Amiloride-sensitive epithelial Na+ channels reconstituted into planar lipid bilayer membranes

Epithelial sodium channel activity in detergent-resistant membrane microdomains

The activity of epithelial Na(+) selective channels is modulated by various factors, with growing evidence that membrane lipids also participate in the regulation. In the present study, Triton X-100 extracts of whole cells and of apical membrane-enriched preparations from cultured A6 renal epithelial cells were floated on continuous-sucrose-density gradients. Na(+) channel protein, probed by immunostaining of Western blots, was detected in the high-density fractions of the gradients (between 18 and 30% sucrose), which contain the detergent-soluble material but also in the lighter, detergent-resistant 16% sucrose fraction. Single amiloride-sensitive Na(+) channel activity, recorded after incorporation of reconstituted proteoliposomes into lipid bilayers, was exclusively localized in the 16% sucrose fraction. In accordance with other studies, high- and low-density fractions of sucrose gradients likely represent membrane domains with different lipid contents. However, exposure of the cells to cholesterol-depleting or sphingomyelin-depleting agents did not affect transepithelial Na(+) current, single-Na(+) channel activity, or the expression of Na(+) channel protein. This is the first reconstitution study of native epithelial Na(+) channels, which suggests that functional channels are compartmentalized in discrete domains within the plane of the apical cell membrane.

Biochemical status of renal epithelial Na+ channels determines apparent channel conductance, ion selectivity, and amiloride sensitivity

Purified bovine renal papillary Na+ channels, when reconstituted into planar lipid bilayers, reside in three conductance states: a 40-pS main state, and two subconductive states (12-13 pS and 24-26 pS). The activity of these channels is regulated by phosphorylation and by G-proteins. Protein kinase A (PKA)-induced phosphorylation increased channel activity by increasing the open state time constants from 160 +/- 30 (main conductance), and 15 +/- 5 ms (both lower conductances), respectively, to 365 +/- 30 ms for all of them. PKA phosphorylation also altered the closed time of the channel from 250 +/- 30 ms to 200 +/- 35 ms, thus shifting the channel into a lower-conductance, long open time mode. PKA phosphorylation increased the PNa:PK of the channel from 7:1 to 20:1, and shifted the amiloride inhibition curve to the right (apparent K(i)amil from 0.7 to 20 microM). Pertussis toxin-induced ADP-ribosylation of either phosphorylated of either phosphorylated or nonphosphorylated channels decreased the PNa:PK to 2:1 and 4:1, respectively, and altered K(i)amil to 8 and 2 microM for phosphorylated and nonphosphorylated channels, respectively. GTP-gamma-S treatment of either phosphorylated or nonphosphorylated channels resulted in an increase of PNa:PK to 30:1 and 10:1, respectively, and produced a leftward shift in the amiloride dose-response curve, altering K(i)amil to 0.5 and 0.1 microM, respectively. These results suggest that amiloride-sensitive renal Na+ channel biophysical characteristics are not static, but depend upon the biochemical state of the channel protein and/or its associated G-protein.

Immunopurification and functional reconstitution of a Na+ channel complex from rat lymphocytes

Patch-clamp experiments have demonstrated an amiloride-sensitive Na+ conductance in human B lymphoid cells. We measured whole cell currents in rat lymphocytes and observed a similar Na(+)-specific inward conductance. The presence of 400 microM 8-(4-chlorophenylthio)adenosine 3',5'-cyclic monophosphate in the bath significantly increased the inward current, and this adenosine 3',5'-cyclic monophosphate activation was abolished by 2 microM amiloride. We immunopurified a protein complex from rat lymphocyte membranes using an anti-bovine kidney Na+ channel antibody. The complex consisted of five distinct polypeptides with apparent M(r) values of 110,000, 92,000, 59,000, 48,000, and 42,000. This putative channel complex was incorporated into planar lipid bilayers, where we observed single Na+ channel activity that was blocked by amiloride in a concentration-dependent manner. The addition of protein kinase A and ATP to the "intracellular" solution elicited a twofold increase in channel activity. Reverse transcription-polymerase chain reaction analysis was used to determine if the rat lymphocytes express the message for the recently cloned Na+ channel of the rat colon (rENaC). Primers for the alpha-subunit of rENaC identified no message in the lymphocyte RNA, while primers for the beta-subunit of the clone produced low levels of the expected product. Thus it appears that a rENaC-like beta-subunit may be an essential component of the lymphocyte Na+ channel that was isolated. At the same time, this channel is different from those recently cloned in that it does not include an alpha-subunit homologous to that of rENaC.

