Zinc modulation of a transient potassium current and histochemical localization of the metal in neurons of the suprachiasmatic nucleus

Daily electrical activity in the master circadian clock of a diurnal mammal

Circadian rhythms in mammals are orchestrated by a central clock within the suprachiasmatic nuclei (SCN). Our understanding of the electrophysiological basis of SCN activity comes overwhelmingly from a small number of nocturnal rodent species, and the extent to which these are retained in day-active animals remains unclear. Here, we recorded the spontaneous and evoked electrical activity of single SCN neurons in the diurnal rodent Rhabdomys pumilio, and developed cutting-edge data assimilation and mathematical modeling approaches to uncover the underlying ionic mechanisms. As in nocturnal rodents, R. pumilio SCN neurons were more excited during daytime hours. By contrast, the evoked activity of R. pumilio neurons included a prominent suppressive response that is not present in the SCN of nocturnal rodents. Our modeling revealed and subsequent experiments confirmed transient subthreshold A-type potassium channels as the primary determinant of this response, and suggest a key role for this ionic mechanism in optimizing SCN function to accommodate R. pumilio's diurnal niche.

Examination of Zinc in the Circadian System

Zinc is a trace element that is essential for a large number of biological and biochemical processes in the body. In the nervous system zinc is packaged into synaptic vesicles by the ZnT3 transporter, and synaptic release of zinc can influence the activity of postsynaptic cells, either directly through its own cognate receptors, or indirectly by modulating activation of receptors for other neurotransmitters. Here, we explore the anatomical and functional aspects of zinc in the circadian system. Melanopsin-containing retinal ganglion cells in the mouse retina were found to colocalize ZnT3, indicating that they can release zinc at their synaptic targets. While the master circadian clock in the hamster suprachiasmatic nucleus (SCN) was found to contain, at best, sparse zincergic input, the intergeniculate leaflet (IGL) of hamsters and mice were found to have prominent zincergic input. Levels of zinc in these areas were not affected by time of day. Additionally, IGL zinc staining persisted following enucleation, indicating other prominent sources of zinc instead of, or in addition to, the retina. Neither enhancement nor chelation of free zinc at either the SCN or IGL altered circadian responses to phase-shifting light in hamsters. Finally, entrainment, free-running, and circadian responses to light were explored in mice lacking the ZnT3 gene. In every aspect explored, the ZnT3 knockout mice were not significantly different from their wildtype counterparts. These findings highlight the presence of zinc in areas critical for circadian functioning but have yet to identify a role for zinc in these areas.

The dynamics of GABA signaling: Revelations from the circadian pacemaker in the suprachiasmatic nucleus

Virtually every neuron within the suprachiasmatic nucleus (SCN) communicates via GABAergic signaling. The extracellular levels of GABA within the SCN are determined by a complex interaction of synthesis and transport, as well as synaptic and non-synaptic release. The response to GABA is mediated by GABA_A receptors that respond to both phasic and tonic GABA release and that can produce excitatory as well as inhibitory cellular responses. GABA also influences circadian control through the exclusively inhibitory effects of GABA_B receptors. Both GABA and neuropeptide signaling occur within the SCN, although the functional consequences of the interactions of these signals are not well understood. This review considers the role of GABA in the circadian pacemaker, in the mechanisms responsible for the generation of circadian rhythms, in the ability of non-photic stimuli to reset the phase of the pacemaker, and in the ability of the day-night cycle to entrain the pacemaker.

Novel description of ionic currents recorded with the action potential clamp technique: application to excitatory currents in suprachiasmatic nucleus neurons

The traditional method of recording ionic currents in neurons has been with voltage-clamp steps. Other waveforms such as action potentials (APs) can be used. The AP clamp method reveals contributions of ionic currents that underlie excitability during an AP (Bean BP. Nat Rev Neurosci 8: 451-465, 2007). A novel usage of the method is described in this report. An experimental recording of an AP from the literature is digitized and applied computationally to models of ionic currents. These results are compared with experimental AP-clamp recordings for model verification or, if need be, alterations to the model. The method is applied to the tetrodotoxin-sensitive sodium ion current, INa, and the calcium ion current, ICa, from suprachiasmatic nucleus (SCN) neurons (Jackson AC, Yao GL, Bean BP. J Neurosci 24: 7985-7998, 2004). The latter group reported voltage-step and AP-clamp results for both components. A model of INa is constructed from their voltage-step results. The AP clamp computational methodology applied to that model compares favorably with experiment, other than a modest discrepancy close to the peak of the AP that has not yet been resolved. A model of ICa was constructed from both voltage-step and AP-clamp results of this component. The model employs the Goldman-Hodgkin-Katz equation for the current-voltage relation rather than the traditional linear dependence of this aspect of the model on the Ca(2+) driving force. The long-term goal of this work is a mathematical model of the SCN AP. The method is general. It can be applied to any excitable cell.

