A patch-clamp study of potassium channels and whole-cell currents in acinar cells of the mouse lacrimal gland

Randomized Controlled Crossover Trial Comparing the Impact of Sham or Intranasal Tear Neurostimulation on Conjunctival Goblet Cell Degranulation

PURPOSE

The aim of the study was to investigate the effects of the Allergan Intranasal Tear Neurostimulator (ITN) on conjunctival goblet cell (GC) degranulation.

DESIGN

A randomized, double-masked, placebo-controlled crossover trial.

METHODS

A total of 15 subjects (5 normal and 10 dry eye) were enrolled in a 3-visit study consisting of 1 screening and 2 separate randomized-masked ITN treatments (sham extranasal or intranasal). Tear meniscus height (TMH) was measured by anterior segment optical coherence tomography before and after applications. Impression cytology (IC) was taken from the bulbar conjunctiva of the right eye for periodic acid-Schiff staining and from the left eye for MUC5AC mucin immunostaining at baseline and after each treatment. The ratio of degranulated to nondegranulated GCs was measured as a marker of secretion.

RESULTS

In all participants, both inferior bulbar (IB) and temporal bulbar (TB) cytology specimens stained for MUC5AC revealed a significantly higher ratio of degranulated to nondegranulated GCs after the ITN (IB: 2.28 ± 1.27 and TB: 1.81 ± 1.01) compared to baseline (IB: 0.56 ± 0.55, P = .015) (TB: 0.56 ± 0.32, P = .003) and extranasal sham application (IB: 0.37 ± 0.29, P = .001) (TB: 0.39 ± 0.33, P = .001). When the same analysis was repeated in the dry eye or control groups, the ratio was significantly higher after ITN than the baseline ratio and ratio after extranasal application in both groups (P < .05). Moreover, although control subjects had a higher ratio of degranulated to nondegranulated GCs at baseline (0.75 ± 0.52) compared with the dry eye group (0.41 ± 0.27), the ratio became slightly higher in dry eye (2.04 ± 1.12 vs 1.99 ± 1.21 in control) after the ITN application. There was no significant difference between the IB or TB conjunctiva locations in terms of the effectiveness of the ITN application on conjunctival goblet cell secretory response.

CONCLUSIONS

These preliminary results document that the Allergan ITN can stimulate degranulation of goblet cells in the conjunctiva, which is a promising new approach for the management of dry eye.

Electronic enhancement of tear secretion

OBJECTIVE

To study electrical stimulation of the lacrimal gland and afferent nerves for enhanced tear secretion, as a potential treatment for dry eye disease. We investigate the response pathways and electrical parameters to safely maximize tear secretion.

APPROACH

We evaluated the tear response to electrical stimulation of the lacrimal gland and afferent nerves in isofluorane-anesthetized rabbits. In acute studies, electrical stimulation was performed using bipolar platinum foil electrodes, implanted beneath the inferior lacrimal gland, and a monopolar electrode placed near the afferent ethmoid nerve. Wireless microstimulators with bipolar electrodes were implanted beneath the lacrimal gland for chronic studies. To identify the response pathways, we applied various pharmacological inhibitors. To optimize the stimulus, we measured tear secretion rate (Schirmer test) as a function of pulse amplitude (1.5-12 mA), duration (0.1-1 ms) and repetition rate (10-100 Hz).

MAIN RESULTS

Stimulation of the lacrimal gland increased tear secretion by engaging efferent parasympathetic nerves. Tearing increased with stimulation amplitude, pulse duration and repetition rate, up to 70 Hz. Stimulation with 3 mA, 500 μs pulses at 70 Hz provided a 4.5 mm (125%) increase in Schirmer score. Modulating duty cycle further increased tearing up to 57%, compared to continuous stimulation in chronically implanted animals (36%). Ethmoid (afferent) nerve stimulation increased tearing similar to gland stimulation (3.6 mm) via a reflex pathway. In animals with chronically implanted stimulators, a nearly 6 mm increase (57%) was achieved with 12-fold less charge density per pulse (0.06-0.3 μC mm(-2) with 170-680 μs pulses) than the damage threshold (3.5 μC mm(-2) with 1 ms pulses).

SIGNIFICANCE

Electrical stimulation of the lacrimal gland or afferent nerves may be used as a treatment for dry eye disease. Clinical trials should validate this approach in patients with aqueous tear deficiency, and further optimize electrical parameters for maximum clinical efficacy.

Fluid secretion and the Na+-K+-2Cl- cotransporter in mouse exorbital lacrimal gland

We have previously suggested that fluid flow in the mouse exorbital lacrimal gland is driven by the opening of apical Cl- and K+ channels. These ions move into the lumen of the gland and water follows by osmosis. In many tissues, the Na+-K+-2Cl- cotransporter (NKCC1) replaces the Cl- and K+ ions that move into the lumen. We hypothesize that mouse exorbital lacrimal glands would have NKCC1 co-transporters and that they would be important in fluid transport by this gland. We used immunocytochemistry to localize NKCC1-like immunoreactivity to the membranes of the acinar cells as well as to the basolateral membranes of the duct cells. We developed a method to measure tear flow and its composition from mouse glands in situ. Stimulation with the acetylcholine agonist carbachol produced a peak flow followed by a plateau. Ion concentration measurements of this stimulated fluid showed it was high in K+ and Cl-. Treatment of the gland with furosemide, a blocker of the NKCC1 cotransporter, reduced the plateau phase of fluid flow by approximately 30%. Isolated cells exposed to a hypertonic shock shrank by approximately 20% and then showed a regulatory volume increase (RVI). Both the RVI and swelling were blocked by treatment with furosemide. Cells isolated from these glands shrink by approximately 10% in the presence of carbachol. Blocking NKCC1 with furosemide reduced the amount of shrinkage by approximately 50%. These data suggest that NKCC1 plays an important role in fluid secretion by the exorbital gland of mice.

Tissue distribution of GAP1(IP4BP) and GAP1(m): two inositol 1,3,4,5-tetrakisphosphate-binding proteins

Two members of the GAP1 family, GAP1(IP4BP) and GAP1(m), have been shown to bind the putative second messenger Ins(1,3,4,5)P4 with high affinity and specificity, though other aspects of their behaviour suggest that in vivo, whereas GAP1(IP4BP) may function as an Ins(1,3,4,5)P4 receptor, GAP1(m) may be a receptor for the lipid second messenger PtdIns(3,4,5)P3. As a step towards clarifying their cellular roles, we describe here how we have raised and characterised antisera that are specific for the two proteins, and used these to undertake a comprehensive study of their tissue distribution. Both proteins are widely expressed, but there are several clear differences between them in the tissues that show the highest levels of expression.

