Inositol 1,4,5-trisphosphate-induced Ca2+ release is regulated by cytosolic Ca2+ in intact skeletal muscle

Microinjection of inositol 1,4,5-trisphosphate (InsP ₃) into intact skeletal muscle fibers isolated from frogs (Rana temporaria) increased resting cytosolic Ca²⁺ concentration ([Ca²⁺]_i) as measured by double-barreled Ca²⁺-selective microelectrodes. In contrast, microinjection of inositol 1-phosphate, inositol 1,4-biphosphate, and inositol 1,4,5,6-tetrakisphosphate did not induce changes in [Ca²⁺]_i. Incubation in low-Ca²⁺ solution, or in the presence of L-type Ca²⁺ channel blockers did not affect InsP ₃-induced release of cytosolic Ca²⁺. Neither ruthenium red, a blocker of ryanodine receptor Ca²⁺-release channels, nor cytosolic Mg²⁺, a known inhibitor of the Ca²⁺-induced Ca²⁺-release process, modified the InsP ₃-induced release of cytosolic Ca²⁺. However, heparin, a blocker of InsP ₃ receptors, inhibited InsP ₃-induced release of cytosolic Ca²⁺. Also, pretreatment with dantrolene or azumulene, two inhibitors of cytosolic Ca²⁺ release, reduced [Ca²⁺]_i, and prevented InsP ₃ from inducing release of cytosolic Ca²⁺. Incubation in caffeine or lengthening of the muscle increased [Ca²⁺]_i and enhanced the ability of InsP ₃ to induce release of cytosolic Ca²⁺. These results indicate that InsP ₃, at physiological concentrations, induces Ca²⁺ release in intact muscle fibers, and suggest that the InsP ₃-induced Ca²⁺ release is regulated by [Ca²⁺]_i. A Ca²⁺-dependent effect of InsP ₃ on cytosolic Ca²⁺ release could be of importance under physiological or pathophysiological conditions associated with alterations in cytosolic Ca²⁺ homeostasis. Received: 15 December 1995/Received after revision and accepted: 10 May 1996     

Localized IP3-evoked Ca2+ release activates a K+ current in primary vagal sensory neurons

Electrophysiological and microfluorimetric techniques were used to determine whether intracellular photorelease of caged IP(3), and the consequent release of Ca(2+), could trigger a Ca(2+)-activated K(+) current (I(IP3)). Photorelease of caged IP(3) evoked an I(IP3) that averaged 2.36 +/- 0.35 (SE) pA/pF in 24 of 28 rabbit primary vagal sensory neurons (nodose ganglion neurons, NGNs) voltage-clamped at -50 mV. I(IP3) was abolished by intracellular BAPTA (2 mM), a Ca(2+) chelator. Changing the K(+) equilibrium potential by increasing extracellular K(+) ion concentration caused a predicted Nernstian shift in the reversal potential of I(IP3). These results indicated that I(IP3) was a Ca(2+)-dependent K(+) current. I(IP3) was unaffected by three common antagonists of Ca(2+)-activated K(+) currents: bath-applied iberiotoxin (50 nM) or apamin (100 nM), and intracellular 8-Br-cAMP (100 microM) included in the patch pipette. We have previously demonstrated that both IP(3)-evoked Ca(2+) release and Ca(2+)-induced Ca(2+) release (CICR) are co-expressed in NGNs and that CICR can trigger a Ca(2+)-activated K(+) current. In the present study, using caffeine, a CICR agonist, to selectively attenuate intracellular Ca(2+) stores, we showed that IP(3)-evoked Ca(2+) release occurs independently of CICR, but interestingly, that a component of I(IP3) requires CICR. These data suggest that IP(3)-evoked Ca(2+) release activates a K(+) current that is pharmacologically distinct from other Ca(2+)-activated K(+) currents in NGNs. We describe several models that explain our results based on Ca(2+) signaling microdomains in NGNs.     

Tracking presynaptic Ca2+ dynamics during neurotransmitter release with Ca2+-activated K+ channels

Neurotransmitter release during action potentials is thought to require transient, localized [Ca2+]i as high as hundreds of micromolar near presynaptic release sites. Most experimental attempts to characterize the magnitude and time course of these Ca2+ domains involve optical methods that sample large volumes, require washout of endogenous buffers and often affect Ca2+ kinetics and transmitter release. Endogenous calcium-activated potassium (KCa) channels colocalize with presynaptic Ca2+ channels in Xenopus nerve-muscle cultures. We used these channels to quantify the rapid, dynamic changes in [Ca2+]i at active zones during synaptic activity. Confirming Ca2+-domain predictions, these KCa channels revealed [Ca2+]i over 100 microM during synaptic activity and much faster buildup and decay of Ca2+ domains than shown using other techniques.     

