Ion-Ion interactions at the selectivity filter. Evidence from K(+)-dependent modulation of tetraethylammonium efficacy in Kv2.1 potassium channels

In the Kv2.1 potassium channel, binding of K(+) to a high-affinity site associated with the selectivity filter modulates channel sensitivity to external TEA. In channels carrying Na(+) current, K(+) interacts with the TEA modulation site at concentrations 相似文献   

K(+) occupancy of the N-methyl-d-aspartate receptor channel probed by Mg(2+) block

The single-channel kinetics of extracellular Mg(2+) block was used to probe K(+) binding sites in the permeation pathway of rat recombinant NR1/NR2B NMDA receptor channels. K(+) binds to three sites: two that are external and one that is internal to the site of Mg(2+) block. The internal site is approximately 0.84 through the electric field from the extracellular surface. The equilibrium dissociation constant for this site for K(+) is 304 mM at 0 mV and with Mg(2+) in the pore. The occupancy of any one of the three sites by K(+) effectively prevents the association of extracellular Mg(2+). Occupancy of the internal site also prevents Mg(2+) permeation and increases (by approximately sevenfold) the rate constant for Mg(2+) dissociation back to the extracellular solution. Under physiological intracellular ionic conditions and at -60 mV, there is approximately 1,400-fold apparent decrease in the affinity of the channel for extracellular Mg(2+) and approximately 2-fold enhancement of the apparent voltage dependence of Mg(2+) block caused by the voltage dependence of K(+) occupancy of the external and internal sites.     

褪黑素激活大鼠大脑中动脉BKCa通道的受体依赖和非受体依赖途径

目的：研究褪黑素通过大电导Ca²⁺激活K⁺（BK_Ca）通道介导大脑中动脉张力变化的作用机制。方法：8周龄雄性Wistar大鼠,麻醉后取大脑中动脉,酶消化法急性分离脑中动脉平滑肌细胞,采用膜片钳技术全细胞记录模式检测细胞外液加入褪黑素前后BK_Ca通道和电压门控钾（K_V）通道的电流密度,褪黑素受体抑制剂2-苯基-N-乙酰色胺（luzindole）孵育后,全细胞记录模式记录加入褪黑素后BK_Ca通道电流幅值和贴附式单通道记录模式记录加入褪黑素后BK_Ca通道Po值,内面向外记录模式检测加入褪黑素后BK_Ca通道电导（G）,开放概率（Po）,平均开放时间（To）和关闭时间（Tc）。结果：①褪黑素（100 μmol/L）显著增加全细胞BK_Ca通道电流密度,但对K_V通道电流密度无显著影响;②luzindole （1 μmol/L）显著抑制褪黑素引起的BK_Ca通道电流密度增加;③贴附式单通道记录模式下,褪黑素（100 μmol/L）增加BK_Ca单通道Po值,luzindole （1 μmol/L）显著抑制褪黑素引起的Po增加;④内面向外单通道记录模式下,褪黑素（1 μmol/L,100 μmol/L）缩短BK_Ca单通道的To和Tc值,且Tc较To显著缩短;结论：褪黑素通过受体依赖和非受体依赖途径激活BK_Ca通道,介导大脑中动脉血管舒张。     

Calcium channel selectivity for divalent and monovalent cations. Voltage and concentration dependence of single channel current in ventricular heart cells