Identification and regulation of K+ and Cl- channels in human parotid acinar cells

The properties of K+ channels in these cells were studied using patch-clamp methods. Two channels, with conductances of 165+/-13 pS (n=6) and 30+/-1 pS (n=3), were identified in single-channel experiments. In cell-attached patches the reversal potentials were -67+/-8 and -74+/-2 mV for the large and small conductance channel, respectively, suggesting that both channels are K+-selective. The large conductance channel was also shown to be K+-selective in inside-out patches. The open probability (P(o)) of this channel was increased at depolarizing potentials and by increasing intracellular Ca2+ concentration ([Ca2+]i). These properties suggest that the large conductance channel is a 'maxi' Ca2+-activated K+ channel (BK(Ca)). The small conductance channel was not observed in inside-out patches. Carbachol (CCh; 10(-5) M) activated the BK(Ca) channel, but not the small conductance channel, in cell-attached patches. CCh also caused a dose-dependent increase in [Ca2+]i measured by fura-2 in microspectrofluorimetric studies, with a half-maximal response at approximately 3x10(-6) M. Neither isoproterenol (10(-5) M) nor substance P (10(-6) M) affected K+-channel activity or [Ca2+]i. In whole-cell experiments, CCh caused an increase in outward current. Charybdotoxin (10(-7) M), a BK(Ca) blocker, inhibited a large component of the CCh-induced current. A large component of the charybdotoxin-insensitive current may be carried by Ca2+-activated Cl- channels, which were also observed in human parotid acinar cells. The results indicate that BK(Ca) channels make a significant contribution to the whole-cell conductance in human parotid acinar cells.

Ca2+ regulation of a large conductance K+ channel in cultured rat cerebellar Purkinje neurons

The calcium sensitivity of a large conductance voltage-sensitive potassium channel found in cultured rat cerebellar Purkinje neurons was studied in membrane patches from the somatic region of the cultured Purkinje neurons using single-channel recording techniques. The potassium channel had a conductance of approximately 94 picosiemens (pS) under physiologic ionic conditions and was active at depolarized membrane potentials. Activity due to this channel type was not observed when the saline at the internal surface of the membrane was calcium free. Low intracellular calcium concentration (10 nM) triggered channel activity at depolarized membrane potentials. Channel activity increased further with increasing intracellular calcium concentrations and was evident at more negative membrane potentials. The high sensitivity of this potassium channel type to intracellular calcium and its abundance in the Purkinje neuron membrane may reflect a prominent role in the control of action potential duration and interspike interval when the neurons are firing in a rapid, repetitive mode.

Calcium-activated potassium channels in adrenal chromaffin cells

Rat chromaffin cells express an interesting diversity of Ca(2+)-dependent K+ channels, including a voltage-independent, small-conductance, apamin-sensitive SK channel and two variants of voltage-dependent, large-conductance BK channels. The two BK channel variants are differentially segregated among chromaffin cells, such that BK current is completely inactivating in about 75-80% of rat chromaffin cells, while the remainder express a mix of inactivating and non-inactivating current or mostly non-inactivating BKs current. The single-channel conductance of BKi channels is identical to that of BKs channels. Although rates of current activation are similar in the two variants, the deactivation kinetics of the two channels also differ. Furthermore, BKi channels are somewhat less sensitive to scorpion toxins than BKs channels. The slow component of BKi channel deactivation may be an important determinant of the functional role of these channels. During blockade of SK current, cells with BKi current fire tonically during sustained depolarizing current injection, whereas cells with BKs current tend to fire only a few action potentials before becoming quiescent. The ability to repetitively fire requires functional BKi channels, since partial blockade of BKi channels by CTX makes a BKi cell behave much like a BKs cell. In contrast, the physiological significance of BKi inactivation may arise from the ability of secretagogue-induced [Ca2+]i elevations to regulate the availability of BKi channels during subsequent action potentials (Herrington et al., 1995). By reducing the number of BK channels available for repolarization, the time course of action potentials may be prolonged. This possibility remains to be tested directly. These results raise a number of interesting questions pertinent to the control of secretion in rat adrenal chromaffin cells. An interesting hypothesis is that cells with a particular kind of BK current may reflect particular subpopulations of chromaffin cells. These subpopulations might differ either in the nature of the material secreted from the cell (e.g., Douglass and Poisner, 1965) or in the responsiveness to particular secretagogues. The differences in electrical behavior between cells with BKi and BKs current suggest that the pattern of secretion that might be elicited by a single type of stimulus could differ. For BKi cells, secretion may occur in a tonic fashion during sustained depolarization, while secretion from cells with BKs current may be more phasic. In the absence of specific structural information about the domains responsible for inactivation of BKi channels, our understanding of the mechanism of inactivation remains indirect. BKi inactivation shares many features with N-terminal inactivation of voltage-dependent K+ channels. However, there are provocative differences between the two types of inactivation which require us to propose that the native inactivation domain of BKi channels may occlude access of permeant ions to the BK channel permeation pathway in a position at some distance from the actual mouth of the channel. Further understanding of the structural and mechanistic basis of inactivation of BKi channels promises to provide new insights into both the cytoplasmic topology of BK channels and the Ca(2+)- and voltage-dependent steps involved in channel activation.

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.

A voltage-sensitive transient potassium current in mouse pancreatic acinar cells

We describe, for the first time, a potassium current in acutely isolated mouse pancreatic acinar cells. This current is activated by depolarization and has many of the characteristics of the fast transient potassium current of neurones where roles in shaping action potential duration and frequency have been proposed. Although acinar cells do not carry action potentials, our experiments indicate that the primary regulator of the current in these cells is the membrane potential. In whole-cell patch-clamped cells we demonstrate an outward current activated by depolarization. This current was transient and inactivated over the duration of the pulse (100-500 ms). The decay of the inactivation was adequately fitted by a single exponential. The time constant of decay, tau, at a membrane potential of +20 mV was 34 +/- 0.6 ms (mean +/- SEM, n = 6) and decreased with more positive pulse potentials. The steady-state inactivation kinetics showed that depolarized holding potentials reduced the amplitude of the current observed with a half-maximal inactivation at a membrane potential of -40.6 +/- 0.33 mV (mean +/- SEM, n = 5). These activation and inactivation characteristics were not affected by low intracellular calcium (10(-10) mol.l-1) or by an increase in calcium (up to 180 nmol.l-1). In addition we found no effect on the current of dibutyryl cyclic adenosine monophosphate (db-cAMP) or the agonist acetylcholine. The current was blocked by 4-aminopyridine (Kd approximately 0.5 mmol.l-1) but not affected by 10 mmol.l-1 tetraethylammonium.(ABSTRACT TRUNCATED AT 250 WORDS)

Ca(2+)-activated K+ channels are involved in regulatory volume decrease in acinar cells isolated from the rat lacrimal gland

The volumes of acinar cells isolated from rat lacrimal gland were measured on computer by video-imaging. Cells were found to swell on exposure to hypotonic solutions; they subsequently exhibited a regulatory volume decrease (RVD). RVD was inhibited in the absence of extracellular Ca2+, and by the K+ channel blocker tetraethylammonium chloride (2 mM TEA+). The possible involvement of K+ channels in RVD was further investigated in cell-attached patches. Exposing the cells to a hypotonic solution activated channels with a conductance of 141 +/- 6 pS (n = 11). These channels were partially blocked by 0.5 mM TEA+, and channel activation was not observed in the absence of extracellular Ca2+. Experiments in the inside-out patch configuration demonstrated that the channels activated by hypotonic stress were "maxi" Ca(2+)-activated K+ channels. It is concluded that the opening of these channels plays an important role in RVD, by facilitating K+ loss from the cell.

