Modifications of A-current kinetics in mammalian central neurones induced by extracellular zinc

Hyperexcitability and Hyperplasticity Disrupt Cerebellar Signal Transfer in the IB2 KO Mouse Model of Autism

Autism spectrum disorders (ASDs) are pervasive neurodevelopmental conditions that often involve mutations affecting synaptic mechanisms. Recently, the involvement of cerebellum in ASDs has been suggested, but the underlying functional alterations remained obscure. We investigated single-neuron and microcircuit properties in IB2 (Islet Brain-2) KO mice of either sex. The IB2 gene (chr22q13.3 terminal region) deletion occurs in virtually all cases of Phelan-McDermid syndrome, causing autistic symptoms and a severe delay in motor skill acquisition. IB2 KO granule cells showed a larger NMDA receptor-mediated current and enhanced intrinsic excitability, raising the excitatory/inhibitory balance. Furthermore, the spatial organization of granular layer responses to mossy fibers shifted from a "Mexican hat" to a "stovepipe hat" profile, with stronger excitation in the core and weaker inhibition in the surround. Finally, the size and extension of long-term synaptic plasticity were remarkably increased. These results show for the first time that hyperexcitability and hyperplasticity disrupt signal transfer in the granular layer of IB2 KO mice, supporting cerebellar involvement in the pathogenesis of ASD.SIGNIFICANCE STATEMENT This article shows for the first time a complex set of alterations in the cerebellum granular layer of a mouse model [IB2 (Islet Brain-2) KO] of autism spectrum disorders. The IB2 KO in mice mimics the deletion of the corresponding gene in the Phelan-McDermid syndrome in humans. The changes reported here are centered on NMDA receptor hyperactivity, hyperplasticity, and hyperexcitability. These, in turn, increase the excitatory/inhibitory balance and alter the shape of center/surround structures that emerge in the granular layer in response to mossy fiber activity. These results support recent theories suggesting the involvement of cerebellum in autism spectrum disorders.

Cytosolic increased labile Zn2+ contributes to arrhythmogenic action potentials in left ventricular cardiomyocytes through protein thiol oxidation and cellular ATP depletion

Intracellular labile (free) Zn²⁺-level ([Zn²⁺]_i) is low and increases markedly under pathophysiological conditions in cardiomyocytes. High [Zn²⁺]_i is associated with alterations in excitability and ionic-conductances while exact mechanisms are not clarified yet. Therefore, we examined the elevated-[Zn²⁺]_i on some sarcolemmal ionic-mechanisms, which can mediate cardiomyocyte dysfunction. High-[Zn²⁺]_i induced significant changes in action potential (AP) parameters, including depolarization in resting membrane-potential and prolongations in AP-repolarizing phases. We detected also the time-dependent effects such as induction of spontaneous APs at the time of ≥ 3 min following [Zn²⁺]_i increases, a manner of cellular ATP dependent and reversible with disulfide-reducing agent dithiothreitol, DTT. High-[Zn²⁺]_i induced inhibitions in voltage-dependent K⁺-channel currents, such as transient outward K⁺-currents, I_to, steady-state currents, I_ss and inward-rectifier K⁺-currents, I_K1, reversible with DTT seemed to be responsible from the prolongations in APs. We, for the first time, demonstrated that lowering cellular ATP level induced significant decreaeses in both I_ss and I_K1, while no effect on I_to. However, the increased-[Zn²⁺]_i could induce marked activation in ATP-sensitive K⁺-channel currents, I_KATP, depending on low cellular ATP and thiol-oxidation levels of these channels. The mRNA levels of Kv4.3, Kv1.4 and Kv2.1 were depressed markedly with increased-[Zn²⁺]_i with no change in mRNA level of Kv4.2, while the mRNA level of I_KATP subunit, SUR2A was increased significantly with increased-[Zn²⁺]_i, being reversible with DTT. Overall we demonstrated that high-[Zn²⁺]_i, even if nanomolar levels, alters cardiac function via prolonged APs of cardiomyocytes, at most, due to inhibitions in voltage-dependent K⁺-currents, although activation of I_KATP is playing cardioprotective role, through some biochemical changes in cellular ATP- and thiol-oxidation levels. It seems, a well-controlled [Zn²⁺]_i can be novel therapeutic target for cardiac complications under pathological conditions including oxidative stress.