Blockade of SK-type Ca2+-activated K+ channels uncovers a Ca2+-dependent slow afterdepolarization in nigral dopamine neurons

Sharp electrode current-clamp recording techniques were used to characterize the response of nigral dopamine (DA)-containing neurons in rat brain slices to injected current pulses applied in the presence of TTX (2 microM) and under conditions in which apamin-sensitive Ca2+-activated K+ channels were blocked. Addition of apamin (100-300 nM) to perfusion solutions containing TTX blocked the pacemaker oscillation in membrane voltage evoked by depolarizing current pulses and revealed an afterdepolarization (ADP) that appeared as a shoulder on the falling phase of the voltage response. ADP were preceded by a ramp-shaped slow depolarization and followed by an apamin-insensitive hyperpolarizing afterpotential (HAP). Although ADPs were observed in all apamin-treated cells, the duration of the response varied considerably between individual neurons and was strongly potentiated by the addition of TEA (2-3 mM). In the presence of TTX, TEA, and apamin, optimal stimulus parameters (0.1 nA, 200-ms duration at -55 to -68 mV) evoked ADP ranging from 80 to 1,020 ms in duration (355.3 +/- 56.5 ms, n = 16). Both the ramp-shaped slow depolarization and the ensuing ADP were markedly voltage dependent but appeared to be mediated by separate conductance mechanisms. Thus, although bath application of nifedipine (10-30 microM) or low Ca2+, high Mg2+ Ringer blocked the ADP without affecting the ramp potential, equimolar substitution of Co2+ for Ca2+ blocked both components of the voltage response. Nominal Ca2+ Ringer containing Co2+ also blocked the HAP evoked between -55 and -68 mV. We conclude that the ADP elicited in DA neurons after blockade of apamin-sensitive Ca2+-activated K+ channels is mediated by a voltage-dependent, L-type Ca2+ channel and represents a transient form of the regenerative plateau oscillation in membrane potential previously shown to underlie apamin-induced bursting activity. These data provide further support for the notion that modulation of apamin-sensitive Ca2+-activated K+ channels in DA neurons exerts a permissive effect on the conductances that are involved in the expression of phasic activity.     

N-type Ca2+ channels carry the largest current: implications for nanodomains and transmitter release

Presynaptic terminals favor intermediate-conductance Ca(V)2.2 (N type) over high-conductance Ca(V)1 (L type) channels for single-channel, Ca(2+) nanodomain-triggered synaptic vesicle fusion. However, the standard Ca(V)1>Ca(V)2>Ca(V)3 conductance hierarchy is based on recordings using nonphysiological divalent ion concentrations. We found that, with physiological Ca(2+) gradients, the hierarchy was Ca(V)2.2>Ca(V)1>Ca(V)3. Mathematical modeling predicts that the Ca(V)2.2 Ca(2+) nanodomain, which is ～25% more extensive than that generated by Ca(V)1, can activate a calcium-fusion sensor located on the proximal face of the synaptic vesicle.     

A PKC epsilon-ENH-channel complex specifically modulates N-type Ca2+ channels

Multiple protein kinase C (PKC) isozymes are present in neurons, where they regulate a variety of cellular functions. Due to the lack of specific PKC isozyme inhibitors, it remains unknown how PKC acts on its selective target(s) and achieves its specific actions. Here we show that a PKC binding protein, enigma homolog (ENH), interacts specifically with both PKCepsilon and N-type Ca2+ channels, forming a PKCepsilon-ENH-Ca2+ channel macromolecular complex. Coexpression of ENH facilitated modulation of N-type Ca2+ channel activity by PKC. Disruption of the complex reduced the potentiation of the channel activity by PKC in neurons. Thus, ENH, by interacting specifically with both PKCepsilon and the N-type Ca2+ channel, targets a specific PKC to its substrate to form a functional signaling complex, which is the molecular mechanism for the specificity and efficiency of PKC signaling.     

