A Ca2+-inhibited non-selective cation conductance contributes to pacemaker currents in mouse interstitial cell of Cajal

Interstitial cells of Cajal (ICC) provide pacemaker activity in some smooth muscles. The nature of the pacemaker conductance is unclear, but studies suggest that pacemaker activity is due to a voltage-independent, Ca²⁺-regulated, non-selective cation conductance. We investigated Ca²⁺-regulated conductances in murine intestinal ICC and found that reducing cytoplasmic Ca²⁺ activates whole-cell inward currents and single-channel currents. Both the whole-cell currents and single-channel currents reversed at 0 mV when the equilibrium potentials of all ions present were far from 0 mV. Recordings from on-cell patches revealed oscillations in unitary currents at the frequency of pacemaker currents in ICC. Voltage-clamping cells to −60 mV did not change the oscillatory activity of channels in on-cell patches. Depolarizing cells with high external K⁺ caused loss of resolvable single-channel currents, but the oscillatory single-channel currents were restored when the patches were stepped to negative potentials. Unitary currents were also resolved in excised patches. The single-channel conductance was 13 pS, and currents reversed at 0 mV. The channels responsible were strongly activated by 10⁻⁷ m Ca²⁺, and 10⁻⁶ m Ca²⁺ reduced activity. The 13 pS channels were strongly activated by the calmodulin inhibitors calmidazolium and W-7 in on-cell and excised patches. Calmidazolium and W-7 also activated a persistent inward current under whole-cell conditions. Murine ICC express Ca²⁺-inhibited, non-selective cation channels that are periodically activated at the same frequency as pacemaker currents. This conductance may contribute to the pacemaker current and generation of electrical slow waves in GI muscles.     

Propagation of slow waves requires IP3 receptors and mitochondrial Ca2+ uptake in canine colonic muscles

In the gastrointestinal (GI) tract electrical slow waves yield oscillations in membrane potential that periodically increase the open probability of voltage-dependent Ca²⁺ channels and facilitate phasic contractions. Slow waves are generated by the interstitial cells of Cajal (ICC), and these events actively propagate through ICC networks within the walls of GI organs. The mechanism that entrains spontaneously active pacemaker sites throughout ICC networks to produce regenerative propagation of slow waves is unresolved. Agents that block inositol 1,4,5-trisphosphate (IP₃) receptors and mitochondrial Ca²⁺ uptake were tested on the generation of slow waves in the canine colon. A partitioned chamber apparatus was used to test the effects of blocking slow-wave generation on propagation. We found that active propagation occurred along strips of colonic muscle, but when the pacemaker mechanism was blocked in a portion of the tissue, slow waves decayed exponentially from the point where the pacemaker mechanism was inhibited. An IP₃ receptor inhibitor, mitochondrial inhibitors, low external Ca²⁺, and divalent cations (Mn²⁺ and Ni²⁺) caused exponential decay of the slow waves in regions of muscle exposed to these agents. These data demonstrate that the mechanism that initiates slow waves is reactivated from cell-to-cell during the propagation of slow waves. Voltage-dependent conductances present in smooth muscle cells are incapable of slow-wave regeneration. The data predict that partial loss of or disruptions to ICC networks observed in human motility disorders could lead to incomplete penetration of slow waves through GI organs and, thus, to defects in myogenic regulation.     

Functional characterization of a Ca2+-activated non-selective cation channel in human atrial cardiomyocytes

Cardiac arrhythmias, which occur in a wide variety of conditions where intracellular calcium is increased, have been attributed to the activation of a transient inward current ( I _ti). I _ti is the result of three different [Ca]_i-sensitive currents: the Na⁺–Ca²⁺ exchange current, a Ca²⁺-activated chloride current and a Ca²⁺-activated non-selective cationic current. Using the cell-free configuration of the patch-clamp technique, we have characterized the properties of a Ca²⁺-activated non-selective cation channel (NSC_Ca) in freshly dissociated human atrial cardiomyocytes. In excised inside-out patches, the channel presented a linear I–V relationship with a conductance of 19 ± 0.4 pS. It discriminated poorly among monovalent cations (Na⁺ and K⁺) and was slightly permeable to Ca²⁺ ions. The channel's open probability was increased by depolarization and a rise in internal calcium, for which the K _d for [Ca²⁺]_i was 20.8 μ m . Channel activity was reduced in the presence of 0.5 m m ATP or 10 μ m glibenclamide on the cytoplasmic side to 22.1 ± 16.8 and 28.5 ± 8.6%, respectively, of control. It was also inhibited by 0.1 m m flufenamic acid. The channel shares several properties with TRPM4b and TRPM5, two members of the 'TRP melastatin' subfamily. In conclusion, the NSC_Ca channel is a serious candidate to support the delayed after-depolarizations observed in [Ca²⁺] overload and thus may be implicated in the genesis of arrhythmias.     