A novel analysis of excitatory currents during an action potential from suprachiasmatic nucleus neurons

A new application of the action potential (AP) voltage-clamp technique is described based on computational analysis. An experimentally recorded AP is digitized. The resulting Vi vs. ti data set is applied to mathematical models of the ionic conductances underlying excitability for the cell from which the AP was recorded to test model validity. The method is illustrated for APs from suprachiasmatic nucleus (SCN) neurons and the underlying tetrodotoxin-sensitive Na(+) current, INa, and the Ca(2+) current, ICa. Voltage-step recordings have been made for both components from SCN neurons (Jackson et al. 2004). The combination of voltage-step and AP clamp results provides richer constraints for mathematical models of voltage-gated ionic conductances than either set of results alone, in particular the voltage-step results. For SCN neurons the long-term goal of this work is a realistic mathematical model of the SCN AP in which the equations for I(Na) and I(Ca) obtained from this analysis will be a part. Moreover, the method described in this report is general. It can be applied to any excitable cell.

Metal toxicity at the synapse: presynaptic, postsynaptic, and long-term effects

Metal neurotoxicity is a global health concern. This paper summarizes the evidence for metal interactions with synaptic transmission and synaptic plasticity. Presynaptically metal ions modulate neurotransmitter release through their interaction with synaptic vesicles, ion channels, and the metabolism of neurotransmitters (NT). Many metals (e.g., Pb(2+), Cd(2+), and Hg(+)) also interact with intracellular signaling pathways. Postsynaptically, processes associated with the binding of NT to their receptors, activation of channels, and degradation of NT are altered by metals. Zn(2+), Pb(2+), Cu(2+), Cd(2+), Ni(2+), Co(2+), Li(3+), Hg(+), and methylmercury modulate NMDA, AMPA/kainate, and/or GABA receptors activity. Al(3+), Pb(2+), Cd(2+), and As(2)O(3) also impair synaptic plasticity by targeting molecules such as CaM, PKC, and NOS as well as the transcription machinery involved in the maintenance of synaptic plasticity. The multiple effects of metals might occur simultaneously and are based on the specific metal species, metal concentrations, and the types of neurons involved.

Acid-sensing ion channels in neurones of the rat suprachiasmatic nucleus

We used reduced slice reparations to study ASIC-like currents in the rat central clock suprachiasmatic nucleus (SCN). In reduced SCN preparations, a drop of extracellular pH evoked a desensitizing inward current to excite SCN neurones to fire at higher rates. Under voltage-clamped conditions, all SCN neurones responded to a 5 s pH step to 6.4 with an inward current that decayed with an average time constant of 1.2 s to 10% of the peak at the end of step. The current was blocked by amiloride with an IC(50) of 14 microm and was carried mainly by Na(+), suggesting an origin of ASIC-like channels. The SCN neurones were sensitive to neutral pH, with 94% of cells responding to pH 7.0 with an inward current. The study of sensitivity to pH between 7.0 and 4.4 revealed a two-component dose-dependent H(+) activation in most SCN neurones, with the first component (85% in amplitude) having a pH(50) of 6.6, and the second (15%) a pH(50) of 5. The ASIC-like currents were potentiated by lactate and low Ca(2+), but were inhibited by Zn(2+). RT-PCR analysis demonstrated the presence of mRNA for ASIC1a, 2a, 2b, and 3 in SCN. Compared to other central neurones, the unique presence of ASIC3 along with ASIC1a in SCN neurones may contribute to the high pH sensitivity and unusual inhibition by Zn(2+). The high pH sensitivity suggests that the SCN neurones are susceptive to extracellular acidification of physiological origins and that the ASIC current might play a role in regulating SCN excitability.

Tetraethylammonium (TEA) increases the inactivation time constant of the transient K+ current in suprachiasmatic nucleus neurons

Identifying the mechanisms that drive suprachiasmatic nucleus (SCN) neurons to fire action potentials with a higher frequency during the day than during the night is an important goal of circadian neurobiology. Selective chemical tools with defined mechanisms of action on specific ion channels are required for successful completion of these studies. The transient K(+) current (I(A)) plays an active role in neuronal action potential firing and may contribute to modulating the circadian firing frequency. Tetraethylammonium (TEA) is frequently used to inhibit delayed rectifier K(+) currents (I(DR)) during electrophysiological recordings of I(A). Depolarizing voltage-clamped hamster SCN neurons from a hyperpolarized holding potential activated both I(A) and I(DR). Holding the membrane potential at depolarized values inactivated I(A) and only the I(DR) was activated during a voltage step. The identity of I(A) was confirmed by applying 4-aminopyridine (5 mM), which significantly inhibited I(A). Reducing the TEA concentration from 40 mM to 1 mM significantly decreased the I(A) inactivation time constant (tau(inact)) from 9.8+/-3.0 ms to 4.9+/-1.2 ms. The changes in I(A)tau(inact) were unlikely to be due to a surface charge effect. The I(A) amplitude was not affected by TEA at any concentration or membrane potential. The isosmotic replacement of NaCl with choline chloride had no effect in I(A) kinetics demonstrating that the TEA effects were not due to a reduction of extracellular NaCl. We conclude that TEA modulates, in a concentration dependent manner, tau(inact) but not I(A) amplitude in hamster SCN neurons.