ATP suppresses activity of Ca2+ -activated K+ channels by Ca2+ chelation

Ca²⁺-activated maxi K⁺ channels were studied in inside-out patches from smooth muscle cells isolated from either porcine coronary arteries or guinea-pig urinary bladder. As described by Groschner et al. (Pflügers Arch 417:517, 1990), channel activity (NP _o) was stimulated by 3 M [Ca²⁺]_c (1 mM Ca-EGTA adjusted to a calculated pCa of 5.5) and was suppressed by the addition of 1 mM Na₂ATP. The following results suggest that suppression of NP _o by Na₂ATP is due to Ca²⁺ chelation and hence reduction of [Ca²⁺]_c and reduced Ca²⁺ activation of the channel. The effect was absent when Mg ATP was used instead of Na₂ATP. The effect was diminished by increasing the [EGTA] from 1 to 10 mM. The effect was absent when [Ca²⁺]_c was buffered with 10 mM HDTA (apparent pK _Ca 5.58) instead of EGTA (pK _Ca 6.8). A Ca²⁺-sensitive electrode system indicated that 1 mM Na₂ATP reduced [Ca²⁺]_c in 1 mM Ca-EGTA from 3 M to 1.4 M. Na₂ATP, Na₂GTP, Li₄AMP-PNP and NaADP reduced measured [Ca²⁺]_c in parallel with their suppression of NP _o. After the Na₂ATP-induced reduction of [Ca²⁺]_c was re-adjusted by adding either CaCl₂ or MgCl₂, the effect of Na₂ATP on NP _o disappeared. In vivo, intracellular [Mg²⁺] exceeds free [ATP^4–], hence ATP modulation of maxi K⁺ channels due to Ca²⁺ chelation is without biological relevance.     

Inhibitory effect of pranidipine on N-type voltage-dependent Ca2+ channels in mice

We investigated the N-type voltage-dependent calcium channel blocking action of pranidipine, a novel dihydropyridine (DHP) derivative. Pranidipine significantly suppressed KCl-induced intracellular calcium changes ([Ca(2+)](i)) in a dose-dependent fashion in dorsal root ganglion neurons. A patch-clamp investigation revealed a dose-dependent blocking effect on N-type currents. Intrathecal injection of pranidipine significantly shortened the licking time in the late phase of the formalin test, as occurs with cilnidipine and amlodipine, which act on L- and N-type channels. Conversely, nicardipine, which acts exclusively on L-type channels, had no antinociceptive effect. Our results indicate that pranidipine inhibits N-type calcium channels. Furthermore, it exerts an antinociceptive effect, which might be related to an attenuation of synaptic transmission by nociceptive neurons due to the blocking effect of pranidipine on N-type calcium channels in primary nociceptive afferent fibers.     

Modulation of N-type Ca2+ channels by intracellular pH in chick sensory neurons

Both physiological and pathological neuronal events, many of which elevate intracellular [Ca2+], can produce changes in intracellular pH of between 0.15 and 0.5 U, between pH 7.4 and 6.8. N-type Ca2+ channels, which are intimately involved in exocytosis and other excitable cell processes, are sensitive to intracellular pH changes. However, the pH range over which N-type Ca2+ channels are sensitive, and the sensitivity of N-type Ca2+ channels to small changes in intracellular pH, are unknown. We studied the influence of intracellular pH changes on N-type calcium channel currents in dorsal root ganglion neurons, acutely isolated from 14-day-old chick embryos. Intracellular pH was monitored in patch-clamp recordings with the fluorescent dye, BCECF, and manipulated in both the acidic and basic direction by extracellular application of NH4+ in the presence and absence of intracellular NH4+. Changes in intracellular pH between 6.6 and 7.5 produced a graded change in Ca2+ current magnitude with no apparent shift in activation potential. Intracellular acidification from pH 7.3 to 7.0 reversibly inhibited Ca2+ currents by 40%. Acidification from pH 7.3 to pH 6.6 reversibly inhibited Ca2+ currents by 65%. Alkalinization from pH 7.3 to 7.5 potentiated Ca2+ currents by approximately 40%. Channels were sensitive to pHi changes with high intracellular concentrations of the Ca2+ chelator, bis-(o-aminophenoxy)-N,N,N',N'-tetraacetic acid, which indicates that the effects of pHi did not involve a Ca2+-dependent mechanism. These data indicate that N-type Ca2+ channel currents are extremely sensitive to small changes in pHi in the range produced by both physiological and pathological events. Furthermore, these data suggest that modulation of N-type Ca2+ channels by pHi may play an important role in physiological processes that produce small changes in pHi and a protective role in pathological mechanisms that produce larger changes in pHi.     

