Inhibition of potassium conductance by barium in frog skin epithelium.

The effect of Ba2+ (0.5 mM, corial side) upon the transport characteristics of the frog skin epithelium was investigated. It was observed that Ba2+ decreased the conductance of the preferably K+-permeable basolateral border to less than 30% of its control value. Furthermore, Ba2+ abolished the K+ electrode-like behaviour, existing at the basolateral membrane under conditions of zero transcellular current flow, for [K+] below 10--15 mM. Effects upon other parameters of transepithelial transport (electromotive forces and resistance of outer or basolateral border and shunt pathway, respectively) were small and might represent secondary events. It is concluded that Ba2+ inhibits passive fluxes of K+ across basolateral membranes of tight, Na+ transporting epithelia, similar to its influence upon membranes of nonpolar cells.     

Inhibition of potassium conductance by barium in frog skin epithelium

The effect of Ba²⁺ (0.5 mM, corial side) upon the transport characteristics of the frog skin epithelium was investigated. It was observed that Ba²⁺ decreased the conductance of the preferably K⁺-permeable basolateral border to less than 30% of its control value. Furthermore, Ba²⁺ abolished the K⁺ electrode-like behaviour, existing at the basolateral membrane under conditions of zero transcellular current flow, for [K⁺] below 10–15 mM. Effects upon other parameters of transepithelial transport (electromotive forces and resistance of outer or basolateral border and shunt pathway, respectively) were small and might represent secondary events. It is concluded that Ba²⁺ inhibits passive fluxes of K⁺ across basolateral membranes of tight, Na⁺ transporting epithelia, similar to its influence upon membranes of nonpolar cells.     

Basolateral Cl- channels in the larval bullfrog skin epithelium

The addition of 150 U/ml nystatin to the mucosal surface of isolated skin from larval bullfrogs increases apical membrane permeability and allows a voltage clamp to be applied to the basolateral membrane. With identical Ringer's solutions bathing either side of the tissue the short-circuit current (I(SC)) averaged 7.60+/-0.78 micro A/cm2, and this current could be increased or decreased by imposing a Cl- concentration gradient. Fluctuation analysis of the I(SC) gave power spectra that could be fit with low- and high-frequency Lorentzian functions having corner frequencies of 1.48+/-0.06 Hz and 48.5+/-11.4 Hz, respectively. The Lorentzian plateau was minimal at the lowest I(SC) and increased as the I(SC) became greater in the positive or negative direction. Current-voltage plots with identical Ringer's on either side of the tissue showed a pattern of outward rectification. Cell attached patches of cells isolated from the skin with collagenase-trypsin treatment showed spontaneous channel activity with a conductance of 20.9 pS at a pipette potential, -Vp=20 mV. Current-voltage plots of single channels showed a similar pattern of rectification to that of the intact skin, and partial replacement of Cl- by gluconate in the pipette solution shifted the reversal potential from zero to about 40 mV, which is close to the expected shift of the reversal potential of the chloride current through a Cl- selective ion channel. These results suggest that the basolateral Cl- conductance of the larval skin is mediated by a channel with properties that resemble a volume-sensing outward-rectifier anion channel that has been described in a variety of cell types     

Basolateral membrane K permselectivity and regulation in bullfrog cornea epithelium

Summary Ion channels permeable to barium and calcium were reconstituted from theAplysia nervous system into phospholipid bilayers formed on the tips of patch electrodes. With asymmetrical concentrations of barium or calcium on the two sides of the bilayer, the single-channel currents reversed at the calculated barium or calcium reversal potentials, indicating that the channels were cation selective. Channels with conductances of 10, 25 and 36 pS were routinely observed. Calcium and barium were equally effective as charge carriers for the 36-pS channel, whereas magnesium was at least fifteenfold less effective. The gating of all three channels was independent of the voltage across the bilayer, but was affected by the dihydropyridine calcium channel agonist Bay K 8644 (Bay K). In the presence of Bay K but not in its absence, long discrete gating events were routinely observed, suggesting that the dihydropyridine increased the probability of long open states as it does for calcium channels in other systems.Bilayers invariably contained more than a single channel (or conductance state). This was observed even when theAplysia nervous system membranes were prepared in the presence of cytoskeleton disrupting agents, or when the membrane proteins were diluted extensively with exogenous phospholipid. Furthermore, transitions between conductance levels were observed with high frequency. These findings, together with the fact that all of the conductance states share certain properties including voltage-independence and sensitivity to Bay K, suggest that the apparent multiple channel types may in fact represent subconductance states of a single ion channel.     

