Ca2+-activated K+ channels in the apical membrane of Necturus choroid plexus

Targeting choroid plexus epithelium as a novel therapeutic strategy for hydrocephalus

The choroid plexus is a tissue located in the lateral ventricles of the brain and is composed mainly of choroid plexus epithelium cells. The main function is currently thought to be the secretion of cerebrospinal fluid and the regulation of its pH, and more functions are gradually being demonstrated. Assistance in the removal of metabolic waste and participation in the apoptotic pathway are also the functions of choroid plexus. Besides, it helps to repair the brain by regulating the secretion of neuropeptides and the delivery of drugs. It is involved in the immune response to assist in the clearance of infections in the central nervous system. It is now believed that the choroid plexus is in an inflammatory state after damage to the brain. This state, along with changes in the cilia, is thought to be an abnormal physiological state of the choroid plexus, which in turn leads to abnormal conditions in cerebrospinal fluid and triggers hydrocephalus. This review describes the pathophysiological mechanism of hydrocephalus following choroid plexus epithelium cell abnormalities based on the normal physiological functions of choroid plexus epithelium cells, and analyzes the attempts and future developments of using choroid plexus epithelium cells as a therapeutic target for hydrocephalus.

Cerebrospinal Fluid Secretion by the Choroid Plexus

The choroid plexus epithelium is a cuboidal cell monolayer, which produces the majority of the cerebrospinal fluid. The concerted action of a variety of integral membrane proteins mediates the transepithelial movement of solutes and water across the epithelium. Secretion by the choroid plexus is characterized by an extremely high rate and by the unusual cellular polarization of well-known epithelial transport proteins. This review focuses on the specific ion and water transport by the choroid plexus cells, and then attempts to integrate the action of specific transport proteins to formulate a model of cerebrospinal fluid secretion. Significant emphasis is placed on the concept of isotonic fluid transport across epithelia, as there is still surprisingly little consensus on the basic biophysics of this phenomenon. The role of the choroid plexus in the regulation of fluid and electrolyte balance in the central nervous system is discussed, and choroid plexus dysfunctions are described in a very diverse set of clinical conditions such as aging, Alzheimer's disease, brain edema, neoplasms, and hydrocephalus. Although the choroid plexus may only have an indirect influence on the pathogenesis of these conditions, the ability to modify epithelial function may be an important component of future therapies.

Physiological roles of aquaporins in the choroid plexus

The choroid plexus is a specialized tissue that lines subdomains within the four ventricles of the brain where most of the cerebrospinal fluid is produced. Maintenance of an equilibrium in volume and composition of the cerebrospinal fluid (CSF) is vital for a normal brain function, ensuring an optimal environment for the neurons. The necessarily high water permeability of the choroid plexus barrier is made possible by the abundant expression of a water channel, Aquaporin-1 (AQP1), on the apical side of the membrane from early stages of development through adulthood. Data from studies of AQP1 suggest that it also can contribute as a gated ion channel, and suggest that the AQP1-mediated ionic conductance has physiological significance for the regulation of cerebrospinal fluid secretion. The regulation of AQP1 ion channels could be one of several transport mechanisms that contribute to the decreased CSF secretion in response to endogenous signaling molecules such as atrial natriuretic peptide. Numerous classes of ion channels and transporters are targeted specifically to each side of the cellular membrane, and they all work in concert to secrete CSF. Several signaling cascades have a direct effect on transporters and ion channels present in the choroid plexus epithelium, altering their transport activity and therefore modulating the net transcellular movement of solutes and water. Several neurotransmitters, neuropeptides, and growth factors can influence CSF secretion by direct effect on transport mechanisms of the epithelium. The mammalian choroid plexus receives innervation from noradrenergic sympathetic fibers, cholinergic and peptidergic fibers that modulate CSF secretion. Water imbalance in the brain can have life-threatening consequences resulting from altered excitability and neurodegeneration, disruption of the supply of nutrients, loss of signaling molecules, and the accumulation of unwanted toxins and metabolites. Understanding the mechanisms involved in the modulation of CSF secretion is of fundamental importance. An appreciation of AQP1 as an ion channel in addition to its role as a water channel should offer new targets for therapeutic strategies in diseases involving water imbalance in the brain.

Ion channel diversity, channel expression and function in the choroid plexuses

Knowledge of the diversity of ion channel form and function has increased enormously over the last 25 years. The initial impetus in channel discovery came with the introduction of the patch clamp method in 1981. Functional data from patch clamp experiments have subsequently been augmented by molecular studies which have determined channel structures. Thus the introduction of patch clamp methods to study ion channel expression in the choroid plexus represents an important step forward in our knowledge understanding of the process of CSF secretion.

Two K⁺ conductances have been identified in the choroid plexus: Kv1 channel subunits mediate outward currents at depolarising potentials; Kir 7.1 carries an inward-rectifying conductance at hyperpolarising potentials. Both K⁺ channels are localised at the apical membrane where they may contribute to maintenance of the membrane potential while allowing the recycling of K⁺ pumped in by Na⁺-K⁺ ATPase. Two anion conductances have been identified in choroid plexus. Both have significant HCO₃^- permeability, and may play a role in CSF secretion. One conductance exhibits inward-rectification and is regulated by cyclic AMP. The other is carried by an outward-rectifying channel, which is activated by increases in cell volume. The molecular identity of the anion channels is not known, nor is it clear whether they are expressed in the apical or basolateral membrane. Recent molecular evidence indicates that choroid plexus also expresses the non-selective cation channels such as transient receptor potential channels (TRPV4 and TRPM3) and purinoceptor type 2 (P2X) receptor operated channels. In conclusion, good progress has been made in identifying the channels expressed in the choroid plexus, but determining the precise roles of these channels in CSF secretion remains a challenge for the future.

