part of the oral pontine reticular (vRPO) nucleus and the effects of cholinergic agonists on them, intracellular recordings were obtained from 45 cells in a rat brain-slice preparation. Intracellular staining was performed with 2% biocytin in potassium acetate (1 M)-filled micropipettes. Results demonstrated the presence of two types of vRPO neurons. Type I cells (n=12, 24%) were characterized by a break with a decrease of the depolarizing slope following hyperpolarizing pulses which delayed the return to the resting V_m and subsequent spike-firing. The delay was antagonized by 4-AP (200–500 μM) which specifically blocks the transient outward K⁺-mediated current I_A. Type II neurons (n=38, 76%) displayed a typical depolarizing sag during hyperpolarizing current pulses which was blocked by Cs⁺. This behavior is characteristic of the hyperpolarization-activated current I_Q. These two neuronal types displayed different morphological features. Most type I and II cells (100 and 73.7%, respectively) were depolarized by acetylcholine (1–15 μM), carbachol (0.5–1 μM) and muscarine (1–10 μM) through the activation of post-synaptic muscarinic receptors. The remaining type II cells (26.3%) were hyperpolarized (1–10 min, 3–15 mV) through the activation of post-synaptic muscarinic receptors. Results are consistent with the hypothesis that the vRPO could be a neuronal target of Cch in eliciting paradoxical sleep because most of its neurons are activated by muscarinic agonists. © 1979 Elsevier Science B.V. All rights reserved.     

Ionic mechanisms of action of prion protein fragment PrP(106–126) in rat basal forebrain neurons

Prion diseases are neurodegenerative disorders that are characterized by the presence of the misfolded prion protein (PrP). Neurotoxicity in these diseases may result from prion‐induced modulation of ion channel function, changes in neuronal excitability, and consequent disruption of cellular homeostasis. We therefore examined PrP effects on a suite of potassium (K⁺) conductances that govern excitability of basal forebrain neurons. Our study examined the effects of a PrP fragment [PrP(106–126), 50 nM] on rat neurons using the patch clamp technique. In this paradigm, PrP(106–126) peptide, but not the “scrambled” sequence of PrP(106–126), evoked a reduction of whole‐cell outward currents in a voltage range between –30 and +30 mV. Reduction of whole‐cell outward currents was significantly attenuated in Ca²⁺‐free external media and also in the presence of iberiotoxin, a blocker of calcium‐activated potassium conductance. PrP(106–126) application also evoked a depression of the delayed rectifier (I_K) and transient outward (I_A) potassium currents. By using single cell RT‐PCR, we identified the presence of two neuronal chemical phenotypes, GABAergic and cholinergic, in cells from which we recorded. Furthermore, cholinergic and GABAergic neurons were shown to express K_v4.2 channels. Our data establish that the central region of PrP, defined by the PrP(106–126) peptide used at nanomolar concentrations, induces a reduction of specific K⁺ channel conductances in basal forebrain neurons. These findings suggest novel links between PrP signalling partners inferred from genetic experiments, K⁺ channels, and PrP‐mediated neurotoxicity. © 2010 Wiley‐Liss, Inc.     

Effects of Acetazolamide on Transient K+ Currents and Action Potentials in Nodose Ganglion Neurons of Adult Rats

