RIM‐binding proteins recruit BK‐channels to presynaptic release sites adjacent to voltage‐gated Ca2+‐channels

The active zone of presynaptic nerve terminals organizes the neurotransmitter release machinery, thereby enabling fast Ca²⁺‐triggered synaptic vesicle exocytosis. BK‐channels are Ca²⁺‐activated large‐conductance K⁺‐channels that require close proximity to Ca²⁺‐channels for activation and control Ca²⁺‐triggered neurotransmitter release by accelerating membrane repolarization during action potential firing. How BK‐channels are recruited to presynaptic Ca²⁺‐channels, however, is unknown. Here, we show that RBPs (for RIM‐binding proteins), which are evolutionarily conserved active zone proteins containing SH3‐ and FN3‐domains, directly bind to BK‐channels. We find that RBPs interact with RIMs and Ca²⁺‐channels via their SH3‐domains, but to BK‐channels via their FN3‐domains. Deletion of RBPs in calyx of Held synapses decreased and decelerated presynaptic BK‐currents and depleted BK‐channels from active zones. Our data suggest that RBPs recruit BK‐channels into a RIM‐based macromolecular active zone complex that includes Ca²⁺‐channels, synaptic vesicles, and the membrane fusion machinery, thereby enabling tight spatio‐temporal coupling of Ca²⁺‐influx to Ca²⁺‐triggered neurotransmitter release in a presynaptic terminal.     

Ca2+-activated K channels in parotid acinar cells: The functional basis for the hyperpolarized activation of BK channels

Fluid secretion relies on a close interplay between Ca²⁺-activated Cl and K channels. Salivary acinar cells contain both large conductance, BK, and intermediate conductance, IK1, K channels. Physiological fluid secretion occurs with only modest (<500 nM) increases in intracellular Ca²⁺ levels but BK channels in many cell types and in heterologous expression systems require very high concentrations for significant activation. We report here our efforts to understand this apparent contradiction. We determined the Ca²⁺ dependence of IK1 and BK channels in mouse parotid acinar cells. IK1 channels activated with an apparent Ca²⁺ affinity of about 350 nM and a hill coefficient near 3. Native parotid BK channels activated at similar Ca²⁺ levels unlike the BK channels in other cell types. Since the parotid BK channel is encoded by an uncommon splice variant, we examined this clone in a heterologous expression system. In contrast to the native parotid channel, activation of this expressed “parslo” channel required very high levels of Ca²⁺. In order to understand the functional basis for the special properties of the native channels, we analyzed the parotid BK channel in the context of the horrigan-Aldrich model of BK channel gating. We found that the shifted activation of parotid BK channels resulted from a hyperpolarizing shift of the voltage dependence of voltage sensor activation and channel opening and included a large change in the coupling of these two processes.Key words: ion channels, Ca²⁺-activated K channels, maxi-K channels, IK1 channels     

Impaired Ca2+-dependent activation of large-conductance Ca2+-activated K+ channels in the coronary artery smooth muscle cells of Zucker Diabetic Fatty rats

The large-conductance Ca²⁺-activated K⁺ (BK) channels play an important role in the regulation of cellular excitability in response to changes in intracellular metabolic state and Ca²⁺ homeostasis. In vascular smooth muscle, BK channels are key determinants of vasoreactivity and vital-organ perfusion. Vascular BK channel functions are impaired in diabetes mellitus, but the mechanisms underlying such changes have not been examined in detail. We examined and compared the activities and kinetics of BK channels in coronary arterial smooth muscle cells from Lean control and Zucker Diabetic Fatty (ZDF) rats, using single-channel recording techniques. We found that BK channels in ZDF rats have impaired Ca²⁺ sensitivity, including an increased free Ca²⁺ concentration at half-maximal effect on channel activation, a reduced steepness of Ca²⁺ dose-dependent curve, altered Ca²⁺-dependent gating properties with decreased maximal open probability, and a shortened mean open-time and prolonged mean closed-time durations. In addition, the BK channel β-subunit-mediated activation by dehydrosoyasaponin-1 (DHS-1) was lost in cells from ZDF rats. Immunoblotting analysis confirmed a 2.1-fold decrease in BK channel β₁-subunit expression in ZDF rats, compared with that of Lean rats. These abnormalities in BK channel gating lead to an increase in the energy barrier for channel activation, and may contribute to the development of vascular dysfunction and complications in type 2 diabetes mellitus.     