Maxi K+ channels on human vas deferens epithelial cells

The vas deferens forms part of the male reproductive tract and extends from the cauda epididymis to the prostate. Using the patch clamp technique, we have identified a Ca(2+)-activated, voltage-dependent, maxi K+ channel on the apical membrane of epithelial cells cultured from human fetal vas deferens. The channel had a conductance of approximately 250 pS in symmetrical 140 mM K+ solutions, and was highly selective for K+ over Na+. Channel activity was increased by depolarization and by an elevation of bath (cytoplasmic) Ca2+ concentration, and reduced by cytoplasmic Ba2+ (5 mM) but not by cytoplasmic TEA (10 mM). Channel activity was also dependent on the cation bathing the cytoplasmic face of the membrane, being higher in a Na(+)-rich compared to a K(+)-rich solution. We estimated that up to 600 maxi K+ channels were present on the apical membrane of a vas cell, and that their density was 1-2 per mu 2 of membrane. Activity of the channel was low on intact cells, suggesting that it does not contribute to a resting K+ conductance. However, fluid in the lumen of the human vas deferens has a high K+ concentration and we speculate that the maxi K+ channel could play a role in transepithelial K+ secretion.

Isolation of acini from nasal glands of the guinea-pig

A procedure for isolating the acinar cells of the serous gland in the mammalian nasal septum has been developed. This technique is characterized by meticulous and selective isolation with minimal contamination by the surface epithelial cells and employs enzymatic treatment with collagenase. The isolated cells were confirmed to be serous gland acini as shown by negative staining with Alcian blue and a high electron density of the granules. The acini were more than 90% viable as judged by trypan blue exclusion. Ultrastructural integrity of the cells was well maintained following the isolation procedure. Application of acetylcholine to the isolated acini induced an inward current in a whole-cell patch clamp and increased intracellular Ca2+ concentration measured by fura-2. These acetylcholine responses were completely blocked by atropine. These physiological findings directly demonstrated that nasal gland acini possess muscarinic-activated receptors as previously suggested. These isolated cells hold promise for the in vitro study of secretory mechanisms in the mammalian nasal gland.

Ca2+ activation and pH dependence of a maxi K+ channel from rabbit distal colon epithelium

To determine if their properties are consistent with a role in regulation of transepithelial transport, Ca(2+)-activated K+ channels from the basolateral plasma membrane of the surface cells in the distal colon have been characterized by single channel analysis after fusion of vesicles with planar lipid bilayers. A Ca(2+)-activated K+ channel with a single channel conductance of 275 pS was predominant. The sensitivity to Ca2+ was strongly dependent on the membrane potential and on the pH. At a neutral pH, the K0.5 for Ca2+ was raised from 20 nM at a potential of 0 mV to 300 nM at -40 mV. A decrease in pH at the cytoplasmic face of the K+ channel reduced the Ca2+ sensitivity dramatically. A loss of the high sensitivity to Ca2+ was also observed after incubation with MgCl2, possibly a result of dephosphorylation of the channels by endogenous phosphatases. Modification of the channel protein may thus explain the variation in Ca2+ sensitivity between studies on K+ channels from the same tissue. High affinity inhibition (K0.5 = 10 nM) by charybdotoxin of the Ca(2+)-activated K+ channel from the extracellular face could be lifted by an outward flux of K+ through the channel. However, at the ion gradients and potentials found in the intact epithelium, charybdotoxin should be a useful tool for examination of the role of maxi K+ channels. The high sensitivity for Ca2+ and the properties of the activator site are in agreement with an important regulatory role for the high conductance K+ channel in the epithelial cells.

Calcium-dependent chloride current activated by hyposmotic stress in rat lacrimal acinar cells

We have identified a whole-cell Cl- current activated by hyposmotic stress in rat lacrimal acinar cells using the patch-clamp technique. Superfusion of isolated single cells with hyposmotic solution (80% of control osmolarity) caused a gradual increase of the current, which was reversed on return to the control solution. The current-voltage relationship showed outward rectification, and the current showed time and voltage dependence: slowly activated by depolarizing voltages and rapidly inactivated by hyperpolarizing voltages. The increase in current was not observed when intracellular Ca2+ was chelated with EGTA. It was also inhibited by the absence of extracellular Ca2+, or the presence of gadolinium ions (20 microM Gd3+). We conclude that in rat lacrimal acinar cells hyposmotic stress activates Ca(2+)-dependent Cl- channels as a result of Ca2+ influx through a Gd(3+)-sensitive pathway. The Cl- channels involved appear to be indistinguishable from those activated by muscarinic stimulation. The inhibitory effect of Gd3+ suggests that stretch-activated nonselective cation channels may be responsible for the Ca2+ influx.

High density of Ca(2+)-dependent K+ and Cl- channels on the luminal membrane of lacrimal acinar cells

Tight-seal whole-cell recording and Ca2+ imaging were simultaneously performed on cell clusters or individual acinar cells of rat lacrimal glands during application of the secretagogue acetylcholine. Activation of Ca(2+)-dependent K+ and Cl- currents was selectively followed as a function of time by placing the cell potential near the equilibrium potential for Cl- or for K+ ion, respectively. Upon acetylcholine application to cell clusters, K(+)- and Cl(-)-selective currents displayed a distinctive initial rise ("hump"). At this time, there was only a small elevation of Ca2+ concentration, [Ca2+]i, that was restricted to the luminal end of acinar cells. A quantitative analysis of Ca2+ and current signals during the hump suggested that the luminal membrane contained high densities of K(+)- and Cl(-)-selective channels, roughly 10 times higher than those found in the basolateral domain. Distinct luminal and basolateral membrane domains were preserved in isolated cells, but with less contrasted densities than in cell clusters. The results suggest that Ca(2+)-dependent K+ channels are implicated not only in the transfer of salt from the blood compartment to the interior of acinar cells, as commonly accepted, but also in the electrolyte secretion from the cell interior to the acinar lumen.

Mastoparan blockade of currents through Ca(2+)-activated K+ channels in bovine chromaffin cells

The action of mastoparan (a wasp venom peptide) on "maxi" Ca(2+)-activated K+ channels was studied in excised inside-out patch recordings from cultured bovine chromaffin cells, under normal conditions (160 mM K+ inside, 154 mM Na+ outside). Mastoparan, when applied on the intracellular side of the membrane reduced the open channel probability in a concentration dependent manner. Changes in the channel kinetics were complex. The histograms of the open dwell times were all described by either one or two exponentials. Mastoparan shortened the mean duration of the major (long) component and to a lesser extent the minor (short) component. Closed dwell times, were described by three exponentials. While the short (major) component was prolonged by mastoparan, and the intermediate component was unaffected, the long component was shortened. Overall mean closed times were prolonged. The changes in channel kinetics could only partly be explained by a channel-blocking mechanism, even when assuming that mastoparan acts as both an intermediate and a slow channel blocker suggesting that it affects gating mechanism. The fact that mastoparan is a calmodulin inhibitor and a G-protein activator raises the possibility that in bovine chromaffin cells, either the membrane-bound calmodulin or a G-protein, plays a role in the modulation of Ca(2+)-activated K+ channels.