Calcium-activated chloride currents in olfactory sensory neurons from mice lacking bestrophin-2

Olfactory sensory neurons use a chloride-based signal amplification mechanism to detect odorants. The binding of odorants to receptors in the cilia of olfactory sensory neurons activates a transduction cascade that involves the opening of cyclic nucleotide-gated channels and the entry of Ca²⁺ into the cilia. Ca²⁺ activates a Cl⁻ current that produces an efflux of Cl⁻ ions and amplifies the depolarization. The molecular identity of Ca²⁺-activated Cl⁻ channels is still elusive, although some bestrophins have been shown to function as Ca²⁺-activated Cl⁻ channels when expressed in heterologous systems. In the olfactory epithelium, bestrophin-2 (Best2) has been indicated as a candidate for being a molecular component of the olfactory Ca²⁺-activated Cl⁻ channel. In this study, we have analysed mice lacking Best2. We compared the electrophysiological responses of the olfactory epithelium to odorant stimulation, as well as the properties of Ca²⁺-activated Cl⁻ currents in wild-type (WT) and knockout (KO) mice for Best2. Our results confirm that Best2 is expressed in the cilia of olfactory sensory neurons, while odorant responses and Ca²⁺-activated Cl⁻ currents were not significantly different between WT and KO mice. Thus, Best2 does not appear to be the main molecular component of the olfactory channel. Further studies are required to determine the function of Best2 in the cilia of olfactory sensory neurons.     

Ca2+-activated K+ (BK) channel inactivation contributes to spike broadening during repetitive firing in the rat lateral amygdala

In many neurons, trains of action potentials show frequency-dependent broadening. This broadening results from the voltage-dependent inactivation of K⁺ currents that contribute to action potential repolarisation. In different neuronal cell types these K⁺ currents have been shown to be either slowly inactivating delayed rectifier type currents or rapidly inactivating A-type voltage-gated K⁺ currents. Recent findings show that inactivation of a Ca²⁺-dependent K⁺ current, mediated by large conductance BK-type channels, also contributes to spike broadening. Here, using whole-cell recordings in acute slices, we examine spike broadening in lateral amygdala projection neurons. Spike broadening is frequency dependent and is reversed by brief hyperpolarisations. This broadening is reduced by blockade of voltage-gated Ca²⁺ channels and BK channels. In contrast, broadening is not blocked by high concentrations of 4-aminopyridine (4-AP) or α-dendrotoxin. We conclude that while inactivation of BK-type Ca²⁺-activated K⁺ channels contributes to spike broadening in lateral amygdala neurons, inactivation of another as yet unidentified outward current also plays a role.     

Ca2+ signalling in urethral interstitial cells of Cajal

Interstitial cells of Cajal (ICC) in the urethra have been proposed as specialized pacemakers that are involved in the generation of urethral tone and therefore the maintenance of urinary continence. Recent studies on freshly dispersed ICC from the urethra of rabbits have demonstrated that pacemaker activity in urethra ICC is characterized by spontaneous transient depolarizations (STDs) under current clamp and spontaneous transient inward currents (STICs) under voltage clamp. When these events were simultaneously recorded with changes in intracellular Ca²⁺ (using a Nipkow spinning disk confocal microscope) they were found to be associated with global Ca²⁺ oscillations. In this short review we will consider some of these recent findings regarding the contribution of intracellular Ca²⁺ stores and Ca²⁺ influx to the generation of pacemaker activity in urethral ICC with particular emphasis on the contribution of reverse Na⁺/Ca²⁺ exchange (NCX).     

Glucagon activates Ca2+ and Cl− channels in rat hepatocytes

Glucagon is one of the major hormonal regulators of glucose metabolism, counteracting the hepatic effects of insulin when the concentration of glucose in the bloodstream falls below a certain level. Glucagon also regulates bile flow, hepatocellular volume and membrane potential of hepatocytes. It is clear that changes in cell volume and membrane potential cannot occur without significant ion fluxes across the plasma membrane. The effects of glucagon on membrane currents in hepatocytes, however, are not well understood. Here we show, by patch-clamping of rat hepatocytes, that glucagon activates two types of currents: a small inwardly rectifying Ca²⁺ current with characteristics similar to those of the store-operated Ca²⁺ current and a larger outwardly rectifying Cl⁻ current similar to that activated by cell swelling. We show that the mechanism of glucagon action on membrane conductance involves phospholipase C and adenylyl cyclase. Contribution of the adenylyl cyclase-dependent pathway to activation of the currents depended on Epac (exchange protein directly activated by cAMP), but not on protein kinase A. The activation of Ca²⁺ and Cl⁻ channels is likely to play a key role in the mechanisms by which glucagon regulates hepatocyte metabolism and volume.     