Zinc as a Neuromodulator in the Central Nervous System with a Focus on the Olfactory Bulb

The olfactory bulb (OB) is central to the sense of smell, as it is the site of the first synaptic relay involved in the processing of odor information. Odor sensations are first transduced by olfactory sensory neurons (OSNs) before being transmitted, by way of the OB, to higher olfactory centers that mediate olfactory discrimination and perception. Zinc is a common trace element, and it is highly concentrated in the synaptic vesicles of subsets of glutamatergic neurons in some brain regions including the hippocampus and OB. In addition, zinc is contained in the synaptic vesicles of some glycinergic and GABAergic neurons. Thus, zinc released from synaptic vesicles is available to modulate synaptic transmission mediated by excitatory (e.g., N-methyl-D aspartate (NMDA), alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)) and inhibitory (e.g., gamma-aminobutyric acid (GABA), glycine) amino acid receptors. Furthermore, extracellular zinc can alter the excitability of neurons through effects on a variety of voltage-gated ion channels. Consistent with the notion that zinc acts as a regulator of neuronal activity, we and others have shown zinc modulation (inhibition and/or potentiation) of amino acid receptors and voltage-gated ion channels expressed by OB neurons. This review summarizes the locations and release of vesicular zinc in the central nervous system (CNS), including in the OB. It also summarizes the effects of zinc on various amino acid receptors and ion channels involved in regulating synaptic transmission and neuronal excitability, with a special emphasis on the actions of zinc as a neuromodulator in the OB. An understanding of how neuroactive substances such as zinc modulate receptors and ion channels expressed by OB neurons will increase our understanding of the roles that synaptic circuits in the OB play in odor information processing and transmission.

Zn2+ reduction induces neuronal death with changes in voltage-gated potassium and sodium channel currents

In the present study, cultured rat primary neurons were exposed to a medium containing N,N,N',N'-tetrakis(2-pyridylmethyl)ethylenediamine (TPEN), a specific cell membrane-permeant Zn²⁺ chelator, to establish a model of free Zn²⁺ deficiency in neurons. The effects of TPEN-mediated free Zn²⁺ ion reduction on neuronal viability and on the performance of voltage-gated sodium channels (VGSCs) and potassium channels (Kvs) were assessed. Free Zn²⁺ deficiency 1) markedly reduced the neuronal survival rate, 2) reduced the peak amplitude of I_Na, 3) shifted the I_Na activation curve towards depolarization, 4) modulated the sensitivity of sodium channel voltage-dependent inactivation to a depolarization voltage, and 5) increased the time course of recovery from sodium channel inactivation. In addition, free Zn²⁺ deficiency by TPEN notably enhanced the peak amplitude of transient outward K⁺ currents (I_A) and delayed rectifier K⁺ currents (I_K), as well as caused hyperpolarization and depolarization directional shifts in their steady-state activation curves, respectively. Zn²⁺ supplementation reversed the effects induced by TPEN. Our results indicate that free Zn²⁺ deficiency causes neuronal damage and alters the dynamic characteristics of VGSC and Kv currents. Thus, neuronal injury caused by free Zn²⁺ deficiency may correlate with its modulation of the electrophysiological properties of VGSCs and Kvs.

Single Neuron Optimization as a Basis for Accurate Biophysical Modeling: The Case of Cerebellar Granule Cells

In realistic neuronal modeling, once the ionic channel complement has been defined, the maximum ionic conductance (G_i-max) values need to be tuned in order to match the firing pattern revealed by electrophysiological recordings. Recently, selection/mutation genetic algorithms have been proposed to efficiently and automatically tune these parameters. Nonetheless, since similar firing patterns can be achieved through different combinations of G_i-max values, it is not clear how well these algorithms approximate the corresponding properties of real cells. Here we have evaluated the issue by exploiting a unique opportunity offered by the cerebellar granule cell (GrC), which is electrotonically compact and has therefore allowed the direct experimental measurement of ionic currents. Previous models were constructed using empirical tuning of G_i-max values to match the original data set. Here, by using repetitive discharge patterns as a template, the optimization procedure yielded models that closely approximated the experimental G_i-max values. These models, in addition to repetitive firing, captured additional features, including inward rectification, near-threshold oscillations, and resonance, which were not used as features. Thus, parameter optimization using genetic algorithms provided an efficient modeling strategy for reconstructing the biophysical properties of neurons and for the subsequent reconstruction of large-scale neuronal network models.