The aim of the present study was to determine whether acetazolamide (AZ) contributes to the inhibition of the fast inactivating transient K⁺ current (I_A) in adult rat nodose ganglion (NG) neurons. We have previously shown that pretreatment with either AZ or 4‐AP attenuated or blocked the CO₂‐induced inhibition of slowly adapting pulmonary stretch receptors in in vivo experiments. The patch‐clamp experiments were performed by using the isolated NG neurons. In addition to this, the RT‐PCR of mRNA and the expression of voltage‐gated K⁺ (Kv) 1.4, Kv 4.1, Kv 4.2, and Kv 4.3 channel proteins from nodose ganglia were examined. We used NG neurons sensitive to the 1 mM AZ application. The application of 1 mM AZ inhibited the I_A by approximately 27% and the additional application of 4‐AP (1 mM) further inhibited I_A by 48%. The application of 0.1 μM α‐dendrotoxin (α‐DTX), a slow inactivating transient K⁺ current (I_D) blocker, inhibited the baseline I_A by approximately 27%, and the additional application of 1 mM AZ further decreased the I_A by 51%. In current clamp experiments, AZ application (1 mM) increased the number of action potentials due to the decreased duration of the depolarizing phase of action potentials and/or due to a reduction in the resting membrane potential. Four voltage‐gated K⁺ channel proteins were present, and most (80–90%) of the four Kv channels immunoreactive neurons showed the co‐expression of carbonic anhydrase‐II (CA‐II) immunoreactivity. These results indicate that the application of AZ causes the reduction in I_A via the inhibition of four voltage‐gated K⁺ channel (Kv) proteins without affecting I_D.     

SnCl(2) reduces voltage-activated calcium channel currents of dorsal root ganglion neurons of rats

Stannous dichloride (SnCl₂) occurs in the environment where it has been especially enriched in aquatic ecosystems. Furthermore, it is used in food manufacturing (e.g. for stabilizing soft drinks or as an anti-corrosive substance) and in nuclear medicine where it is employed as a reducing agent for technecium-99m (99mTc) and therefore is applied intravenously to human beings.SnCl₂ is known to have toxic effects on the nervous system which can be related to alterations of intracellular calcium homeostasis ([Ca²⁺]_i). In this study the whole cell patch clamp technique is used on dorsal root ganglion neurons of 3-week-old “Wistar” rats to evaluate the effects of SnCl₂ on voltage-activated calcium channel currents (I_Ca(V)).I_Ca(V) were reduced concentration-dependently by SnCl₂ (1–50 μM). 1 μM SnCl₂ reduced I_Ca(V) by 8.1 ± 4.5% (peak current) and 19.2 ± 8.9% (sustained current), whereas 50 μM inhibited I_Ca(V) by 50.6 ± 4.3% (peak current) and 55.6 ± 11.3% (sustained current). Sustained currents were slightly but not significantly more reduced than peak currents. The effect appeared not to be reversible. The threshold concentration was below 1 μM.The current–voltage relation did not shift which is an indication that different calcium channel subtypes were equally affected. There was a slight but not significant shift of the activation/inactivation curves towards the depolarizing direction.We conclude that voltage-gated calcium channels are affected by Sn²⁺ similarly to other divalent metal cations (e.g. Pb²⁺ or Zn²⁺).The reduction of I_Ca(V) could be related to the neurotoxic effects of SnCl₂.     

Subthreshold delta‐frequency resonance in thalamic reticular neurons

The thalamic reticular nucleus (nRt) is an assembly of GABAergic projection neurons that participate in the generation of brain rhythms during synchronous sleep and absence epilepsy. NRt cells receive inhibitory and excitatory synaptic inputs, and are endowed with an intricate set of intrinsic conductances. However, little is known about how intrinsic and synaptic properties interact to generate rhythmic discharges in these neurons. In order to better understand this interaction, I studied the subthreshold responses of nRt cells to time‐varying inputs. Patch‐clamp recordings were performed in acute slices of rat thalamus (postnatal days 12–21). Sinusoidal current waveforms of linearly changing frequencies were injected into the soma, and the resulting voltage oscillations were recorded. At the resting membrane potential, the impedance profile showed a characteristic resonance at 1.7 Hz. The relative strength of the resonance was 1.2, and increased with membrane hyperpolarization. Small suprathreshold current injections led to preferred spike generation at the resonance frequency. Bath application of ZD7288 or Cs⁺, inhibitors of the hyperpolarization‐activated cation current (I_h), transformed the resonance into low‐pass behaviour, whereas the T‐channel blockers mibefradil and Ni²⁺ decreased the strength of the resonance. It is concluded that nRt cells have an I_h‐mediated intrinsic frequency preference in the subthreshold voltage range that favours action potential generation in the delta‐frequency band.     

