Interaction of Ba2+ with the pores of the cloned inward rectifier K+ channels Kir2.1 expressed in Xenopus oocytes.

Interactions of Ba2+ with K+ and molecules contributing to inward rectification were studied in the cloned inward rectifier K+ channels, Kir2.1. Extracellular Ba2+ blocked Kir2.1 channels with first-order kinetics in a Vm-dependent manner. At Vm more negative than -120 mV, the Kd-Vm relationship became less steep and the dissociation rate constants were larger, suggesting Ba2+ dissociation into the extracellular space. Both depolarization and increasing [K+]i accelerated the recovery from extracellular Ba2+ blockade. Intracellular K+ appears to relieve Ba2+ blockade by competitively slowing the Ba2+ entrance rate, instead of increasing its exit rate by knocking off action. Intracellular spermine (100 microM) reduced, whereas 1 mM [Mg2+]i only slightly reduced, the ability of intracellular K+ to repulse Ba2+ from the channel pore. Intracellular Ba2+ also blocked outward IKir2.1 in a voltage-dependent fashion. At Vm >/= +40 mV, where intrinsic inactivation is prominent, intracellular Ba2+ accelerated the inactivation rate of the outward IKir2.1 in a Vm-independent manner, suggesting interaction of Ba2+ with the intrinsic gate of Kir2.1 channels.     

Activation of inward rectifier K+ channels by hypoxia in rabbit coronary arterial smooth muscle cells

We examined the effects of acute hypoxia on Ba2+-sensitive inward rectifier K+ (K(IR)) current in rabbit coronary arterial smooth muscle cells. The amplitudes of K(IR) current was definitely higher in the cells from small-diameter (<100 microm) coronary arterial smooth muscle cells (SCASMC, -12.8 +/- 1.3 pA/pF at -140 mV) than those in large-diameter coronary arterial smooth muscle cells (>200 microm, LCASMC, -1.5 +/- 0.1 pA pF(-1)). Western blot analysis confirmed that Kir2.1 protein was expressed in SCASMC but not LCASMC. Hypoxia activated much more KIR currents in symmetrical 140 K+. This effect was blocked by the adenylyl cyclase inhibitor SQ-22536 (10 microM) and mimicked by forskolin (10 microM) and dibutyryl-cAMP (500 microM). The production of cAMP in SCASMC increased 5.7-fold after 6 min of hypoxia. Hypoxia-induced increase in KIR currents was abolished by the PKA inhibitors, Rp-8-(4-chlorophenylthio)-cAMPs (10 microM) and KT-5720 (1 microM). The inhibition of G protein with GDPbetaS (1 mM) partially reduced (approximately 50%) the hypoxia-induced increase in KIR currents. In Langendorff-perfused rabbit hearts, hypoxia increased coronary blood flow, an effect that was inhibited by Ba2+. In summary, hypoxia augments the KIR currents in SCASMC via cAMP- and PKA-dependent signaling cascades, which might, at least partly, explain the hypoxia-induced coronary vasodilation.     

L-type Ca2+ channels and K+ channels specifically modulate the frequency and amplitude of spontaneous Ca2+ oscillations and have distinct roles in prolactin release in GH3 cells

GH3 cells showed spontaneous rhythmic oscillations in intracellular calcium concentration ([Ca2+]i) and spontaneous prolactin release. The L-type Ca2+ channel inhibitor nimodipine reduced the frequency of Ca2+ oscillations at lower concentrations (100nM-1 microM), whereas at higher concentrations (10 microM), it completely abolished them. Ca2+ oscillations persisted following exposure to thapsigargin, indicating that inositol 1,4,5-trisphosphate-sensitive intracellular Ca2+ stores were not required for spontaneous activity. The K+ channel inhibitors Ba2+, Cs+, and tetraethylammonium (TEA) had distinct effects on different K+ currents, as well as on Ca2+ oscillations and prolactin release. Cs+ inhibited the inward rectifier K+ current (KIR) and increased the frequency of Ca2+ oscillations. TEA inhibited outward K+ currents activated at voltages above -40 mV (grouped within the category of Ca2+ and voltage-activated currents, KCa,V) and increased the amplitude of Ca2+ oscillations. Ba2+ inhibited both KIR and KCa,V and increased both the amplitude and the frequency of Ca2+ oscillations. Prolactin release was increased by Ba2+ and Cs+ but not by TEA. These results indicate that L-type Ca2+ channels and KIR channels modulate the frequency of Ca2+ oscillations and prolactin release, whereas TEA-sensitive KCa,V channels modulate the amplitude of Ca2+ oscillations without altering prolactin release. Differential regulation of these channels can produce frequency or amplitude modulation of calcium signaling that stimulates specific pituitary cell functions.     