Modulation of A-type potassium currents in retinal horizontal cells by extracellular calcium and zinc

Extracellular Ca2+ and Zn2+ influence many aspects of retinal function. Here, we examined the effect of external Ca2+ and Zn2+ on potassium channels of retinal horizontal cells. When extracellular Ca2+ was lowered from 3 mM to 0.3 mM, horizontal cell transient outward currents elicited by voltage steps from resting membrane potential (−70 mV) were decreased by approximately 50%, whereas the sustained currents remained unchanged. This effect was due to a hyperpolarizing shift in the steady-state inactivation curve of A-type K+ currents when extracellular Ca2+ concentration was lowered. The mean half inactivation potential of the steady-state inactivation curves was hyperpolarized from −56.3 ± 4.7 mV in 3 mM Ca2+ to −76.4 ± 3.9 mV in 0.3 mM Ca2+. Neither the state-steady activation curve nor the kinetics of inactivation was significantly changed in low extracellular Ca2+. The addition of 30 μM Zn2+ restored peak outward currents in 0.3 mM Ca2+. The half inactivation voltages were depolarized from −70 ± 2.8 mV in 0.3 mM Ca2+ to −56 ± 2.6 mV in 0.3 mM Ca2+ plus 30 μM Zn2+. Taken together, the results indicate that external Ca2+ and Zn2+ maintain the activity of A-type potassium channels in retinal horizontal cells by influencing the voltage dependence of steady-state inactivation.

Zinc and copper: pharmacological probes and endogenous modulators of neuronal excitability

As well as being key structural components of many proteins, increasing evidence suggests that zinc and copper ions function as signaling molecules in the nervous system and are released from the synaptic terminals of certain neurons. In this review, we consider the actions of these two ions on proteins that regulate neuronal excitability. In addition to the established actions of zinc, and to a lesser degree copper, on excitatory and inhibitory ligand-gated ion channels, we show that both ions have a number of actions on selected members of the voltage-gated-like ion channel superfamily. For example, zinc is a much more effective blocker of one subtype of tetrodotoxin (TTX)-insensitive sodium (Na+) channel (NaV1.5) than other Na+ channels, whereas a certain T-type calcium (Ca2+) channel subunit (CaV3.2) is particularly sensitive to zinc. For potassium (K+) channels, zinc can have profound effects on the gating of certain KV channels whereas zinc and copper have distinct actions on closely related members of the 2 pore domain potassium channel (K2P) channel family. In addition to direct actions on these proteins, zinc is able to permeate a number of membrane proteins such as (S)-alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA)/kainate receptors, Ca2+ channels and some transient receptor potential (trp) channels. There are a number of important physiological and pathophysiological consequences of these many actions of zinc and copper on membrane proteins, in terms of regulation of neuronal excitability and neurotoxicity. Furthermore, the concentration of free zinc and copper either in the synaptic cleft or neuronal cytoplasm may contribute to the etiology of certain disease states such as Alzheimer's disease (AD) and epilepsy.

Circadian Rhythmicity in AVP Secretion and GABAergic Synaptic Transmission in the Rat Suprachiasmatic Nucleus

A variety of physiological and behavioral functions exhibit circadian changes and these circadian rhythms are driven by oscillatory expression of clock genes in the suprachiasmatic nuclei (SCN). It is still unknown how this molecular clockwork is controlled by extracellular neurohormones and neurotransmitters and which membrane receptors undergo circadian modulation. Circadian rhythm can be measured as a secretion of arginine vasopressin (AVP) in organotypic SCN culture for several weeks. Melatonin applied directly to the SCN late in the day induces a phase advance, when applied late at night or at the beginning of the day melatonin causes a phase delay. The time window for phase advance corresponds with the highest level of melatonin receptors in the SCN but the mechanism of melatonin-induced phase delay is unknown. The principal neurotransmitter on SCN synapses is gamma-aminobutyric acid (GABA), which acts at postsynaptic GABA(A) receptors. Spontaneous release of GABA from presynaptic nerve terminals, recorded as miniature inhibitory postsynaptic currents in the presence of TTX, does not change, but zinc sensitivity of exogenous GABA-induced currents varies during the day and night, possibly due to changes in subunit composition of GABA(A) receptors. We conclude that there is daily variation in the postsynaptic, but not presynaptic, function in the SCN.

Divalent cation modulation of a-type potassium channels in acutely dissociated central neurons from wide-type and mutant Drosophila

Drosophila mutants provide an ideal model to study channel-type specificity of ion channel regulation in situ. In this study, the effects of divalent cations on voltage-gated K+ currents were investigated in acutely dissociated central neurons of Drosophila third instar larvae using the whole-cell patch-clamp recording. Our data showed that micromolar Cd2+ enhanced the peak inactivating current (I(A)) without affecting the delayed component (I(K)). The same results were obtained in Ca(2+)-free external solution, and from slo1 mutation, which eliminates transient Ca(2+)-activated K+ current. Micromolar Cd2+ and Zn2+, and millimolar Ca2+ and Mg2+ all shifted the steady-state inactivation curve of I(A) without affecting the voltage-dependence of I(A) activation, whereas millimolar Cd2+ markedly affected both the activation and steady-state inactivation curves for I(A). Divalent cations affected I(A) with different potency; the sequence was: Zn2+ > Cd2+ > Ca2+ > Mg2+. The modulation of I(A) by Cd2+ was partially inhibited in Sh(M), a null Shaker (one of I(A)-encoding genes) mutation. Taken together, the channel-type specificity, the asymmetric effects on I(A) activation and inactivation kinetics, and the diverse potency of divalent cations all strongly support the idea that physiological divalent cations modulate A-type K+ channels through specific binding to extracellular sites of the channels.