Choline uptake across the ventricular membrane of neonate rat choroid plexus

The uptake of [3H]choline from the cerebrospinal fluid (CSF) side of the rat neonatal choroid plexus was characterized in primary cultures of the choroidal epithelium grown on solid supports. Cell-to-medium concentration ratios were approximately 5 at 1 min and as high as 70 at 30 min. Apical choline uptake was facilitated; the Km was approximately 50 microM. Several organic cations (e.g., hemicholinium-3 and N1-methylnicotinamide) inhibited uptake. The reduction or removal of external Na+ or the addition of 5 mM LiCl had no effect on uptake. However, increasing external K+ concentration from 3 to 30 mM depolarized ventricular membrane potential (-70 to -15 mV) and reduced uptake to 45% of that for the control. Treatment with 1 mM ouabain or 2 mM BaCl2 reduced uptake 45%, and intracellular acidification reduced uptake to approximately 90% of that for controls. These data indicate that the uptake of choline from CSF across the ventricular membrane of the neonatal choroidal epithelium is not directly coupled to Na+ influx but is sensitive to plasma membrane electrical potential.

A novel type of internal barium block of a maxi-K+ channel from human vas deferens epithelial cells

We have recently shown that a maxi-K+ channel from vas deferens epithelial cells contains two Ba2+-binding sites accessible from the external side: a "flickering" site located deep in the channel pore and a "slow" site located close to the extracellular mouth of the channel. Using the patch-clamp technique, we have now studied the effect of internal Ba2+ on this channel. Cytoplasmic Ba2+ produced a voltage- and concentration-dependent "slow" type of block with a dissociation constant of approximately 100 microM. However, based on its voltage dependence and sensitivity to K+ concentration, this block was clearly different from the external "slow" Ba2+ block previously described. Kinetic analysis also revealed a novel "fast flickering" block restricted to channel bursts, with an unblocking rate of approximately 310 s(-1), some 10-fold faster than the external "flickering" block. Taken together, these results show that this channel contains multiple Ba2+-binding sites within the conduction pore. We have incorporated this information into a new model of Ba2+ block, a novel feature of which is that internal "slow" block results from the binding of at least two Ba2+ ions. Our results suggest that current models for Ba2+ block of maxi-K+ channels need to be revised.

Calcium-activated potassium current in cultured rabbit retinal pigment epithelial cells

Calcium-activated potassium current was studied in cultured rabbit retinal pigment epithelial (RPE) cells using whole-cell and single channel patch-clamp recording techniques. When K+ was the principal cation in the electrode, depolarizing voltage steps from a holding potential of -60 mV activated outwardly rectifying current. Outward K+ current was increased by the Ca2+ ionophore ionomycin and reduced when the extracellular Ca2+ concentration was decreased from 2.5 mM to 100 nM in the presence of ionomycin. Outward K+ current recorded in the presence of ionomycin was blocked by iberiotoxin and by charybdotoxin. Single channel recording from cell-attached and excised membrane patches revealed a large conductance Ca2+-activated K+ (K(Ca)) channel. Identification of K(Ca) channels was based on: 1) the voltage-dependence of channel opening; 2) the large unitary conductance (> 200 pS with symmetrical 130 mM K+); 3) the dependence of the reversal potential on the K+ gradient; and 4) increased channel opening after exposure of the cytosolic surface of excised membrane patches to elevated Ca2+. These results demonstrate that Ca2+-activated K+ channels are present in rabbit RPE cells and may play an essential role in the regulation of membrane potential and ion transport.

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.

Maxi K+ channels in the basolateral membrane of the exocrine frog skin gland regulated by intracellular calcium and pH

With the single-channel patch-clamp technique we have identified Ca2+-sensitive, high-conductance (maxi) K+ channels in the basolateral membrane (BLM) of exocrine gland cells in frog skin. Under resting conditions, maxi K+ channels were normally quiescent, but they were activated by muscarinic agonists or by high serosal K+. In excised inside-out patches and with symmetrical 140mmol/l K+, single-channel conductance was 200pS and the channel exhibited a high selectivity for K+ over Na+. Depolarization of the BLM increased maxi K+ channel activity. Increasing cytosolic free Ca2+ (by addition of 100nmol/l thapsigargin to the bathing solution of cell-attached patches also increased channel activity, whereas thapsigargin had no effect when added to excised inside-out patches. An increase in cytosolic free Ca2+ directly activated channel activity in a voltage-dependent manner. Maxi K+ channel activity was sensitive to changes in intracellular pH, with maximal activity at pH 7.4 and decreasing activities following acidification and alkalinization. Maxi K+ channel outward current was reversibly blocked by micromolar concentrations of Ba2+ from the cytosolic and extracellular site, and was irreversibly blocked by micromolar concentrations of charybdotoxin and kaliotoxin from the extracellular site in outside-out patches.

Intracellular pH modulates the activity of chloride channels in isolated lacrimal gland acinar cells

The effects of intracellular pH (pHi) on Ca(2+)-activated Cl- currents in rat lacrimal gland acinar cells were examined. Cl- currents were recorded by conventional whole cell patch-clamp methods using K(+)-free and Na(+)-free solutions. pHi was varied by using electrode solutions with pH at 6.8, 7.3, or 7.8, and Ca2+ activity was buffered at 100 nM with ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid. Increasing pH from 6.8 to 7.8 was found to increase whole cell currents. The currents observed exhibited time-dependent activation at depolarizing potentials and time-dependent inactivation at hyperpolarizing potentials (pH 7.8). This behavior is characteristic of Ca(2+)-activated Cl- channels in lacrimal gland cells. The selectivity of the current was examined at pH 7.8 by removing Cl- from the bath solution. This maneuver caused a positive shift in the reversal potential, as expected for a Cl(-)-selective current. Thus increasing pHi appears to activate Ca(2+)-activated Cl- channels. The possibility that an increase in pHi may help sustain Cl- channel activity during secretory activity is discussed.