Investigation of the binding of Ca2+, Mg2+, Mn2+ and K+ to the vitamin D-dependent Ca2+-binding protein from pig duodenum.

The cation-binding properties of the vitamin D-dependent Ca2+-binding protein from pig duodenum were investigated, mainly by flow dialysis. The protein bound two Ca2+ ions with high affinity, and Mg2+, Mn2+ and K+ were all bound competitively with Ca2+ at both sites. The sites were distinguished by their different affinities for Mn2+, the one with the higher affinity being designated A (Kd 0.61 +/- 0.02 microM) and the other B (Kd 50 +/- 6 microM). Competitive binding studies allied to fluorimetric titration with Mg2+ showed that site A bound Ca2+, Mg2+ and K+ with Kd values of 4.7 +/- 0.8 nM, 94 +/- 18 microM and 1.6 +/- 0.3 mM respectively, and site B bound the same three cations with Kd values of 6.3 +/- 1.8 nM, 127 +/- 38 microM and 2.1 +/- 0.6 mM. For the binding of these cations, therefore, there was no significant difference between the two sites. In the presence of 1 mM-Mg2+ and 150 mM-K+, both sites bound Ca2+ with an apparent Kd of 0.5 microM. The cation-binding properties were discussed relative to those of parvalbumin, troponin C and the vitamin D-dependent Ca2+-binding protein from chick duodenum.     

Permeation and gating properties of the L-type calcium channel in mouse pancreatic beta cells

Ba2+ currents through L-type Ca2+ channels were recorded from cell- attached patches on mouse pancreatic beta cells. In 10 mM Ba2+, single- channel currents were recorded at -70 mV, the beta cell resting membrane potential. This suggests that Ca2+ influx at negative membrane potentials may contribute to the resting intracellular Ca2+ concentration and thus to basal insulin release. Increasing external Ba2+ increased the single-channel current amplitude and shifted the current-voltage relation to more positive potentials. This voltage shift could be modeled by assuming that divalent cations both screen and bind to surface charges located at the channel mouth. The single- channel conductance was related to the bulk Ba2+ concentration by a Langmuir isotherm with a dissociation constant (Kd(gamma)) of 5.5 mM and a maximum single-channel conductance (gamma max) of 22 pS. A closer fit to the data was obtained when the barium concentration at the membrane surface was used (Kd(gamma) = 200 mM and gamma max = 47 pS), which suggests that saturation of the concentration-conductance curve may be due to saturation of the surface Ba2+ concentration. Increasing external Ba2+ also shifted the voltage dependence of ensemble currents to positive potentials, consistent with Ba2+ screening and binding to membrane surface charge associated with gating. Ensemble currents recorded with 10 mM Ca2+ activated at more positive potentials than in 10 mM Ba2+, suggesting that external Ca2+ binds more tightly to membrane surface charge associated with gating. The perforated-patch technique was used to record whole-cell currents flowing through L-type Ca2+ channels. Inward currents in 10 mM Ba2+ had a similar voltage dependence to those recorded at a physiological Ca2+ concentration (2.6 mM). BAY-K 8644 (1 microM) increased the amplitude of the ensemble and whole-cell currents but did not alter their voltage dependence. Our results suggest that the high divalent cation solutions usually used to record single L-type Ca2+ channel activity produce a positive shift in the voltage dependence of activation (approximately 32 mV in 100 mM Ba2+).     

The role of Mg2+ in the inactivation of inwardly rectifying K+ channels in aortic endothelial cells

We have studied the role of Mg2+ in the inactivation of inwardly rectifying K+ channels in vascular endothelial cells. Inactivation was largely eliminated in Mg(2+)-free external solutions and the extent of inactivation was increased by raising Mg2+o. The dose-response relation for the reduction of channel open probability showed that Mg2+o binds to a site (KD = approximately 25 microM at -160 mV) that senses approximately 38% of the potential drop from the external membrane surface. Analysis of the single-channel kinetics showed that Mg2+ produced a class of long-lived closures that separated bursts of openings. Raising Mg2+o reduced the burst duration, but less than expected for an open-channel blocking mechanism. The effects of Mg2+o are antagonized by K+o in manner which suggests that K+ competes with Mg2+ for the inactivation site. Mg2+o also reduced the amplitude of the single-channel current at millimolar concentrations by a rapid block of the open channel. A mechanism is proposed in which Mg2+ binds to the closed channel during hyperpolarization and prevents it from opening until it is occupied by K+.     