Basolateral membrane K+ channels in renal epithelial cells

The major function of epithelial tissues is to maintain proper ion, solute, and water homeostasis. The tubule of the renal nephron has an amazingly simple structure, lined by epithelial cells, yet the segments (i.e., proximal tubule vs. collecting duct) of the nephron have unique transport functions. The functional differences are because epithelial cells are polarized and thus possess different patterns (distributions) of membrane transport proteins in the apical and basolateral membranes of the cell. K(+) channels play critical roles in normal physiology. Over 90 different genes for K(+) channels have been identified in the human genome. Epithelial K(+) channels can be located within either or both the apical and basolateral membranes of the cell. One of the primary functions of basolateral K(+) channels is to recycle K(+) across the basolateral membrane for proper function of the Na(+)-K(+)-ATPase, among other functions. Mutations of these channels can cause significant disease. The focus of this review is to provide an overview of the basolateral K(+) channels of the nephron, providing potential physiological functions and pathophysiology of these channels, where appropriate. We have taken a "K(+) channel gene family" approach in presenting the representative basolateral K(+) channels of the nephron. The basolateral K(+) channels of the renal epithelia are represented by members of the KCNK, KCNJ, KCNQ, KCNE, and SLO gene families.     

Maxi K+ channels and their relationship to the apical membrane conductance in Necturus gallbladder epithelium

Using the patch-clamp technique, we have identified large-conductance (maxi) K+ channels in the apical membrane of Necturus gallbladder epithelium, and in dissociated gallbladder epithelial cells. These channels are more than tenfold selective for K+ over Na+, and exhibit unitary conductance of approximately 200 pS in symmetric 100 mM KCl. They are activated by elevation of internal Ca2+ levels and membrane depolarization. The properties of these channels could account for the previously observed voltage and Ca2+ sensitivities of the macroscopic apical membrane conductance (Ga). Ga was determined as a function of apical membrane voltage, using intracellular microelectrode techniques. Its value was 180 microS/cm2 at the control membrane voltage of -68 mV, and increased steeply with membrane depolarization, reaching 650 microS/cm2 at -25 mV. We have related maxi K+ channel properties and Ga quantitatively, relying on the premise that at any apical membrane voltage Ga comprises a leakage conductance and a conductance due to maxi K+ channels. Comparison between Ga and maxi K+ channels reveals that the latter are present at a surface density of 0.09/microns 2, are open approximately 15% of the time under control conditions, and account for 17% of control Ga. Depolarizing the apical membrane voltage leads to a steep increase in channel steady-state open probability. When correlated with patch-clamp studies examining the Ca2+ and voltage dependencies of single maxi K+ channels, results from intracellular microelectrode experiments indicate that maxi K+ channel activity in situ is higher than predicted from the measured apical membrane voltage and estimated bulk cytosolic Ca2+ activity. Mechanisms that could account for this finding are proposed.     

cAMP-activated apical membrane chloride channels in Necturus gallbladder epithelium. Conductance, selectivity, and block