Molecular mechanisms for passive and active transport of water

Water crosses cell membranes by passive transport and by secondary active cotransport along with ions. While the first concept is well established, the second is new. The two modes of transport allow cellular H2O homeostasis to be viewed as a balance between H2O leaks and H2O pumps. Consequently, cells can be hyperosmolar relative to their surroundings during steady states. Under physiological conditions, cells from leaky epithelia may be hyperosmolar by roughly 5 mosm liter-1, under dilute conditions, hyperosmolarities up to 40 mosm liter-1 have been recorded. Most intracellular H2O is free to serve as solvent for small inorganic ions. The mechanism of transport across the membrane depends on how H2O interacts with the proteinaceous or lipoid pathways. Osmotic transport of H2O through specific H2O channels such as CHIP 28 is hydraulic if the pore is impermeable to the solute and diffusive if the pore is permeable. Cotransport of ions and H2O can be a result of conformational changes in proteins, which in addition to ion transport also translocate H2O bound to or occlude in the protein. A cellular model of a leaky epithelium based on H2O leaks and H2O pumps quantitatively predicts a number of so-far unexplained observations of H2O transport.

Evidence for two types of potassium current in rat choroid plexus epithelial cells

The whole-cell patch-clamp technique was applied to rat choroid plexus epithelial cells. The resting membrane potential was -53 mV. The whole-cell conductance was mainly K+ selective, and the K+ current observed appeared to contain two distinct components. Depolarizing voltage pulses (more positive than 0 mV) evoked time-dependent outward currents which resembled delayed-rectifying K+ currents in other tissues. The current exhibited time-dependent activation and, at potentials more positive than 40 mV, slower time-dependent inactivation. The reversal potential measured by tail current analysis showed a shift of 43 mV for a tenfold increase in extracellular K+ concentration ([K+]o). The current was reduced by extracellular 5 mM Ba2+, 5 mM tetraethylammonium (TEA+), 5 mM Cs+ and 1 mM 4-aminopyridine (4-AP). In contrast, hyperpolarizing voltage pulses evoked time-independent, inward-rectifying currents. The reversal potential measured by voltage-ramp commands showed a shift of 42 mV for a tenfold increase in [K+]o. The chord conductance did not appear to increase with increasing [K+]o. The current was reduced by extracellular 5 mM Ba2+ and 0.5 mM Cs+, but not by 5 mM TEA+ or 1 mM 4-AP. These data suggest that two populations of K+ channel contribute to the conductance of choroid plexus epithelial cells.

Microdialysis analysis of effects of loop diuretics and acetazolamide on chloride transport from blood to CSF

With the hypothesis that the NaCl cotransporter in mammalian choroid plexus (CP) has a role in CSF formation, we postulated that loop diuretic agents would curtail transport of Cl from blood to CSF. Microdialysis in the cisterna magna of Sprague-Dawley rats was used to assess the ability of furosemide and ethacrynic acid (i.e. loop agents that interfere directly with cotransport) to inhibit 36Cl transport from blood to CSF over a 3-h period. Cl uptake by CSF was quantified as % volume of distribution (Vd) of 36Cl, i.e. 100 x cpm/g CSF divided by cpm/ml plasma. Uptake curves of Vd vs. time were constructed for the various treatments; then, to compare drug effects, the curves were analyzed for: (i) the early slope of uptake (Kin), (ii) the steady-state value for Vd, and (iii) the area-under-curve (AUC). Assessment of the curve parameters collectively revealed that at 5 mg/kg, both furosemide (FUR) and ethacrynic acid (EA) reduced Cl penetration into CSF by one quarter; at 50 mg/kg, these loop agents decreased Cl uptake by about a third. On the other hand, 50 mg/kg of the carbonic anhydrase inhibitor, acetazolamide, reduced Cl uptake into CSF by 55-60%. Thus, NaCl cotransport inhibitors maximally reduced Cl transport in the rat by about 35%; this inhibition was less extensive than that brought about by acetazolamide, which interferes with CSF secretion by a different mechanism.

Serotonin activates Cl- channels in the apical membrane of rat choroid plexus epithelial cells

The effects of serotonin on ion channel activity in epithelial cells from rat choroid plexus were examined. Serotonin (50 nM, 500 nM and 1 microM) stimulated channel activity in cell-attached patches. The current-voltage (I-V) relationship for the serotonin-activated channel gave a conductance of 26.6 +/- 1.5 pS and the current reversed at an applied electrode potential (-Vp) = 15.3 +/- 3.3 mV with a KCl-rich electrode solution (n = 8). Similar I-V relationships were obtained using electrode solutions in which K+ was replaced by other cations (Na+ and N-methyl-D-glucamine), suggesting that the serotonin-activated channels are selective to Cl-. The effect of 1 microM serotonin on channel activity was inhibited by ritanserin (30 and 100 nM) which has a high affinity for serotonin 5-HT1C receptors and 5-HT2 receptors. Spiperone (30 nM), which binds weakly to 5-HT1C receptors but has a high affinity for 5-HT2 receptors, did not inhibit the actions of serotonin. These data suggest that serotonin increases Cl- channel activity by acting on the 5-HT1C receptors on the epithelium.