Exaggerated Mg2+ Inhibition of KCNJ2 as a Consequence of Reduced PIP2 Sensitivity in Andersen Syndrome

Andersen syndrome is an autosomal dominant disorder characterized by cardiac arrhythmias, periodic paralysis and dysmorphic features. Many Andersen syndrome cases have been associated with loss-of-function mutations in the inward rectifier K+ channel Kir2.1 encoded by KCNJ2. Using engineered concatenated tetrameric channels we determined the mechanism for dominant loss-of-function associated with a trafficking-competent missense mutation, Kir2.1-T74A. This mutation alters a conserved threonine residue in an N-terminal domain analogous to the slide helix identified in the structure of a bacterial inward rectifier. Incorporation of a single mutant subunit in channel tetramers was sufficient to cause a selective impairment of whole-cell outward current, but no difference in the level of inward current compared with wild-type (WT) tetramers. The presence of two mutant subunits resulted in greatly reduced outward and impaired inward currents. Experiments using excised inside-out membrane patches revealed that tetramers with one mutant subunit exhibited increased Mg2+ inhibition. Additional experiments demonstrated that concatenated tetramers containing one T74A subunit had reduced PIP2 sensitivity, and that outward current carried by mutant tetramers could be restored by addition of PIP2 in the absence of Mg2+. Our results are consistent with the involvement of the Kir2.1 N-terminus in PIP2 modulation of channel activity and support the existence of an inverse relationship between PIP2 sensitivity and Mg2+ inhibition of Kir2.1 channels. Our data also indicate that a single mutant subunit is sufficient to explain dominant-negative behavior of Kir2.1-T74A in Andersen syndrome.     

External barium influences the gating charge movement of Shaker potassium channels.

External Ba2+ speeds the OFF gating currents (IgOFF) of Shaker K+ channels but only upon repolarization from potentials that are expected to open the channel pore. To study this effect we used a nonconducting and noninactivating mutant of the Shaker K+ channel, ShH4-IR (W434F). External Ba2+ slightly decreases the quantity of ON gating charge (QON) upon depolarization to potentials near -30 mV but has little effect on the quantity of charge upon stepping to more hyperpolarized or depolarized potentials. More strikingly, Ba2+ significantly increases the decay rate of IgOFF upon repolarization to -90 mV from potentials positive to approximately -55 mV. For Ba2+ to have this effect, the depolarizing command must be maintained for a duration that is dependent on the depolarizing potential (> 4 ms at -30 mV and > 1 ms at 0 mV). The actions of Ba2+ on the gating current are dose-dependent (EC50 approximately 0.2 mM) and are not produced by either Ca2+ or Mg2+ (2 mM). The results suggest that Ba2+ binds to a specific site on the Shaker K+ channel that destabilizes the open conformation and thus facilitates the return of gating charge upon repolarization.     