Effect of acetylcholine on single Ca2(+)-activated K+ channels in bovine chromaffin cells

The single channel current amplitudes of "maxi" Ca2(+)-activated K+ channels from bovine chromaffin cell membranes are reduced when acetylcholine is applied to the internal surface of the membrane, which can be explained by a fast channel block. The block is concentration dependent with moderate affinity. It becomes progressively greater with depolarization although the voltage dependence is not pronounced. Acetylcholine reduces the probability of the open state in the same concentration range and in an essentially voltage independent manner. The changes in the channel kinetics are complex. Whilst the long component of the open intervals is shortened (by 48%; from 9.5 to 5.1 ms), the long component of the closed intervals is prolonged (by 96%; from 45 to 89 ms). The short components (open and closed) are essentially unaffected. Short open intervals are reduced by 4% (from 1.09 to 1.05 ms), whilst short closed intervals are reduced by 5% (from 2.3 to 2.2 ms). These changes in the channel kinetics can be explained at least partly if one assumes that acetylcholine, in addition to its fast channel blocking activity, acts also as a slow blocker. If so, both binding sites are expected to be located close to the mouth of the channel pore. Alternatively, acetylcholine may be affecting the gating mechanism, presumably by interfering with the Ca2+ binding.     

Modulation of recombinant transient-receptor-potential-like (TRPL) channels by cytosolic Ca2+

Whole-cell current recordings were used to examine the involvement of intracellular Ca2+ in the modulation of recombinant transient-receptor-potential like (TRPL) channels of Drosophila photoreceptor cells. TRPL was stably transfected in Chinese hamster ovary (CHO) cells and the expression of a calmodulin-binding protein with a molecular mass that corresponded to TRPL was demonstrated using calmodulin overlays. In cells expressing TRPL, ionic currents that were prominently outwardly rectifying were detected prior to activation of intracellular signalling pathways. The outwardly rectifying currents reversed close to 0 mV and did not occur after removal of permeant cations from the intracellular space. This suggests that TRPL forms non-selective cationic channels that appear to be constitutively active in mammalian cell lines. The TRPL channel currents were enhanced by manoeuvres that activate the phospholipase C (PLC) signalling pathway. These included activation of membrane receptors by thrombin, activation of G proteins by cell dialysis with guanosine 5'-O-(3-thiotriphosphate) (GTP[gamma-S]) and release of Ca2+ from intracellular stores by dialysis with inositol 1,4,5-trisphosphate (IP3). After complete depletion of Ca2+ stores, IP3 had no effect on TRPL currents, suggesting that IP3 does not activate recombinant TRPL channels directly. However, thapsigargin, which induces a rise of cytosolic Ca2+, increased TRPL channel currents. Cell dialysis with solutions containing various concentrations of Ca2+ enhanced TRPL currents in a dose-dependent manner (EC50=450 nM Ca2+). Conversely, chelation of cytosolic Ca2+ abolished TRPL channel currents. The present results indicate that the activity of recombinant TRPL channels expressed in mammalian cell lines is up-regulated by a rise of cytosolic Ca2+.     

Maxi K+ channels in leaky epithelia are regulated by intracellular Ca2+, pH and membrane potential

We have studied a Ca²⁺-activated K⁺ channel in the ventricular membrane of the epithelium of choroid plexus by means of the patch-clamp technique, using excised inside-out patches. The channel was highly K⁺ selective. It had a conductance of 200 pS with 112 mM KCl on both sides of the membrane. The probability for the channel being open increased with intracellular Ca²⁺, pH and with membrane potential. The channel shows two gating modes. The primary gating mode has open and closed times which depend strongly on membrane potential, intracellular Ca²⁺ and pH. It accounts for the variation of the channel open probability. Lowering intracellular pH from 7.4 to 6.4 reduced the channel open probability mainly by increasing the channel closed time. It appears, that H⁺ can compete with Ca²⁺ in binding to the same site, thereby preventing channel opening. A second gating mode consisted of short-lived closures, or flickers. The open and closed time for this process were largely independent of membrane potential, intracellular Ca²⁺ and pH. The channel density was 0.4 m^–2 corresponding to a K⁺-permeability of 2.2 10^–5 cm s^–1 if the channels were fully open. In cell-attached patches we measured the open probability of the channel in the intact cell membrane. The channel is almost totally closed under normal cellular conditions. This type of channel is therefore not the membrane component that forms the electrodiffusive pathway for K⁺-ions.     