Reduced transmitter release conferred by mutations in theslowpoke-encoded Ca2+-activated K+ channel gene ofDrosophila

Potassium channels control the repolarization of nerve terminals and thus play important roles in the control of synaptic transmission. Here we describe the effects of mutations in theslowpoke gene, which is the structural gene for a calcium activated potassium channel, on transmitter release at the neuromuscular junction inDrosophila melanogaster. Surprisingly, we find that theslowpoke mutant exhibits reduced transmitter release compared to normal. Similarly, theslowpoke mutation significantly suppresses the increased transmitter release conferred either by a mutation inShaker or by application of 4-aminopyridine, which blocks theShaker-encoded potassium channel at theDrosophila nerve terminal. Furthermore, theslowpoke mutation suppresses the striking increase in transmitter release that occurs following application of 4-aminopyridine to theether a go-go mutant. This suppression is most likely the result of a reduction of Ca²⁺ influx into the nerve terminal in theslowpoke mutant. We hypothesize that the effects of theslowpoke mutation are indirect, perhaps resulting from increased Ca²⁺ channel inactivation, decreased Na⁺ or Ca²⁺ channel localization or gene expression, or by increases in the expression or activity of potassium channels distinct fromslowpoke.     

Ca2+/calmodulin binding to PSD‐95 mediates homeostatic synaptic scaling down

Postsynaptic density protein‐95 (PSD‐95) localizes AMPA‐type glutamate receptors (AMPARs) to postsynaptic sites of glutamatergic synapses. Its postsynaptic displacement is necessary for loss of AMPARs during homeostatic scaling down of synapses. Here, we demonstrate that upon Ca²⁺ influx, Ca²⁺/calmodulin (Ca²⁺/CaM) binding to the N‐terminus of PSD‐95 mediates postsynaptic loss of PSD‐95 and AMPARs during homeostatic scaling down. Our NMR structural analysis identified E17 within the PSD‐95 N‐terminus as important for binding to Ca²⁺/CaM by interacting with R126 on CaM. Mutating E17 to R prevented homeostatic scaling down in primary hippocampal neurons, which is rescued via charge inversion by ectopic expression of CaM^R126E, as determined by analysis of miniature excitatory postsynaptic currents. Accordingly, increased binding of Ca²⁺/CaM to PSD‐95 induced by a chronic increase in Ca²⁺ influx is a critical molecular event in homeostatic downscaling of glutamatergic synaptic transmission.     

Heteromeric channels formed by TRPC1, TRPC4 and TRPC5 define hippocampal synaptic transmission and working memory

Canonical transient receptor potential (TRPC) channels influence various neuronal functions. Using quantitative high‐resolution mass spectrometry, we demonstrate that TRPC1, TRPC4, and TRPC5 assemble into heteromultimers with each other, but not with other TRP family members in the mouse brain and hippocampus. In hippocampal neurons from Trpc1/Trpc4/Trpc5‐triple‐knockout (Trpc1/4/5^?/?) mice, lacking any TRPC1‐, TRPC4‐, or TRPC5‐containing channels, action potential‐triggered excitatory postsynaptic currents (EPSCs) were significantly reduced, whereas frequency, amplitude, and kinetics of quantal miniature EPSC signaling remained unchanged. Likewise, evoked postsynaptic responses in hippocampal slice recordings and transient potentiation after tetanic stimulation were decreased. In vivo, Trpc1/4/5^?/? mice displayed impaired cross‐frequency coupling in hippocampal networks and deficits in spatial working memory, while spatial reference memory was unaltered. Trpc1/4/5^?/? animals also exhibited deficiencies in adapting to a new challenge in a relearning task. Our results indicate the contribution of heteromultimeric channels from TRPC1, TRPC4, and TRPC5 subunits to the regulation of mechanisms underlying spatial working memory and flexible relearning by facilitating proper synaptic transmission in hippocampal neurons.     

Exploring the Ca2+-dependent synaptic dynamics in vibro-dissociated cells

Dynamic alteration of the synaptic strength is one of the most important processes occurring in the nervous system. Combination of electrophysiology, confocal imaging and molecular biology led to significant advances in this research field. Yet, a progress in this area, in particular in studies of changes in the quantal behavior of central synapses and impact of glial cells on individual synapses, is hampered by technical difficulties of resolving small quantal synaptic currents. In this paper we will show how the technique of non-enzymatic vibro-dissociation, which enables to isolate living neurons avoiding artifacts of cell culture and preserving functional synapse, can be used to obtain a valuable information on fine details and mechanisms of synaptic plasticity. In particular, we will describe our recent results on Ca²⁺-dependent modulation of the postsynaptic AMPA and NMDA receptors in the individual synaptic boutons.     