Surface charge and properties of cardiac ATP-sensitive K+ channels

ATP-sensitive K+ (KATP) channels are present in a wide variety of tissues. The sensitivity of these channels to closure by cytosolic ATP (ATPi) varies significantly among different tissues and even within the same tissue. The purpose of this study was to test the hypothesis that negative surface charges modulate the sensitivity of the KATP channels to ATPi by influencing surface potential in the vicinity of the ATP- binding site(s) of the channel. Unitary currents through KATP channels were measured in inside-out membrane patches excised from rabbit ventricular myocytes using the patch-clamp technique. Agents known to be effective at screening negative surface charges were applied to the cytosolic surface of the patches, and their effects on ATP sensitivity were examined. These agents included Mg2+ (2-15 mM), Ba2+ (2-10 mM), and the polycations protamine (0.01-10 microM), poly-L-lysine (500 microM), and poly-L-arginine (0.5 microM). The divalent cations and the various polycations all dramatically reduced the concentration of ATPi required to half-maximally suppress current through KATP channels (Kd), from approximately 100 microM in the absence of these agents to 1.6-8 microM in their presence. The effects were dose dependent. Protamine also reduced the sensitivity of KATP channels to block by cytosolic ADP. The sensitivity of KATP channels to block by ATP was independent of membrane potential, suggesting that the ATP-binding site is not located within the transmembrane voltage field. The effects of the polycation poly-L-lysine on ATP sensitivity were also independent of membrane potential or the direction (inward or outward) of current through KATP channels. In addition to increasing ATP sensitivity, Mg2+, Ba2+, and the polycations all caused dose-dependent block of inward and outward currents through KATP channels over similar concentration ranges as their effects on ATP sensitivity. The block of inward current by polycations was not associated with reduction of single-channel conductance or evidence of fast open channel block. However, the polycations did cause a modest reduction in single-channel conductance of outward current. These results are consistent with the presence of negative surface charges that reduce the local ATP concentration at the ATP-binding site(s) on the channel, relative to the bulk cytosolic ATP concentration. Screening these negative surface charges with divalent cations or polycations decreases the local ATP gradient, resulting in a decrease in the apparent Kd for ATP.(ABSTRACT TRUNCATED AT 400 WORDS)     

Interaction of internal Ba2+ with a cloned Ca(2+)-dependent K+ (hslo) channel from smooth muscle

We have studied potassium currents through a cloned Ca(2+)-dependent K+ channel (hslo) from human myometrium. Currents were recorded in inside- out macropatches from membranes of Xenopus laevis oocytes. In particular, the inactivation-like process that these channels show at high positive potentials was assessed in order to explore its molecular nature. This current inhibition conferred a bell shape to the current- voltage curves. The kinetic and voltage dependence of this process suggested the possibility of a Ba2+ block. There were the following similarities between the inactivation process observed at zero-added Ba2+ and the internal Ba2+ block of hslo channels: (a) in the steady state, the voltage dependence of the current inhibition observed at zero-added Ba2+ was the same as the voltage dependence of the Ba2+ block; (b) the time constant for recovery from current decay at zero- added Ba2+ was the same as the time constant for current recovery from Ba2+ blockade; and (c) current decay was largely suppressed in both cases by adding a Ba2+ chelator [(+)-18-crown-6-tetracarboxylic acid] to the internal solution. In our experimental conditions, we determined that the Kd for the complex chelator-Ba2+ is 1.6 x 10(-10) M. We conclude that the current decay observed at zero-added Ba2+ to the internal solution is due to contaminant Ba2+ present in our solutions (approximately 70 nM) and not to an intrinsic gating process. The Ba2+ blocking reaction in hslo channels is bimolecular. Ba2+ binds to a site (Kd = 0.36 +/- 0.05 mM at zero applied voltage) that senses 92 +/- 25% of the potential drop from the internal membrane surface.     

Block of CaV1.2 channels by Gd3+ reveals preopening transitions in the selectivity filter

Using the lanthanide gadolinium (Gd(3+)) as a Ca(2+) replacing probe, we investigated the voltage dependence of pore blockage of Ca(V)1.2 channels. Gd(+3) reduces peak currents (tonic block) and accelerates decay of ionic current during depolarization (use-dependent block). Because diffusion of Gd(3+) at concentrations used (<1 microM) is much slower than activation of the channel, the tonic effect is likely to be due to the blockage that occurred in closed channels before depolarization. We found that the dose-response curves for the two blocking effects of Gd(3+) shifted in parallel for Ba(2+), Sr(2+), and Ca(2+) currents through the wild-type channel, and for Ca(2+) currents through the selectivity filter mutation EEQE that lowers the blocking potency of Gd(3+). The correlation indicates that Gd(3+) binding to the same site causes both tonic and use-dependent blocking effects. The apparent on-rate for the tonic block increases with the prepulse voltage in the range -60 to -45 mV, where significant gating current but no ionic current occurs. When plotted together against voltage, the on-rates of tonic block (-100 to -45 mV) and of use-dependent block (-40 to 40 mV) fall on a single sigmoid that parallels the voltage dependence of the gating charge. The on-rate of tonic block by Gd(3+) decreases with concentration of Ba(2+), indicating that the apparent affinity of the site to permeant ions is about 1 mM in closed channels. Therefore, we propose that at submicromolar concentrations, Gd(3+) binds at the entry to the selectivity locus and that the affinity of the site for permeant ions decreases during preopening transitions of the channel.     