The KCNQ5 potassium channel from mouse: A broadly expressed M-current like potassium channel modulated by zinc, pH, and volume changes

The KCNQ proteins compose a sub-group of the voltage-activated potassium channel family. The family consists of five members (KCNQ1 to 5--also named Kv7.1 to Kv7.5) encoded by single genes, which all give rise to proteins forming slowly activating potassium-selective ion channels. The physiological importance of the KCNQ channel family is emphasized by the fact that mutations in four of the five genes have been linked to human pathologies (KCNQ1 to 4). Here, we present the cloning and characterization of a novel KCNQ5 ortholog from mouse isolated by homology cloning from total mouse brain RNA (GenBank accession number: AY679158). The predicted protein is 95% identical to human KCNQ5. Upon expression in Xenopus oocytes, these proteins form voltage-dependent slowly activating channels with half-maximal activation at -21 mV. Our functional characterization revealed three novel modes of modulation: pH-dependent potentiation by Zn2+ (EC50 = 21.8 microM at pH 7.4), inhibition by acidification (IC50 = 0.75 microM; pKa = 6.1), and regulation by small changes in cell volume. Furthermore, the channels are activated by the anti-convulsant drug retigabine (EC50 = 2.0 microM) and inhibited by the M-current blockers linopiridine and XE-991. Finally, real-time RT-PCR was used to quantify the expression profile in a wide range of mouse tissues. These experiments revealed a relatively broad expression pattern in the nervous system but also expression in other tissues. Highest overall expression levels were observed in cortex and hippocampus. This study shows that murine KCNQ5 channels, in addition to sharing biophysical and pharmacological characteristics with the human ortholog, are tightly regulated by physiological stimuli such as changes in extracellular Zn2+, pH, and tonicity, thus adding to the complex regulation of these channels.

Mechanism of spontaneous firing in dorsomedial suprachiasmatic nucleus neurons

We studied acutely dissociated neurons from the dorsomedial (shell) region of the rat suprachiasmatic nucleus (SCN) with the aim of determining the ionic conductances that underlie spontaneous firing. Most isolated neurons were spontaneously active, firing rhythmically at an average frequency of 8 +/- 4 Hz. After application of TTX, oscillatory activity generally continued, but more slowly and at more depolarized voltages; these oscillations were usually blocked by 2 microm nimodipine. To quantify the ionic currents underlying normal spontaneous activity, we voltage clamped cells using a segment of the spontaneous activity of each cell as voltage command and then used ionic substitution and selective blockers to isolate individual currents. TTX-sensitive sodium current flowed throughout the interspike interval, averaging -3 pA at -60 mV and -11 pA at -55 mV. Calcium current during the interspike interval was, on average, fourfold smaller. Except immediately before spikes, calcium current was outweighed by calcium-activated potassium current, and in current clamp, nimodipine usually depolarized cells and slowed firing only slightly (average, approximately 8%). Thus, calcium current plays only a minor role in pacemaking of dissociated SCN neurons, although it can drive oscillatory activity with TTX present. During normal pacemaking, the early phase of spontaneous depolarization (-85 to -60 mV) is attributable mainly to background conductance; cells have relatively depolarized resting potentials (with firing stopped by TTX and nimodipine) of -55 to -50 mV, although input resistance is high (9.5 +/- 4.1 GOmega). During the later phase of pacemaking (positive to -60 mV), TTX-sensitive sodium current is dominant.

Distribution of zincergic neurons in the mouse forebrain

Synaptically released zinc is thought to play an important role in neuronal signaling by modulating excitatory and inhibitory receptors and intracellular signaling proteins. Consequently, neurons that release zinc have been implicated in synaptic plasticity underlying learning and memory as well as neuropathological processes such as epilepsy, stroke, and Alzheimer's disease. To characterize the distribution of these neurons, investigators have relied on a technique that involves the retrograde transport of zinc-selenium crystals from axonal boutons to the cell bodies of origin. However, one major problem with this method is that labeling of cell bodies is obscured by high levels of staining in synaptic boutons, particularly within forebrain structures where this staining is most intense. Here, we used a modification of the retrograde labeling method that eliminates terminal staining for zinc, thereby enabling a clear and comprehensive description of these neurons. Zincergic neurons were found in all cerebral cortical regions and were arranged in a distinct laminar pattern, restricted to layers 2/3, 5, and 6 with no labeling in layer 4. In the hippocampus, labeling was present in CA1, CA3, and the dentate gyrus but not in CA2. Labeled cell bodies were also observed in most amygdaloid nuclei, anterior olfactory nuclei, claustrum, tenia tecta, endopiriform region, lateral ventricle, lateral septum, zona incerta, superior colliculus, and periaqueductal gray. Moreover, retrograde labeling was also noted in the dorsomedial and lateral hypothalamus, regions that previously were thought to be devoid of neurons with a zincergic phenotype. Collectively these data show that zincergic neurons comprise a large population of neurons in the murine forebrain and will provide an anatomical framework for understanding the functional importance of these neurons in the mammalian brain.