Voltage-gated Ca2+ channels in accessory lobe neurons of the chick

Birds have ten pairs of protrusions, “accessory lobes”, on the lateral sides of the lumbosacral spinal cord. It has been proposed that accessory lobes act as a sensory organ of equilibrium and neurons in accessory lobes transmit sensory information to the motor center. We have reported that cells in chick accessory lobes express functional voltage-gated Na⁺ and K⁺ channels and generate action potentials. In this study, we examined properties of voltage-gated Ca²⁺ channels (VGCCs). The amplitude of voltage-gated Ca²⁺ channel currents carried by Ca²⁺ and Ba²⁺ increased gradually during 10 min rather than showing the usual run-down. The current–voltage relationship of Ba²⁺ currents was consistent with that of the high-voltage-activated Ca²⁺ channel. The proportion of Ba²⁺ currents inhibited by ω-conotoxin GVIA was larger than 80 %, indicating that the major subtype is N type. Amplitudes of tail currents of Ca²⁺ currents evoked by repetitive pulses at 50 Hz are stable for 1 s. If the major subtype of VGCCs at synaptic terminals is also N type, this property may contribute to the establishment of stable synaptic connections between accessory lobe neurons, which are reported to fire at frequencies higher than 15 Hz, and postsynaptic neurons in the spinal cord.     

Big-conductance Ca2+-activated K+ channels in physiological and pathophysiological urinary bladder smooth muscle cells

Contraction and relaxation of urinary bladder smooth muscle cells (UBSMCs) represent the important physiological functions of the bladder. Contractile responses in UBSMCs are regulated by a number of ion channels including big-conductance Ca²⁺- activated K⁺ (BK) channels. Great progress has been made in studies of BK channels in UBSMCs. The intent of this review is to summarize recent exciting findings with respect to the functional interactions of BK channels with muscarinic receptors, ryanodine receptors (RyRs) and inositol triphosphate receptors (IP₃Rs) as well as their functional importance under normal and pathophysiological conditions. BK channels are highly expressed in UBSMCs. Activation of muscarinic M₃ receptors inhibits the BK channel activity, facilitates opening of voltage-dependent Ca²⁺ (Ca_V) channels, and thereby enhances excitability and contractility of UBSMCs. Signaling molecules and regulatory mechanisms involving RyRs and IP₃Rs have a significant effect on functions of BK channels and thereby regulate cellular responses in UBSMCs under normal and pathophysiological conditions including overactive bladders. Moreover, BK channels may represent a novel target for the treatment of bladder dysfunctions.     

Micromolar Ca2+ from sparks activates Ca2+-sensitive K+ channels in rat cerebral artery smooth muscle

The goal of the present study was to testthe hypothesis that local Ca²⁺ release events(Ca²⁺ sparks) deliver high local Ca²⁺concentration to activate nearby Ca²⁺-sensitiveK⁺ (BK) channels in the cell membrane of arterial smoothmuscle cells. Ca²⁺ sparks and BK channels were examined inisolated myocytes from rat cerebral arteries with laser scanningconfocal microscopy and patch-clamp techniques. BK channels had anapparent dissociation constant for Ca²⁺ of 19 µM and aHill coefficient of 2.9 at 40 mV. At near-physiological intracellularCa²⁺ concentration ([Ca²⁺]_i; 100 nM) and membrane potential (40 mV), the open probability of a singleBK channel was low (1.2 × 10⁶). A Ca²⁺spark increased BK channel activity to 18. Assuming that 1-100% of the BK channels are activated by a single Ca²⁺ spark, BKchannel activity increases 6 × 10⁵-fold to 6 × 10³-fold, which corresponds to ~30 µM to 4 µM sparkCa²⁺ concentration.1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acidacetoxymethyl ester caused the disappearance of all Ca²⁺sparks while leaving the transient BK currents unchanged. Our resultssupport the idea that Ca²⁺ spark sites are in closeproximity to the BK channels and that local[Ca²⁺]_i reaches micromolar levels to activateBK channels.