Elevation of intracellular cAMP levels in Necturus gallbladder epithelium (NGB) induces an apical membrane Cl- conductance (GaCl). Its characteristics (i.e., magnitude, anion selectivity, and block) were studied with intracellular microelectrode techniques. Under control conditions, the apical membrane conductance (Ga) was 0.17 mS.cm-2, primarily ascribable to GaK. With elevation of cell cAMP to maximum levels, Ga increased to 6.7 mS.cm-2 and became anion selective, with the permeability sequence SCN- > NO3- > I- > Br- > Cl- >> SO4(2-) approximately gluconate approximately cyclamate. GaCl was not affected by the putative Cl- channel blockers Cu2+, DIDS, DNDS, DPC, furosemide, IAA-94, MK-196, NPPB, SITS, verapamil, and glibenclamide. To characterize the cAMP-activated Cl- channels, patch-clamp studies were conducted on the apical membrane of enzyme-treated gallbladders or on dissociated cells from tissues exposed to both theophylline and forskolin. Two kinds of Cl- channels were found. With approximately 100 mM Cl- in both bath and pipette, the most frequent channel had a linear current-voltage relationship with a slope conductance of approximately 10 pS. The less frequent channel was outward rectifying with slope conductances of approximately 10 and 20 pS at -40 and 40 mV, respectively. The Cl- channels colocalized with apical maxi-K+ channels in 70% of the patches. The open probability (Po) of both kinds of Cl- channels was variable from patch to patch (0.3 on average) and insensitive to [Ca2+], membrane voltage, and pH. The channel density (approximately 0.3/patch) was one to two orders of magnitude less than that required to account for GaCl. However, addition of 250 U/ml protein kinase A plus 1 mM ATP to the cytosolic side of excised patches increased the density of the linear 10-pS Cl- channels more than 10- fold to four per patch and the mean Po to 0.5, close to expectations from GaCl. The permeability sequence and blocker insensitivity of the PKA-activated channels were identical to those of the apical membrane. These data strongly suggest that 10-pS Cl- channels are responsible for the cAMP-induced increase in apical membrane conductance of NGB epithelium.     

Carboxy-terminal determinants of conductance in inward-rectifier K channels

Previous studies suggested that the cytoplasmic COOH-terminal portions of inward rectifier K channels could contribute significant resistance barriers to ion flow. To explore this question further, we exchanged portions of the COOH termini of ROMK2 (Kir1.1b) and IRK1 (Kir2.1) and measured the resulting single-channel conductances. Replacing the entire COOH terminus of ROMK2 with that of IRK1 decreased the chord conductance at V(m) = -100 mV from 34 to 21 pS. The slope conductance measured between -60 and -140 mV was also reduced from 43 to 31 pS. Analysis of chimeric channels suggested that a region between residues 232 and 275 of ROMK2 contributes to this effect. Within this region, the point mutant ROMK2 N240R, in which a single amino acid was exchanged for the corresponding residue of IRK1, reduced the slope conductance to 30 pS and the chord conductance to 22 pS, mimicking the effects of replacing the entire COOH terminus. This mutant had gating and rectification properties indistinguishable from those of the wild-type, suggesting that the structure of the protein was not grossly altered. The N240R mutation did not affect block of the channel by Ba(2+), suggesting that the selectivity filter was not strongly affected by the mutation, nor did it change the sensitivity to intracellular pH. To test whether the decrease in conductance was independent of the selectivity filter we made the same mutation in the background of mutations in the pore region of the channel that increased single-channel conductance. The effects were similar to those predicted for two independent resistors arranged in series. The mutation increased conductance ratio for Tl(+):K(+), accounting for previous observations that the COOH terminus contributed to ion selectivity. Mapping the location onto the crystal structure of the cytoplasmic parts of GIRK1 indicated that position 240 lines the inner wall of this pore and affects the net charge on this surface. This provides a possible structural basis for the observed changes in conductance, and suggests that this element of the channel protein forms a rate-limiting barrier for K(+) transport.     

Basolateral potassium channels of rabbit colon epithelium: role in sodium absorption and chloride secretion