Day–night variations in zinc sensitivity of GABAA receptor-channels in rat suprachiasmatic nucleus

In the suprachiasmatic nucleus (SCN), electrical activity, secretion, and other cellular functions undergo profound rhythm during day-night cycle due to oscillatory expression of clock gene constituents. Although SCN is enriched with gamma-aminobutyric acid (GABA)-ergic neurons, it is unknown whether there are circadian changes in the GABAA receptor expression and/or function. Here we investigated the possible daily variations in zinc sensitivity of GABAA channels in rat SCN neurons maintained in brain slices. Extracellular zinc inhibited GABA-induced currents in all ventrolateral (VL) and dorsomedial (DM) SCN neurons studied, as well as in neurons of non-SCN regions. In SCN neurons, the currents evoked by 30 microM GABA were inhibited by Zn2+ with an IC50 of 50.3+/-3.2 microM, whereas currents evoked by 100 microM GABA were inhibited with an IC50 of 181.6+/-32.0 microM. The antagonist action of zinc saturated at 97.4+/-0.7% for 30 microM GABA and 91.6+/-2.7% for 100 microM GABA. These observations indicate that Zn2+ inhibits SCN GABAA receptor competitively and in part non-competitively. In SCN neurons, but not in other neurons, the zinc sensitivity varied with daily time. During the day, the calculated IC50 for zinc was significantly lower than during the night (43.9+/-4.7 microM vs. 58.6+/-3.8, respectively). These results indicate that native GABAA receptors in SCN neurons display pharmacological properties of receptors having and not having gamma subunit and that the proportionality of these receptors could change during the day and night.

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-induced changes in ionic currents of clonal rat pancreatic -cells: activation of ATP-sensitive K+ channels

The effects of zinc (Zn2+) on excitability and ionic conductances were analysed on RINm5F insulinoma cells under whole-cell and outside-out patch-clamp recording conditions. We found that extracellular application of 10-20 microM Zn2+ induced a reversible abolition of Ca2+ action potential firing, which was accompanied by an hyperpolarisation of the resting membrane potential. Higher concentrations of Zn2+, in the tens to hundreds micromolar range, induced a reversible reduction of voltage-gated Ca2+ and, to a lesser extent, K+ currents. Low-voltage-activated Ca2+ currents were more sensitive to Zn2+ block than high voltage-activated Ca2+ currents. The Zn2+-induced hyperpolarisation arose from a dose-dependent increase in a voltage-independent K+ conductance that was pharmacologically identified as an ATP-sensitive K+ (KATP) conductance. The effect was rapid in onset, readily reversible, voltage independent, and related to intracellular ATP concentration. In the presence of 1 mM intracellular ATP, half-maximal activation of KATP channels was obtained with extracellular application of 1.7 microM Zn2+. Single channel analysis revealed that extracellular Zn2+ increased the KATP channel open-state probability with no change in the single channel conductance. Our data support the hypothesis that Zn2+ binding to KATP protein subunits results in an activation of the channels, therefore regulating the resting membrane potential and decreasing the excitability of RINm5F cells. Taken together, our results suggest that Zn2+ can influence insulin secretion in pancreatic beta-cells through a negative feedback loop, involving both KATP and voltage-gated conductances.

Zinc increases the excitability of dopaminergic neurons in rat substantia nigra

The effect of zinc ions (Zn(2+)) on the neuronal excitability of substantia nigra (SN) where the zinc level is known higher in Parkinsonian brains than that in normal brains has not yet been elucidated. We, therefore, examined the effect of Zn(2+) on the intrinsic electrical properties of dopaminergic SN neurons, using a whole-cell recording method. Zn(2+) hyperpolarized dopaminergic SN neurons at resting state. Also Zn(2+) shortened the duration of evoked spikes, developed a fast afterhyperpolarization, and increased their firing frequency. Voltage-clamp studies showed that Zn(2+) decreased 4-aminopyridine-sensitive outward currents, suggesting that a transient A-like potassium channel be one of the major targets Zn(2+) can modulate in the SN neurons.

Zinc modulation of ionic currents in the horizontal limb of the diagonal band of Broca

We examined modulation of ionic currents by Zn2+ in acutely dissociated neurons from the rat's horizontal limb of the diagonal band of Broca using the whole-cell patch-clamp technique. Application of 50 microM Zn2+ increased the peak amplitude of the transiently activated potassium current, I(A) (at + 30 mV), from 2.20+/-0.08 to 2.57+/-0.11 nA (n = 27). This response was reversible and could be repeated in 0 Ca2+/1 microM tetrodotoxin (n = 15). Zn2+ shifted the inactivation curve to the right, resulting in a shift in the half-inactivation voltage from 76.4+/-2.2 to -53.4+/-2.0 mV (n = 11), with no effect on the voltage dependence of activation gating (n = 15). There was no significant difference in the time to peak under control conditions (7.43+/-0.35 ms, n = 14) and in the presence of Zn2+ (8.20+/-0.57 ms, n = 14). Similarly, the time constant of decay of I(A) (tau(d)) at + 30 mV showed no difference (control: 38.68+/-3.68 ms, n = 15; Zn2+: 38.48+/-2.85 ms, n = 15). I(A) was blocked by 0.5-1 mM 4-aminopyridine. In contrast to its effects on I(A), Zn2+ reduced the amplitude of the delayed rectifier potassium current (I(K)). The reduction of outward K+ currents was reproducible when cells were perfused with 1 microM tetrodotoxin in a 0 Ca2+ external solution. The amplitude of the steady-state outward currents at +30 mV under these conditions was reduced from 6.40+/-0.23 (control) to 5.76+/-0.18 nA in the presence of Zn2+ (n = 16). The amplitudes of peak sodium currents (INa) were not significantly influenced (n = 10), whereas barium currents (I(Ba)) passing through calcium channels were potently modulated. Zn2+ reversibly reduced I(Ba) at -10 mV by approximately 85% from -2.06+/-0.14 nA under control conditions to -0.30+/-0.10 nA in the presence of Zn2+ (n = 14). Further analyses of Zn2+ effects on specific calcium channels reveals that it suppresses all types of high-voltage-activated Ca2+ currents. Under current-clamp conditions, application of Zn2+ resulted in an increase in excitability and loss of accommodation (n = 13), which appears to be mediated through its effects on Ca2+-dependent conductances.