Kv3 channel assembly, trafficking and activity are regulated by zinc through different binding sites

Zinc, a divalent heavy metal ion and an essential mineral for life, regulates synaptic transmission and neuronal excitability via ion channels. However, its binding sites and regulatory mechanisms are poorly understood. Here, we report that Kv3 channel assembly, localization and activity are regulated by zinc through different binding sites. Local perfusion of zinc reversibly reduced spiking frequency of cultured neurons most likely by suppressing Kv3 channels. Indeed, zinc inhibited Kv3.1 channel activity and slowed activation kinetics, independent of its site in the N-terminal T1 domain. Biochemical assays surprisingly identified a novel zinc-binding site in the Kv3.1 C-terminus, critical for channel activity and axonal targeting, but not for the zinc inhibition. Finally, mutagenesis revealed an important role of the junction between the first transmembrane (TM) segment and the first extracellular loop in sensing zinc. Its mutant enabled fast spiking with relative resistance to the zinc inhibition. Therefore, our studies provide novel mechanistic insights into the multifaceted regulation of Kv3 channel activity and localization by divalent heavy metal ions.

Differential effects of Zn2+ on activation, deactivation, and inactivation kinetics in neuronal voltage-gated Na+ channels

Whole-cell, patch-clamp recordings were carried out in acutely dissociated neurons from entorhinal cortex (EC) layer II to study the effects of Zn(2+) on Na(+) current kinetics and voltage dependence. In the presence of 200 μM extracellular Cd(2+) to abolish voltage-dependent Ca(2+) currents, and 100 mM extracellular Na(+), 1 mM Zn(2+) inhibited the transient Na(+) current, I (NaT), only to a modest degree (~17% on average). A more pronounced inhibition (~36%) was induced by Zn(2+) when extracellular Na(+) was lowered to 40 mM. Zn(2+) also proved to modify I (NaT) voltage-dependent and kinetic properties in multiple ways. Zn(2+) (1 mM) shifted the voltage dependence of I (NaT) activation and that of I (NaT) onset speed in the positive direction by ~5 mV. The voltage dependence of I (NaT) steady-state inactivation and that of I (NaT) inactivation kinetics were markedly less affected by Zn(2+). By contrast, I (NaT) deactivation speed was prominently accelerated, and its voltage dependence was shifted by a significantly greater amount (~8 mV on average) than that of I (NaT) activation. In addition, the kinetics of I (NaT) recovery from inactivation were significantly slowed by Zn(2+). Zn(2+) inhibition of I (NaT) showed no signs of voltage dependence over the explored membrane-voltage window, indicating that the above effects cannot be explained by voltage dependence of Zn(2+)-induced channel-pore block. These findings suggest that the multiple, voltage-dependent state transitions that the Na(+) channel undergoes through its activation path are differentially sensitive to the gating-modifying effects of Zn(2+), thus resulting in differential modifications of the macroscopic current's activation, inactivation, and deactivation. Computer modeling provided support to this hypothesis.

The glucagon-producing alpha cell: an electrophysiologically exceptional cell

Activation of potassium channels normally serves to reduce cellular activity but recent data indicate that the glucagon-secreting alpha cells are different in this respect and that inhibition of voltage-gated potassium channels results in a paradoxical inhibition of glucagon secretion. Here we discuss these findings and attempt to provide a model for the regulation of glucagon secretion that incorporates these observations.

Citrobacter rodentium colitis evokes post-infectious hyperexcitability of mouse nociceptive colonic dorsal root ganglion neurons

To investigate the possible contribution of peripheral sensory mechanisms to abdominal pain following infectious colitis, we examined whether the Citrobacter rodentium mouse model of human E. coli infection caused hyperexcitability of nociceptive colonic dorsal root ganglion (DRG) neurons and whether these changes persisted following recovery from infection. Mice were gavaged with C. rodentium or distilled water. Perforated patch clamp recordings were obtained from acutely dissociated Fast Blue labelled colonic DRG neurons and afferent nerve recordings were obtained from colonic afferents during ramp colonic distensions. Recordings were obtained on day 10 (acute infection) and day 30 (infection resolved). Following gavage, colonic weights, myeloperoxidase (MPO) activity, stool cultures, and histological scoring established that infection caused colitis at day 10 which resolved by day 30 in most tissues. Electrophysiological recordings at day 10 demonstrated hyperexcitability of colonic DRG neurons (40% mean decrease in rheobase, P = 0.02; 50% mean increase in action potential discharge at twice rheobase, P = 0.02). At day 30, the increase in action potential discharge persisted (approximately 150% increase versus control; P = 0.04). In voltage clamp studies, transient outward (I(A)) and delayed rectifier (I(K)) currents were suppressed at day 10 and I(A) currents remained suppressed at day 30. Colonic afferent nerve recordings during colonic distension demonstrated enhanced firing at day 30 in infected animals. These studies demonstrate that acute infectious colitis evokes hyperexcitability of colonic DRG neurons which persists following resolution of the infection and that suppression of I(A) currents may play a role. Together, these findings suggest that peripheral pain mechanisms could contribute to post-infectious symptoms in conditions such as post-infectious irritable bowel syndrome.