Calcium-activated potassium channels in native endothelial cells from rabbit aorta: conductance, Ca2+ sensitivity and block

1. Isolated native endothelial cells, obtained by treatment of rabbit aortic endothelium with papain and dithiothreitol, were voltage clamped, and single channel (unitary) and spontaneous transient outward currents (STOCs) were recorded from both whole cells and excised membrane patches. 2. In inside-out patches, the reversal potential of unitary currents was dependent on the extracellular K+ concentration and had a single-channel slope conductance of 220 pS in symmetrical 140 mM-K+ solutions. The open-state probability (Po) of the unitary K+ currents was sensitive to the intracellular Ca2+ concentration with half-maximal activation at approximately 1 microM at +20 mV. The ionic selectivity and Ca2+ sensitivity indicate that a large conductance, Ca(2+)-activated K+ channel is present in freshly dissociated rabbit aortic endothelial cells. 3. The frequency and amplitude of whole-cell unitary currents and amplitude of spontaneous transient outward currents were voltage-dependent. Whole-cell outward K+ currents evoked by depolarizing voltage ramps had amplitudes often corresponding to the simultaneous opening of more than five single Ca(2+)-activated K+ channels. Lowering the intracellular EGTA concentration tenfold, and hence the Ca2+ buffering capacity of the cell, increased unitary K+ current activity and shifted the relationship between Po and membrane potential by approximately -20 mV. 4. Bradykinin (1 microM), adenosine 5'-triphosphate (3 microM) and acetylcholine (3 microM) applied extracellularly evoked a biphasic increase in N Po (where N is number of channels activated) of the Ca(2+)-activated K+ channel studied in the whole-cell recording configuration. The development of a biphasic response to agonist stimulation requires a source of extracellular Ca2+. The sustained increase in N Po of the Ca(2+)-activated K+ channel was attenuated upon the removal of external Ca2+ (Mg2+ replacement) or in the presence of the Ca2+ entry blocker, Ni2+, and the potassium channel blockers tetrabutylammonium (TBA) or tetraethylammonium (TEA). 5. Unitary and spontaneous transient outward currents were inhibited by extracellularly applied TEA (0.5 mM), TBA (0.5-5 mM) and charybdotoxin (100 nM). Ca(2+)-activated K+ currents were blocked completely by 5 mM-TEA, whereas 3,4-diaminopyridine (1 mM), Ba2+ (10 mM) and apamin (0.1-1 microM) did not abolish these K+ currents. 6. The K+ channel opener cromakalim (10 microM) evoked a sustained increase in N Po of the Ca(2+)-activated K+ channels which was not potentiated by the addition of bradykinin. Glibenclamide (10 microM) alone increased N Po and partially inhibited the cromakalim-induced increase in N Po with respect to control.(ABSTRACT TRUNCATED AT 400 WORDS)

Maxi K+ channel in apical membrane of vestibular dark cells

Recordings were made on excised apical membrane patches from vestibular dark cells from the semicircular canal of gerbils to determine if ion channels could be involved in the process of K+ secretion. Both nonselective cation channels [Am. J. Physiol. 262 (Cell Physiol. 31): C1430-C1436, 1992] and K(+)-selective channels were found. The K+ channels occurred in only 0.7% of the patches. In symmetrical 145 mM KCl solutions, the current-voltage (I-V) relation of the K(+)-selective channel was linear, indicating the absence of rectification, and the conductance was 240 +/- 8 pS (n = 8). The Goldman-Hodgkin-Katz equation for current carried solely by K+ could be fitted to the I-V relation in asymmetrical K+ and Na+ solutions and yielded a K+ permeability of 5.78 x 10(-13) cm3/s (n = 12). The channel was shown to be impermeable to Li+, NH4+, N-methyl-D-glucamine, and Cl-. Channel activity increased with depolarization and with increasing free [Ca2+]; for voltages between +40 and -60 mV, the strongest regulation occurred in the range 10(-6) to 10(-5) M Ca2+. Tetraethylammonium (2 x 10(-2) M) had from the cytosolic side no effect on the open probability (Po) but completely inhibited activity from the extracellular side. Po was reduced by Ba2+ (5 x 10(-3) M), verapamil (10(-4) M), quinine (10(-4) M), and quinidine (10(-4) and 10(-3) M), while lidocaine (5 x 10(-3) M) had no measurable effect on Po but decreased the amplitude. Rb+ and Cs+ were either poorly permeable or partially blocked the channel in a voltage-dependent manner.(ABSTRACT TRUNCATED AT 250 WORDS)

Acetylcholine- and caffeine-evoked repetitive transient Ca(2+)-activated K+ and C1- currents in mouse submandibular cells

1. Resting and acetylcholine-induced membrane currents were measured in single mouse submandibular acinar cells using the patch-clamp whole-cell current recording technique. 2. Micromolar ACh activated a large, sustained outward, Ca(2+)-dependent K+ current and a single transient inward Ca(2+)-dependent C1-current. 3. Nanomolar ACh induced a series of transients in both the K+ and C1- currents; C1- current activation was now observed throughout the period of agonist application. We consider this repetitive transient current activation better able to support sustained fluid and electrolyte secretion than the response elicited by a high dose of agonist. 4. Repetitive K+ and C1- current transients were also induced by 1 mM-caffeine, consistent with caffeine-induced Ca2+ release from the Ca(2+)-sensitive Ca2+ stores which are thought to comprise part of the pathway for activation of secretion. 5. The ACh-induced current transients were inhibited by 10 mM-caffeine, 100 microM-IBMX and 10 microM membrane-permeable cyclic AMP. Therefore, it seems likely that caffeine is able to inhibit agonist-induced calcium mobilization via a cyclic AMP-dependent pathway.

Cationic channels sensitive to extracellular ATP in rat lacrimal cells

1. Responses of isolated rat lacrimal cells to local applications of ATP were studied using tight-seal whole-cell recording and/or Fura-2-derived calcium concentration measurements. 2. In cells where variations in Ca2+ concentration were prevented by use of a strong Ca2+ buffer, ATP was found to induce an inward current response at negative holding potentials. With 10 microM-ATP, the current amplitude ranged between 20 and 200 pA. The reversal potential of this ATP-induced current was close to 0 mV with normal external solution and shifted to -19 +/- 3 mV (mean +/- S.D.) when the concentration of external monovalent cations was halved. These results indicate that the channels have a cationic selectivity. The response amplitude decreased markedly from trial to trial, indicating a desensitization process which was irreversible on the time scale of the recordings. 3. Steady state I-V curves for the ATP-induced current in normal saline showed a marked inward rectification. This rectification appeared to be linked to a time-dependent activation of the channels, as hyperpolarizing voltage jumps elicited a time-dependent current increase. This relaxation could be fitted by a double-exponential function, with time constants (at -120 mV) of 0.9 +/- 0.3 ms and 110 +/- 6.4 ms. 4. Variance analysis of the ATP-induced current gave a single-channel current value of 0.34 pA at -60 mV. The single-channel current amplitude varied linearly with potential, with a slope close to 6 pS. The relation between noise covariance and time could be fitted by a double-exponential function, with time constants (at -60 mV) of 0.8 +/- 0.4 ms and 6.8 +/- 3.4 ms (mean +/- S.D.). 5. In an isotonic Ca2+ solution, 10 microM-ATP induced an inward current at -60 mV with a calculated single-channel current amplitude obtained from noise analysis close to 0.2 pA. In an external solution containing 10 mM-calcium and no sodium, 50 microM-ATP elicited a current with a reversal potential of -19 mV. 6. Fura-2 measurements were performed in intact cells or in cells dialysed with a low concentration of Ca2+ buffer (e.g. 0.5 mM-EGTA). Under such conditions ATP induced increases of the internal Ca2+ concentration with very variable amplitudes. In some cells Ca2+ rises of 50 nM or lower were found. Minimal activation of Ca(2+)-dependent channels was then observed. In other cells large Ca2+ rises (up to 500 nM) were observed and were then correlated with marked activation of Ca(2+)-dependent channels.(ABSTRACT TRUNCATED AT 400 WORDS)