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.

Zinc and flunitrazepam modulation of GABA-mediated currents in rat suprachiasmatic neurons

The suprachiasmatic nucleus (SCN) of the hypothalamus is responsible for generating circadian rhythms in mammals, and GABA is the predominant neurotransmitter in the SCN. Properties of gamma-aminobutyric acid-A (GABAA) responses in SCN neurons were examined in acutely prepared hypothalamic slices from 3- to 8-wk-old rats with the use of whole cell voltage-clamp techniques. Zn2+ reduced the amplitude of GABAA-mediated spontaneous inhibitory postsynaptic currents (sIPSCs) in a concentration-dependent manner ranging from a reduction of control amplitude to 88% at 10 microM to 27% at 1,000 microM. Zn2+ reduced IPSC amplitude to a similar degree in the presence of tetrodotoxin and also significantly reduced the amplitude of currents evoked by application of exogenous GABA (100 microM, pressure applied). Zn2+ increased the frequency of IPSCs at lower concentrations and decreased it at higher ones. Flunitrazepam (100 nM) usually failed to potentiate the amplitude of sIPSCs, but prolonged sIPSC kinetics. Two exponential components were normally resolved in the sIPSC decay constants, and flunitrazepam significantly increased those two components. Thus flunitrazepam increased the duration of sIPSCs and potentiated the amplitude of currents evoked by pressure application of GABA. Zn2+ and benzodiazepine each modulated the effect of GABA in nearly all cells, suggesting that most SCN neurons have a similar GABAA receptor subunit composition in this respect. Zn2+ also affected sIPSC frequency, which suggests that Zn2+ increased neuronal firing rate at lower concentrations. These results begin to define the cellular roles that these GABAA receptor modulators might play in circadian regulation.

Modulation of transient outward current by extracellular protons and Cd2+ in rat and human ventricular myocytes

1. The effects of extracellular acidosis and Cd2+ on the transient outward current (Ito) have been investigated in rat and human ventricular myocytes, using the whole-cell patch-clamp technique. 2. In rat myocytes, exposure to acidic extracellular solution (pH 6.0) shifted both steady-state activation and inactivation curves to more positive potentials, by 20.5 +/- 2.7 mV (mean +/- S.E.M.; n = 4) and 19.8 +/- 1.2 mV, respectively. Cd2+ also shifted the activation and inactivation curves in a positive direction in a concentration-dependent manner. 3. In human myocytes, the steady-state activation and inactivation curves were located at more positive potentials. The effect of Cd2+ was similar, but acidosis had less effect than in rat myocytes (e.g. pH 6.0 shifted activation by only 7.2 +/- 2.2 mV and inactivation by 13.7 +/- 0.5 mV; n = 4). 4. In both species, the effect of acidosis decreased with increasing concentrations of Cd2+ and vice versa, suggesting competition between H+ and Cd2+ for a common binding site. 5. The data indicate that acidosis and divalent cations influence Ito via a similar mechanism and act competitively in both rat and human myocytes, but that human cells are less sensitive to the effects of acidosis.

The SCN is comprised of a population of coupled oscillators

The circadian clock in the suprachiasmatic nucleus (SCN) of the mammalian hypothalamus exhibits two necessary properties: (1) a mechanism for the generation of autonomous circadian rhythms in individual pacemaker cells, and (2) a means to synchronize the autonomous pacemaker cells. A variety of potential components of the endogenous pacemaker, including ion channels, second messengers, transcriptional factors, and the protein targets of kinases and transcription factors are reviewed. Similarly, reverse transmitter transport, extracellular ion fluxes, small membrane-diffusible molecules, glial regulation, and neural adhesion molecules are considered as possible synchronizing factors. Provisional criteria are suggested for empirical distinction of endogenous pacemaker versus synchronizing mechanisms.

Somatodendritic depolarization-activated potassium currents in rat neostriatal cholinergic interneurons are predominantly of the A type and attributable to coexpression of Kv4.2 and Kv4.1 subunits