Insulin increases excitability via a dose-dependent dual inhibition of voltage-activated K+ currents in differentiated N1E-115 neuroblastoma cells

A role in the control of excitability has been attributed to insulin via modulation of potassium (K(+)) currents. To investigate insulin modulatory effects on voltage-activated potassium currents in a neuronal cell line with origin in the sympathetic system, we performed whole-cell voltage-clamp recordings in differentiated N1E-115 neuroblastoma cells. Two main voltage-activated K(+) currents were identified: (a) a relatively fast inactivating current (I(fast) - time constant 50-300 ms); (b) a slow delayed rectifying K(+) current (I(slow) - time constant 1-4 s). The kinetics of inactivation of I(fast), rather than I(slow), showed clear voltage dependence. I(fast) and I(slow) exhibited different activation and inactivation dependence for voltage, and have different but nevertheless high sensitivities to tetraethylammonium, 4-aminopyridine and quinidine. In differentiated cells - rather than in non-differentiated cells - application of up to 300 nm insulin reduced I(slow) only (IC(50) = 6.7 nm), whereas at higher concentrations I(fast) was also affected (IC(50) = 7.7 microm). The insulin inhibitory effect is not due to a change in the activation or inactivation current-voltage profiles, and the time-dependent inactivation is also not altered; this is not likely to be a result of activation of the insulin-growth-factor-1 (IGF1) receptors, as application of IGF1 did not result in significant current alteration. Results suggest that the current sensitive to low concentrations of insulin is mediated by erg-like channels. Similar observations concerning the insulin inhibitory effect on slow voltage-activated K(+) currents were also made in isolated rat hippocampal pyramidal neurons, suggesting a widespread neuromodulator role of insulin on K(+) channels.

Characterization and function of TWIK-related acid sensing K+ channels in a rat nociceptive cell

We examined the properties of a proton sensitive current in acutely dissociated, capsaicin insensitive nociceptive neurons from rat dorsal root ganglion (DRG). The current had features consistent with K(+) leak currents of the KCNK family (TASK-1, TASK-3; TWIK-related acid sensing K(+)). Acidity and alkalinity induced inward and outward shifts in the holding current accompanied by increased and decreased whole cell resistance consistent with a K(+) current. We used alkaline solutions to open the channel and examine its properties. Alkaline evoked currents (AECs; pH 10.0-10.75), reversed near the K(+) equilibrium potential (-74 mV), and were suppressed 85% in 0 mM K(+). AECs were insensitive to Cs(+) (1 mM) and anandamide (1 microM), but blocked by Ba(++) (1 mM), quinidine (100 microM) or Ruthenium Red (10 microM). This pharmacology was identical to that of rat TASK-3 and inconsistent with that of TASK-1 or TASK-2. The TASK-like AEC was not modulated by PKA (forskolin, kappa opioid agonists U69593 and GR8696, somatostatin) but was inhibited by PKC activator phorbol-12-myristate-13 acetate (PMA). When acidic solutions were used, we were able to isolate a Ba(++) and Ruthenium Red insensitive current that was inhibited by Zn(++). This Zn(++) sensitive component of the proton sensitive current was consistent with TASK-1. In current clamp studies, acidic pH produced sensitive changes in resting membrane potential but did not influence excitability (pH 7.2-6.8). In contrast, Zn(++) produced substantial changes in excitability at physiological pH. Alkaline solutions produced hyperpolarization followed by proportional burst discharges (pH 10.75-11.5) and increased excitability (at pH 7.4). In conclusion, multiple TASK currents were present in a DRG nociceptor and differentially contributed to distinct discharge mechanisms.

Dual effect of Zn2+ on multiple types of voltage-dependent Ca2+ currents in rat palaeocortical neurons