Regulation of mouse choroid plexus apical Cl- and K+ channels by serotonin

Using patch-clamp techniques, we have characterized ion channels in the apical membrane of the mouse choroid plexus epithelium and have examined the effect of serotonin on these channels. When the pipette contained 140 mM KCl and the bath contained NaCl Ringer solution, cell-attached patches revealed both Cl- and K+ channels. The Cl- channel was activated by hyperpolarizing membrane potentials, and 70% were also activated by large depolarizing potentials (pipette potential, Vp, more negative than -40 mV). The channel exhibited linear current-voltage (I-V) relations with a conductance of 4 +/- 1 pS (n = 30), and a reversal potential at Vp = -14 +/- 1 mV (n = 30). The majority of the K+ channels (84%) were activated by depolarizing membrane potentials. These exhibited linear I-V relations with a conductance of 18 +/- 1 pS (n = 10) and a reversal potential at Vp = -51 +/- 8 mV (n = 10). Serotonin (10(-6) M) increased the open probability (Po) of active Cl- channels (n = 20) by an order of magnitude at the resting potential (Vp = 0 mV) as well as activating previously silent Cl- channels. In contrast, complete inhibition of K+ channel activity was observed in the majority of experiments. There was a 30 s delay after exposure of the tissue to serotonin, thereafter the K+ channel was rapidly inhibited (within 1 min) prior to the stimulation of the Cl- channel. Stimulation of the Cl- channel by serotonin was abolished by mianserin (10(-3) M). We conclude that serotonin exerts its effect on apical Cl- channels via the 5-HT1c receptor. The modulation of these channels by serotonin may be important to CSF secretion and its regulation.

Effects of divalent cations on the activation of a calcium-dependent potassium channel in hippocampal neurons

The activation of a calcium-dependent K+ channel K(Ca) in cultured hippocampal neurons has been studied after the addition, to the internal solution, of the divalent cations magnesium (Mg2+), strontium (Sr2+) or barium (Ba2+). With physiological K+ across inside-out patches and Ca2+ present at 0.2 mM in the bath solution, a 90-pS channel was activated with an open probability in excess of 75%. When the internal Ca2+ was reduced to levels near 5 microM, the channel-open probability was significantly diminished. However, if 0.2 mM concentrations of either Mg2+ or Sr2+ were added to the internal solution, the open probability was increased to a value close to original level. In the presence of internal Ca2+ at 0.1 microM, the K(Ca) channel was not active and was not activated with the addition of 0.2 mM Mg2+ or Sr2+ to the internal solution. Thus, Mg2+ or Sr2+ were not able to active K(Ca) in the absence of Ca2+; however, both of these divalent cations could potentiate the Ca(2+)-induced activation of K(Ca) if internal Ca2+ was near 5 microM. The results indicate that Mg2+ could have a role as an internal modulator of K(Ca) in the Ca(2+)-dependent regulation of excitability in nerve membrane. Replacement of Ca2+ with Ba2+, or addition of Ba2+ to Ca-containing solutions, caused significant decreases in the channel-open probability for K(Ca). The action of Ba2+ was primarily mediated by a decrease in the frequency of channel opening. At a concentration of 5 microM, Ba2+ diminished the channel-open probability by one-half.

Chloride channels of high conductance in the microvillous membrane of term human placenta

The patch clamp technique has been used to study ion channels in the undisturbed microvillous membrane of the human placental syncytiotrophoblast. In villi from 55 placentae delivered by caesarean section, high resistance seals were achieved in approximately 30 percent of attempts. Of these, a large conductance chloride channel was identified in seven inside-out and two 'cell' attached patches. The channel had the following properties: (a) a slope conductance of 313 +/- 9 pS, (b) the presence of sub-conductance states, (c) voltage dependency, being open predominantly between +/- 20 mV and inactivating at more extreme potentials and (d) inhibition by DIDS (4-acetamido-4'-diisothiocyanostilbene 2,2-disulphonic acid). These are characteristic features of 'maxi' chloride channels which have been identified in a variety of cell types (Gogelein, 1988). The role of the chloride channel in ion transport by or homeostasis of the syncytiotrophoblast has yet to be determined.

Potassium transport at the blood-brain and blood-CSF barriers

Figure 5 gives a summary of K transporters at the BBB based on the available evidence. It appears that the cerebral endothelial cells have an array of potassium channels, although the degree to which each is open under physiological conditions is uncertain. Different channels are present on the luminal and abluminal membranes, and the opening and closing of these channels may allow modulation of the brain K influx and efflux rates and play a role in brain K homeostasis. These channels may also play a role in hyperosmotic brain volume regulation by increasing the entry rate of potassium into brain and may be involved in volume regulation of the endothelial cell itself. The nature of fluid transport at the BBB remains to be fully elucidated, with the presence of a Na/K/2Cl co-transporter being uncertain. The abluminal inwardly-rectifying channel may act as a leak pathway to allow modulation of fluid secretion by the Na/K ATPase without altering the K concentration of that fluid. Finally, there is some evidence that K transport at the BBB is under hormonal and neuronal control. The cerebral capillaries possess receptors for many of the hormones present in blood and brain.

Two types of chloride channel in the apical membrane of rat choroid plexus epithelial cells

The patch clamp technique has been used to study ion channel activity in the apical (ventricular) membrane of epithelial cells from the rat choroid plexus. Two different classes of Cl(-)-selective channel were identified. A low conductance (26 pS) channel which was the predominant feature in cell-attached and inside-out patches. The occurrence of this channel appeared to increase in tissue bathed in forskolin. It was activated in inside-out patches by increasing the Ca2+ concentration at the intracellular face of the membrane and by depolarising potentials. The second class of channel was observed infrequently (2% of patches) and appeared to be similar to 'maxi'-Cl- channels which have been described in many other cell types. It had a conductance of 320 pS, opened to sub-conductance levels and displayed a marked voltage dependence in inside-out patches. The possible contribution of these channels to Cl- transport during the production of cerebrospinal fluid (CSF) is discussed.