A homozygous mutation of voltage‐gated sodium channel βI gene SCN1B in a patient with Dravet syndrome

Dravet syndrome is a severe form of epileptic encephalopathy characterized by early onset epileptic seizures followed by ataxia and cognitive decline. Approximately 80% of patients with Dravet syndrome have been associated with heterozygous mutations in SCN1A gene encoding voltage‐gated sodium channel (VGSC) α_I subunit, whereas a homozygous mutation (p.Arg125Cys) of SCN1B gene encoding VGSC β_I subunit was recently described in a patient with Dravet syndrome. To further examine the involvement of homozygous SCN1B mutations in the etiology of Dravet syndrome, we performed mutational analyses on SCN1B in 286 patients with epileptic disorders, including 67 patients with Dravet syndrome who have been negative for SCN1A and SCN2A mutations. In the cohort, we found one additional homozygous mutation (p.Ile106Phe) in a patient with Dravet syndrome. The identified homozygous SCN1B mutations indicate that SCN1B is an etiologic candidate underlying Dravet syndrome.     

Up-regulation of A-type potassium currents protects neurons against cerebral ischemia

Excitotoxicity is the major cause of many neurologic disorders including stroke. Potassium currents modulate neuronal excitability and therefore influence the pathological process. A-type potassium current (I_A) is one of the major voltage-dependent potassium currents, yet its roles in excitotoxic cell death are not well understood. We report that, following ischemic insults, the I_A increases significantly in large aspiny (LA) neurons but not medium spiny (MS) neurons in the striatum, which correlates with the higher resistance of LA neurons to ischemia. Activation of protein kinase Cα increases I_A in LA neurons after ischemia. Cultured neurons from transgenic mice lacking both Kv1.4 and Kv4.2 subunits exhibit an increased vulnerability to ischemic insults. Increase of I_A by recombinant expression of Kv1.4 or Kv4.2 is sufficient in improving the survival of MS neurons against ischemic insults both in vitro and in vivo. These results, taken together, provide compelling evidence for a protective role of I_A against ischemia.     

Development of resurgent and persistent sodium currents in mesencephalic trigeminal neurons

Sodium channels play multiple roles in the formation of neural membrane properties in mesencephalic trigeminal (Mes V) neurons and in other neural systems. Mes V neurons exhibit conditional robust high‐frequency spike discharges. As previously reported, resurgent and persistent sodium currents (I_NaR and I_NaP, respectively) may carry small currents at subthreshold voltages that contribute to generation of spike firing. These currents play an important role in maintaining and allowing high‐frequency spike discharge during a burst. In the present study, we investigated the developmental changes in tetrodotoxin‐sensitive I_NaR and I_NaP underlying high‐frequency spike discharges in Mes V neurons. Whole‐cell patch‐clamp recordings showed that both current densities increased one and a half times from postnatal day (P) 0–6 neurons to P7–14 neurons. Although these neurons do not exhibit subthreshold oscillations or burst discharges with high‐frequency firing, I_NaR and I_NaP do exist in Mes V neurons at P0–6. When the spike frequency at rheobase was examined in firing Mes V neurons, the developmental change in firing frequency among P7–14 neurons was significant. I_NaR and I_NaP density at ?40 mV also increased significantly among P7–14 neurons. The change to an increase in excitability in the P7–14 group could result from this quantitative change in I_NaP. In neurons older than P7 that exhibit repetitive firing, quantitative increases in I_NaR and I_NaP density may be major factors that facilitate and promote high‐frequency firing as a function of age in Mes V neurons.     