     

Norepinephrine activates store-operated Ca2+ entry coupled to large-conductance Ca2+-activated K+ channels in rat pinealocytes

Norepinephrine (NE) is one of the major neurotransmitters that determine melatonin production in the pineal gland. Although a substantial amount of Ca²⁺ influx is triggered by NE, the Ca²⁺ entry pathway and its physiological relevance have not been elucidated adequately. Herein we report that the Ca²⁺ influx triggered by NE significantly regulates the protein level of serotonin N-acetyltransferase, or arylalkylamine N-acetyltransferase (AANAT), a critical enzyme in melatonin production, and is responsible for maintaining the Ca²⁺ response after repetitive stimulation. Ca²⁺ entry evoked by NE was dependent on PLC activation. NE evoked a substantial amount of Ca²⁺ entry even after cells were treated with 1-oleoyl-2-acetyl-sn-glycerol (OAG), an analog of diacylglycerol. To the contrary, further OAG treatment after cells had been exposed to OAG did not evoke additional Ca²⁺ entry. Moreover, NE failed to induce further Ca²⁺ entry after the development of Ca²⁺ entry induced by thapsigargin (Tg), suggesting that the pathway of Ca²⁺ entry induced by NE might be identical to that of Tg. Interestingly, Ca²⁺ entry evoked by NE or Tg induced membrane hyperpolarization that was reversed by iberiotoxin (IBTX), a specific inhibitor of large-conductance Ca²⁺-activated K⁺ (BK) channels. Moreover, IBTX-sensitive BK current was observed during application of NE, suggesting that activation of the BK channels was responsible for the hyperpolarization. Furthermore, the activation of BK channels triggered by NE contributed to regulation of the protein level of AANAT. Collectively, these results suggest that NE triggers Ca²⁺ entry coupled to BK channels and that NE-induced Ca²⁺ entry is important in the regulation of AANAT. serotonin N-acetyltransferase; pineal gland     

Calcineurin Mediates Synaptic Scaling Via Synaptic Trafficking of Ca2+-Permeable AMPA Receptors

Homeostatic synaptic plasticity is a negative-feedback mechanism for compensating excessive excitation or inhibition of neuronal activity. When neuronal activity is chronically suppressed, neurons increase synaptic strength across all affected synapses via synaptic scaling. One mechanism for this change is alteration of synaptic AMPA receptor (AMPAR) accumulation. Although decreased intracellular Ca²⁺ levels caused by chronic inhibition of neuronal activity are believed to be an important trigger of synaptic scaling, the mechanism of Ca²⁺-mediated AMPAR-dependent synaptic scaling is not yet understood. Here, we use dissociated mouse cortical neurons and employ Ca²⁺ imaging, electrophysiological, cell biological, and biochemical approaches to describe a novel mechanism in which homeostasis of Ca²⁺ signaling modulates activity deprivation-induced synaptic scaling by three steps: (1) suppression of neuronal activity decreases somatic Ca²⁺ signals; (2) reduced activity of calcineurin, a Ca²⁺-dependent serine/threonine phosphatase, increases synaptic expression of Ca²⁺-permeable AMPARs (CPARs) by stabilizing GluA1 phosphorylation; and (3) Ca²⁺ influx via CPARs restores CREB phosphorylation as a homeostatic response by Ca²⁺-induced Ca²⁺ release from the ER. Therefore, we suggest that synaptic scaling not only maintains neuronal stability by increasing postsynaptic strength but also maintains nuclear Ca²⁺ signaling by synaptic expression of CPARs and ER Ca²⁺ propagation.     

Effects of mechanical stretch on the functions of BK and L-type Ca2+ channels in vascular smooth muscle cells

It is well recognized that pathologically increased mechanical stretch plays a critical role in vascular remodeling during hypertension. However, how the stretch modulates the functions of ion channels of vascular smooth muscle cells (VSMCs) remains to be elucidated. Here, we demonstrated the effects of mechanical stretch on the activity of large conductance calcium, voltage-activated potassium (BK) and L-type Ca²⁺ channels. In comparison with 5% stretch (physiological), 15% stretch (pathological) upregulated the current density of L-type Ca²⁺ and BK channels as well as the frequency and amplitude of calcium oscillation in VSMCs. 15% stretch also increased the open probability and mean open time of the BK channel compared with 5% stretch. BK and L-type Ca²⁺ channels participated in the mechanical stretch-modulated calcium oscillation. Our results suggested that during hypertension, pathological stretch altered the activity of BK and L-type Ca²⁺ channels and manipulated the calcium oscillation of VSMCs.     