The effects of Na+ replacement on intracellular pH and [Ca2+] in rabbit salivary gland acinar cells

1. The role of Na(+)-dependent mechanisms in regulating the intracellular pH (pHi) and free calcium concentration ([Ca2+]i) in acinar cells of the rabbit mandibular salivary gland was examined. The fluorescent dyes BCECF and Fura-2 were used to measure pHi and [Ca2+]i respectively in suspensions of isolated acini. 2. Replacement of all the extracellular Na+ with N-methyl-D-glucamine (NMDG) decreased resting pHi from a control value of 7.1-7.2 to 6.8-6.9. Re-addition of Na+ or Li+ caused a recovery of pHi towards control values. This recovery was blocked by 10-50 microM-ethylisopropylamiloride (EIPA), suggesting that it was mediated by Na(+)-H+ exchange. The rate of recovery of pHi when Na+ was re-introduced increased with Na+ concentration with an apparent Km for Na+ of around 30 mM. 3. Replacement of all of the extracellular Na+ with Li+ caused only a small decrease in resting pHi. 4. Stimulation of acini with 1 microM-acetylcholine (ACh) evoked an intracellular acidosis both under control conditions and when acini were bathed in Na(+)-free media. Following the acidosis pHi recovered in acini bathed in either control medium or Na(+)-free (Li+) medium, but not in acini bathed in Na(+)-free (NMDG) medium or in control medium containing EIPA. 5. Stimulation of acini bathed in Na(+)-free, HCO(3-)-free medium with ACh did not cause any change in pHi. 6. Re-addition of Na+ to acini bathed in Na(+)-free, HCO(3-)-free medium evoked the same rate of alkalinization whether or not the acini had been stimulated with ACh, suggesting that receptor stimulation per se did not lead to an activation of acid extrusion. 7. Resting [Ca2+]i was elevated in acini bathed in Na(+)-free (NMDG) medium, but not in acini bathed in Na(+)-free (Li+) medium. 8. ACh evoked a maintained rise in [Ca2+]i in acini bathed in control medium and in Na(+)-free media with either NMDG or Li+ as the Na+ substitute. 9. Experiments in which external Ca2+ was reduced to low levels (by the addition of EGTA) just prior to addition of ACh showed that ACh released intracellular Ca2+ stores under both control and Na(+)-free conditions. 10. In acini bathed in Na(+)-free (NMDG) solution and stimulated with ACh, re-addition of either Na+ or Li+ reduced [Ca2+]i. The reduction of [Ca2+]i on Na+ re-addition was blocked by EIPA. [Ca2+]i could also be reduced under these conditions by alkalinizing the cytosol using the weak base trimethylamine.(ABSTRACT TRUNCATED AT 400 WORDS)

Secondary active transport of water across ventricular cell membrane of choroid plexus epithelium of Necturus maculosus

1. The interaction between Cl-, K+ and H2O fluxes were studied in the ventricular membrane of the choroid plexus epithelium from Necturus maculosus by means of ion-selective microelectrodes. The flux of H2O was measured by means of K+ electrodes as the dilution or concentration of intracellular choline ions, Ch+i. 2. In one series of experiments Cl- was readministered to the ventricular solution of tissues incubated in media with low Cl- concentrations. The resulting influx of Cl- was associated with an instantaneous influx of K+ and H2O. 3. Both the Cl- and the K+ influxes were reduced by the diuretic furosemide but were unaffected by inhibitors of Na+, K(+)-ATPase or changes in membrane potentials induced by Ba2+. Since the influx of K+ proceeds against its electrochemical gradient and is unaffected by changes in membrane potentials, the membrane exhibits secondary active, electroneutral transport of K+. 4. The influx of water, initiated simultaneously with the influx of K+ and Cl-, commenced before these ions had changed the osmolarity of the intracellular solution significantly. The influx of H2O could proceed against an osmotic gradient. The influx stopped when 100 mmol l-1 of mannitol was added to the ventricular solution at the same time as the Cl- ions. The influx of H2O was inhibited by K+ removal, furosemide or high external Ba2+ (10 mmol l-1), but not by strophanthidin, ouabain or low concentrations of Ba2+ (0.5 mmol l-1). The influx could not continue with other permeable anions, NO3-, acetate- or SCN-, replacing Cl-. 5. In another series of experiments Cl- was removed from the ventricular solution of tissues bathed in saline solutions with normal concentrations of Cl-. The resulting efflux of Cl- was associated with an instantaneous efflux of K+ and H2O. This efflux of H2O could proceed against an osmotic gradient of up to 70 mosmol l-1. This effect was inhibited by furosemide, in which case the water fluxes were entirely dependent on the osmotic gradients and the osmotic water permeability Lp of the ventricular membrane. 6. The data suggest that there is a coupling between the flux of KCl and of water in the ventricular membrane, which implies that the reflection coefficient sigma for KCl under the given circumstances is less than one. I suggest that the ability of leaky epithelia to transport against osmotic gradients depends on such a coupling, which derives from the properties of the proteins through which K+, Cl- and H2O leave the cell.

Potassium conductance of smooth muscle cells from rabbit aorta in primary culture