Amiloride-sensitive apical membrane sodium channels of everted Ambystoma collecting tubule

Patch clamp methods were used to characterize sodium channels on the apical membrane of Ambystoma distal nephron. The apical membranes were exposed by everting and perfusing initial collecting tubules in vitro. In cell-attached patches, we observed channels whose mean inward unitary current averaged 0.39 +/- 0.05 pA (9 patches). The conductance of these channels was 4.3 +/- 0.2 pS. The unitary current approached zero at a pipette voltage of -92 mV. When clamped at the membrane potential the channel expressed a relatively high open probability (0.46). These characteristics, together with observation that doses of 0.5 to 2 microM amiloride reversibly inhibited the channel activity, are consistent with the presence of the high amiloride affinity, high sodium selectivity channel reported for rat cortical collecting tubule and cultured epithelial cell lines. We used antisodium channel antibodies to identify biochemically the epithelial sodium channels in the distal nephron of Ambystoma. Polyclonal antisodium channel antibodies generated against purified bovine renal, high amiloride affinity epithelial sodium channel specifically recognized 110, 57, and 55 kDa polypeptides in Ambystoma and localized the channels to the apical membrane of the distal nephron. A polyclonal antibody generated against a synthetic peptide corresponding to the C-terminus of Apx, a protein associated with the high amiloride affinity epithelial sodium channel expressed in A6 cells, specifically recognized a 170 kDa polypeptide. These data corroborate that the apically restricted sodium channels in Ambystoma are similar to the high amiloride affinity, sodium selective channels expressed in both A6 cells and the mammalian kidney.

Structure and function of amiloride-sensitive Na+ channels

A new molecular biological epoch in amiloride-sensitive Na+ channel physiology has begun. With the application of these new techniques, undoubtedly a plethora of new information and new questions will be forthcoming. First and foremost, however, is the question of how many discrete amiloride-sensitive Na+ channels exist. This question is important not only for elucidating structure-function relationships, but also for developing strategies for pharmacological or, ultimately, genetic intervention in such diseases as obstructive nephropathy, Liddle's syndrome, or salt-sensitive hypertension where amiloride-sensitive Na+ channel dysfunction has been implicated [17, 62]. Epithelia Na+ channels purified from kidney are multimeric. However, it is not yet clear which subunits are regulatory and which participate directly as a part of the Na+ conducting core and what is the nature of the gate. The combination of electrophysiologic techniques such as patch clamp and the ability to study reconstituted channels in planar lipid bilayers along with molecular biology techniques to potentially manipulate the individual subunits should provide the answers to questions that have puzzled physiologists for decades. It seems clear that the robust versatility of the channel in responding to a wide range of differing and potentially synergistic regulatory inputs must be a function of its multimeric structure and relation to the cytoskeleton. Multiple mechanisms of regulation imply multiple regulatory sites. This hypothesis has been validated by the demonstration that enzymatic carboxyl methylation and phosphorylation have both individual and synergistic effects on the purified channel in planar lipid bilayers. Of the multiple mechanisms proposed for channel regulation, evidence is now available to support the ideas that channels may be activated (or inactivated) by direct modifications including phosphorylation and carboxyl methylation, by activation or association of regulatory proteins such as G proteins, and by recruitment from subapical membrane domains. The observation that channel gating is achieved primarily through regulation of open probability without alterations in conductance may simplify future understanding of the molecular events involved in gating once the regulatory sites have been identified. As more Na+ channels or Na+ channel subunits are cloned from different epithelia, it will become possible to piece together the puzzle of epithelial Na+ channels. It is interesting to observe that renal Na+ channel proteins contain a subunit which falls into the 70 kD range. This size protein is in the range reported for the aldosterone-induced proteins [12, 46, 153].(ABSTRACT TRUNCATED AT 400 WORDS)

Interaction of amiloride with rat parotid muscarinic and alpha-adrenergic receptors

1. In rat parotid acini, amiloride inhibited the secretion of amylase and the efflux of calcium and rubidium in response to carbamylcholine and to norepinephrine. 2. Amiloride competitively inhibited the binding of [3H]N-methylscopolamine and [3H] is thus a competitive antagonist of muscarinic and norepinephrine alpha-adrenergic receptors. 3. Amiloride did not affect the response to substance P with respect to secretion or ion movements. 4. Thus the Na+/H+ antiporter is not involved in the short-term regulation of amylase secretion and calcium and potassium movements in rat parotid gland function.