Single channel and whole cell recordings were used to study ion permeation through Ca channels in isolated ventricular heart cells of guinea pigs. We evaluated the permeability to various divalent and monovalent cations in two ways, by measuring either unitary current amplitude or reversal potential (Erev). According to whole cell measurements of Erev, the relative permeability sequence is Ca2+ greater than Sr2+ greater than Ba2+ for divalent ions; Mg2+ is not measurably permeant. Monovalent ions follow the sequence Li+ greater than Na+ greater than K+ greater than Cs+, and are much less permeant than the divalents. These whole cell measurements were supported by single channel recordings, which showed clear outward currents through single Ca channels at strong depolarizations, similar values of Erev, and similar inflections in the current-voltage relation near Erev. Information from Erev measurements stands in contrast to estimates of open channel flux or single channel conductance, which give the sequence Na+ (85 pS) greater than Li+ (45 pS) greater than Ba2+ (20 pS) greater than Ca2+ (9 pS) near 0 mV with 110-150 mM charge carrier. Thus, ions with a higher permeability, judged by Erev, have lower ion transfer rates. In another comparison, whole cell Na currents through Ca channels are halved by less than 2 microM [Ca]o, but greater than 10 mM [Ca]o is required to produce half-maximal unitary Ca current. All of these observations seem consistent with a recent hypothesis for the mechanism of Ca channel permeation, which proposes that: ions pass through the pore in single file, interacting with multiple binding sites along the way; selectivity is largely determined by ion affinity to the binding sites rather than by exclusion by a selectivity filter; occupancy by only one Ca ion is sufficient to block the pore's high conductance for monovalent ions like Na+; rapid permeation by Ca ions depends upon double occupancy, which only becomes significant at millimolar [Ca]o, because of electrostatic repulsion or some other interaction between ions; and once double occupancy occurs, the ion-ion interaction helps promote a quick exit of Ca ions from the pore into the cell.     

Regulation of melatonin 1a receptor signaling and trafficking by asparagine-124.

Melatonin is a pineal hormone that regulates seasonal reproduction and has been used to treat circadian rhythm disorders. The melatonin 1a receptor is a seven- transmembrane domain receptor that signals predominately via pertussis toxin-sensitive G-proteins. Point mutations were created at residue N124 in cytoplasmic domain II of the receptor and the mutant receptors were expressed in a neurohormonal cell line. The acidic N124D- and E-substituted receptors had high-affinity (125)I-melatonin binding and a subcellular localization similar to the neutral N124N wild-type receptor. Melatonin efficacy for the inhibition of cAMP by N124D and E mutations was significantly decreased. N124D and E mutations strongly compromised melatonin efficacy and potency for inhibition of K(+)-induced intracellular Ca(++) fluxes and eliminated control of spontaneous calcium fluxes. However, these substitutions did not appear to affect activation of Kir3 potassium channels. The hydrophobic N124L and N124A or basic N124K mutations failed to bind (125)I-melatonin and appeared to aggregate or traffic improperly. N124A and N124K receptors were retained in the Golgi. Therefore, mutants at N124 separated into two sets: the first bound (125)I-melatonin with high affinity and trafficked normally, but with reduced inhibitory coupling to adenylyl cyclase and Ca(++) channels. The second set lacked melatonin binding and exhibited severe trafficking defects. In summary, asparagine-124 controls melatonin receptor function as evidenced by changes in melatonin binding, control of cAMP levels, and regulation of ion channel activity. Asparagine-124 also has a unique structural effect controlling receptor distribution within the cell.     

Ionic selectivity, saturation, and block in sodium channels. A four- barrier model

Ionic fluxes in Na channels of myelinated axons show ionic competition, block, and deviations from simple flux independence. These phenomena are particularly evident when external Na+ ions are replaced by other permeant or impermeant ions. The observed currents require new flux equations not based on the concepts of free diffusion. A specific permeability model for the Na channel is developed from Eyring rate theory applied to a chain of saturable binding sites. There are four energy barriers in the pore and only one ion is allowed inside at a time. Deviations from independence arise from saturation. The model shows that ionic permeability ratios measured from zero-current potentials can differ from those measured from relative current amplitudes or conductances. The model can be fitted to experiments with various external sodium substitutes by varying only two parameters: For each ion the height of the major energy barrier (the selectivity filter) determines the biionic zero-current potential and the depth of the energy well (binding site) just external to that barrier then determines the current amplitudes. Voltage clamp measurements with myelinated nerve fibers are given showing numerous examples of deviations from independence in ionic fluxes. Strong blocks of ionic currents by guanidinium compounds and Tl+ ions are fitted by binding within the channel with apparent dissociation constants in the range 50-122 mM. A small block with high Na+ concentrations can be fitted by Na+ ion binding with a dissociation constant of 368 mM. The barrier model is given a molecular interpretation that includes stepwise dehydration of the permeating ion as it interacts with an ionized carboxylic acid.     