Anoctamin/TMEM16 family members are Ca2+-activated Cl− channels

Ca²⁺-activated Cl⁻ channels (CaCCs) perform many important functions in cell physiology including secretion of fluids from acinar cells of secretory glands, amplification of olfactory transduction, regulation of cardiac and neuronal excitability, mediation of the fast block to polyspermy in amphibian oocytes, and regulation of vascular tone. Although a number of proteins have been proposed to be responsible for CaCC currents, the anoctamin family (ANO, also known as TMEM16) exhibits characteristics most similar to those expected for the classical CaCC. Interestingly, this family of proteins has previously attracted the interest of both developmental and cancer biologists. Some members of this family are up-regulated in a number of tumours and functional deficiency in others is linked to developmental defects.     

Role of extracellular Ca2+ in gating of CaV1.2 channels

We examined changes in ionic and gating currents in Ca_V1.2 channels when extracellular Ca²⁺ was reduced from 10 m m to 0.1 μ m . Saturating gating currents decreased by two-thirds ( K _D≈ 40 μ m ) and ionic currents increased 5-fold ( K _D≈ 0.5 μ m ) due to increasing Na⁺ conductance. A biphasic time dependence for the activation of ionic currents was observed at low [Ca²⁺], which appeared to reflect the rapid activation of channels that were not blocked by Ca²⁺ and a slower reversal of Ca²⁺ blockade of the remaining channels. Removal of Ca²⁺ following inactivation of Ca²⁺ currents showed that Na⁺ currents were not affected by Ca²⁺-dependent inactivation. Ca²⁺-dependent inactivation also induced a negative shift of the reversal potential for ionic currents suggesting that inactivation alters channel selectivity. Our findings suggest that activation of Ca²⁺ conductance and Ca²⁺-dependent inactivation depend on extracellular Ca²⁺ and are linked to changes in selectivity.     

Voltage-dependent calcium entry underlies propagation of slow waves in canine gastric antrum

Electrical slow waves in gastrointestinal (GI) muscles are generated by interstitial cells of Cajal (ICC), and these events actively propagate through networks of ICC within the walls of GI organs. The mechanism by which spontaneously active pacemaker sites throughout ICC networks are entrained to produce orderly propagation of slow waves is unresolved. A three-chambered partition bath was used to test the effects of agents that affect metabolism, membrane potential and voltage-dependent Ca²⁺ entry on slow wave propagation in canine antral smooth muscle strips. Slow waves evoked by electrical field stimulation actively propagated from end to end of antral muscle strips with a constant latency between two points of recording. When the central chamber of the bath was perfused with low-temperature solutions, mitochondrial inhibitors, reduced extracellular Ca²⁺ or blockers of voltage-dependent Ca²⁺ channels, active propagation failed. Depolarization or hyperpolarization of the tissue within the central chamber also blocked propagation. Blockade of propagation by reduced extracellular Ca²⁺ and inhibitors of dihydropyridine-resistant Ca²⁺ channels suggests that voltage-dependent Ca²⁺ entry may be the 'entrainment factor' that facilitates active propagation of slow waves in the gastric antrum.     

Differential expression of ionic conductances in interstitial cells of Cajal in the murine gastric antrum

Two distinct populations of interstitial cells of Cajal (ICC) exist within the tunica muscularis of the gastric antrum, and these cells serve different physiological functions. One population of ICC generates and actively propagates electrical slow waves, and the other population of ICC is innervated by excitatory and inhibitory motor neurons and mediates enteric motor neurotransmission. In spite of the key role of ICC in gastric excitability, little is known about the ionic conductances that underlie the functional diversity of these cells. In the present study we isolated ICC from the murine gastric antrum and investigated the Ca²⁺-dependent ionic conductances expressed by these cells using the patch clamp technique. Conductances in ICC were compared with those expressed in smooth muscle cells. The cells studied were identified by RT-PCR using cell-specific primers that included Myh11 (smooth muscle cells), Kit (ICC) and Uchl1 (enteric neurons) following electrophysiolgical recordings. Distinct ionic conductances were observed in Kit-positive cells. One group of ICC expressed a basal non-selective cation conductance (NSCC) that was inhibited by an increase in [Ca²⁺]_i in a calmodulin (CaM)-dependent manner. A second population of ICC generated spontaneous transient inward currents (STICs) and expressed a basal noisy NSCC that was facilitated by an increase in [Ca²⁺]_i in a CaM-dependent manner. The [Ca²⁺]_i-facilitated NSCC in ICC was blocked by the Cl⁻ channel antagonists 4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid (DIDS), anthracene-9-carboxylate (9-AC) and niflumic acid. These data suggest that distinct NSCC are expressed in subpopulations of ICC and these conductances may underlie the functional differences of these cells within the gastric antrum.     