Stimulus-secretion coupling: cytoplasmic calcium signals and the control of ion channels in exocrine acinar cells

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The ATP-induced inward current in mouse lacrimal acinar cells is potentiated by isoprenaline and GTP

1. ATP activates calcium (Ca2+) influx in mouse lacrimal acinar cells in the absence of phosphoinositide hydrolysis. Extracellular ATP (1 mM) activates receptor-operated cation channels, promoting entry of Na+ and Ca2+ (inward current). This Ca2+ influx in turn activates K+ channels resulting in a delayed, outward, current component. The present study uses patch-clamp current recording techniques to investigate the role of beta-adrenoceptor mechanisms, intracellular cyclic AMP and GTP in the regulation of the ATP-induced inward currents. 2. The beta-adrenoceptor agonist, isoprenaline (1 microM), does not increase the resting membrane currents but markedly enhances the ATP-induced inward and outward currents. This effect of isoprenaline is blocked by the beta-adrenoceptor antagonist propranolol. 3. Internal application of cyclic AMP mimics the potentiating effect of isoprenaline. 100 microM-cyclic AMP increases the ATP-induced inward and outward currents to about 200% as compared to control responses. 4. Pre-treatment of the cells with the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (IBMX; 1 mM), also results in a marked potentiation of the ATP-induced inward currents to 170% as compared to control responses. 5. The ATP-induced inward current responses are not blocked by either the removal of extracellular Ca2+ or by chelation of intracellular Ca2+ (by inclusion of 10 mM-EGTA in the recording pipette). Both protocols did however block the potentiating effect of internal cyclic AMP on the ATP-induced inward current responses. 6. Intracellular ATP (10 mM) reduces the amplitude of the inward currents evoked by external ATP application by about 60% and the currents were no longer potentiated by internal cyclic AMP. 7. Intracellular GTP or GTP-gamma-S (100 microM in the pipette solution) potentiates the current responses to ATP, increasing both the amplitude and duration of the inward currents. 8. In excised inside-out patches, with ATP in the recording pipette (i.e. external ATP), the catalytic subunit of the cyclic AMP-dependent protein kinase activated the cation channels. The effect of the catalytic subunit was readily reversible and abolished by an inhibitor of the protein kinase. 9. External ATP activates Ca2+ influx in lacrimal acinar cells by a mechanism that is distinct from that activated by phosphoinositide-coupled receptors. The effect is mediated by direct activation of cation channels in the cell surface membrane which allow for significant entry of Ca2+.(ABSTRACT TRUNCATED AT 400 WORDS)

Activation of ion transport pathways by changes in cell volume

Swelling-activated K+ and Cl- channels, which mediate RVD, are found in most cell types. Prominent exceptions to this rule include red cells, which together with some types of epithelia, utilize electroneutral [K(+)-Cl-] cotransport for down-regulation of volume. Shrinkage-activated Na+/H+ exchange and [Na(+)-K(+)-2 Cl-] cotransport mediate RVI in many cell types, although the activation of these systems may require special conditions, such as previous RVD. Swelling-activated K+/H+ exchange and Ca2+/Na+ exchange seem to be restricted to certain species of red cells. Swelling-activated calcium channels, although not carrying sufficient ion flux to contribute to volume changes may play an important role in the activation of transport pathways. In this review of volume-activated ion transport pathways we have concentrated on regulatory phenomena. We have listed known secondary messenger pathways that modulate volume-activated transporters, although the evidence that volume signals are transduced via these systems is preliminary. We have focused on several mechanisms that might function as volume sensors. In our view, the most important candidates for this role are the structures which detect deformation or stretching of the membrane and the skeletal filaments attached to it, and the extraordinary effects that small changes in concentration of cytoplasmic macromolecules may exert on the activities of cytoplasmic and membrane enzymes (macromolecular crowding). It is noteworthy that volume-activated ion transporters are intercalated into the cellular signaling network as receptors, messengers and effectors. Stretch-activated ion channels may serve as receptors for cell volume itself. Cell swelling or shrinkage may serve a messenger function in the communication between opposing surfaces of epithelia, or in the regulation of metabolic pathways in the liver. Finally, these transporters may act as effector systems when they perform regulatory volume increase or decrease. This review discusses several examples in which relatively simple methods of examining volume regulation led to the discovery of transporters ultimately found to play key roles in the transmission of information within the cell. So, why volume? Because it's functionally important, it's relatively cheap (if you happened to have everything else, you only need some distilled water or concentrated salt solution), and since it involves many disciplines of experimental biology, it's fun to do.

Calcium-activated potassium channels: regulation by calcium

A wide variety of calcium-activated K channels has been described and can be conveniently separated into three classes based on differences in single-channel conductance, voltage dependence of channel opening, and sensitivity to blockers. Large-conductance calcium-activated K channels typically require micromolar concentrations of calcium to open, and their sensitivity to calcium increases with membrane depolarization, suggesting that they may be involved in repolarization events. Small-conductance calcium-activated K channels are generally more sensitive to calcium at negative membrane potentials, but their sensitivity to calcium is independent of membrane potential, suggesting that they may be involved in regulating membrane properties near the resting potential. Intermediate-conductance calcium-activated K channels are a loosely defined group, where membership is determined because a channel does not fit in either of the other two groups. Within each broad group, variations in calcium sensitivity and single-channel conductance have been observed, suggesting that there may be families of closely related calcium-activated K channels. Kinetic studies of the gating of calcium-activated potassium channels have revealed some basic features of the mechanisms involved in activation of these channels by calcium, including the number of calcium ions participating in channel opening, the number of major conformations of the channels involved in the gating process, and the number of transition pathways between open and closed states. Methods of analysis have been developed that may allow identification of models that give accurate descriptions of the gating of these channels. Although such kinetic models are likely to be oversimplifications of the behavior of a large macromolecule, these models may provide some insight into the mechanisms that control the gating of the channel, and are subject to falsification by new data.

Calcium-activated potassium channels in rat dissociated ventromedial hypothalamic neurons

Abstract A potassium-selective channel, characterized by a single channel conductance of 160 pS was demonstrated to be present in rat freshly dispersed ventromedial hypothalamic nucleus neurons. The single channel activity was shown to be dependent, using inside-out membrane patches, upon the presence of intracellular calcium ions, with maximal sensitivity between 10(-6) and 10(-6) M[Ca(2+)], and to be modulated by membrane voltage, depolarization causing an increase in open-state probability in the presence of an activating concentration of calcium. Therefore these properties place this channel into the category of a large conductance (maxi-K(+)) calcium-activated potassium (Ca(2+)-K(+)) channel. This channel is active in cell-attached recordings from glucoreceptive cells when depolarized by glucose or tolbutamide with openings often associated with action current repolarization. These openings were shown to be abolished in the presence of extracellular Cd(2+) and La(3+) ions, which block calcium channels, suggesting that extracellular calcium entry upon cell depolarization is responsible for their activation. On a few occasions, a larger conductance (250 pS) Ca(2+)-K(+) channel was observed in inside-out membrane patches isolated from ventromedial hypothalamic nucleus neurons. In contrast to the 160 pS channel, the presence of intracellularly-applied ATP caused a concentration-dependent, reversible inhibition of its open-state probability.