In order to assess the role of different classes of K(+) channels in recirculation of K(+) across the basolateral membrane of rabbit distal colon epithelium, the effects of various K(+) channel inhibitors were tested on the activity of single K(+) channels from the basolateral membrane, on macroscopic basolateral K(+) conductance, and on the rate of Na(+) absorption and Cl(-) secretion. In single-channel measurements using the lipid bilayer reconstitution system, high-conductance (236 pS), Ca(2+)-activated K(+) (BK(Ca)) channels were most frequently detected; the second most abundant channel was a low-conductance K(+) channel (31 pS) that exhibited channel rundown. In addition to Ba(2+) and charybdotoxin (ChTX), the BK(Ca) channels were inhibited by quinidine, verapamil and tetraethylammonium (TEA), the latter only when present on the side of the channel from which K(+) flow originates. Macroscopic basolateral K(+) conductance, determined in amphotericin-permeabilised epithelia, was also markedly reduced by quinidine and verapamil, TEA inhibited only from the lumen side, and serosal ChTX was without effect. The chromanol 293B and the sulphonylurea tolbutamide did not affect BK(Ca) channels and had no or only a small inhibitory effect on macroscopic basolateral K(+) conductance. Transepithelial Na(+) absorption was partly inhibited by Ba(2+), quinidine and verapamil, suggesting that BK(Ca) channels are involved in basolateral recirculation of K(+) during Na(+) absorption in rabbit colon. The BK(Ca) channel inhibitors TEA and ChTX did not reduce Na(+) absorption, probably because TEA does not enter intact cells and ChTX is 'knocked off' its extracellular binding site by K(+) outflow from the cell interior. Transepithelial Cl(-) secretion was inhibited completely by Ba(2+) and 293B, partly by quinidine but not by the other K(+) channel blockers, indicating that the small (<3 pS) K(V)LQT1 channels are responsible for basolateral K(+) exit during Cl(-) secretion. Hence different types of K(+) channels mediate basolateral K(+) exit during transepithelial Na(+) and Cl(-) transport.     

Basolateral membrane potassium conductance is independent of sodium pump activity and membrane voltage in canine tracheal epithelium

Summary When secretagogues stimulate Cl secretion in canine tracheal epithelium, apical membrane Cl conductance (G _a ^Cl ) increases, and then basolateral membrane K conductance (G _b ^K ) increases. Conversely, inhibition ofG _a ^Cl results in a secondary decrease inG _b ^K . The coordination of the two membrane conductances and regulation ofG _b ^K is critical for maintaining constant intracellular ion concentrations and transepithelial Cl secretion. The purpose of this study was to test two hypotheses about the regulation ofG _b ^K . First, we asked whetherG _b ^K is directly linked to the activity of the Na,K-ATPase. We found that pump activity could be dissociated from K conductance. Inhibition of the Na pump with ouabain, in nonsecreting tissues led to an increase inG _b . Elevation of the bathing solution K concentration produced a similar effect. Addition of ouabain to secreting tissues did not appear to alterG _b . These results indicate thatG _b ^K does not directly parallel Na pump activity. Second, we asked whether changes inG _b ^K are voltage dependent. We prevented secretagogue-induced depolarization of the electrical potential difference across the basolateral membrane _b by clamping _b at its resting value during stimulation of Cl secretion with epinephrine. Despite maintaining _b constant, the typical changes in transepithelial resistance and the ratio of membrane resistances persisted. This observation indicates that depolarization is not required for the secretagogue-induced increase inG _b ^K . In addition we examined the effect of depolarizing and hyperpolarizing _b by passing transepithelial current in secreting and nonsecreting epithelia. Despite depolarizing and hyperpolarizing _b within the physiologic range, we observed no significant changes in transepithelial resistance or the ratio of membrane resistance that would suggest a change inG _b ^K . This observation indicates that changes in _b are not sufficient to alterG _b ^K . Thus,G _b ^K appears to be regulated by factors other than membrane voltage, or direct coupling to the Na pump.     

Energetics of Shaker K channels block by inactivation peptides

A synthetic peptide of the NH2-terminal inactivation domain of the ShB channel blocks Shaker channels which have an NH2-terminal deletion and mimics many of the characteristics of the intramolecular inactivation reaction. To investigate the role of electrostatic interactions in both peptide block and the inactivation process we measured the kinetics of block of macroscopic currents recorded from the intact ShB channel, and from ShB delta 6-46 channels in the presence of peptides, at different ionic strengths. The rate of inactivation and the association rate constants (k(on)) for the ShB peptides decreased with increasing ionic strength. k(on) for a more positively charged peptide was more steeply dependent on ionic strength consistent with a simple electrostatic mechanism of enhanced diffusion. This suggests that a rate limiting step in the inactivation process is the diffusion of the NH2-terminal domain towards the pore. The dissociation rates (k(off)) were insensitive to ionic strength. The temperature dependence of k(on) for the ShB peptide was very high, (Q10 = 5.0 +/- 0.58), whereas k(off) was relatively temperature insensitive (Q10 approximately 1.1). The results suggest that at higher temperatures the proportion of time either the peptide or channel spends in the correct conformation for binding is increased. There were two components to the time course of recovery from block by the ShB peptide, indicating two distinct blocked states, one of which has similar kinetics and dependence on external K+ concentration as the inactivated state of ShB. The other is voltage- dependent and at -120 mV is very unstable. Increasing the net charge on the peptide did not increase sensitivity to knock-off by external K+. We propose that the free peptide, having fewer constraints than the tethered NH2-terminal domain binds to a similar site on the channel in at least two different conformations.     