The effects of Zn(2+) were evaluated on high-voltage-activated Ca(2+) currents expressed by pyramidal neurons acutely dissociated from rat piriform cortex. Whole-cell, patch-clamp experiments were carried out using Ba(2+) (5 mM) as the charge carrier. Zn(2+) blocked total high-voltage-activated Ba(2+) currents with an IC(50) of approximately 21 microM. In addition, after application of non-saturating Zn(2+) concentrations, residual currents activated with substantially slower kinetics than control Ba(2+) currents. Both of the above-mentioned effects of Zn(2+) were also observed in high-voltage-activated currents recorded in the presence of nearly-physiological concentrations of extracellular Ca(2+) (1 and 2 mM) rather than Ba(2+). Under the latter conditions, 30 microM Zn(2+) inhibited high-voltage-activated currents somewhat less than observed in extracellular Ba(2+) (approximately 47% and approximately 41%, respectively, vs. approximately 59%), but slowed Ca(2+)-current activation to very similar degrees. All of the pharmacological components in which Ba(2+) currents could be dissected (L-, N-, P/Q-, and R-type) were inhibited by Zn(2+), the percentage of current blocked by 30 microM Zn(2+) ranging from 34 to 57%. Moreover, the activation kinetics of all pharmacological Ba(2+) current components were slowed by Zn(2+). Hence, the lower activation speed observed in residual Ba(2+) currents after Zn(2+) block is due to a true slowing of macroscopic Ca(2+)-current activation kinetics and not to the preferential inhibition of a fast-activating current component. The inhibitory effect of Zn(2+) on Ba(2+) current amplitude was voltage-independent over the whole voltage range explored (-60 to +30 mV), hence the Zn(2+)-dependent decrease of Ba(2+) current activation speed is not the consequence of a voltage- and time-dependent relief from block. Zn(2+) also caused a slight, but significant, reduction of Ba(2+) current deactivation speed upon repolarization, which is further evidence against a depolarization-dependent unblocking mechanism. Finally, the slowing effect of Zn(2+) on Ca(2+)-channel activation kinetics was found to result in a significant, extra reduction of Ba(2+) current amplitude when action-potential-like waveforms, rather than step pulses, were used as depolarizing stimuli. We conclude that Zn(2+) exerts a dual action on multiple types of voltage-gated Ca(2+) channels, causing a blocking effect and altering the speed at which channels are delivered to conducting states, with mechanism(s) that could be distinct.

Inhibition of the activity of T lymphocyte Kv1.3 channels by extracellular zinc

The inhibitory effect of zinc on voltage-gated Kv1.3 channels in human T lymphocytes was investigated using the "whole-cell" patch-clamp technique. Application of 10 and 20 microM Zn caused a concentration-dependent shift of activation midpoint of the whole-cell currents from -19.65+/-1.03 mV (mean+/-SE) under control conditions to 9.84+/-0.66 mV upon application of 20 microM Zn. This effect was saturated at zinc concentrations higher than 20 microM. The activation rate was considerably slower, whereas the deactivation rate was not significantly affected by Zn. Inactivation midpoint was shifted from -53.06+/-0.44 mV under control conditions to -36.05+/-0.48 mV in the presence of 100 microM Zn. Inactivation rate was not significantly affected upon Zn treatment. Whole-cell potassium currents were reduced to about 70% of their control values with no clear concentration dependence in the zinc concentration range from 10 to 100 microM. When raising the zinc concentration to levels above 100 microM, a concentration-dependent inhibition of the whole-cell currents appeared additionally to the changes in channel gating. The channels were half-blocked at the zinc concentration of 346+/-40 microM and the Hill slope coefficient was 1.89+/-0.21. The inhibitory effect of zinc was not complete at micromolar concentrations and was saturated at concentrations higher than 1mM. This inhibitory effect was not accompanied by any further modification in the shift of the activation and inactivation midpoints nor by a slowing of the channel activation rate. The inhibitory effect of zinc was significantly diminished in the presence of 150 mM K(+) in the extracellular solution, whereas the zinc-induced shift of the activation threshold and slowing of the activation kinetics remained unchanged when raising extracellular potassium concentration. It is suggested that zinc acts on two independent binding sites on the channels. Binding to one site that is saturated at concentrations higher than 20 microM affects the channel gating. Binding to another site at concentrations higher than 100 microM inhibits the currents without affecting the channel gating.

Zinc and copper influence excitability of rat olfactory bulb neurons by multiple mechanisms