Unlike other neostriatal neurons, cholinergic interneurons exhibit spontaneous, low-frequency, repetitive firing. To gain an understanding of the K+ channels regulating this behavior, acutely isolated adult rat cholinergic interneurons were studied using whole-cell voltage-clamp and single-cell reverse transcription-PCR techniques. Cholinergic interneurons were identified by the presence of choline acetyltransferase (ChAT) mRNA. Depolarization-activated potassium currents in cholinergic interneurons were dominated by a rapidly inactivating, K+-selective A current that became active at subthreshold potentials. Depolarizing prepulses inactivated this component of the current, leaving a delayed, rectifier-like current. Micromolar concentrations of Cd2+ dramatically shifted the voltage dependence of the A current without significantly affecting the delayed rectifier. The A-channel antagonist 4-aminopyridine (4-AP) produced a voltage-dependent block (IC50, approximately 1 mM) with a prominent crossover at millimolar concentrations. On the other hand, TEA preferentially blocked the sustained current component at concentrations <10 mM. Single-cell mRNA profiling of subunits known to give rise to rapidly inactivating K+ currents revealed the coexpression of Kv4.1, Kv4.2, and Kv1.4 mRNAs but low or undetectable levels of Kv4.3 and Kv3.4 mRNAs. Kv1.1, beta1, and beta2 subunit mRNAs, but not beta3, were also commonly detected. The inactivation recovery kinetics of the A-type current were found to match those of Kv4.2 and 4.1 channels and not those of Kv1.4 or Kv1. 1 and beta1 channels. Immunocytochemical analysis confirmed the presence of Kv4.2 but not Kv1.4 subunits in the somatodendritic membrane of ChAT-immunoreactive neurons. These results argue that the depolarization-activated somatodendritic K+ currents in cholinergic interneurons are dominated by Kv4.2- and Kv4. 1-containing channels. The properties of these channels are consistent with their playing a prominent role in governing the slow, repetitive discharge of interneurons seen in vivo.

Somatodendritic depolarization-activated potassium currents in rat neostriatal cholinergic interneurons are predominantly of the A type and attributable to coexpression of Kv4.2 and Kv4.1 subunits

Unlike other neostriatal neurons, cholinergic interneurons exhibit spontaneous, low-frequency, repetitive firing. To gain an understanding of the K+ channels regulating this behavior, acutely isolated adult rat cholinergic interneurons were studied using whole-cell voltage-clamp and single-cell reverse transcription-PCR techniques. Cholinergic interneurons were identified by the presence of choline acetyltransferase (ChAT) mRNA. Depolarization-activated potassium currents in cholinergic interneurons were dominated by a rapidly inactivating, K+-selective A current that became active at subthreshold potentials. Depolarizing prepulses inactivated this component of the current, leaving a delayed, rectifier-like current. Micromolar concentrations of Cd2+ dramatically shifted the voltage dependence of the A current without significantly affecting the delayed rectifier. The A-channel antagonist 4-aminopyridine (4-AP) produced a voltage-dependent block (IC50, approximately 1 mM) with a prominent crossover at millimolar concentrations. On the other hand, TEA preferentially blocked the sustained current component at concentrations <10 mM. Single-cell mRNA profiling of subunits known to give rise to rapidly inactivating K+ currents revealed the coexpression of Kv4.1, Kv4.2, and Kv1.4 mRNAs but low or undetectable levels of Kv4.3 and Kv3.4 mRNAs. Kv1.1, beta1, and beta2 subunit mRNAs, but not beta3, were also commonly detected. The inactivation recovery kinetics of the A-type current were found to match those of Kv4.2 and 4.1 channels and not those of Kv1.4 or Kv1. 1 and beta1 channels. Immunocytochemical analysis confirmed the presence of Kv4.2 but not Kv1.4 subunits in the somatodendritic membrane of ChAT-immunoreactive neurons. These results argue that the depolarization-activated somatodendritic K+ currents in cholinergic interneurons are dominated by Kv4.2- and Kv4. 1-containing channels. The properties of these channels are consistent with their playing a prominent role in governing the slow, repetitive discharge of interneurons seen in vivo.

Zinc and brain injury

Zinc is an essential catalytic or structural element of many proteins, and a signaling messenger that is released by neural activity at many central excitatory synapses. Growing evidence suggests that zinc may also be a key mediator and modulator of the neuronal death associated with transient global ischemia and sustained seizures, as well as perhaps other neurological disease states. Manipulations aimed at reducing extracellular zinc accumulation, or cellular vulnerability to toxic zinc exposure, may provide a novel therapeutic approach toward ameliorating pathological neuronal death in these settings.

The galvanization of biology: a growing appreciation for the roles of zinc

Zinc ions are key structural components of a large number of proteins. The binding of zinc stabilizes the folded conformations of domains so that they may facilitate interactions between the proteins and other macromolecules such as DNA. The modular nature of some of these zinc-containing proteins has allowed the rational design of site-specific DNA binding proteins. The ability of zinc to be bound specifically within a range of tetrahedral sites appears to be responsible for the evolution of the side range of zinc-stabilized structural domains now known to exist. The lack of redox activity for the zinc ion and its binding and exchange kinetics also may be important in the use of zinc for specific functional roles.

A rapidly activating type of outward rectifier K+ current and A-current in rat suprachiasmatic nucleus neurones