Delayed expression of large conductance K+ channels reshaping agonist-induced currents in mouse pancreatic acinar cells

Epithelial secretory cells display cell-specific mechanisms of fluid secretion and express large conductance voltage- and Ca²⁺-activated K⁺ (Maxi-K) channels that generate the membrane negativity for effective Cl⁻ exit to the lumen. Rat and mouse pancreatic acinar cells had been thought to be peculiar in this sense because of the previously reported lack of Maxi-K channels. However, this view is not entirely correct as evidenced in the present paper. Searching for their presence in pancreatic acinar cells in mice from 5 to 84 weeks of age with patch-clamp current measurements, we demonstrated that the expression of Maxi-K channels is regulated in an age-associated manner after birth. The expression started at approximately 12 postnatal weeks and increased steadily up to 84 weeks. In support of this, RT-PCR could not detect mSlo mRNA, the Maxi-K gene, at either 7 or 8 weeks but could at 58 and 64 postnatal weeks. These results suggest that a key steering element for fluid secretion, the Maxi-K channel, is progressively re-organized in rodent pancreas. A pancreatic secretagogue, acetylcholine, evoked Maxi-K channel current overlapping to various degrees on the previously known current response. This suggests that the rise in internal Ca²⁺ activates Maxi-K channels which reshape the mode of secretagogue-evoked current response and contribute to Cl⁻ driving in fluid secretion in an age-associated fashion.     

Human ClCa1 modulates anionic conduction of calcium-dependent chloride currents

Proteins of the CLCA gene family including the human ClCa1 (hClCa1) have been suggested to constitute a new family of chloride channels mediating Ca²⁺-dependent Cl⁻ currents. The present study examines the relationship between the hClCa1 protein and Ca²⁺-dependent Cl⁻ currents using heterologous expression of hClCa1 in HEK293 and NCIH522 cell lines and whole cell recordings. By contrast to previous reports claiming the absence of Cl⁻ currents in HEK293 cells, we find that HEK293 and NCIH522 cell lines express constitutive Ca²⁺-dependent Cl⁻ currents and show that hClCa1 increases the amplitude of Ca²⁺-dependent Cl⁻ currents in those cells. We further show that hClCa1 does not modify the permeability sequence but increases the Cl⁻ conductance while decreasing the G _SCN−/ G _Cl− conductance ratio from ∼2–3 to ∼1. We use an Eyring rate theory (two barriers, one site channel) model and show that the effect of hClCa1 on the anionic channel can be simulated by its action on lowering the first and the second energy barriers. We conclude that hClCa1 does not form Ca²⁺-dependent Cl⁻ channels per se or enhance the trafficking/insertion of constitutive channels in the HEK293 and NCIH522 expression systems. Rather, hClCa1 elevates the single channel conductance of endogenous Ca²⁺-dependent Cl⁻ channels by lowering the energy barriers for ion translocation through the pore.     

Different kinetic properties of two T-type Ca2+ currents of rat reticular thalamic neurones and their modulation by enflurane

Currents arising from T-type Ca²⁺ channels in nucleus reticularis thalami (nRT) play a critical role in generation of low-amplitude oscillatory bursting involving mutually interconnected cortical and thalamic neurones, and are implicated in the state of arousal and sleep, as well as seizures. Here we show in brain slices from young rats that two kinetically different T-type Ca²⁺ currents exist in nRT neurones, with a slowly inactivating current expressed only on proximal dendrites, and fast inactivating current predominantly expressed on soma. Nickel was about twofold more potent in blocking fast (IC₅₀ 64 μ m ) than slow current (IC₅₀ 107 μ m ). The halogenated volatile anaesthetic enflurane blocked both currents, but only the slowly inactivating current was affected in voltage-dependent fashion. Slow dendritic current was essential for generation of low-threshold Ca²⁺ spikes (LTS), and both enflurane and nickel also suppressed LTS and neuronal burst firing at concentrations that blocked isolated T currents. Differential kinetic properties of T currents expressed in cell soma and proximal dendrites of nRT neurones indicate that various subcellular compartments may exhibit different membrane properties in response to small membrane depolarizations. Furthermore, since blockade of two different T currents in nRT neurones by enflurane and other volatile anaesthetics occurs within concentrations that are relevant during clinical anaesthesia, our findings suggest that these actions could contribute to some important clinical effects of anaesthetics.     