Basolateral K conductance: role in regulation of NaCl absorption and secretion

In this review we explore the possible role of basolateral K conductance (gK) in the regulation of salt absorption and secretion. This inquiry is prompted by a growing body of evidence which, taken together, suggests that basolateral gK is very labile and that alterations in basolateral gK may be a key feature in both stimulatory and inhibitory regulatory mechanisms. We first consider the role of basolateral gK in relation to models for salt absorption and secretion, particularly in relation to the maintenance of cellular charge balance and the obligatory coupling between the apical and basolateral membranes that is produced by transcellular current flow. Next, we review some of the experimental evidence that suggests that changes in basolateral gK are associated with transport regulation. The cellular mechanisms that are known to impact on K channel regulation are considered in a general way, and finally, we consider the use of integrated models for understanding possible coordinate regulation of apical and basolateral cell membranes.

Extracellular ATP activates receptor-operated cation channels in mouse lacrimal acinar cells to promote calcium influx in the absence of phosphoinositide metabolism

In exocrine acinar cells a variety of neurotransmitters (e.g. acetylcholine) stimulate phosphatidylinositol 4,5-bisphosphate hydrolysis elevating intracellular calcium to activate calcium-dependent membrane currents (outward K+ and inward Cl-). This study shows that in lacrimal acinar cells extracellular application of ATP is also associated with outward and inward current responses; these, however, are not the result of phosphoinositide metabolism. ATP directly activates receptor-operated cation channels which permit influx of Na+ and Ca+ (the inward current). The elevation in [Ca2+]i which results is sufficient to activate the outward K+ current. ATP thus promotes Ca+ influx in the absence of phosphoinositide metabolism.

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.

Effects of Corticotrophin Releasing Factor, Muscarine and Somatostatin on Rubidium and Potassium Efflux from Mouse AtT-20 Pituitary Cells

Effects of secretagogues and anti-secretagogues of ACTH secretion on K+ permeability in the clonal pituitary cell line AtT-20 were measured by recording 86Rb or 42K efflux. Efflux was accelerated by the secretagogues K+, corticotrophin, forskolin, isoprenaline, and the Ca-ionophore A23187. Efflux was reduced by the inhibitors somatostatin, muscarine, and oxotremorine, or by removing external Ca. Efflux was also reduced by the K+-channel blocking compound d-tubocurarine but not by tetraethylammonium. Muscarine, oxotremorine, somatostatin, and 0 Ca2+ also reduced intracellular Ca2+ measured by quin-2 fluorescence. It is suggested that most of the resting 86Rb or 42K efflux measured under these conditions occurs via tubocurarine-sensitive Ca2+-dependent K+-channels, and that changes in efflux rate produced by secretagogues or anti-secretagogues are secondary to changes in intracellular Ca2+.

Cholinergically-induced changes in outward currents in hair cells isolated from the semicircular canal of the frog

Two cholinergically-induced modulations of membrane conductances have been identified in hair cells isolated from the crista ampullaris of the leopard frog (Rana pipiens), using the whole cell recording configuration of the patch clamp technique. Of 56 crista hair cells tested, 28 showed drug-induced changes in membrane current or membrane potential which were repeatable and could be reversed with washout of drug. The predominant effect (observed in 20 hair cells) of acetylcholine (Ach, 100 microM) to 1mM) or carbachol (1 microM to 50 microM) applied to these hair cells was the reduction of an outward current corresponding to a change in conductance of approximately -0.22 nS. This action by Ach on hair cells has been inferred from previous studies of afferent fiber discharge which reported an increase in firing rate with stimulation of efferent fibers or exogenous application of cholinomimetics (Bernard et al., 1985; Valli et al., 1986; Guth et al., 1986; Norris et al., 1988a). The Ach-induced reduction in outward current was associated with a depolarization of the zero-current membrane potential by approximately +2.5 mV. In a total of 8 hair cells, an Ach-induced reversible increase in outward current was recorded. Changes in conductance were approximately +0.13 nS and were associated with a hyperpolarization of the zero-current membrane potential by approximately -2.2 mV. This current increase is likely to be responsible for the inhibitory post-synaptic potentials (IPSPs) which have previously been recorded intracellularly from acoustico-lateralis hair cells during stimulation of the efferent innervation (Flock and Russell, 1976; Ashmore and Russell, 1982; Art et al., 1984, 1985). Of the remaining 28 hair cells, six cells failed to exhibit any change in membrane conductance or membrane potential in the presence of cholinomimetics while an additional 15 cells exhibited decreases, and 7 cells exhibited increases in outward conductance, during application of Ach or carbachol, which were neither reversible with washout nor repeatable. The Ach-induced decrease in outward current could be reversible blocked by removal of Ca2+ from the external solution. The antagonism of the Ach-induced decrease in outward current by atropine (10(-5) M) suggests that this current may correspond to a facilitatory, 'atropine-preferring' Ach receptor mediated response previously identified in the isolated semicircular canal (Norris et al., 1988a).(ABSTRACT TRUNCATED AT 400 WORDS)

The physiological role of calcium-dependent channels

Calcium (Ca2+)-dependent channels may be classified in three broad categories, which are, respectively, selective for potassium ions, for chloride ions, and for monovalent cations. The usual action of Ca2+ is to increase the probability of opening of the channels, but examples of the reverse, Ca2+-induced inhibition of ion channels, have recently been found. Ca2+-dependent channels help to shape the action potentials of excitable cells as well as the synaptic currents of muscular and neuronal preparations. They are involved in several aspects of electrolyte transport including regulation of osmolarity in animal cells and of turgor in plant cells, electrolyte secretion in exocrine glands, fluid absorption and secretion in epithelial tissues.

Current fluctuations and oscillations in smooth muscle cells from hog carotid artery. Role of the sarcoplasmic reticulum

Electrical activity of enzymatically isolated, smooth muscle cells from hog carotid arteries was recorded under current clamp and voltage clamp. Under the experimental conditions, membrane potential usually was not stable, and spontaneous hyperpolarizing transients of approximately 100-msec duration were recorded. The amplitude of the transients was markedly voltage dependent and ranged from about 20 mV at a membrane potential of 0 mV to undetectable at membrane potentials negative to -60 mV. Under voltage clamp, transient outward currents displayed a similar voltage dependency. These fluctuations reflect a K+ current; they were abolished by 10 mM tetraethylammonium chloride, a K+ channel blocker, and the current fluctuations reversed direction in high extracellular K+ concentration. Modulators of intracellular Ca2+ concentration also affected electrical activity. Lowering intracellular Ca2+ concentration by addition of 10 mM EGTA to the pipette solution or suppressing sarcoplasmic reticulum function by superfusion with caffeine (10 mM), ryanodine (1 microM), or histamine (3-10 microM) blocked the rapid voltage and current spikes. However, caffeine and histamine induced a much slower hump of outward current before blocking the rapid spikes. This slower transient outward current could be elicited only once after external Ca2+ was removed and is consistent with an activation of K+ channels by Ca2+ released from internal stores. In contrast, removal of external Ca2+ alone failed to abolish the rapid spikes. These results suggest that 1) a Ca2+-dependent K+ conductance can markedly affect the electrical behavior of arterial smooth muscle cells and 2) internal Ca2+ stores, probably the sarcoplasmic reticulum, can support rapid and frequent releases of Ca2+. Exposure to a low concentration of histamine (3 microM) caused synchronization of the irregular, rapid fluctuations giving rise to slow, periodic oscillations of Ca2+-activated K+ conductance with a frequency of 0.1-0.3 Hz. These regular oscillations are reminiscent of periodic Ca2+-induced Ca2+ release, were inhibited by 10 mM caffeine, and point to a modulation of sarcoplasmic reticulum Ca2+ release by histamine.