Modification of cardiac Na+ channels by batrachotoxin: effects on gating, kinetics, and local anesthetic binding.

The purpose of the present study was to examine the characteristics of Na+ channel modification by batrachotoxin (BTX) in cardiac cells, including changes in channel gating and kinetics as well as susceptibility to block by local anesthetic agents. We used the whole cell configuration of the patch clamp technique to measure Na+ current in guinea pig myocytes. Extracellular Na+ concentration and temperature were lowered (5-10 mM, 17 degrees C) in order to maintain good voltage control. Our results demonstrated that 1) BTX modifies cardiac INa, causing a substantial steady-state (noninactivating) component of INa, 2) modification of cardiac Na+ channels by BTX shifts activation to more negative potentials and reduces both maximal gNa and selectivity for Na+; 3) binding of BTX to its receptor in the cardiac Na+ channel reduces the affinity of local anesthetics for their binding site; and 4) BTX-modified channels show use-dependent block by local anesthetics. The reduced blocking potency of local anesthetics for BTX-modified Na+ channels probably results from an allosteric interaction between BTX and local anesthetics for their respective binding sites in the Na+ channel. Our observations that use-dependent block by local anesthetics persists in BTX-modified Na+ channels suggest that this form of extra block can occur in the virtual absence of the inactivated state. Thus, the development of use-dependent block appears to rely primarily on local anesthetic binding to activated Na+ channels under these conditions.     

Opening rate of acetylcholine receptor channels.

The nicotinic acetylcholine (ACh) receptor is responsible for rapid conversion of chemical signals to electrical signals at the neuromuscular junction. Because the receptor and its ion channel are components of a single transmembrane protein, the time between ACh binding and channel opening can be minimized. To determine just how quickly the channel opens, we made rapid (100-400 microseconds) applications of 0.1-10 mM ACh to outside-out, multichannel membrane patches from BC3H-1 cells, while measuring the onset of current flow through the channels at 11 degrees C. Onset time is steeply dependent upon ACh concentration when channel activation is limited by binding of ACh (0.1-1 mM). At +50 mV, the 20-80% onset time reaches a plateau near 110 microseconds above 5 mM ACh as channel opening becomes rate limiting. Thus, we calculate the opening rate, beta = 12/ms, without reference to specific channel activation schemes. At -50 mV, the combination of a rapid, voltage-dependent block of channels by ACh with a finite solution exchange time distorts onset. To determine opening rate at -50 mV, we determine the kinetic parameters of block from "steady-state" current and noise analyses, assume a sequential model of channel activation/block, and numerically simulate current responses to rapid perfusion of ACh. Using this approach, we find beta = 15/ms. In contrast to the channel closing rate, the opening rate is relatively insensitive to voltage.     

Divalent cation block and competition between divalent and monovalent cations in the large-conductance K+ channel from Chara australis