Block of squid axon K channels by internally and externally applied barium ions

We have studied the interactions of Ba ion with K channels. Ba2+ blocks these channels when applied either internally or externally in millimolar concentrations. Periodic depolarizations enhance block with internal Ba2+, but diminish the block caused by external Ba2+. At rest, dissociation of Ba2+ from blocked channels is very slow, as ascertained by infrequent test pulses applied after washing Ba2+ form either inside or outside. The time constant for recovery from internal and external Ba2+ is the same. Frequent pulsing greatly shortens recovery time constant after washing away both Ba2+in and Ba2+out. Block by Ba2+ applied internally or externally is voltage dependent. Internal Ba2+ block behaves like a one-step reaction governed by a dissociation constant (Kd) that decreases e-fold/12 mV increase of pulse voltage: block deepens with more positive pulse voltage. For external Ba2+, Kd decreases e-fold/18 mV as holding potential is made more negative: block deepens with increasing negativity. Millimolar external concentrations of some cations can either lessen (K+) or enhance (NH+4, Cs+) block by external Ba2+. NH+4 apparently enhances block by slowing exist of Ba ions from the channels. Rb+ and Cs+ also slow clearing of Ba ions from channels. We think that (a) internally applied Ba2+ moves all the way through the channels, entering only when activation gates are open; (b) externally applied Ba2+ moves two-thirds of the way in, entering predominantly when activation gates are closed; (c) at a given voltage, Ba2+ occupies the same position in the channels whether it entered from inside or outside.     

Negative surface charge density near heart calcium channels. Relevance to block by dihydropyridines

We have measured the density of negative surface charges near the voltage sensor for inactivation gating of (L-type) Ca channels in intact calf Purkinje fibers and in isolated myocytes from guinea pig and rat ventricles. Divalent cation-induced changes in the half-maximal voltage for inactivation were determined and were well described by curves predicted by surface potential theory. We measured shifts in inactivation induced by Ca, Sr, and Ba in the single cells, and by Sr in the Purkinje fibers. All of the data were consistent with an estimated negative surface charge density of 1 electronic charge per 250 A2. In addition, the data suggest that Ca, but neither Ba nor Sr, binds to the negative charges with an association constant on the order of 1 M-1. We find that divalent ion-induced changes in surface potential can account for most of the antagonism between these ions and Ca channel block by 1,4-dihydropyridines.     

Modulation of tyramine signaling by osmolality in an insect secretory epithelium

The control of water balance in multicellular organisms depends on absorptive and secretory processes across epithelia. This study concerns the effects of osmolality on the function of the Malpighian tubules (MTs), a major component of the insect excretory system. Previous work has shown that the biogenic amine tyramine increases transepithelial chloride conductance and urine secretion in Drosophila MTs. This study demonstrates that the response of MTs to tyramine, as measured by the depolarization of the transepithelial potential (TEP), is modulated by the osmolality of the surrounding medium. An increase in osmolality caused decreased tyramine sensitivity, whereas a decrease in osmolality resulted in increased tyramine sensitivity; changes in osmolality of ±20% resulted in a nearly 10-fold modulation of the response to 10 nM tyramine. The activity of another diuretic agent, leucokinin, was similarly sensitive to osmolality, suggesting that the modulation occurs downstream of the tyramine receptor. In response to continuous tyramine signaling, as likely occurs in vivo, the TEP oscillates, and an increase in osmolality lengthened the period of these oscillations. Increased osmolality also caused a decrease in the rate of urine production; this decrease was attenuated by the tyraminergic antagonist yohimbine. A model is proposed in which this modulation of tyramine signaling enhances the conservation of body water during dehydration stress. The modulation of ligand signaling is a novel effect of osmolality and may be a widespread mechanism through which epithelia respond to changes in their environment. Drosophila; Malpighian tubule; cell volume regulation; G protein-coupled receptor; biogenic amines     