Inositol 1,3,4,5-tetrakisphosphate and inositol 1,4,5-trisphosphate act by different mechanisms when controlling Ca2+ in mouse lacrimal acinar cells

In internally perfused single lacrimal acinar cells the competitive inositol 1,4,5-trisphosphate (Ins 1,4,5-P3)-antagonist heparin inhibits the ACh-evoked K+ current response mediated by internal Ca2+ and also blocks both the Ins 1,4,5-P3-evoked transient as well as the sustained K+ current increase evoked by combined stimulation with internal Ins 1,4,5-P3 and inositol 1,3,4,5-tetrakisphosphate (Ins 1,3,4,5-P4). When, during sustained stimulation with both Ins 1,4,5-P3 and Ins 1,3,4,5-P4, one of the inositol polyphosphates is removed, the K+ current declines; whereas removal of Ins 1,4,5-P3 results in an immediate termination of the response, removal of Ins 1,3,4,5-P4 only causes a very gradual and slow reduction in the current. Ins 1,3,4,5-P4 is therefore not an acute controller of Ca2+ release from stores into the cytosol, but modulates the release of Ca2+ induced by Ins 1,4,5,P3 by an unknown mechanism, perhaps by linking Ins 1,4,5 P3-sensitive and insensitive Ca2+ stores.

Inositol 1,3,4,5-tetrakisphosphate is essential for sustained activation of the Ca2+-dependent K+ current in single internally perfused mouse lacrimal acinar cells

We have examined the effects of various inositol polyphosphates, alone and in combination, on the Ca2+-activated K+ current in internally perfused, single mouse lacrimal acinar cells. We used the patch-clamp technique for whole-cell current recording with a set-up allowing exchange of the pipette solution during individual experiments so that control and test periods could be directly compared in individual cells. Inositol 1,4,5-trisphosphate (Ins 1,4,5 P3) (10-100 microM) evoked a transient increase in the Ca2+-sensitive K+ current that was independent of the presence of Ca2+ in the external solution. The transient nature of the Ins 1,4,5 P3 effect was not due to rapid metabolic breakdown, as similar responses were obtained in the presence of 5 mM 2,3-diphosphoglyceric acid, that blocks the hydrolysis of Ins 1,4,5 P3, as well as with the stable analogue DL-inositol 1,4,5-trisphosphorothioate (Ins 1,4,5 P(S)3) (100 microM). Ins 1,3,4 P3 (50 microM) had no effect, whereas 50 microM Ins 2,4,5 P3 evoked responses similar to those obtained by 10 microM Ins 1,4,5 P3. A sustained increase in Ca2+-dependent K+ current was only observed when inositol 1,3,4,5-tetrakisphosphate (Ins 1,3,4,5 P4) (10 microM) was added to the Ins 1,4,5 P3 (10 microM)-containing solution and this effect could be terminated by removal of external Ca2+. The effect of Ins 1,3,4,5 P4 was specifically dependent on the presence of Ins 1,4,5 P3 as it was not found when 10 microM concentrations of Ins 1,3,4 P3 or Ins 2,4,5 P3 were used.(ABSTRACT TRUNCATED AT 250 WORDS)

Ion channels in normal human and cystic fibrosis sweat gland cells

Single-channel patch-clamp techniques were used to study the population of apical membrane ion channels in cultured sweat gland secretory cells from normal and cystic fibrosis subjects. Four types of anion channels and two types of cation channels were found. At physiological voltages, anion channels had chord conductances of 10, 18, 24, and greater than 200 pS. All had linear current-voltage relations except the 24 pS channel, which showed outward rectification. Cation channels had chord conductances of 5 and 18 pS, were linear, and were nonselective for a variety of cations. Channel types and proportions were equivalent in control, cystic fibrosis, and cystic fibrosis heterozygote cells. Beyond showing that the distribution of channel types remains unchanged in cystic fibrosis cells, the data provide a basis for comparison with cells cultured under different conditions, with other cell types, and with native tissues.

Two K+ channel types, muscarinic agonist-activated and inwardly rectifying, in a Cl- secretory epithelium: the avian salt gland

Patches of membrane on cells isolated from the nasal salt gland of the domestic duck typically contained two types of K+ channel. One was a large-conductance ("maxi") K+ channel which was activated by intracellular calcium and/or depolarizing membrane voltages, and the other was a smaller-conductance K+ channel which exhibited at least two conductance levels and displayed pronounced inward rectification. Barium blocked both channels, but tetraethylammonium chloride and quinidine selectively blocked the larger K+ channel. The large K+ channel did not appear to open under resting conditions but could be activated by application of the muscarinic agonist, carbachol. The smaller channels were open under resting conditions but the gating was not affected by carbachol. Both of these channels reside in the basolateral membranes of the Cl- secretory cells but they appear to play different roles in the life of the cell.

Lacrimal fluid and electrolyte secretion: a review

Lacrimal gland fluid is an important component of the precorneal tear film. The rate of lacrimal gland fluid secretion is controlled primarily by parasympathetic innervation, and it is, apparently, modulated by sympathetic innervation. Lacrimal gland fluid is produced in two stages, secretion of a primary fluid which resembles an isotonic ultrafiltrate of plasma in the acinus-early intercalated duct region, and secretion of a KCl-rich fluid in subsequent ductal elements. Little is known about the electrolyte transport mechanisms of the ductal epithelia. Recent work using a variety of techniques, including tracer flux measurements, intracellular electrical recording, intracellular ion activity measurements, patch clamping, and analytical subcellular fractionation, supports a model for transcellular Cl-secretion in the acinus which involves Cl--selective channels in the apical plasma membrane and an array of Na+/H+ antiporters, Cl-/HCO3-antiporters, K+ channels, and Na,K-ATPase in the basal-lateral plasma membrane.