Vascular smooth muscle cells were obtained from rabbit aorta and were studied in primary culture on days 1-7 after seeding with electrophysiological techniques. In impalement experiments a mean membrane potential difference (PD) of -50 +/- 0.3 mV (n = 387) was obtained with Ringer-type solution in the bath. PD was depolarized by 6 +/- 0.3 mV (n = 45) and 16 +/- 2 mV (n = 5) when the bath K+ concentration was increased from the control value of 3.6 mmol/l to 13.6 and 23.6 mmol/l, respectively. Ba2+ (0.1-1 mmol/l) depolarized PD. Tetraethylammonium (TEA, 10 mmol/l) depolarized PD only slightly but significantly. Verapamil (0.1 mmol/l) and charybdotoxin (10 nmol/l) had no effect on PD. The conductance properties of these cells were further examined with the patch-clamp technique. K+ channels were spontaneously present in cell-attached patches. When the pipette was filled with 145 mmol/l KCl, a mean conductance (gK) of 209.6 +/- 4.6 mV (n = 17) was read from the current/voltage curves at a clamp voltage (Vc) of 0 mV. After excision K+ channels were found in 129 patches with inside-out and in 50 with outside-out configuration. With KCl on one and NaCl on the other side the mean gK at a Vc of 0 mV was 134.6 +/- 3.9 pS (n = 179). The mean permeability was 0.89 +/- 0.03 x 10(-12) cm3/s. With symmetrical KCl solution the mean gK was 227 +/- 6 pS (n = 17). The conductance sequence was gK much greater than gRb = gCs = gNa = 0. TEA blocked dose-dependently only from the outside (1-10 mmol/l). Lidocaine (5 mmol/l) quinidine (0.01-1 mmol/l) and quinine (0.01-1 mmol/l) blocked from both sides. Charybdotoxin (0.5-5 nmol/l) blocked only from the extracellular side. Ba2+ blocked from the cytosolic side and the inhibition was increased by depolarization and reduced by hyperpolarization. At a Vc of 0 mV a half-maximal inhibition (IC50) of 2 mumol/l was obtained. Verapamil and diltiazem blocked from both sides, verapamil with an IC50 of 2 mumol/l and diltiazem with an IC50 of 10 mumol/l. The open probability of this channel was increased by CA2+ on the cytosolic side at activities greater than 0.1 mumol/l. Half-maximal activation occurred at Ca2+ activities exceeding 1 mumol/l. The present data indicate that the vascular smooth muscle cells of rabbit aorta in primary culture possess a K+ conductance. In excised patches only a maxi K+ channel was detected. This channel has properties different from the macroscopic K+ conductance.(ABSTRACT TRUNCATED AT 400 WORDS)

Single-channel K+ currents in Drosophila muscle and their pharmacological block

Four types of nonvoltage-activated potassium channels in the body-wall muscles of Drosophila third instar larvae have been identified by the patch-clamp technique. Using the inside-out configuration, tetraethylammonium (TEA), Ba2+, and quinidine were applied to the cytoplasmic face of muscle membranes during steady-state channel activation. The four channels could be readily distinguished on the basis of their pharmacological sensitivities and physiological properties. The KST channel was the only type that was activated by stretch. It had a high unitary conductance (100 pS in symmetrical 130/130 mM KCl solution), was blocked by TEA (Kd approximately 35 mM), and was the most sensitive to Ba2+ (complete block at 10(-4) M). A Ca(2+)-activated potassium channel, KCF.72 pS (130/130) mM KCl), was gated open at greater than 10(-8) m Ca2+, was the least sensitive to Ba2+ Kd of approximately 3 mM) and TEA (Kd of approximately 100 mM), and was not affected by quinidine. K2 was a small conductance channel of 11 pS (130/2 KCl, pipette/bath), and was very sensitive to quinidine, being substantially blocked at 0.1 mM. It also exhibited a half block at approximately 0.3 mM Ba2+ and approximately 25 mM TEA. A fourth channel type, K3, was the most sensitive to TEA (half block less than 1 mM). It displayed a partial block to Ba2+ at 10 mM, but no block by 0.1 mM quinidine. The blocking effects of TEA, Ba2+ and quinidine were reversible in all channels studied. The actions of TEA and Ba2+ appeared qualitatively different: in all four channels, TEA reduced the apparent unitary conductance, whereas Ba2+ decreased channel open probability.

A maxi calcium-activated potassium channel from chick lens epithelium

The apical membrane of embryonic chick lens epithelium contains at high density, a large conductance K+ channel whose open probability is increased by Ca++ at the inner surface of the membrane and by depolarization. The conductance of the channel when it is fully open in symmetrical 150 mM K+ solutions is 214 +/- 3 pS (mean +/- std. error). The current through the channel is a function of the K+ concentration. Gating (open probability) at positive transmembrane voltages increases as the internal [Ca++] is raised above 10(-7) M. The open probability decreases monotonically as the transmembrane voltage is made more negative. The channel is at least 87 times more permeable to K+ than to Na+ or Li+ and shows appreciable permeability to Rb+ and NH4+. It has at least three subconductance levels amounting to approximately 3/4, 1/2, and 1/4 the fully open unitary conductance. The occurrence of these subconductance levels is highly variable from one patch to another. The channel is blocked by physiological levels of internal Na+ but not over a physiological voltage range. This block is partially overcome by elevated external K+. This K+ channel from chick lens epithelium is blocked by a number of compounds known to block BK channels in other tissues. Here we show that decamethonium and Ba++ are effective blockers when added to the inner bathing solution at concentrations greater than .1 mM. Tetraethylammonium, Cs+, quinine, quinidine and Ba++ are all effective blockers when applied to the outer side of the channel in the .1 mM - 5 mM range. With the exception of internal Ba++, all of these compounds produce a fast flicker-type blockade. We use a one-site model to quantify the blockade caused by these flicker producing agents. The voltage dependence of the blockade by Cs+ suggests that this channel probably allows multiple occupancy.

The effects of bumetanide, amiloride and Ba2+ on fluid and electrolyte secretion in rabbit salivary gland

1. In order to distinguish between models of anion secretion, the effects of transport inhibitors on saliva flow rate and electrolyte composition were studied during the plateau phase of secretion in rabbit mandibular salivary glands. 2. Bumetanide, an inhibitor of Na+,K+,2Cl- co-transport, inhibited flow rate (by 60%) and reduced Cl- concentration. K+ and HCO3- concentrations were increased. Forskolin, an adenylate cyclase activator which inhibits ductal transport, did not significantly affect this pattern of changes. 3. Amiloride, used at concentrations that would inhibit Na(+)-H+ exchange, inhibited flow rate (by 30%). Cl- concentration was initially increased before subsequently decreasing at the same time as HCO3- concentration increased. These concentration changes can probably be attributed to ductal transport. When amiloride was applied to glands perfused with nominally HCO3- -free solutions, inhibition of flow rate was rapid and almost complete. 4. When amiloride and bumetanide were both present in the perfusate, flow rate was inhibited by 92%. The pattern of electrolyte changes was not significantly different from that observed in the presence of bumetanide alone. 5. Inhibition of K+ channel activity using Ba2+ also inhibited flow rate. Cl- concentration was increased as was K+ concentration. HCO3- concentration was not increased. 6. The anion exchange inhibitor DIDS (4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid) had no effect on either flow rate or electrolyte concentration. It did, however, elicit secretion in the absence of acetylcholine. 7. The data suggest that Na(+)-H+ and Cl- -HCO3- exchangers are unlikely to be involved in fluid and electrolyte secretion in these glands as suggested by some authors. Most of the data can be explained by postulating the existence of non-specific anion channels in the apical membranes of the acinar cells.