Small-conductance Ca2+-dependent K+ channels are the target of spike-induced Ca2+ release in a feedback regulation of pyramidal cell excitability

Cooperative regulation of inosiol-1,4,5-trisphosphate receptors (IP(3)Rs) by Ca(2+) and IP(3) has been increasingly recognized, although its functional significance is not clear. The present experiments first confirmed that depolarization-induced Ca(2+) influx triggers an outward current in visual cortex pyramidal cells in normal medium, which was mediated by apamin-sensitive, small-conductance Ca(2+)-dependent K(+) channels (SK channels). With IP(3)-mobilizing neurotransmitters bath-applied, a delayed outward current was evoked in addition to the initial outward current and was mediated again by SK channels. Calcium turnover underlying this biphasic SK channel activation was investigated. By voltage-clamp recording, Ca(2+) influx through voltage-dependent Ca(2+) channels (VDCCs) was shown to be responsible for activating the initial SK current, whereas the IP(3)R blocker heparin abolished the delayed component. High-speed Ca(2+) imaging revealed that a biphasic Ca(2+) elevation indeed underlays this dual activation of SK channels. The first Ca(2+) elevation originated from VDCCs, whereas the delayed phase was attributed to calcium release from IP(3)Rs. Such enhanced SK currents, activated dually by incoming and released calcium, were shown to intensify spike-frequency adaptation. We propose that spike-induced calcium release from IP(3)Rs leads to SK channel activation, thereby fine tuning membrane excitability in central neurons.     

Inhibition of K(+)-evoked glutamate release from rat neocortical and hippocampal slices by gabapentin

Gabapentin (Neurontin((R))) has preclinical and clinical efficacy as an anticonvulsant, antihyperalgesic, anxiolytic, and neuroprotective drug. Since L-glutamic acid (GLU) is involved in various CNS (central nervous system) disorders, gabapentin may attenuate the release of this neurotransmitter possibly by interacting with the auxiliary alpha(2)delta subunit of voltage-sensitive calcium channels (VSCC). The effects of gabapentin, pregabalin (S-(+)-3-isobutylgaba) and its enantiomer R-(-)-3-isobutylgaba, and N- and P/Q-type VSCC-targeting peptide ligands (omega-conotoxin MVIIA, omega-conotoxin MVIIC, omega-agatoxin TK) were assessed in vitro on K(+)-evoked (endogenous) GLU release from rat neocortical and hippocampal slices. Gabapentin and pregabalin decreased GLU release by 11-26% with R-(-)-3-isobutylgaba being less effective than pregabalin. The reference N- and P/Q-type VSCC-targeting ligands reduced GLU release by 19-55% to implicate these VSCC in this Ca(2+)-dependent process. The inhibitory effect of gabapentin and related compounds on GLU release may reflect a subtle modulation of VSCC function which normalizes pathological changes in neurotransmitter release.     

Ca2+ channels that activate Ca2+-dependent K+ currents in neostriatal neurons

It is demonstrated that not all voltage-gated calcium channel types expressed in neostriatal projection neurons (L, N, P, Q and R) contribute equally to the activation of calcium-dependent potassium currents. Previous work made clear that different calcium channel types contribute with a similar amount of current to whole-cell calcium current in neostriatal neurons. It has also been shown that spiny neurons posses both “big” and “small” types of calcium-dependent potassium currents and that activation of such currents relies on calcium entry through voltage-gated calcium channels. In the present work it was investigated whether all calcium channel types equally activate calcium-dependent potassium currents. Thus, the action of organic calcium channel antagonists was investigated on the calcium-activated outward current. Transient potassium currents were reduced by 4-aminopyridine and sodium currents were blocked by tetrodotoxin. It was found that neither 30 nM ω-Agatoxin-TK, a blocker of P-type channels, nor 200 nM calciseptine or 5 μM nitrendipine, blockers of L-type channels, were able to significantly reduce the outward current. In contrast, 400 nM ω-Agatoxin-TK, which at this concentration is able to block Q-type channels, and 1 μM ω-Conotoxin GVIA, a blocker of N-type channels, both reduced outward current by about 50%. These antagonists given together, or 500 nM ω-Conotoxin MVIIC, a blocker of N- and P/Q-type channels, reduced outward current by 70%. In addition, the N- and P/Q-type channel blockers preferentially reduce the afterhyperpolarization recorded intracellularly.The results show that calcium-dependent potassium channels in neostriatal neurons are preferentially activated by calcium entry through N- and Q-type channels in these conditions.     