The patch-clamp technique is used to investigate divalent ion block of the large-conductance K+ channel from Chara australis. Block by Ba2+, Ca2+, Mg2+, and Pt(NH3)4(2+) from the vacuolar and cytoplasmic sides is used to probe the structure of, and ion interactions within, the pore. Five divalent ion binding sites are detected. Vacuolar Ca2+ reduces channel conductance by binding to a site located 7% along the membrane potential difference (site 1, delta = 0.07; from the vacuolar side); it also causes channel closures with mean a duration of approximately 0.1-1 ms by binding at a deeper site (site 2, delta = 0.3). Ca2+ can exit from site 2 into both the vacuolar and cytoplasmic solutions. Cytoplasmic Ca2+ reduces conductance by binding at two sites (site 3, delta = -0.21; site 4, delta = -0.6; from the cytoplasmic side) and causes closures with a mean duration of 10-100 ms by binding to site 5 (delta = -0.7). The deep sites exhibit stronger ion specificity than the superficial sites. Cytoplasmic Ca2+ binds sequentially to sites 3-5 and Ca2+ at site 5 can be locked into the pore by a second Ca2+ at site 3 or 4. Ca2+ block is alleviated by increasing [K+] on the same side of the channel. Further, Ca2+ occupancy of the deep sites (2, 4, and 5) is reduced by K+, Rb+, NH4+, and Na+ on the opposite side of the pore. Their relative efficacy correlates with their relative permeability in the channel. While some Ca2+ and K+ sites compete for ions, Ca2+ and K+ can simultaneously occupy the channel. Ca2+ binding at site 1 only partially blocks channel conduction. The results suggest the presence of four K+ binding sites on the channel protein. One cytoplasmic facing site has an equilibrium affinity of 10 mM (site 6, delta = -0.3) and one vacuolar site (site 7, delta less than 0.2) has low affinity (greater than 500 mM). Divalent ion block of the Chara channel shows many similarities to that of the maxi-K channel from rat skeletal muscle.     

An ion''s view of the potassium channel. The structure of the permeation pathway as sensed by a variety of blocking ions

We have studied the block of potassium channels in voltage-clamped squid giant axons by nine organic and alkali cations, in order to learn how the channel selects among entering ions. When added to the internal solution, all of the ions blocked the channels, with inside-positive voltages enhancing the block. Cesium blocked the channels from the outside as well, with inside-negative voltages favoring block. We compared the depths to which different ions entered the channel by estimating the "apparent electrical distance" to the blocking site. Simulations with a three-barrier, double-occupancy model showed that the "apparent electrical distance," expressed as a fraction of the total transmembrane voltage, appears to be less than the actual value if the blocking ion can pass completely through the channel. These calculations strengthen our conclusion that sodium and cesium block at sites further into the channel than those occupied by lithium and the organic blockers. Our results, considered together with earlier work, demonstrate that the depth to which an ion can readily penetrate into the potassium channel depends both on its size and on the specific chemical groups on its molecular surface. The addition of hydroxyl groups to alkyl chains on a quaternary ammonium ion can both decrease the strength of binding and allow deeper penetration into the channel. For alkali cations, the degree of hydration is probably crucial in determining how far an ion penetrates. Lithium, the most strongly hydrated, appeared not to penetrate as far as sodium and cesium. Our data suggest that there are, minimally, four ion binding sites in the permeation pathway of the potassium channel, with simultaneous occupancy of at least two.     

Permeation properties of a Ca(2+)-blockable monovalent cation channel in the ectoderm of the chick embryo: pore size and multioccupancy probed with organic cations and Ca2+

A Ca(2+)-blockable monovalent cation channel is present in the apical membrane of the ectoderm of the gastrulating chick embryo. We used the patch clamp technique to study several single-channel permeation properties of this channel. In symmetrical conditions without Ca2+, the Na+ current carried by the channel rectifies inwardly. The channel has an apparent dissociation constant for extracellular Na+ of 115 mM at 0 mV and a low density of negative surface charge (-0.03 e/nm2) at its extracellular entrance. The minimal pore diameter is approximately 5.8 A, as calculated from the relative permeabilities of 10 small organic cations. Extracellular application of six large organic cations decreased the inward Na+ current in a voltage-dependent manner, which strongly suggests an intrachannel block. The presence of at least two ion binding sites inside the pore is inferred from the Na+ dependence of the block by the organic cations. This hypothesis is strengthened by the fact that the extracellular Ca2+ block is also modified by the Na+ concentration. In particular, the rise of the unblocking rate with increased Na+ concentrations clearly suggests the presence of an interaction between Ca2+ and Na+ inside the channel. A low probability of double occupancy at physiological ionic conditions is implied from the absence of an anomalous mole fraction effect with mixtures of extracellular Li+ and K+. Finally, the absence of inward current at very strong hyperpolarizations and in the presence of 10 mM extracellular Ca2+ demonstrates the absence of significant Ca2+ current through this channel. It is argued that this embryonic epithelial Ca(2+)-blockable monovalent cation channel is related to both L-type Ca2+ channel and cyclic nucleotide-gated channels.     