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.     

TWIK-1, a ubiquitous human weakly inward rectifying K+ channel with a novel structure.

A new human weakly inward rectifying K+ channel, TWIK-1, has been isolated. This channel is 336 amino acids long and has four transmembrane domains. Unlike other mammalian K+ channels, it contains two pore-forming regions called P domains. Genes encoding structural homologues are present in the genome of Caenorhabditis elegans. TWIK-1 currents expressed in Xenopus oocytes are time-independent and present a nearly linear I-V relationship that saturated for depolarizations positive to O mV in the presence of internal Mg2+. This inward rectification is abolished in the absence of internal Mg2+. TWIK-1 has a unitary conductance of 34 pS and a kinetic behaviour that is dependent on the membrane potential. In the presence of internal Mg2+, the mean open times are 0.3 and 1.9 ms at -80 and +80 mV, respectively. The channel activity is up-regulated by activation of protein kinase C and down-regulated by internal acidification. Both types of regulation are indirect. TWIK-1 channel activity is blocked by Ba2+(IC50=100 microM), quinine (IC50=50 microM) and quinidine (IC50=95 microM). This channel is of particular interest because its mRNA is widely distributed in human tissues, and is particularly abundant in brain and heart. TWIK-1 channels are probably involved in the control of background K+ membrane conductances.     

External barium block of Shaker potassium channels: evidence for two binding sites

External barium ions inhibit K+ currents of Xenopus oocytes expressing ShH4 delta 6-46, the non-inactivating deletion of the Shaker K+ channel. At the macroscopic level, Ba2+ block comprises both a fast and a slow component. The fast component is less sensitive to Ba2+ (apparent dissociation constant at 0 mV, K(0), approximately 19.1 mM) than the slow component and is also less voltage dependent (apparent electrical distance, delta, approximately 0.14). The slow component (K(0), approximately 9.4 mM, delta approximately 0.25) is relieved by outward K+ current, which suggests that the corresponding binding site resides within the channel conduction pathway. At the single channel level, the fast component of block is evidenced as an apparent reduction in amplitude, suggesting an extremely rapid blocking and unblocking reaction. In contrast, the slow component appears to be associated with long blocked times that are present from the beginning of a depolarizing command. Installation of the slow component is much slower than a diffusion limited process; for example, the blocking time constant (tau) produced by 2 mM Ba2+ is approximately 159 s (holding potential, HP = -90 mV). However, the blocking rate of this slow component is not a linear function of external Ba2+ and tends to saturate at higher concentrations. This is inconsistent with a simple bi-molecular blocking reaction. These features of external Ba2+ block can be accounted for by a simple model of two sequential Ba2+ binding sites, where the deeper of the two sites produces the slow component of block.     

Vasa recta pericytes express a strong inward rectifier K+ conductance

Strong inward rectifier potassium channels are expressed by some vascular smooth muscle cells and facilitate K+-induced hyperpolarization. Using whole cell patch clamp of isolated descending vasa recta (DVR), we tested whether strong inward rectifier K+ currents are present in smooth muscle and pericytes. Increasing extracellular K+ from 5 to 50 and 140 mmol/l induced inward rectifying currents. Those currents were Ba2+ sensitive and reversed at the K+ equilibrium potential imposed by the electrode and extracellular buffers. Ba2+ binding constants in symmetrical K+ varied between 0.24 and 24 micromol/l at -150 and -20 mV, respectively. Ba2+ blockade was time and voltage dependent. Extracellular Cs+ also blocked the inward currents with binding constants between 268 and 4,938 micromol/l at -150 and -50 mV, respectively. Ba2+ (30 micromol/l) and ouabain (1 mmol/l) depolarized pericytes by an average of 11 and 24 mV, respectively. Elevation of extracellular K+ from 5 to 10 mmol/l hyperpolarized pericytes by 6 mV. That hyperpolarization was reversed by Ba2+ (30 micromol/l). We conclude that strong inward rectifier K+ channels and Na+-K+-ATPase contribute to resting potential and that KIR channels can mediate K+-induced hyperpolarization of DVR pericytes.     