Ca2+ channels,ryanodine receptors and Ca2+-activated K+ channels: a functional unit for regulating arterial tone

Local calcium transients (‘Ca²⁺ sparks’) are thought to be elementary Ca²⁺ signals in heart, skeletal and smooth muscle cells. Ca²⁺ sparks result from the opening of a single, or the coordinated opening of many, tightly clustered ryanodine receptor (RyR) channels in the sarcoplasmic reticulum (SR). In arterial smooth muscle, Ca²⁺ sparks appear to be involved in opposing the tonic contraction of the blood vessel. Intravascular pressure causes a graded membrane potential depolarization to approximately ?40 mV, an elevation of arterial wall [Ca²⁺]_i and contraction (‘myogenic tone’) of arteries. Ca²⁺ sparks activate calcium-sensitive K⁺ (K_Ca) channels in the sarcolemmal membrane to cause membrane hyperpolarization, which opposes the pressure induced depolarization. Thus, inhibition of Ca²⁺ sparks by ryanodine, or of K_Ca channels by iberiotoxin, leads to membrane depolarization, activation of L -type voltage-gated Ca²⁺ channels, and vasoconstriction. Conversely, activation of Ca²⁺ sparks can lead to vasodilation through activation of K_Ca channels. Our recent work is aimed at studying the properties and roles of Ca²⁺ sparks in the regulation of arterial smooth muscle function. The modulation of Ca²⁺ spark frequency and amplitude by membrane potential, cyclic nucleotides and protein kinase C will be explored. The role of local Ca²⁺ entry through voltage-dependent Ca²⁺ channels in the regulation of Ca²⁺ spark properties will also be examined. Finally, using functional evidence from cardiac myocytes, and histological evidence from smooth muscle, we shall explore whether Ca²⁺ channels, RyR channels, and K_Ca channels function as a coupled unit, through Ca²⁺ and voltage, to regulate arterial smooth muscle membrane potential and vascular tone.     

Ca2+ channels that activate Ca2+-dependent K+ currents in neostriatal neurons

It is demonstrated that not all voltage-gated calcium channel types expressed in neostriatal projection neurons (L, N, P, Q and R) contribute equally to the activation of calcium-dependent potassium currents. Previous work made clear that different calcium channel types contribute with a similar amount of current to whole-cell calcium current in neostriatal neurons. It has also been shown that spiny neurons possess both "big" and "small" types of calcium-dependent potassium currents and that activation of such currents relies on calcium entry through voltage-gated calcium channels. In the present work it was investigated whether all calcium channel types equally activate calcium-dependent potassium currents. Thus, the action of organic calcium channel antagonists was investigated on the calcium-activated outward current. Transient potassium currents were reduced by 4-aminopyridine and sodium currents were blocked by tetrodotoxin. It was found that neither 30 nM omega-Agatoxin-TK, a blocker of P-type channels, nor 200 nM calciseptine or 5 microM nitrendipine, blockers of L-type channels, were able to significantly reduce the outward current. In contrast, 400 nM omega-Agatoxin-TK, which at this concentration is able to block Q-type channels, and 1 microM omega-Conotoxin GVIA, a blocker of N-type channels, both reduced outward current by about 50%. These antagonists given together, or 500 nM omega-Conotoxin MVIIC, a blocker of N- and P/Q-type channels, reduced outward current by 70%. In addition, the N- and P/Q-type channel blockers preferentially reduce the afterhyperpolarization recorded intracellularly. The results show that calcium-dependent potassium channels in neostriatal neurons are preferentially activated by calcium entry through N- and Q-type channels in these conditions.     