Zinc and copper are highly concentrated in several mammalian brain regions, including the olfactory bulb and hippocampus. Whole cell electrophysiological recordings were made from rat olfactory bulb neurons in primary culture to compare the effects of zinc and copper on synaptic transmission and voltage-gated ion channels. Application of either zinc or copper eliminated GABA-mediated spontaneous inhibitory postsynaptic potentials. However, in contrast to the similarity of their effects on inhibitory transmission, spontaneous glutamate-mediated excitatory synaptic activity was completely blocked by copper but only inhibited by zinc. Among voltage-gated ion channels, zinc or copper inhibited TTX-sensitive sodium channels and delayed rectifier-type potassium channels but did not prevent the firing of evoked single action potentials or dramatically alter their kinetics. Zinc and copper had distinct effects on transient A-type potassium currents. Whereas copper only inhibited the A-type current, zinc modulation of A-type currents resulted in either potentiation or inhibition of the current depending on the membrane potential. The effects of zinc and copper on potassium channels likely underlie their effects on repetitive firing in response to long-duration step depolarizations. Copper reduced repetitive firing independent of the initial membrane voltage. In contrast, whereas zinc reduced repetitive firing at membrane potentials associated with zinc-mediated enhancement of the A-type current (-50 mV), in a significant proportion of neurons, zinc increased repetitive firing at membrane potentials associated with zinc-mediated inhibition of the A-type current (-90 mV). Application of zinc or copper also inhibited voltage-gated Ca(2+) channels, suggesting a possible role for presynaptic modulation of neurotransmitter release. Despite similarities between the effects of zinc and copper on some ligand- and voltage-gated ion channels, these data suggest that their net effects likely contribute to differential modulation of neuronal excitability.

A-type potassium current in myenteric neurons from guinea-pig small intestine

Biophysical properties of A-type K(+) currents (I(A)) in myenteric neurons from guinea-pig small intestine were studied. I(A) was present in both AH- and S-type myenteric neurons. Reduction of external Ca(2+) did not affect the current. Current density was 13.5+/-10.2 pA/pF in 68 AH-type neurons and 23.4+/-8.2 pA/pF in 31 S-type neurons. S-type neurons appeared to be a homogeneous group based on density of I(A). AH-type neurons were subdivided into two groups with current densities of 9.4+/-4.3 and 25.4+/-4.3 pA/pF. All other biophysical properties of the current were not statistically different for AH- and S-type neurons. Steady-state activation and inactivation curves showed half-activation potentials at -7 mV (k=15. 0 mV) and -86 mV (k=11.5 mV). The curves overlapped at potentials near the resting potential of approximately -55 mV. Time constants for activation ranged from 3.6 to 0.52 ms at test potentials between -20 and 50 mV. Inactivation time constants fell between 41.5 and 11 ms at test potentials between -20 and 50 mV. Time constants for recovery from inactivation fit a double-exponential curve with fast and slow recovery times of 11 and 550 ms. 4-Aminopyridine suppressed I(A) when it was activated at -20 mV following a pre-pulse to -110 mV. Addition of Zn(2+) in the external solution resulted in a concentration-dependent shift of the activation and inactivation curves in the depolarized direction. Zn(2+) slowed the activation and inactivation kinetics of I(A) by factors of 3.3- and 1.2-fold over a wide range of potentials. Elevation of external H(+) suppressed the effect of Zn(2+) with a pK of 7.3-7.4. The effects of Zn(2+) were interpreted as not being due to surface charge screening, because the affinity of Zn(2+) for its binding site on the A-channel was estimated to be between 170 and 312 microM, while the background concentration of Mg(2+) was 10 mM. The enteric nervous system is perceived as an independent integrative nervous system (brain-in-the-gut) that is responsible for local organizational control of motility and secretory patterns of gut behavior. AH- and S-type neurons are synaptically interconnected to form the microcircuits of the enteric nervous system. The results suggest that I(A) is a significant determinant of neuronal excitability for both the firing of nerve impulses and the various synaptic events in the two types of neurons.

The multifarious hippocampal mossy fiber pathway: a review

The hippocampal mossy fiber pathway between the granule cells of the dentate gyrus and the pyramidal cells of area CA3 has been the target of numerous scientific studies. Initially, attention was focused on the mossy fiber to CA3 pyramidal cell synapse because it was suggested to be a model synapse for studying the basic properties of synaptic transmission in the CNS. However, the accumulated body of research suggests that the mossy fiber synapse is rather unique in that it has many distinct features not usually observed in cortical synapses. In this review, we have attempted to summarize the many unique features of this hippocampal pathway. We also have attempted to reconcile some discrepancies that exist in the literature concerning the pharmacology, physiology and plasticity of this pathway. In addition we also point out some of the experimental challenges that make electrophysiological study of this pathway so difficult.Finally, we suggest that understanding the functional role of the hippocampal mossy fiber pathway may lie in an appreciation of its variety of unique properties that make it a strong yet broadly modulated synaptic input to postsynaptic targets in the hilus of the dentate gyrus and area CA3 of the hippocampal formation.