Two stable, conducting conformations of the selectivity filter in Shaker K+ channels

We have examined the voltage dependence of external TEA block of Shaker K(+) channels over a range of internal K(+) concentrations from 2 to 135 mM. We found that the concentration dependence of external TEA block in low internal K(+) solutions could not be described by a single TEA binding affinity. The deviation from a single TEA binding isotherm was increased at more depolarized membrane voltages. The data were well described by a two-component binding scheme representing two, relatively stable populations of conducting channels that differ in their affinity for external TEA. The relative proportion of these two populations was not much affected by membrane voltage but did depend on the internal K(+) concentration. Low internal K(+) promoted an increase in the fraction of channels with a low TEA affinity. The voltage dependence of the apparent high-affinity TEA binding constant depended on the internal K(+) concentration, becoming almost voltage independent in 5 mM. The K(+) sensitivity of these low- and high-affinity TEA states suggests that they may represent one- and two-ion occupancy states of the selectivity filter, consistent with recent crystallographic results from the bacterial KcsA K(+) channel. We therefore analyzed these data in terms of such a model and found a large (almost 14-fold) difference between the intrinsic TEA affinity of the one-ion and two-ion modes. According to this analysis, the single ion in the one-ion mode (at 0 mV) prefers the inner end of the selectivity filter twofold more than the outer end. This distribution does not change with internal K(+). The two ions in the two-ion mode prefer to occupy the inner end of the selectivity filter at low K(+), but high internal K(+) promotes increased occupancy of the outer sites. Our analysis further suggests that the four K(+) sites in the selectivity filter are spaced between 20 and 25% of the membrane electric field.     

Ionic permeability characteristics of the N-methyl-D-aspartate receptor channel

N-methyl-D-aspartate (NMDA) receptor channels in cultured CA1 hippocampal neurons were studied using patch-clamp techniques. The purpose of the research was to determine the occupancy of the channel by permeant cations and to determine the influence of charged residues in or near the pore. The concentration dependence of permeability ratios, the mole-fraction dependence of permeability ratios, the concentration dependence of the single-channel conductance, and a single-channel analysis of Mg2+ block all independently indicated that the NMDA receptor behaves as a singly-occupied channel. More precisely, there is one permeant cation at a time occupying the site or sites that are in the narrow region of the pore directly in the permeation pathway. Permeability-ratio measurements in mixtures of monovalent and divalent cations indicated that local charges in or near the pore do not produce a large local surface potential in physiologic solutions. In low ionic strength solutions, a local negative surface potential does influence the ionic environment near the pore, but in normal physiologic solutions the surface potential appears too small to significantly influence ion permeation. The results indicate that the mechanism for the high Ca2+ conductance of the NMDA receptor channel is not the same as for the voltage-dependent Ca2+ channel (VDCC). The VDCC has two high affinity, interacting binding sites that provide high Ca2+ selectivity and conductance. The binding site of the NMDA receptor is of lower affinity. Therefore, the selectivity for Ca2+ is not as high, but the lower affinity of binding provides a faster off rate so that interacting sites are not required for high conductance.     

Blockade of GABAA receptor channels by niflumic acid prevents agonist dissociation