Influence of filter supports on transport characteristics of cultured A6 kidney cells

Amphibian A6 kidney cells grown on Anocell filters developed a transepithelial potential difference of 37 mV, a short-circuit current (Isc) of 8 microA/cm2, and a resistance of 5 k omega.cm2. Other observations suggested a viable arginine vasopressin (AVP) V2 receptor-second messenger pathway in these cells: 1) AVP increased both an amiloride-sensitive Isc and adenosine 3',5'-cyclic monophosphate (cAMP) formation, and 2) scanning electron micrographs of A6 cells cultured on Anocell and ICN Cellagen filters demonstrated increased microvilli formation on the apical surface after AVP action. However, osmotic water flow (JV) across A6 cells on filter supports was not altered by either AVP or the permeable cAMP analogue dibutyryl cAMP (osmotic permeability coefficient = 2.5 x 10(-3) cm/s). Diffusional water flow (Jdw) measured across A6 cells on Anocell filters using tritiated water (THO) ranged from 6 to 8 microliters.min-1.cm-2. Neither AVP nor the membrane-permeabilizing agents amphotericin B and digitonin were able to enhance unidirectional THO fluxes, although amphotericin B increased the Isc. These results suggested that there was an unknown barrier in series with the A6 cells limiting water flow. THO fluxes across filter supports, without an associated cellular monolayer, gave Jdw values in the range 7-30 microliters.min-1.cm-2. Jv across the bare filter support was in the range of 0.3-1.5 microliters.min-1.cm-2, similar to that measured in the presence of an A6 monolayer. These observations suggest that the filter may be rate limiting for transepithelial water flow. Chloride fluxes across Anocell filters showed a stable value of 5 mu eq.h-1.cm-2. These observations exhibit the limitations of filter supports in the study of transport phenomena in cultured cells.

Single-channel characteristics of a purified bovine renal amiloride-sensitive Na+ channel in planar lipid bilayers

We have purified an amiloride-inhibitable Na+ channel protein from bovine renal papillae using ion-exchange and immunoaffinity chromatography. In the present study, these purified Na+ channels were reconstituted into planar lipid bilayers, and their single-channel characteristics were studied. We observed both large- and small-conductance Na(+)-selective ion channels in planar lipid bilayers. Single-channel conductance for the large- and small-conductance channels saturated as a function of Na+ concentration. These relations could be fitted by a simple Langmuir isotherm with a Michaelis constant of 55 and 45 mM and a maximum open-state conductance of 56 or 8.4 pS, respectively. Both channels were perfectly cation selective, with a Na(+)-to-K+ permeability ratio of 6.7:1 for the large channel and 7.8:1 for the small channel, and their open single-channel current-voltage relations were linear when bathed with symmetrical Na+ solutions. The percent open time of the reconstituted large or small channels varied between 10 and 50% or 1 and 20%, respectively. After application of amiloride, both the large- and small-conductance Na+ channels were inhibited in a dose-dependent manner.

Aldosterone increases the amiloride-sensitivity of the rat gustatory neural response to NaCl

1. The percentage inhibition of the chorda tympani neural response to NaCl by topical application of amiloride to the tongue was significantly larger in rats pretreated with aldosterone than in control animals. 2. Adrenalectomized rats pretreated with aldosterone had significantly larger amiloride-induced inhibitions to a NaCl stimulus than did adrenalectomized control animals. 3. These data suggest that aldosterone may increase the number of active amiloride-sensitive sodium channels in the apical membrane of taste cells, as is known to occur in sodium transporting tissues of amphibians and mammals. They additionally represent a previously unnoticed hormonal influence over the gustatory system.