1. The properties of calcium-independent (i.e. persisting in the absence of external calcium) depolarization-activated potassium currents in suprachiasmatic nucleus (SCN) neurones (n = 75) were studied under voltage-clamp conditions with whole-cell patch-clamp recordings in rat hypothalamic slices (150-175 microns). 2. Two distinct types of potassium currents were found. One was a rapidly activating and slowly inactivating type of outward rectifier (named IK(FR) for fast rectifier potassium current), similar to a potassium current described in cardiac muscle, and the other was a transient A-current (IA). 3. The rates of activation and deactivation of IK(FR) were voltage dependent. Time constants of activation fitted to n4 kinetics and declined from 3.5 ms (at -20 mV) to 1.1 ms (at 60 mV). Inactivation had a biexponential time course with voltage-independent time constants of 0.3 s (minor component) and 3.0 s (major component) between 10 and 50 mV. IK(FR) was activated above -40 mV with a V1/2 (membrane potential at half-maximal activation) of 14 +/- 2 mV and slope factor of -17 +/- 1 mV reaching a conductance (not maximal) of 10.8 +/- 1.7 nS at 60 mV. Steady-state inactivation had a slope factor of 11 +/- 1 mV. 4. IK(FR) was highly selective for K+ (PNa/PK = 0.002). Tetraethylammonium (TEA) reduced IK(FR) reversibly (IC50 = 20 mM), while 4-aminopyridine (4-AP) at 10 mM had little effect. The remaining current in 30 mM TEA was similar to that in control conditions, indicating that TEA reduced IK(FR) rather than revealed an additional TEA-resistant current. 5. The rate of IA activation was voltage dependent with time to peak declining from 8.5 ms (at -40 mV) to 3.6 ms (at 60 mV). Inactivation had a biexponential time course with voltage-dependent and voltage-independent time constants. The two components were similar in amplitude. IA was activated above -60 mV, reaching a maximal conductance of 3.6 +/- 0.4 nS at above 20 mV. Steady-state inactivation was complete above -10 mV. Rates of onset of inactivation (at -40 mV) and recovery from inactivation (at -100 mV) were similar with time constants of 39 +/- 5 and 41 +/- 9 ms, respectively. 6. IK(FR) and IA were found in every neurone tested in the SCN and in all locations throughout the nucleus. The possible function of these currents is discussed, particularly in relation to the circadian rhythm of firing rate in the SCN.

Zinc potentiation of neurotransmission and inhibition of background cationic conductance in rat cultured hippocampal neurones

1. The facilitation by zinc (Zn2+) of neurotransmission and the mechanisms underlying it were electrophysiologically investigated in rat cultured hippocampal neurones using whole-cell voltage- and current-clamp techniques. 2. Under whole-cell voltage clamp with an intracellular solution containing CsCl as a major salt, inward postsynaptic currents were observed at -40 mV in a cell culture where a neuronal network had been formed. The postsynaptic currents appeared to be mediated by gamma-aminobutyric acid (GABA) because the inward currents were abolished when intracellular CsCl was replaced with caesium phosphate and they were blocked by bicuculline (10 microM), an antagonist to GABA-gated channels. The currents were, however, also blocked by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 30 microM), an antagonist to non-NMDA glutamate-gated channels, suggesting a contribution of a glutamatergic mechanism to the generation of the currents. Zn2+ (10 and 100 microM) potentiated the postsynaptic currents. 3. In addition to the potentiation of the postsynaptic currents, Zn2+ shifted net membrane current at -60 mV in an outward direction. The current-voltage relationship obtained under various ionic conditions indicated that Zn2+ inhibits a current component which is mainly carried by extracellular Na+. 4. Under whole-cell current clamp, Zn2+ (10 microM) induced a small hyperpolarization (up to 20 mV), which was accompanied by potentiation of the postsynaptic potentials and spike potentials. Tests were carried out to examine whether changes in resting potential by different protocols mimic responses observed with Zn2+. Hyperpolarization induced by current injection through patch pipettes increased the amplitude of postsynaptic currents, but did not enhance the appearance of spike potentials. In contrast, when extracellular K+ concentration was decreased from 5 to 2.5 mM, cells were hyperpolarized and spike potentials of large amplitude appeared. 5. The results suggest that Zn2+ potentiates neurotransmission and inhibits a background cationic current mainly carried by extracellular Na+ under physiological conditions. The inhibition of the Na+ permeation may increase membrane excitability and thereby contribute to the potentiation of neurotransmission.

Differential effects of sulfhydryl reagents on saxitoxin and tetrodotoxin block of voltage-dependent Na channels

We have probed a cysteine residue that confers resistance to tetrodotoxin (TTX) block in heart Na channels, with membrane-impermeant, cysteine-specific, methanethiosulfonate (MTS) analogs. Covalent addition of a positively charged group to the cysteinyl sulfhydryl reduced pore conductance by 87%. The effect was selectively prevented by treatment with TTX, but not saxitoxin (STX). Addition of a negatively charged group selectively inhibited STX block without affecting TTX block. These results agree with models that place an exposed cysteinyl sulfhydryl in the TTX site adjacent to the mouth of the pore, but do not support the contention that STX and TTX are interchangeable. The surprising differences between the two toxins are consistent with the hypothesis that the toxin-receptor complex can assume different conformations when STX or TTX bound.

Modulation of the gating of the transient outward potassium current of rat isolated cerebellar granule neurons by lanthanum

The effects of the trivalent cation, lanthanum (La3+) on voltage-dependent K+ conductances were studied in rat isolated cerebellar granule neurons under whole-cell voltage-clamp conditions. La3+ at low micromolar concentrations caused a pronounced enhancement in the outward current evoked by depolarising steps from -50 mV, with the apparent recruitment of an inactivating component. The steady-state inactivation curve for the transient outward current, evoked by depolarising steps from -140 mV, was shifted by approximately 40 mV in the depolarising direction by 10 microM La3+, with a slight increase in the slope factor. The kinetics of activation and inactivation were slowed in the presence of La3+. A shift of 10 mV in the depolarising direction was seen for the activation curve of the delayed rectifier current in the presence of 10 microM La3+. These results indicate that La3+ has a potent effect on the gating characteristics of voltage-activated K+ currents. This effect cannot be explained by surface charge considerations.