Apamin Boosting of Synaptic Potentials in CaV2.3 R-Type Ca2+ Channel Null Mice

SK2- and K_V4.2-containing K⁺ channels modulate evoked synaptic potentials in CA1 pyramidal neurons. Each is coupled to a distinct Ca²⁺ source that provides Ca²⁺-dependent feedback regulation to limit AMPA receptor (AMPAR)- and NMDA receptor (NMDAR)-mediated postsynaptic depolarization. SK2-containing channels are activated by Ca²⁺ entry through NMDARs, whereas K_V4.2-containing channel availability is increased by Ca²⁺ entry through SNX-482 (SNX) sensitive Ca_V2.3 R-type Ca²⁺ channels. Recent studies have challenged the functional coupling between NMDARs and SK2-containing channels, suggesting that synaptic SK2-containing channels are instead activated by Ca²⁺ entry through R-type Ca²⁺ channels. Furthermore, SNX has been implicated to have off target affects, which would challenge the proposed coupling between R-type Ca²⁺ channels and K_V4.2-containing K⁺ channels. To reconcile these conflicting results, we evaluated the effect of SK channel blocker apamin and R-type Ca²⁺ channel blocker SNX on evoked excitatory postsynaptic potentials (EPSPs) in CA1 pyramidal neurons from Ca_V2.3 null mice. The results show that in the absence of Ca_V2.3 channels, apamin application still boosted EPSPs. The boosting effect of Ca_V2.3 channel blockers on EPSPs observed in neurons from wild type mice was not observed in neurons from Ca_V2.3 null mice. These data are consistent with a model in which SK2-containing channels are functionally coupled to NMDARs and K_V4.2-containing channels to Ca_V2.3 channels to provide negative feedback regulation of EPSPs in the spines of CA1 pyramidal neurons.     

Miro1‐dependent mitochondrial positioning drives the rescaling of presynaptic Ca2+ signals during homeostatic plasticity

Mitochondrial trafficking is influenced by neuronal activity, but it remains unclear how mitochondrial positioning influences neuronal transmission and plasticity. Here, we use live cell imaging with the genetically encoded presynaptically targeted Ca²⁺ indicator, SyGCaMP5, to address whether presynaptic Ca²⁺ responses are altered by mitochondria in synaptic terminals. We find that presynaptic Ca²⁺ signals, as well as neurotransmitter release, are significantly decreased in terminals containing mitochondria. Moreover, the localisation of mitochondria at presynaptic sites can be altered during long‐term activity changes, dependent on the Ca²⁺‐sensing function of the mitochondrial trafficking protein, Miro1. In addition, we find that Miro1‐mediated activity‐dependent synaptic repositioning of mitochondria allows neurons to homeostatically alter the strength of presynaptic Ca²⁺ signals in response to prolonged changes in neuronal activity. Our results support a model in which mitochondria are recruited to presynaptic terminals during periods of raised neuronal activity and are involved in rescaling synaptic signals during homeostatic plasticity.     

Implications of G-Protein-Mediated Ca2+ Channel Inhibition for Neurotransmitter Release and Facilitation

G-protein-mediated inhibition of Ca²⁺ current is ubiquitous in neurons, and in synaptic terminals it can lead to a reduction in transmitter release (presynaptic inhibition). This type of Ca²⁺ current inhibition can often be relieved by prepulse depolarization, so the disinhibition of Ca²⁺ current can combine with Ca²⁺-dependent mechanisms for activity-induced synaptic facilitation to amplify this form of short-term plasticity. We combine a mathematical model of a G-protein-regulated Ca²⁺ channel with a model of transmitter secretion to study the potential effects of G-protein-mediated Ca²⁺ channel inhibition and disinhibition on transmitter release and facilitation. We investigate several scenarios, with the goal of observing a range of behaviors that may occur in different synapses. We find that the effects of Ca²⁺ channel disinhibition depend greatly on the location and distribution of inhibited channels. Facilitation can be greatly enhanced if all channels are subject to inhibition or if the subpopulation of channels subject to inhibition are located closer to release sites than those insensitive to inhibition, an arrangement that has been suggested by recent experiments (Stanley and Mirotznik, 1997). We also find that the effect of disinhibition on facilitation is greater for longer action potentials. Finally, in the case of homosynaptic inhibition, where Ca²⁺ channel inhibition occurs through the binding of transmitter molecules to presynaptic autoreceptors, there will be little reduction in transmitter release during the first of two successive bursts of impulses. The reduction of release during the second burst will be significantly greater, and if the unbinding rate of autoreceptors is relatively low, then the effects of G-protein-mediated channel inhibition become more pronounced as the duration of the interburst interval is increased up to a critical point, beyond which the inhibitory effects become less pronounced. This is in contrast to presynaptic depression due to the depletion of the releasable vesicle pool, where longer interburst intervals allow for a more complete replenishment of the pool. Thus, G-protein-mediated Ca²⁺ current inhibition leads to a reduction in transmitter release, while having a highly variable amplifying effect on synaptic facilitation. The dynamic properties of this form of presynaptic inhibition are very different from those of vesicle depletion.     