Regulation of maxi-K+ channels on pancreatic duct cells by cyclic AMP-dependent phosphorylation

Using the patch-clamp technique we have identified a Ca2(+)-sensitive, voltage-dependent, maxi-K+ channel on the basolateral surface of rat pancreatic duct cells. The channel had a conductance of approximately 200 pS in excised patches bathed in symmetrical 150 mM K+, and was blocked by 1 mM Ba2+. Channel open-state probability (Po) on unstimulated cells was very low, but was markedly increased by exposing the cells to secretin, dibutyryl cyclic AMP, forskolin or isobutylmethylxanthine. Stimulation also shifted the Po/voltage relationship towards hyperpolarizing potentials, but channel conductance was unchanged. If patches were excised from stimulated cells into the inside-out configuration, Po remained high, and was not markedly reduced by lowering bath (cytoplasmic) Ca2+ concentration from 2 mM to 0.1 microM. However, activated channels were still blocked by 1 mM Ba2+. Channel Po was also increased by exposing the cytoplasmic face of excised patches to the purified catalytic subunit of cyclic AMP-dependent protein kinase. We conclude that cyclic AMP-dependent phosphorylation can activate maxi-K+ channels on pancreatic duct cells via a stable modification of the channel protein itself, or a closely associated regulatory subunit, and that phosphorylation alters the responsiveness of the channels to Ca2+. Physiologically, these K+ channels may contribute to the basolateral K+ conductance of the duct cell and, by providing a pathway for current flow across the basolateral membrane, play an important role in pancreatic bicarbonate secretion.

The luminal K+ channel of the thick ascending limb of Henle's loop

In vitro perfused rat thick ascending limbs of Henle's loop (TAL) were used (n = 260) to analyse the conductance properties of the luminal membrane applying the patch-clamp technique. Medullary (mTAL) and cortical (cTAL) tubule segments were dissected and perfused in vitro. The free end of the tubule was held and immobilized at one edge by a holding pipette kept under continuous suction. A micropositioner was used to insert a patch pipette into the lumen, and a gigaohm seal with the luminal membrane was achieved in 455 instances out of considerably more trials. In approximately 20% of all gigaohm seals recordings of single ionic channels were obtained. We have identified only one single type of K+ channel in these cell-attached and cell-excised recordings. In the cell-attached configuration with KCl or NaCl in the pipette, the channel had a conductance of 60 +/- 6 pS (n = 24) and 31 +/- 7 pS (n = 4) respectively. In cell-free patches with KCl either in the patch pipette or in the bath and with a Ringer-type solution (NaCl) on the opposite side the conductance was 72 +/- 4 pS (n = 37) at a clamp voltage of 0 mV. The permeability was 0.33 +/- 0.02 . 10(-12) cm3/s. The selectivity sequence of this channel was: K+ = Rb+ = NH4+ = Cs+ greater than Li+ much greater than Na+ = 0; the conductance sequence was K+ much greater than Li+ much greater than Rb+ = Cs+ = NH4+ = Na+ = 0. In excised patches Rb+, Cs+ and NH4+ when present in the bath at 145 mmol/l all inhibited K+ currents out of the pipette. The channel kinetics were described by one open (9.5 +/- 1.5 ms, n = 18) and by two closed (1.4 +/- 0.1 and 14 +/- 2 ms) time constants. The open probability of this channel was increased by depolarization. The channel open probability was reduced voltage dependently by Ba2+ (half maximal inhibition at 0 mV: 0.07 mmol/l) from the cytosolic side. Verapamil, diltiazem, quinine and quinidine inhibited at approximately 1 mumol/l -0.1 mmol/l from either side. Similarly, the amino cations lidocaine, tetraethylammonium and choline inhibited at 10-100 mmol/l. The channel was downregulated in its open probability by cytosolic Ca2+ activities greater than 10(-7) mol/l and by adenosine triphosphate greater than or equal to 10(-4) mol/l. The open probability was downregulated by decreasing cytosolic pH (2-fold by a decrease in pH by less than or equal to 0.2 units).(ABSTRACT TRUNCATED AT 400 WORDS)

The activation of calcium and calcium-activated potassium channels in mammalian colonic smooth muscle by substance P