Purified IP3 receptor from smooth muscle forms an IP3 gated and heparin sensitive Ca2+ channel in planar bilayers.

The IP3 receptor of aortic smooth muscle, purified to near homogeneity, was incorporated into vesicle derived planar bilayers. The receptor forms channels which are gated by Ins(1,4,5)P3 (0.5 microM) and are permeable to Ca2+ (Ca2+ greater than K+ much greater than Cl-). Channel activation is specific for Ins(1,4,5)P3. Essentially no activation of channel currents was found for Ins(1,3,4)P3 or Ins(1,3,4,5)P4 at 10 microM. Heparin (25 micrograms/ml) blocked induced currents completely at all levels of activity while ATP (50 microM) increased mean current levels 2 to 4 fold. Ins(1,4,5)P3 activated mean currents increased non-linearly with voltage above about -40 mV applied voltage. Mean current levels could be reversibly adjusted by voltage to the single channel level (0 to -50 mV) or to macroscopic levels (-50 to -100 mV) over periods exceeding 1 h. Single channel events are characterized by fast transitions between predominantly non-resolved sublevels. Estimates of maximal single event currents yield a slope conductance of 32 +/- 4 pS (0 to -60 mV, 50 mM CaCl2). Thus, the purified IP3 receptor forms a channel with functional properties characteristic of IP3 triggered Ca2+ release.     

High-affinity binding of Ca2+ to bovine alpha-lactalbumin in the absence and presence of EGTA.

Literature values for the Kd for Ca2+ in bovine alpha-lactalbumin range over 3 orders of magnitude. There is a difference between two results obtained with EGTA as a metal-ion buffer, partly because different values for the Kd of Ca2+-EGTA were used in the calculations, and a much wider difference between results obtained in the presence and absence of EGTA, which has been attributed to an interaction between EGTA and the protein. Titrations in a flow-dialysis cell showed that Mn2+ competed with Ca2+ for the high-affinity site on the protein, and the results, combined with a Kd for Mn2+ of 2.1 +/- 0.1 microM, which was determined fluorimetrically, gave a Kd for Ca2+ of 1.3 +/- 0.1 nM. When alpha-lactalbumin containing 45Ca2+ was titrated with EGTA in a flow-dialysis cell, and widely accepted metal-chelation data for EGTA were used in the calculations, a Kd for Ca2+ of 1.10 +/- 0.03 nM was obtained. The results from the two methods are so similar as to indicate that the affinity for Ca2+ was unaffected by the presence of EGTA.     

Ser165 in the second transmembrane region of the Kir2.1 channel determines its susceptibility to blockade by intracellular Mg2+

The strong inward rectification of Kir2.1 currents is reportedly due to blockade of the outward current by cytoplasmic magnesium (Mg(2+)(i)) and polyamines, and is known to be determined in part by three negatively charged amino acid residues: Asp172, Glu224, and Glu299 (D172, E224, E299). Our aim was to identify additional sites contributing to the inward rectification of Kir2.1 currents. To accomplish this, we introduced into wild-type Kir2.1 and its D172N and D172N & E224G & E299S mutants various point mutations selected on the basis of a comparison of the sequences of Kir2.1 and the weak rectifier sWIRK. By analyzing macroscopic currents recorded from Xenopus oocytes using two-electrode voltage clamp, we determined that S165L mutation decreases inward rectification, especially with the triple mutant. The susceptibility to blockade by intracellular blockers was examined using HEK293 transfectants and the inside-out patch clamp configuration. The sensitivity to spermine was significantly diminished in the D172N and triple mutant, but not the S165L mutant. Both the S165L and D172N mutants were less susceptible to blockade by Mg(2+)(i) than the wild-type channel, and the susceptibility was still lower in the D172N & S165L double mutant. These results suggest that S165 is situated deeper into the pore from inside than D172, where it is accessible to Mg(2+)(i) but not to spermine. The single channel conductance of the D172N mutant was similar to that of the wild-type Kir2.1, whereas the conductance of the S165L mutant was significantly lower. Permeation by extracellular Rb+ (Rb(+)(o)) was dramatically increased by S165L mutation, but was increased only slightly by D172N mutation. By contrast, the Rb+/K+ permeability ratio was increased equally by D172N and S165L mutation. We therefore propose that S165 forms the narrowest part of the Kir2.1 pore, where both extracellular and intracellular blockers plug the permeation pathway.