Glutamate selectively increases the high-threshold Ca channel current in sensory and hippocampal neurons

Previous studies resulted in conflicting conclusions that glutamate application either decreases or increases the activity of Ca²⁺ channels in hippocampal neurons. We studied whole-cell Ca²⁺ currents (I_Ca) in chick dorsal root ganglion neurons and rat hippocampal cells. For both cell types glutamate (1–30 μM) increased high-threshold Ca²⁺ current. It was independent of the charge carriers, Ca²⁺ or Ba²⁺. Low-threshold Ca²⁺ channel current and the fast sodium current were not changed with glutamate application. The effect developed within 1–2 min and then further facilitated after washout of the agonist. A second application of glutamate produced no additional increase in _ICa. No changes in the time-course of whole-cell currents were observed, suggesting that glutamate recruits ‘sleepy’ Ca²⁺ channels. Whatever its mechanism, overlasting increase of I_Ca by glutamate may be important in neuronal plasticity.     

Transforming growth factor-β2 selectively alters the developmental expression of the fast transient A-current in cultured rat superior cervical ganglion neurons

Cultures of neonatal rat superior cervical ganglion (SCG) were utilized to examine the ability of transforming growth factor-β2 (TGFβ2) to alter voltage-gated K⁺ channel development. Whole-cell patch clamp recordings were used to monitor changes in three separate K⁺ currents: A rapidly inactivating A-current (I_Af), a slowly inactivating A-current (I_As), and a non-inactivating current (I_K). Continuous TGFβ2 (10 ng/ml) treatment selectively altered the normal developmental decrease in I_Af expression in SCG neurons, but did not significantly change I_As or I_K expression. After 2 weeks of treatment, the mean I_Af current density in control cultures had decreased 67%, while the I_Af current density in TGFβ2 treated cultures remained near initial values (∼2.7-fold higher than control). This difference remained even after 4 weeks of exposure. TGFβ2 did not appear to change the activation kinetics or voltage-dependence of I_Af. These findings indicate that TGFβ2 may play an important role in modulating the development of neuronal excitability by regulating the expression of voltage-gated K⁺ channels. J. Neurosci. Res. 49:475–484, 1997. © 1997 Wiley-Liss, Inc.     

Downregulation of cannabinoid receptor 1 from neuropeptide Y interneurons in the basal ganglia of patients with Huntington's disease and mouse models

Cannabinoid receptor 1 (CB₁ receptor) controls several neuronal functions, including neurotransmitter release, synaptic plasticity, gene expression and neuronal viability. Downregulation of CB₁ expression in the basal ganglia of patients with Huntington's disease (HD) and animal models represents one of the earliest molecular events induced by mutant huntingtin (mHtt). This early disruption of neuronal CB₁ signaling is thought to contribute to HD symptoms and neurodegeneration. Here we determined whether CB₁ downregulation measured in patients with HD and mouse models was ubiquitous or restricted to specific striatal neuronal subpopulations. Using unbiased semi‐quantitative immunohistochemistry, we confirmed previous studies showing that CB₁ expression is downregulated in medium spiny neurons of the indirect pathway, and found that CB₁ is also downregulated in neuropeptide Y (NPY)/neuronal nitric oxide synthase (nNOS)‐expressing interneurons while remaining unchanged in parvalbumin‐ and calretinin‐expressing interneurons. CB₁ downregulation in striatal NPY/nNOS‐expressing interneurons occurs in R6/2 mice, Hdh^Q150/Q150 mice and the caudate nucleus of patients with HD. In R6/2 mice, CB₁ downregulation in NPY/nNOS‐expressing interneurons correlates with diffuse expression of mHtt in the soma. This downregulation also occludes the ability of cannabinoid agonists to activate the pro‐survival signaling molecule cAMP response element‐binding protein in NPY/nNOS‐expressing interneurons. Loss of CB₁ signaling in NPY/nNOS‐expressing interneurons could contribute to the impairment of basal ganglia functions linked to HD.