Single-channel behavior of a purified epithelial Na+ channel subunit that binds amiloride

The apical membrane of high electrical resistance epithelia, which is selectively permeable to Na+, plays an essential role in the maintenance of salt balance. Na+ entry from the apical fluid into the cells is mediated by amiloride-blockable Na(+)-specific channels. The channel protein, purified from both amphibian and mammalian sources, is composed of several subunits, only one of which the 150-kDa polypeptide, specifically binds the Na+ transport inhibitor amiloride. The goal of the present study was to investigate whether the isolated amiloride-binding subunit of the channel could conduct Na+. The patch-clamp technique was used to study the 150-kDa polypeptide incorporated into a lipid bilayer formed on the tip of a glass pipette. Unitary conductance jumps averaged 4.8 pS at 100 mM Na2HPO4. Open times ranged from 24 ms to several seconds. The channel spent most of the time in the closed state. Channel conductance and gating were independent of voltage between -60 and +100 mV. Amiloride (0.1 microM) decreased the mean open time of the channel by 98%. We conclude that the 150-kDa subunit of the amiloride-blockable Na+ channel conducts current and may be sufficient for the Na+ transport function of the whole channel.

Regulation of renal epithelial sodium channels

The high selectivity, low conductance, amiloride-blockable, sodium channel of the mammalian distal nephron (i.e. cortical collecting tubule) is the site of discretionary regulation which allows maintainance of total body sodium balance. In order to understand the physiological events that participate in this regulation, we have used the patch-clamp technique which allows us to measure individual Na+ channel currents and permits access to the cytosolic side of the channel-protein as well as its associated regulatory components. Most of our experiments have utilized the A6 amphibian renal cell line, which when grown on permeable supports is an excellent model for the mammalian distal nephron. Different mechanisms have been examined: (1) regulation by hormonal factors such as Anti-Diuretic Hormone (ADH) and aldosterone, (2) regulation by G-proteins, (3) modulation by protein kinase C (PK-C), and (4) modulation by products of arachidonic acid metabolism. Consistent with noise analysis of tight epithelial tissues, ADH treatment increased the number of active channels in apical membrane patches of A6 cells, without any apparent change in the open probability (Po) of the individual channels. Agents that increased intracellular cAMP mimicked the effects of ADH. In contrast, aldosterone was found to act through a dramatic increase in Po rather than through changes in channel density. Inhibition of methylation by deazaadenosine antagonizes the stimulatory effect of aldosterone. In excised inside-out patches GTP gamma S inhibits channel activity, whereas GDP beta S or pertussis toxin stimulates activity suggesting regulatory control by G-proteins. PK-C has been shown to contribute to 'feed-back inhibition' of apical Na+ conductance in tight epithelia.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and functional reconstitution of the cystic fibrosis transmembrane conductance regulator (CFTR)

Circumstantial evidence has accumulated suggesting that CFTR is a regulated low-conductance Cl- channel. To test this postulate directly, we have purified to homogeneity a recombinant CFTR protein from a high-level baculovirus-infected insect cell line. Evidence of purity included one- and two-dimensional gel electrophoresis, N-terminal peptide sequence, and quantitative amino acid analysis. Reconstitution into proteoliposomes at less than one molecule per vesicle was accomplished by established procedures. Nystatin and ergosterol were included in these vesicles, so that nystatin conductance could serve as a quantitative marker of vesicle fusion with a planar lipid bilayer. Upon incorporation, purified CFTR exhibited regulated chloride channel activity, providing evidence that the protein itself is the channel. This activity exhibited the basic biophysical and regulatory properties of the type of Cl- channel found exclusively in CFTR-expressing cell types and believed to underlie cAMP-evoked secretion in epithelial cells.

Regulation of Na+ channels in the cortical collecting duct by AVP and mineralocorticoids

A variety of experimental approaches have shown that AVP and mineralocorticoids stimulate Na+ transport through their effects on the number and kinetic properties of amiloride-sensitive Na+ channels in the apical membrane. The different mechanisms by which AVP and mineralocorticoid act on the Na+ channel provide a basis for synergism in their actions, perhaps by a scheme such as that proposed in Figure 5. However, the details of this interaction will require a better understanding of the molecular details involved in activating quiescent channels, increasing their open probability, and reorientating or inserting channels to an operational position in the apical membrane. Electrophysiological and biochemical approaches have gone a long way toward elucidating some of these molecular details. But the latter approach in particular has indicated that the Na+ channel may have multiple regulatory subunits and thus be a target for several intracellular second messengers and autacoids other than those involved in the actions of AVP and aldosterone. The challenges for future research in this area are multiple. It seems likely that the primary amino acid sequence of the channel subunits will soon become available from cloning and sequencing approaches, but the application of this knowledge to understanding how the subunits are integrated into the complete protein and mediate regulatory signals will be a formidable task. It will be important to determine the normal extracellular signals (other than aldosterone and AVP) and the associated intracellular second messengers that alter channel activity. It will also be important to understand how some species such as the rabbit may "turn off" the stimulatory effect of AVP on Na+ reabsorption in the CCD, and how this regulatory process is altered when these cells are cultured. At the whole animal level, it will also be important to investigate whether changes in one or more of the normal regulatory pathways that impinge on the Na+ channel might be involved in a diminished ability to excrete a salt load, as is observed in some models of hypertension. All of these issues need to be understood at the molecular level, and it seems likely they will provide exciting physiological insights at all levels.