Inhibition of neuronal KV potassium currents by the antidepressant drug, fluoxetine

1. The effect of the antidepressant drug, fluoxetine on neuronal delayed rectifier (KV) potassium (K) currents was investigated using perforated-patch whole-cell electrophysiological recording methods. 2. Fluoxetine was an effective inhibitor of KV currents in cerebellar granule neurons (CGNs) and also inhibited recombinant KV1.1 channels expressed in Chinese hamster ovary (CHO) cells. 3. Fluoxetine had an IC50 of 11 microM in CGNs but was slightly less potent on KV1.1 channels (IC50=55 microM). Interestingly, fluoxetine was a much more potent inhibitor of KV1.1 expressed in mammalian cells than has been found previously for the same homomeric channel expressed in Xenopus oocytes. 4. At concentrations that produced around 50% block, the shape of the KV currents in the presence of fluoxetine was simply scaled down when compared to control currents. 5. The effect of fluoxetine on KV currents in CGNs was neither voltage-dependent nor dependent on the channels being in their open state. Both of these observations suggest that fluoxetine does not act as a simple open channel blocking agent. 6. It is concluded that block of KV currents in mammalian neurons can occur at therapeutic levels of fluoxetine. This could lead to an increase in neuronal excitability and this effect may contribute to the therapeutic antidepressant action of fluoxetine.

Zn2+ modulation of neuronal transient K+ current: fast and selective binding to the deactivated channels

Modulation of voltage-dependent transient K(+) currents (A type K(+) or K(A) current) by Zn(2+) was studied in rat hippocampal neurons by the whole-cell patch-clamp technique. It is found that Zn(2+) selectively binds to the resting (deactivated or closed) K(A) channels with a dissociation constant (K(d)) of approximately 3 microM, whereas the affinity between Zn(2+) and the inactivated K(A) channels is 1000-fold lower. Zn(2+) therefore produces a concentration-dependent shift of the K(A) channel inactivation curve and enhances the K(A) current elicited from relatively positive holding potentials. It is also found that the kinetics of Zn(2+) action are fast enough to compete with the transition rates between different gating states of the channel. The rapid and selective binding of Zn(2+) to the closed K(A) channels keeps the channel in the closed state and explains the ion's concentration-dependent slowing effect on the activation of K(A) current. This in turn accounts for the inhibitory effect of Zn(2+) on the K(A) current elicited from hyperpolarized holding potentials. Because the molecular mechanisms underlying these gating changes are kinetic interactions between the binding-unbinding of Zn(2+) and the intrinsic gating processes of the channel, the shift of the inactivation curve and slowing of K(A) channel activation are quantitatively correlated with ambient Zn(2+) over a wide concentration range without "saturation"; i.e., The effects are already manifest in micromolar Zn(2+), yet are not saturated even in millimolar Zn(2+). Because the physiological concentration of Zn(2+) could vary over a similarly wide range according to neural activities, Zn(2+) may be a faithful physiological "fine tuner," controlling and controlled by neural activities through its effect on the K(A) current.

Functional heterogeneity of periglomerular cells in the rat olfactory bulb

The periglomerular cells of the rat olfactory bulb, a virtually unknown population of interneurons, have been studied applying the whole-cell patch-clamp technique to thin slices. A prominent result, obtained under current-clamp conditions, is that these cells appear to be functionally heterogeneous, and show distinct excitability profiles. Voltage-clamp analysis allows the identification of the ionic basis of these differences and suggests a division into at least two classes, based on the characteristics of the K+ conductances. The first group displays two K+ conductances (delayed rectifier, gKV, and fast transient, gA) of similar amplitude, and under current-clamp conditions shows the usual outward rectifying behaviour at depolarized potentials. The second group has a large gA, and a small or absent gKV. Consequently, following sustained depolarizations under current-clamp conditions leading to inactivation of gA, these neurons do not show any sign of outward rectification and behave as ohmic elements, as normally observed only at hyperpolarized potentials. The transition ion zinc (10-300 microM) affects gA but not gKV The inactivation process (steady-state curve and rate constant) is strongly altered by Zn2+, the activation process less so; open-channel conductance is not affected. The Zn2+ effect is unlikely to be due to surface charge screening or to a mechanism involving channel block. In view of the substantial presence of zinc ions in the olfactory nerve terminals, its actions on the A-current could be of some relevance for physiological function.