Small conductance Ca2+-activated K+ channels and calmodulin

Small conductance Ca²⁺-activated K⁺ channels (SK channels) contribute to the long lasting afterhyperpolarization (AHP) that follows an action potential in many central neurones. The biophysical and pharmacological attributes of cloned SK channels strongly suggest that one or more of them underlie the medium component of the AHP that regulates interspike interval and plays an important role in setting tonic firing frequency. The cloned SK channels comprise a distinct subfamily of K⁺ channels. Heterologously expressed SK channels recapitulate the biophysical and pharmacological hallmarks of native SK channels, being gated solely by intracellular Ca²⁺ ions with no voltage dependence to their gating, small unitary conductance values and sensitivity to the bee venom peptide toxin, apamin. Molecular, biochemical and electrophysiological studies have revealed that Ca²⁺ gating in SK channels is due to heteromeric assembly of the SK α pore-forming subunits with calmodulin (CaM). Ca²⁺ binding to the N-terminal E–F hands of CaM is responsible for SK channel gating. Crystallographic studies suggest that SK channels gate as a dimer-of-dimers, and that the physical gate of SK channels resides at or near the selectivity filter of the channels. In addition, Ca²⁺-independent interactions between the SK channel α subunits and CaM are necessary for proper membrane trafficking.     

Simultaneous imaging of Ca2+ signals in interstitial cells of Cajal and longitudinal smooth muscle cells during rhythmic activity in mouse ileum

Electrical rhythmicity in smooth muscle cells is essential for the movement of the gastrointestinal tract. Interstitial cells of Cajal (ICC) lie adjacent to smooth muscle layers and are implicated as the pacemaker cells. However, the pace making mechanism remains unclear. To study the intercellular interaction during electrical rhythm generation, we visualized changes in intracellular Ca²⁺ concentration ([Ca²⁺]_i) in smooth muscle cells and myenteric ICC within segments of mouse ileum loaded with a fluorescent Ca²⁺ indicator, fluo-3. We observed rhythmic [Ca²⁺]_i changes in longitudinal smooth muscle cells travelling rapidly through the smooth muscle cell layer. Between the rhythmic Ca²⁺ transients, we found brief Ca²⁺ transients localized to small areas within smooth muscle cells. The amplitude but not the periodicity of rhythmic [Ca²⁺]_i transients in both cell types was partially inhibited by nicardipine, an L-type Ca²⁺ channel antagonist, suggesting that the rhythmic [Ca²⁺]_i transients reflect membrane potential depolarizations corresponding to both slow waves and triggered Ca²⁺ spikes. Longitudinal smooth muscle cells and myenteric ICC showed synchronous spontaneous [Ca²⁺]_i transients in eight out of 21 ileac preparations analysed. In the remaining preparations, the synchrony between ICC and smooth muscle cells was absent, although the rhythmicity of the smooth muscle cells was not disturbed. These results suggest that myenteric ICC may play multiple roles including pace making for physiological bowel movement.     

Distinct contributions of small and large conductance Ca2+-activated K+ channels to rat Purkinje neuron function

The cerebellum is important for many aspects of behaviour, from posture maintenance and goal-oriented reaching movements to timing tasks and certain forms of learning. In every case, information flowing through the cerebellum passes through Purkinje neurons, which receive input from the two primary cerebellar afferents and generate continuous streams of action potentials that constitute the sole output from the cerebellar cortex to the deep nuclei. The tonic firing behaviour observed in Purkinje neurons in vivo is maintained in brain slices even when synaptic inputs are blocked, suggesting that Purkinje neuron activity relies to a significant extent on intrinsic conductances. Previous research has suggested that the interplay between Ca²⁺ currents and Ca²⁺-activated K⁺ channels (K_Ca channels) is important for Purkinje cell activity, but how many different K_Ca channel types are present and what each channel type contributes to cell behaviour remains unclear. In order to better understand the ionic mechanisms that control the behaviour of these neurons, we investigated the effects of different Ca²⁺ channel and K_Ca channel antagonists on Purkinje neurons in acute slices of rat cerebellum. Our data show that Ca²⁺ entering through P-type voltage-gated Ca²⁺ channels activates both small-conductance (SK) and large-conductance (BK) K_Ca channels. SK channels play a role in setting the intrinsic firing frequency, while BK channels regulate action potential shape and may contribute to the unique climbing fibre response.