Voltage dependent membrane conductances in cultured renal distal cells

Cultured Na(+)-transporting epithelia from amphibian renal distal tubule (A6) were impaled with microelectrodes and analyzed at short-circuit and after transepithelial voltage perturbation to evaluate the influence of voltage on apical and basolateral membrane conductances. For equivalent circuit analysis, amiloride was applied at each setting of transepithelial potential. At short-circuit, apical and basolateral membrane conductances averaged 88 and 497 microS/cm2, respectively (n = 10). Apical membrane conductance, essentially due to Na(+)-specific pathways, decreased after depolarization of the apical membrane. The drop was considerably larger than predicted by the Goldman-Hodgkin-Katz (GHK) constant-field equation. This suggests decrease in permeability of the apical Na+ channels upon depolarization. Basolateral membrane conductance, preferentially determined by K+ channels, increased after hyperpolarization of the basolateral membrane. This behavior is contrary to the prediction of the GHK constant field equation and reflects inward rectification of the K+ channels. The observed rectification patterns can be valuable for maintenance of cellular homeostasis.

A new non-voltage-dependent, epithelial-like Na+ channel in vascular smooth muscle cells

A new type of Na+ channel was identified in smooth muscle cells of the rat aortic cell line A7r5, and in smooth muscle cells cultured from rat aorta and rat portal vein. The channel is highly selective for Na+ (PNa/PK greater than 11). It is active in cell-attached patches, and independent of the trans-patch membrane potential. The single channel conductance is low (10.7 pS). Two substates were identified. This channel is insensitive to effectors of other types of Na+ channels, such as amiloride (100 microM) or tetrodotoxin (100 microM). It is inhibited by phenamil at high concentrations (greater than 10 microM). The mean open state probability P(O) varied from patch to patch (0.05-0.88). Kinetics analysis reveals a complex behaviour: open times separate in short (tau 1 = 84 ms) and long (tau 2 = 845 ms) openings and closed times separate into short (tau 1 = 60 ms) and long closures (tau 2 = 272-3130 ms). Short openings and long closures are preponderant at a low P(O). Long openings are absent in the presence of phenamil (50 microM) and are unaffected by amiloride (100 microM). Fluctuations of the channel activity in cell-attached patches and the fast disappearance after excision suggest that this channel is under metabolic control. This vascular smooth muscle channel appears to be a potentially important Na+ entry pathway for vascular cells and an amiloride-resistant homologue of the epithelial Na+ channel.

Apical and basolateral conductance in cultured A6 cells

Confluent monolayers of the cultured renal distal tubule cell line (A6) were impaled with microelectrodes under short-circuit conditions. Specific membrane conductances were calculated from equivalent circuit equations. Transport properties of the apical and basolateral membranes were investigated during control conditions and short-term increases in basolateral potassium concentration [K+] from 2.5 to 20 mmol/l, with or without 0.5 mmol/l Ba2+ at the basolateral side. As in most other epithelia, the apical membrane represents the major resistive barrier. Transcellular, apical and basolateral membrane conductances (gc, go and gi respectively), obtained from 22 acceptable microelectrode studies, averaged 61, 80 and 292 microS/cm2, respectively. There was a highly significant correlation between short-circuit current (Isc) and go, whereas gi was unrelated to Isc. The Isc, which averaged 4.1 microA/cm2, was almost completely blocked by amiloride. This was associated with fast hyperpolarization; the intracellular potential (Vsc) increased from -69 to -83 mV and the fractional apical resistance rose to nearly 100%. Using the values of Vsc during amiloride at normal and high [K+], an apparent transference number for K+ at the basolateral membrane of 0.72 can be calculated. This value corresponds with the decrease in gi to about 25% of the control values after blocking the K+ channels with Ba2+. The nature of the remaining conductance is presently unclear. The cellular current decreased during high [K+] and Ba2+, in part resulting from reduction of the electrochemical gradient for apical Na+ uptake due to the depolarization.(ABSTRACT TRUNCATED AT 250 WORDS)