The modulation by the nonsteroidal anti-inflammatory drug niflumic acid (NFA) of the GABAA receptor-mediated currents was studied in acutely isolated cerebellar Purkinje cells using the whole-cell recording and fast drug application system. At concentrations of 3–300 μM NFA potentiated GABA (2 μM)-activated currents, and at concentrations of 1–3 mM NFA blocked these responses. The NFA-induced block was strongly voltage-dependent. Analysis of the voltage dependence of the block suggests that the blocking action of NFA is a result of NFA binding at the site located within GABAA channel pore. The termination of GABA and NFA application was followed by a transient increase of the inward current — “tail” current. These data suggest that NFA acts as a sequential open channel blocker, which prevents dissociation of agonist while the channel is blocked. The tail current develops because, prior to dissociation of agonist, the channels that are in the blocked state must return to the close state via the open state. The tail currents were compared in the presence and absence of gabazine, a competitive antagonist that also allosterically inhibits GABA_A receptors. Application of gabazine only during development of tail current did not change neither amplitude nor time course of this current, while noncompetitive antagonists picrotoxin and penicillin blocked it. Protection of tail current from gabazine block indicates that GABA cannot dissociate from the open-blocked state and the agonist was trapped on the receptor while the channel was open. Trapping was specific for the agonist, because the positive allosteric modulator zolpidem (benzodiazepine site agonist) was able to potentiate the tail current in the absence of GABA in the external solution. Our observations provide a model-independent functional support of the hypothesis that open channel block of GABAA channels by NFA prevents an escape of the agonist from its binding sites.     

New Views of Multi-Ion Channels

The rate constants of acetylcholine receptor channels (AChR) desensitization and recovery were estimated from the durations and frequencies of clusters of single-channel currents. Diliganded-open AChR desensitize much faster than either unliganded- or diliganded-closed AChR, which indicates that the desensitization rate constant depends on the status of the activation gate rather than the occupancy of the transmitter binding sites. The desensitization rate constant does not change with the nature of the agonist, the membrane potential, the species of permeant cation, channel block by ACh, the subunit composition (ε or γ), or several mutations that are near the transmitter binding sites. The results are discussed in terms of cyclic models of AChR activation, desensitization, and recovery. In particular, a mechanism by which activation and desensitization are mediated by two distinct, but interrelated, gates in the ion permeation pathway is proposed.     

Localization, physiological significance and possible clinical implication of gastrointestinal melatonin.

The gastrointestinal tract (GIT) is a major source of extrapineal melatonin. In some animals, tissue concentrations of melatonin in the GIT surpass blood levels by 10-100 times and the digestive tract contributes significantly to melatonin concentrations in the peripheral blood, particularly during the day. Some melatonin found in the GIT may originate from the pineal gland, as the organs of the digestive system contain binding sites, which in some species exhibit circadian variation. Unlike the production of pineal melatonin, which is under the photoperiodic control, release of GI melatonin seems to be related to periodicity of food intake. Melatonin and melatonin binding sites were localized in all GI tissues of mammalian and avian embryos. Postnatally, melatonin was localized in the GIT of newborn mice and rats. Phylogenetically, melatonin and melatonin binding sites were detected in GIT of numerous mammals, birds and lower vertebrates. Melatonin is probably produced in the serotonin-rich enterochromaffin cells (EC) of the GI mucosa and can be released into the portal vein postprandially. In addition, melatonin can act as an autocrine or a paracrine hormone affecting the function of GI epithelium, lymphatic tissues of the immune system and the smooth muscles of the digestive tube. Finally, melatonin may act as a luminal hormone, synchronizing the sequential digestive processes. Higher peripheral and tissue levels of melatonin were observed not only after food intake but also after a long-term food deprivation. Such melatonin release may have a direct effect on the various GI tissues but may also act indirectly via the CNS; such action might be mediated by sympathetic or parasympathetic nerves. Melatonin can protect GI mucosa from ulceration by its antioxidant action, stimulation of the immune system and by fostering microcirculation and epithelial regeneration. Melatonin may reduce the secretion of pepsin and the hydrochloric acid and influence the activity of the myoelectric complexes of the gut via its action in the CNS. Tissue or blood levels of melatonin may serve as a marker of GI lesions or tumors. Clinically, melatonin has a potential for a prevention or treatment of colorectal cancer, ulcerative colitis, irritable bowel syndrome, children colic and diarrhea.     

Two barium binding sites on a maxi K+ channel from human vas deferens epithelial cells.