1. The regulation of Ca2(+)-activated K+ channels by the agonist substance P in freshly dissociated smooth muscle cells from the rabbit longitudinal colonic muscle was characterized using the patch clamp technique. 2. In the cell-attached recording mode, when pipette and bath solutions contained equal [K+] (126 mM), the Ca2(+)-activated K+ channels showed a linear current-voltage relationship (between -50 mV and 50 mV) with a slope conductance of 210 +/- 35 pS (n = 12). Reversal potential measurements indicated that the channel was highly selective for K+ over Na+ (PK/PNa = 110). 3. Channels were activated by depolarizing membrane voltages and cytosolic Ca2+, and in inside-out patches channel activation depended sigmoidally on voltage and [Ca2+]. The potential for half-activation at a cytosolic [Ca2+] of 5 x 10(-6) M was 0 mV. A tenfold increase in cytosolic Ca2+ resulted in a 60 mV shift of the sigmoidal voltage activation curve to more negative potentials. 4. Threshold concentrations of substance P (10(-12) M), which did not result in cell contraction, caused a prolonged activation of K+ channels. The K+ channels were observed to open in clusters: simultaneous opening of multiple channels was interrupted by complete, prolonged channel closure. 5. Lowering bath [Ca2+] to submicromolar concentrations abolished the effect of substance P. The activation of K+ channels by substance P (10(-12) M) was also inhibited by the dihydropyridine nifedipine (10(-6) M), a blocker of L-type Ca2+ channels. 6. In the whole-cell recording mode, with the pipette solution containing 126 mM-KCl, 0.77 mM-EGTA and 1 mM-ATP, depolarization from a holding potential of -70 mV elicited outward currents which increased to steady-state values. These were K+ currents as they were blocked by TEA (tetraethylammonium, 30 mM) and Ba2+ (1 mM) and were abolished when pipette K+ was replaced by Cs+. 7. The depolarization-activated outward current was not affected by lowering extracellular [Ca2+] or by the Ca2+ channel antagonists Cd2+ (200 microM), nifedipine (10(-6)-10(-5) M) or verapamil (10(-6) M). The current was greatly reduced when the EGTA concentration in the pipette solution was increased from 0.77 to 10 mM. 8. When the pipette solution contained CsCl, membrane depolarization activated inward currents. The peak inward current was identified as current through L-type Ca2+ channels based on its voltage- and time-dependent kinetics, and its modulation by dihydropyridines.(ABSTRACT TRUNCATED AT 400 WORDS)

Reconstitution of a calcium-activated potassium channel in basolateral membranes of rabbit colonocytes into planar lipid bilayers

A highly enriched preparation of basolateral membrane vesicles was isolated from rabbit distal colon surface epithelial cells employing the method described by Wiener, Turnheim and van Os (Weiner, H., Turnheim, K., van Os, C.H. (1989) J. Membrane Biol. 110:147-162) and incorporated into planar lipid bilayers. With very few exceptions, the channel activity observed was that of a high conductance. Ca2+-activated K+ channel. This channel is highly selective for K+ over Na+ and Cl-, displays voltage-gating similar to "maxi" K(Ca) channels found in other cell membranes, and kinetic analyses are consistent with the notion that K+ diffusion through the channel involves either the binding of a single K+ ion to a site within the channel or "single-filing" ("multi-ion occupancy"). Channel activity is inhibited by the venom from the scorpion Leiurus quinquestriatus, Ba2+, quinine, and trifluoperazine. The possible role of this channel in the function of these cells is discussed.

Ca2+ and cAMP activate K+ channels in the basolateral membrane of crypt cells isolated from rabbit distal colon

Using patch-clamp techniques, we have studied Ca2+-activated K+ channels in the basolateral membrane of freshly isolated epithelial cells from rabbit distal colon. Epithelial cell clusters were obtained from distal colon by gentle mechanical disruption of isolated crypts. Gigaohm seals were obtained on the basolateral surface of the cell clusters. At the resting potential (approximately -45 mV), with NaCl Ringer's bathing the cell, the predominant channels had a conductance of 131 +/- 25 pS. Channel activity depended on voltage as depolarization of the membrane increased the open probability. In excised inside-out patches, channels were found to be selective for K+ over Na+. Channel activity correlated directly with bath Ca2+ concentration in the excised patches. Channel currents were blocked by 5 mM TEA+ and 1 mM Ba2+. In cell-attached patches, after addition of the Ca2+ ionophore A23187, which increases intracellular Ca2+, open probability was markedly increased. Channel activity was also regulated by cAMP as addition of 1 mM dibutyryl-cAMP in the bath solution in cell-attached patches increased channel open probability over 20-fold. Channels that had been activated by cAMP were further activated by Ca2+. We conclude that the basolateral membrane of epithelial cells from descending colon contains a class of potassium channels, which are regulated by intracellular Ca2+ and cAMP.

Ca2+-activated K+ currents in Necturus choroid plexus

The tight-seal whole-cell recording method has been used to study Necturus choroid plexus epithelium. A cell potential of -59 +/- 2 mV and a whole cell resistance of 56 +/- 6 M omega were measured using this technique. Application of depolarizing step potentials activated voltage-dependent outward currents that developed with time. For example, when the cell was bathed in 110 mM NaCl Ringer solution and the interior of the cell contained a solution of 110 mM KCl and 5 nM Ca2+, stepping the membrane potential from a holding value of -50 to -10 mV evoked outward currents which, after a delay of greater than 50 msec, increased to a steady state in 500 msec. The voltage dependence of the delayed currents suggests that they may be currents through Ca2+-activated K+ channels. Based on the voltage dependence of the activation of Ca2+-activated K+ channels, we have devised a general method to isolate the delayed currents. The delayed currents were highly selective for K+ as their reversal potential at different K+ concentration gradients followed the Nernst potential for K+. These currents were reduced by the addition of TEA+ to the bath solution and were eliminated when Cs+ or Na+ replaced intracellular K+. Increasing the membrane potential to more positive values decreased both the delay and the half-times (t1/2) to the steady value. Increasing the pipette Ca2+ also decreased the delay and decreased t1/2. For instance, when pipette Ca2+ was increased from 5 to 500 nM, the delay and t1/2 decreased from values greater than 50 and 150 msec to values less than 10 and 50 msec. We conclude that the delayed currents are K+ currents through Ca2+-activated K+ channels. At the resting membrane potential of -60 mV, Ca2+-activated K+ channels contribute between 13 to 25% of the total conductance of the cell. The contribution of these channels to cell conductance nearly doubles with membrane depolarization of 20-30 mV. Such depolarizations have been observed when cerebrospinal fluid (CSF) secretion is stimulated by cAMP and with intracellular Ca2+. Thus the Ca2+-activated K+ channels may play a specific role in maintaining intracellular K+ concentrations during CSF secretion.