Amiloride-sensitive Na+ transport across cultured renal (A6) epithelium: evidence for large currents and high Na:K selectivity

Electrical techniques were used to determine the Na:K selectivity of the amiloride-sensitive pathway and to characterize cellular and paracellular properties of A6 epithelium. Under control conditions, the mean transepithelial voltage (VT) was -57 +/- 5 mV, the short-circuit current (Isc) averaged 23 +/- 2 microA/cm2 and the transepithelial resistance (RT) was 2.8 +/- 0.3 k omega cm2 (n = 13). VT and Isc were larger than reported in previous studies and were increased by aldosterone. The conductance of the amiloride-sensitive pathway (Gamil) was assessed before and after replacement of Na+ in the mucosal bath by K+, using two independent measurements: (1) the slope conductance (GT), determined from current-voltage (I-V) relationships for control and amiloride-treated tissues and (2) the maximum amiloride-sensitive conductance (Gmax) calculated from the amiloride dose-response relationship. The ratio of Gamil in mucosal Na+ solutions to Gamil for mucosal K+ solutions was 22 +/- 6 for GT measurements and 15 +/- 2 for Gmax data. Serosal ion replacements in tissues treated with mucosal nystatin indicated a potassium conductance in the basolateral membrane. Equivalent circuit analyses of nystatin and amiloride data were used to resolve the cellular (Ec) and paracellular (Rj) resistances (approximately 5 k omega cm2 and 8-9 k omega cm2, respectively). Analysis of I-V relationships for tissues depolarized with serosal K+ solutions revealed that the amiloride-sensitive pathway could be described as a Na+ conductance with a permeability coefficient (PNa) = 1.5 +/- 0.2 x 10(-6) cm/s and the intracellular Na+ concentration (Nai) = 5 +/- 1 mM (n = 5), similar to values from other tight epithelia. We conclude that A6 epithelia are capable of expressing large amiloride-sensitive currents which are highly Na+ selective.

Blocker-related changes of channel density. Analysis of a three-state model for apical Na channels of frog skin

Blocker-induced noise analysis of apical membrane Na channels of epithelia of frog skin was carried out with the electroneutral blocker (CDPC, 6-chloro-3,5-diamino-pyrazine-2-carboxamide) that permitted determination of the changes of single-channel Na currents and channel densities with minimal inhibition of the macroscopic rates of Na transport (Baxendale, L. M., and S. I. Helman. 1986. Biophys. J. 49:160a). Experiments were designed to resolve changes of channel densities due to mass law action (and hence the kinetic scheme of blocker interaction with the Na channel) and to autoregulation of Na channel densities that occur as a consequence of inhibition of Na transport. Mass law action changes of channel densities conformed to a kinetic scheme of closed, open, and blocked states where blocker interacts predominantly if not solely with open channels. Such behavior was best observed in "pulse" protocol experiments that minimized the time of exposure to blocker and thus minimized the contribution of much longer time constant autoregulatory influences on channel densities. Analysis of data derived from pulse, staircase, and other experimental protocols using both CDPC and amiloride as noise-inducing blockers and interpreted within the context of a three-state model revealed that Na channel open probability in the absence of blocker averaged near 0.5 with a wide range among tissues between 0.1 and 0.9.

Expression of amiloride-blockable sodium channels in Xenopus oocytes

This report describes the expression of a sodium-selective, amiloride-blockable conductance in Xenopus oocytes that have been injected with RNA prepared from a distal nephron cell line (A6). After injecting the RNA into mature oocytes (stage V or VI) and incubating the oocytes for 2-4 days, the oocytes were examined for amiloride-blockable current. The RNA induced a substantial amiloride-blockable current. Uninjected or water-injected oocytes had no measurable amiloride-blockable current. RNA prepared from aldosterone-treated A6 cells was much more effective in inducing amiloride-blockable sodium current than RNA prepared from aldosterone-depleted A6 cells. Oocytes injected with RNA prepared from mineralocorticoid-depleted cells appeared very similar to water-injected oocytes. The amiloride-blockable current in oocytes has a reversal potential of approximately +50 - +60 mV, which varies 61 mV/decade change in external sodium concentration, suggesting that the current is highly selective for sodium over other ions. In addition, the concentration of amiloride that produces half block of the current is 48 +/- 8 nM. Thus the current expressed in oocytes appears very similar to sodium-selective currents observed from the apical membranes of various tight epithelial tissues.