Signal transduction and control of lacrimal gland protein secretion: a review

Proteins in lacrimal gland fluid are secreted primarily by the acinar cells. Secretory proteins are synthesized in the endoplasmic reticulum, modified in the Golgi apparatus, stored in secretory granules, and released upon a change in the cellular level of second messenger. The second messenger level is controlled by a process termed signal transduction. Agonists, primarily neurotransmitters in the lacrimal gland, bind to receptors in the basolateral membrane of secretory cells. This interaction activates enzymes in the membrane that cause production of second messengers. It has been hypothesized that second messengers stimulate secretion by activating specific protein kinases to phosphorylate proteins important for secretion. In the lacrimal gland, cholinergic agonists stimulate protein secretion. They act by activating phospholipase C to break down phosphatidylinositol bisphosphate into 1,4,5-inositol trisphosphate (1,4,5-IP3) and diacylglycerol (DAG). 1,4,5-IP3 causes release of Ca2+ from intracellular stores. This Ca2+, perhaps in conjunction with calmodulin, activates specific protein kinases that may be involved in secretion. DAG activates protein kinase C which stimulates protein secretion. alpha 1-Adrenergic agonists also stimulate lacrimal gland protein secretion. These agonists use a pathway that is separate from that utilized by cholinergic agonists and vasoactive intestinal peptide (VIP). The specific pathway has not been identified but may be DAG and protein kinase C. VIP, beta-adrenergic agonists, alpha-melanocyte stimulating hormone, and adrenocorticotropic hormone are lacrimal gland secretagogues. They activate adenylate cyclase to produce cAMP. cAMP stimulates protein kinase A, which perhaps causes protein secretion. Thus, three separate cellular pathways stimulate lacrimal gland protein secretion. Cholinergic agonists and VIP also stimulate lacrimal gland fluid secretion, and the same signal transduction pathways utilized by these agonists to stimulate protein secretion are most likely used for electrolyte and water secretion.

Physiological localization of an agonist-sensitive pool of Ca2+ in parotid acinar cells

Muscarinic stimulation of fluid secretion by mammalian salivary acinar cells is associated with a rise in the level of intracellular free calcium ([Ca2+]i) and activation of a calcium-sensitive potassium (K+) conductance in the basolateral membrane. To test in the intact cell whether the rise of [Ca2+]i precedes activation of the K+ conductance (as expected if Ca2+ is the intracellular messenger mediating this response), [Ca2+]i and membrane voltage were measured simultaneously in carbachol-stimulated rat parotid acinar cells by using fura-2 and an intracellular microelectrode. Unexpectedly, the cells hyperpolarize (indicating activation of the K+ conductance) before fura-2 detectable [Ca2+]i begins to rise. This occurs even in Ca2+-depleted medium where intracellular stores are the only source of mobilized Ca2+. Nevertheless, when the increase in [Ca2+]i was eliminated by loading cells with the Ca2+ chelator bis(2-amino-5-methylphenoxy)ethane-N,N,N',N'-tetraacetate (Me2BAPTA) and stimulating in Ca2+-depleted medium, membrane hyperpolarization was also eliminated, indicating that a rise of [Ca2+] is required for the agonist-induced voltage response. Stimulation of Me2BAPTA-loaded cells in Ca2+-containing medium dramatically accentuates the temporal dissociation between the activation of the K+ conductance and the rise of [Ca2+]i. The data are consistent with the hypothesis that muscarinic stimulation results in a rapid localized increase in [Ca2+]i at the acinar basolateral membrane followed by a somewhat delayed increase in total [Ca2+]i. The localized increase cannot be detected by fura-2 but is sufficient to open the Ca2+-sensitive K+ channels located in the basolateral membrane. We concluded that a receptor-mobilized intracellular store of Ca2+ is localized at or near the basolateral membrane.

K+ efflux from the monkey eccrine secretory coil during the transient of stimulation with agonists

1. Using a K+-sensitive extracellular electrode, we attempted to determine whether cholinergic stimulation of the simian palm eccrine sweat gland is associated with transient net K+ efflux as in other exocrine glands. 2. When isolated secretory coils placed in a glass capillary were continuously superfused (method A), 32% of total cellular K+ was lost during 3 min of stimulation with methacholine (MCh) followed by K+ reuptake when stimulation was stopped. 3. When secretory coils were stimulated in a small chamber (without continuous superfusion, method C), MCh (5 x 10(-6) M)-induced maximal K+ efflux as determined by the peak level of extracellular K+ concentrations was dose dependent, inhibited by atropine but not altered by a cholinesterase inhibitor, physostigmine (1.3 x 10(-5) M). Thus the peak K+ level was used as a measure of K+ efflux throughout the study. 4. Phenylephrine (10(-4) M) and A23187 (5 x 10(-6) M) also induced K+ efflux but to a lesser extent than did MCh. 5. Ouabain (10(-3) M)-induced K+ loss was 2.4-fold higher than the peak level of MCh-induced K+ efflux. 6. In a Ca2+-free medium with added EGTA, inhibition of K+ efflux was only partial in the first MCh stimulation but progressively increased on repeated stimulation, suggesting that cytoplasmic or membrane Ca2+ not readily accessible to EGTA may be important for K+ efflux. Inhibition of K+ efflux in the Ca2+-free medium was completely reversed on subsequent addition of Ca2+. 7. Five millimolar Ba2+ partially inhibited MCh-induced K+ efflux. 8. 10(-4) M-bumetanide itself caused a small K+ loss and strongly inhibited the subsequent MCh-induced K+ loss. 9. MCh-induced K+ loss was drastically inhibited in the low-Cl- (by replacing with gluconate- or methylsulphate-) or low-Na+ (by replacing with Tris+) medium. 10. K+ efflux occurs predominantly across the basolateral membrane. 11. Vinblastine at 10(-4) M, which completely inhibits sweat secretion (our unpublished results), however, showed no effect on MCh-induced K+ efflux. 12. We conclude that the transient net K+ efflux associated with MCh stimulation constitutes a crucial primary ionic event in cholinergic eccrine sweat secretion as in other exocrine secretory cells.

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

The properties of Ca2+-activated K+ channels in the apical membrane of the Necturus choroid plexus were studied using single-channel recording techniques in the cell-attached and excised-patch configurations. Channels with large unitary conductances clustered around 150 and 220 pS were most commonly observed. These channels exhibited a high selectivity for K+ over Na+ and K+ over Cs+. They were blocked by high cytoplasmic Na+ concentrations (110 mM). Channel activity increased with depolarizing membrane potentials, and with increasing cytoplasmic Ca2+ concentrations. Increasing Ca2+ from 5 to 500 nM, increased open probability by an order of magnitude, without changing single-channel conductance. Open probability increased up to 10-fold with a 20-mV depolarization when Ca2+ was 500 nM. Lowering intracellular pH one unit, decreased open probability by more than two orders of magnitude, but pH did not affect single-channel conductance. Cytoplasmic Ba2+ reduced both channel-open probability and conductance. The sites for the action of Ba2+ are located at a distance more than halfway through the applied electric field from the inside of the membrane. Values of 0.013 and 117 mM were calculated as the apparent Ba2+ dissociation constants (KD(0 mV] for the effects on probability and conductance, respectively. TEA+ (tetraethylammonium) reduced single-channel current. Applied to the cytoplasmic side, it acted on a site 20% of the distance through the membrane, with a KD(0 mV) = 5.6 mM. A second site, with a higher affinity, KD(0 mV) = 0.23 mM, may account for the near total block of channel conductance by 2 mM TEA+ applied to the outside of the membrane. It is concluded that the channels in Necturus choroid plexus exhibit many of the properties of "maxi" Ca2+-activated K+ channels found in other tissues.