The block of Shaker K+ channels by kappa-conotoxin PVIIA is state dependent.

kappa-conotoxin PVIIA is the first conotoxin known to interact with voltage-gated potassium channels by inhibiting Shaker-mediated currents. We studied the mechanism of inhibition and concluded that PVIIA blocks the ion pore with a 1:1 stoichiometry and that binding to open or closed channels is very different. Open-channel properties are revealed by relaxations of partial block during step depolarizations, whereas double-pulse protocols characterize the slower reequilibration of closed-channel binding. In 2.5 mM-[K+]o, the IC50 rises from a tonic value of approximately 50 to approximately 200 nM during openings at 0 mV, and it increases e-fold for about every 40-mV increase in voltage. The change involves mainly the voltage dependence and a 20-fold increase at 0 mV of the rate of PVIIA dissociation, but also a fivefold increase of the association rate. PVIIA binding to Shaker Delta6-46 channels lacking N-type inactivation or to wild phenotypes appears similar, but inactivation partially protects the latter from open-channel unblock. Raising [K+]o to 115 mM has little effect on open-channel binding, but increases almost 10-fold the tonic IC50 of PVIIA due to a decrease by the same factor of the toxin rate of association to closed channels. In analogy with charybdotoxin block, we attribute the acceleration of PVIIA dissociation from open channels to the voltage-dependent occupancy by K+ ions of a site at the outer end of the conducting pore. We also argue that the occupancy of this site by external cations antagonizes on binding to closed channels, whereas the apparent competition disappears in open channels if the competing cation can move along the pore. It is concluded that PVIIA can also be a valuable tool for probing the state of ion permeation inside the pore.     

Quantification and distribution of big conductance Ca-activated K channels in kidney epithelia

Big conductance Ca²⁺ activated K⁺ channels (BK channels) is an abundant channel present in almost all kind of tissue. The accurate quantity and especially the precise distribution of this channel in kidney epithelia are, however, still debated. The aim of the present study has therefore been to examine the presence of BK channels in kidney epithelia and determine the actual number and distribution of these channels. For this purpose, a selective peptidyl ligand for BK channels called iberiotoxin or the radiolabeled double mutant analog ¹²⁵I-IbTX-D19Y/Y36F has been employed. The presence of BK channels were determined by a isotope flux assay where up to 44% of the total K⁺ channel activity could be inhibited by iberiotoxin indicating that BK channels are widely present in kidney epithelia. Consistent with these functional studies, ¹²⁵I-IbTX-D19Y/Y36F binds to membrane vesicles from outer cortex, outer medulla and inner medulla with B_max values (in fmol/mg protein) of 6.8, 2.6 and 21.4, respectively. These studies were performed applying rabbit kidney epithelia tissue. The distinct distribution of BK channels in both rabbit and rat kidney epithelia was confirmed by autoradiography and immunohistochemical studies. In cortical collecting ducts, BK channels were exclusively located in principal cells while no channels could be found in intercalated cells. The abundant and distinct distribution in kidney epithelia talks in favor for BK channels being important contributors in maintaining salt and water homeostasis.     

Single-file diffusion through K+ channels in frog skin epithelium

Summary The ratio between the unidirectional fluxes of K⁺ across the frog skin with K-permeable outer membranes was determined in the absence of Na⁺ in the apical solutions. The experiments were performed under presteady-state conditions to be able to separate the flux ratio for K⁺ through the cells from contributions to the fluxes through extracellular leaks. The cellular flux ratio deviated strongly from the value calculated from the flux ratio for electrodiffusion. The experiments can be explained if the passive K transport through the epithelial cells proceeds through specific channels by single-file diffusion with a flux ratio exponent of about 2.5.