Using the patch clamp technique, we have investigated the blockade of maxi-K+ channels present on vas deferens epithelial cells by extracellular Ba2+. With symmetrical 140 mM K+ solutions, Ba2+ produced discrete blocking events consisting of both long closings of seconds duration (slow block) and fast closings of milliseconds duration (flickering block). Kinetic analysis showed that flickering block occurred according to an "open channel blocking" scheme and was eliminated by reducing external K+ to 4.5 mM. Slow block showed a complex voltage-dependence. At potentials between -20 mV and 20 mV, blockade was voltage-dependent; at potentials greater than 20 mV, blockade was voltage-independent, but markedly sensitive to the extracellular K+ concentration. These data reveal that the vas deferens maxi-K+ channel has two Ba2+ binding sites accessible from the extracellular side. Site one is located at the cytoplasmic side of the gating region and binding to this site causes flickering block. Site two is located close to the extracellular mouth of the channel and binding to this site causes slow block.     

Molecular mechanisms of neurotoxin action on voltage-gated sodium channels

Voltage-gated sodium channels are the molecular targets for a broad range of neurotoxins that act at six or more distinct receptor sites on the channel protein. These toxins fall into three groups. Both hydrophilic low molecular mass toxins and larger polypeptide toxins physically block the pore and prevent sodium conductance. Alkaloid toxins and related lipid-soluble toxins alter voltage-dependent gating of sodium channels via an allosteric mechanism through binding to intramembranous receptor sites. In contrast, polypeptide toxins alter channel gating by voltage sensor trapping through binding to extracellular receptor sites. The results of recent studies that define the receptor sites and mechanisms of action of these diverse toxins are reviewed here.     

Block of N-type Calcium Channels in Chick Sensory Neurons by External Sodium

L-type Ca²⁺ channels select for Ca²⁺ over sodium Na⁺ by an affinity-based mechanism. The prevailing model of Ca²⁺ channel permeation describes a multi-ion pore that requires pore occupancy by at least two Ca²⁺ ions to generate a Ca²⁺ current. At [Ca²⁺] < 1 μM, Ca²⁺ channels conduct Na⁺. Due to the high affinity of the intrapore binding sites for Ca²⁺ relative to Na⁺, addition of μM concentrations of Ca²⁺ block Na⁺ conductance through the channel. There is little information, however, about the potential for interaction between Na⁺ and Ca²⁺ for the second binding site in a Ca²⁺ channel already occupied by one Ca²⁺. The two simplest possibilities, (a) that Na⁺ and Ca²⁺ compete for the second binding site or (b) that full time occupancy by one Ca²⁺ excludes Na⁺ from the pore altogether, would imply considerably different mechanisms of channel permeation. We are studying permeation mechanisms in N-type Ca²⁺ channels. Similar to L-type Ca²⁺ channels, N-type channels conduct Na⁺ well in the absence of external Ca²⁺. Addition of 10 μM Ca²⁺ inhibited Na⁺ conductance by 95%, and addition of 1 mM Mg²⁺ inhibited Na⁺ conductance by 80%. At divalent ion concentrations of 2 mM, 120 mM Na⁺ blocked both Ca²⁺ and Ba²⁺ currents. With 2 mM Ba²⁺, the IC₅₀ for block of Ba²⁺ currents by Na⁺ was 119 mM. External Li⁺ also blocked Ba²⁺ currents in a concentration-dependent manner, with an IC₅₀ of 97 mM. Na⁺ block of Ba²⁺ currents was dependent on [Ba²⁺]; increasing [Ba²⁺] progressively reduced block with an IC₅₀ of 2 mM. External Na⁺ had no effect on voltage-dependent activation or inactivation of the channel. These data suggest that at physiological concentrations, Na⁺ and Ca²⁺ compete for occupancy in a pore already occupied by a single Ca²⁺. Occupancy of the pore by Na⁺ reduced Ca²⁺ channel conductance, such that in physiological solutions, Ca²⁺ channel currents are between 50 and 70% of maximal.