Voltage-gated Ca2+ channels in type III taste cells

In the mammalian taste bud, the heterogeneous cell population includes three morphologically distinct types of cells, type I to type III, which are also different in their electrophysiological features. Particularly, voltage-gated (VG) Ca²⁺ channels are functional solely in taste cells of the type III. These channels were studied here with external Ba²⁺ ions as current carriers. It was specifically shown that VG Ba²⁺ currents were almost completely blockable with nifedipine as well as with ionic blockers, such as Cd²⁺, Ni²⁺, and Co²⁺. Kinetic properties of VG Ba²⁺ currents in type III cells and their sensitivity to the blockers indicated that these currents were largely mediated by VG Ca²⁺ channels of the L-type. The expression of genes, which encode pore-forming α1-subunits of Ca²⁺ channels, was analyzed using methods of molecular biology. Among four genes encoding L-type Ca²⁺ channel α1-subunits (Ca _ν 1.1-Ca _ν 1.4), the expression of Ca _ν 1.2 was demonstrated in taste cells.     

Ca2+ influx into identified leech neurons induced by 5‐hydroxytryptamine

The role of 5‐hydroxytryptamine (5‐HT, serotonin) in the control of leech behavior is well established and has been analyzed extensively on the cellular level; however, hitherto little is known about the effect of 5‐HT on the cytosolic free calcium concentration ([Ca²⁺]_i) in leech neurons. As [Ca²⁺]_i plays a pivotal role in numerous cellular processes, we investigated the effect of 5‐HT on [Ca²⁺]_i (measured by Fura‐2) in identified leech neurons under different experimental conditions, such as changed extracellular ion composition and blockade of excitatory synaptic transmission. In pressure (P), lateral nociceptive (N1), and Leydig neurons, 5‐HT induced a [Ca²⁺]_i increase which was predominantly due to Ca²⁺ influx since it was abolished in Ca²⁺‐free solution. The 5‐HT‐induced Ca²⁺ influx occurred only if the cells depolarized sufficiently, indicating that it was mediated by voltage‐dependent Ca²⁺ channels. In P and N1 neurons, the membrane depolarization was due to Na⁺ influx through cation channels coupled to 5‐HT receptors, whereby the dose‐dependency suggests an involvement in excitatory synaptic transmission. In Leydig neurons, 5‐HT receptor‐coupled cation channels seem to be absent. In these cells, the membrane depolarization activating the voltage‐dependent Ca²⁺ channels was evoked by 5‐HT‐triggered excitatory glutamatergic input. In Retzius, anterior pagoda (AP), annulus erector (AE), and median nociceptive (N2) neurons, 5‐HT had no effect on [Ca²⁺]_i. © 2004 Wiley Periodicals, Inc. J Neurobiol, 2005     

Comparative effects of H+ and Ca2+ on large-conductance Ca2+- and voltage-gated Slo1 K+ channels

Large-conductance Ca²⁺- and voltage-gated Slo1 BK channels are allosterically activated by depolarization and intracellular ligands such as Ca²⁺. Of the two high-affinity Ca²⁺ sensors present in the channel, the RCK1 sensor also mediates H⁺-dependent activation of the channel. In this study, we examined the comparative mechanisms of the channel activation by Ca²⁺ and H⁺. Steady-state macroscopic conductance-voltage measurements as well as single-channel openings at negative voltages where voltage-sensor activation is negligible showed that at respective saturating concentrations Ca²⁺ is more effective in relative stabilization of the open conformation than H⁺. Calculations using the Debye-Hückel formulation suggest that small structural changes in the RCK1 sensor, on the order of few angstroms, may accompany the H⁺-mediated opening of the channel. While the efficacy of H+ in activation of the channel is less than that of Ca²⁺, H⁺ more effectively accelerates the activation kinetics when examined at the concentrations equipotent on macroscopic voltage-dependent activation. The RCK1 sensor therefore is capable of transducing the nature of the ligand bound and transmits qualitatively different information to the channel's permeation gate.