Voltage-activated potassium channels in mammalian neurons and their block by novel pharmacological agents

1. Electrophysiological studies have shown that a number of different types of potassium (K) channel currents exist in mammalian neurons. Among them are the voltage-gated K channel-currents which have been classified as fast-inactivating A-type currents (KA) and slowly inactivating delayed-rectifier type currents (KDR). 2. Two major molecular superfamilies of K channel have been identified; the KIR superfamily and the Shaker-related superfamily with a number of different pore-forming alpha-subunits in each superfamily. 3. Within the Shaker-related superfamily are the KV family, comprising of at least 18 different alpha-subunits that almost certainly underlie classically defined KA and KDR currents. However, the relationship between each of these cloned alpha-subunits and native voltage-gated K currents remains, for the most part, to be established. 4. Classical pharmacological blockers of voltage-gated K channels such as tetraethylammonium ions (TEA), 4-aminopyridine (4-AP), and certain toxins lack selectivity between different native channel currents and between different cloned K channel currents. 5. A number of other agents block neuronal voltage-gated K channels. All of these compounds are used primarily for other actions they possess. They include organic calcium (Ca) channel blockers, divalent and trivalent metal ions and certain calcium signalling agents such as caffeine. 6. A number of clinically active tricyclic compounds such as imipramine, amitriptyline, and chlorpromazine are also potent inhibitors of neuronal voltage-gated K channels. These compounds are weak bases and it appears that their uncharged form is required for activity. These compounds may provide a useful starting point for the rational design of novel selective K channel blocking agents.

Whole-cell K+ currents in identified olfactory bulb output neurones of rats

1. Voltage-gated whole-cell K+ currents have been investigated in olfactory bulb (OB) output (mitral/tufted) neurones from neonatal rats, which were retrogradely labelled by rhodamine or Fast Blue and identified after enzymatic dissociation. Forty-five per cent of labelled neurones exhibited either phasic or non-phasic spontaneous firing in cell-attached configuration. 2. Four outward K+ currents have been identified in all such identified OB output neurones. They are the transient (IA), the delayed rectifier (IDK), and two Ca(2+)-dependent (IK(Ca)) currents. No inward rectifier was detected. 3. The IA was activated at around -45 mV and reached its peak within 3-10 ms. The decay phase could be described by single exponential distribution with the time constant of 45.2 +/- 3.8 ms at depolarizations 10-60 mV from a holding potential of -70 mV. Its activation and steady-state inactivation processes could be fitted with Boltzmann equations yielding half-maximal activation potentials of 7.6 +/- 0.4 and -47.4 +/- 0.2 mV, respectively. It was sensitive to block by 4-AP (1 mM) and by Zn2+ (1 mM). 4. The IDK was activated at potentials more positive than -30 mV, with half-maximal activation at 21 mV. It was sustained during 1 s test pulses without apparent decay. It was blocked by TEA at a concentration of 20 mM. About 8% of the sustained current, in 11/24 cells tested, was found to resist block by a combination of all pharmacological agents tested. 5. Apamin at 100 nM blocked a TEA-insensitive component which accounted for about 23% of the maximal sustained currents. Iberiotoxin (IbTX), which has been found to block maxi K+ currents more selectively than does charybdotoxin, reversibly blocked Ca(2+)-activated K+ current, with a half-maximal dose of about 100 nM in 8/13 OB output neurones tested. This accounted for 20% of the maximal sustained K+ current. The effect of IbTX was not observed in the presence of 20 mM external TEA. 6. Direct evidence is provided in this study regarding kinetic and pharmacological properties of four types of outward K+ channels in OB output neurones.

Potent block of potassium currents in rat isolated sympathetic neurones by the uncharged form of amitriptyline and related tricyclic compounds

1. The block of K+ currents by amitriptyline and the related tricyclic compounds cyproheptadine and dizocilpine was studied in dissociated rat sympathetic neurones by whole-cell voltage-clamp recording. 2. Cyproheptadine (30 microM) inhibited the delayed-rectifier current (Kv) by 92% and the transient current (KA) by 43%. For inhibition of Kv, cyproheptaidine had a KD of 2.2 microM. Dizocilpine (30 microM) inhibited Kv by 26% and KA by 22%. The stereoisomers of dizocilpine were equally potent at blocking Kv and KA. 3. Amitriptyline, a weak base, was significantly more effective in blocking Kv at pH 9.4 (KD = 0.46 microM) where the ratio of charged to uncharged drug was 50:50 compared with pH 7.4 (KD = 11.9 microM) where the ratio was 99:1. 4. N-methylamitriptyline (10 microM), the permanently charged analogue of amitriptyline, inhibited Kv by only 2% whereas in the same cells amitriptyline (10 microM) inhibited Kv by 36%. 5. Neither amitriptyline nor N-methylamitriptyline had a detectable effect on Kv when added to the intracellular solution. 6. It is concluded that the uncharged form of amitriptyline is approximately one hundred times more potent in blocking Kv than the charged form. However, this does not seem to be due to uncharged amitriptyline having better access to an intracellular binding site.