Voltage-activated ion channels and Ca2+-induced Ca2+ release shape Ca2+ signaling in Merkel cells

Ca²⁺ signaling and neurotransmission modulate touch-evoked responses in Merkel cell–neurite complexes. To identify mechanisms governing these processes, we analyzed voltage-activated ion channels and Ca²⁺ signaling in purified Merkel cells. Merkel cells in the intact skin were specifically labeled by antibodies against voltage-activated Ca²⁺ channels (Ca_V2.1) and voltage- and Ca²⁺-activated K⁺ (BK_Ca) channels. Voltage-clamp recordings revealed small Ca²⁺ currents, which produced Ca²⁺ transients that were amplified sevenfold by Ca²⁺-induced Ca²⁺ release. Merkel cells’ voltage-activated K⁺ currents were carried predominantly by BK_Ca channels with inactivating and non-inactivating components. Thus, Merkel cells, like hair cells, have functionally diverse BK_Ca channels. Finally, blocking K⁺ channels increased response magnitude and dramatically shortened Ca²⁺ transients evoked by mechanical stimulation. Together, these results demonstrate that Ca²⁺ signaling in Merkel cells is governed by the interplay of plasma membrane Ca²⁺ channels, store release and K⁺ channels, and they identify specific signaling mechanisms that may control touch sensitivity.     

Ca2+ influx induced by store release and cytosolic Ca2+ chelation in HT29 colonic carcinoma cells

Cl^– secretion in HT₂₉ cells is regulated by agonists such as carbachol, neurotensin and adenosine 5-triphosphate (ATP). These agonists induce Ca²⁺ store release as well as Ca²⁺ influx from the extracellular space. The increase in cytosolic Ca²⁺ enhances the Cl^– and K⁺ conductances of these cells. Removal of extracellular Ca²⁺ strongly attenuates the secretory response to the above-mentioned agonists. The present study utilises patch-clamp methods to characterise the Ca²⁺ influx pathway. Inhibitors which have been shown previously to inhibit non-selective cation channels, such as flufenamate (0.1 mmol·l^–1, n=6) and Gd³⁺ (10 mol·l^–1, n=6) inhibited ATP (0.1 mmol·l^–1) induced increases in whole-cell conductance (G _m). When Cl^– and K⁺ currents were inhibited by the presence of Cs₂SO₄ in the patch pipette and gluconate in the bath, ATP (0.1 mmol·l^–1) still induced a significant increase in G _m from 1.2±0.3 nS to 4.7±1 nS (n=24). This suggests that ATP induces a cation influx with a conductance of approximately 3–4 nS. This cation influx was inhibited by flufenamate (0.1 mmol·l^–1, n=6) and Gd³⁺ (10 mol·l^–1, n=9). When Ba²⁺ (5 mmol·l^–1) and 4,4-diisothiocyanatostilbene-2-2-disulphonic acid (DIDS, 0.1 mmol·l^–1) were added to the KCl/K-gluconate pipette solution to inhibit K⁺ and Cl^– currents and the cells were clamped to depolarised voltages, ATP (0.1 mmol·l^–1) reduced the membrane current (I _m) significantly from 86±14 pA to 54±11 pA (n=13), unmasking a cation inward current. In another series, the cation inward current was activated by dialysing the cell with a KCl/K-gluconate solution containing 5–10 mmol·l^–1 1,2-bis-(2-aminoethoxy)ethane-N,N,N,N-tetraacetic acid (EGTA) or 1,2-bis-(2-aminophenoxy) ethane-N,N,N,N-tetraacetic acid (BAPTA). The zero-current membrane voltage (V _m) and I _m (at a clamp voltage of +10 mV) were monitored as a function of time. A new steady-state was reached 30–120 s after membrane rupture. V _m depolarised significantly from –33±2 mV to –12±1 mV, and I _m fell significantly from 17±2 pA to 8.9±1.0 pA (n=71). This negative current, representing a cation inward current, was activated when Ca²⁺ stores were emptied and was reduced significantly (I _m) when Ca²⁺ and/or Na⁺ were removed from the bathing solution: removal of Ca²⁺ in the absence of Na⁺ caused a I _m of 5.0±1.2 pA (n=12); removal of Na⁺ in the absence of Ca²⁺ caused a I _m of 12.8±3.5 pA (n=4). The cation inward current was also reduced significantly by La³⁺, Gd³⁺, and flufenamate. We conclude that store depletion induces a Ca²⁺/Na⁺ influx current in these cells. With 145 mmol·l^–1 Na⁺ and 1 mmol·l^–1 Ca²⁺, both ions contribute to this cation inward current. This current is an important component in the agonist-regulated secretory response.