Contragestion and other clinical applications of RU 486, an antiprogesterone at the receptor

RU 486, a steroid with high affinity for the progesterone receptor, is the first available active antiprogesterone. It has been used successfully as a medical alternative for early pregnancy interruption, and it also has other potential applications in medicine and for biochemical and pathophysiological endocrine research.

Single-channel recordings from the apical membrane of the toad urinary bladder epithelial cell

The patch-clamp technique for the recording of single-channel currents was used to investigate the activity of ion channels in the intact epithelium of the toad urinary bladder. High resistance seals were obtained from the apical membrane of tightly stretched tissue. Single-channel recordings revealed the activity of a variety of ion channels that could be classified in 4 groups according to their mean ion conductances, ranging from 5 to 59 pS. In particular, we observed highly selective, amiloride-sensitive Na channels with a mean conductance of 4.8 pS, channels with a similar conductance that were not Na-selective and channels with mean conductance values of 17-58 pS that were mostly seen after stimulation of the tissue with vasopressin or cAMP. When inside-out patches from the apical membrane were exposed to 110 mM fluoride, large conductances (86-490 pS) appeared.

Functional reconstitution of an isolated sodium channel from bovine trachea

An amiloride-sensitive Na+ channel from bovine trachea was isolated using an affinity gel and reconstituted into a planar lipid bilayer. This channel exhibited: 1. Fluctuations with long duration opening and closing times, weak voltage dependence, and a conductance of 6 pS. 2. Selectivity of at least 100-fold for Na+ over K+. 3. Saturates at a Na+ concentration of 90 mM. 4. Blocked by amiloride, 50% inhibition at 0.1 microM.

The effect of amiloride on Na, K and water in bovine corneal epithelium

The Na and K concentrations of bovine corneal epithelium and stroma were determined by chemical analysis. The effect of ambient Na concentration on these concentrations was evaluated. In the epithelium, approx. 10 mmol Na kg-1 H2O entered the cells from the tear side of the cornea. An inhibition of Na entry at the apical membrane by 5 x 10(-5) mol l-1 amiloride resulted in a loss of this amount of Na from the cells, accompanied by a loss of water. A linear relationship between the Na concentration in the stromal tissue and Na concentration on the on the aqueous side of the cornea was observed.

Time-dependent apical membrane K+ and Na+ selectivity in cultured kidney cells

Intracellular microelectrodes were used to study apical membrane selectivity to Na+ and K+ of cultured toad kidney cells (A6) grown on permeable supports. Membrane selectivity was tested by responses of apical membrane potential to replacement of Na+ by K+ or tetraethylammonium and by addition of amiloride to perfusion solutions. The A6 epithelia fell into two groups: those with K+-selective apical membranes, lack of amiloride sensitivity, and near-zero transepithelial potential (group I); and those with Na+-selective apical membranes and a serosa-positive, amiloride-sensitive transepithelial potential (Vm----s; group II). The transition from group I to group II behavior appeared definitive and time dependent, occurring approximately 10 days after plating onto filters. Transepithelial measurements under sterile conditions showed that overnight incubation with aldosterone (10(-7) M), after development of tight junctions (transepithelial resistance elevated) but before development of significant Vm----s, induced the switch from group I to group II behavior. Apical addition of Ba2+, a known blocker of K+ channels, unexpectedly reduced transepithelial resistance (Rm----s) in group I and group II A6, suggesting that it not only blocked K+ channels (when they are present) but may also open a parallel conductive pathway. In summary, after approximately 10 days in culture, apical membranes of A6 epithelia undergo a switch from K+ to Na+ selectivity, overnight incubation with aldosterone can trigger this change, and finally, Ba2+ may open a paracellular conductive pathway.

Ion selectivity of epithelial Na channels

Epithelial Na channels are apparently pore-forming membrane proteins which conduct Na much better than any other biologically abundant ion. The conductance to Na can be 100 to 1000 times higher than that to K. The only other ions that can readily get through this channel are protons and Li. Small organic cations cannot pass through the channel, and water may also be impermeant. The selectivity properties of epithelial Na channels appear to be determined by at least three factors: A high field-strength anionic site, most likely a carboxyl residue of glutamic or aspartic acid residues on the channel protein, probably accounts for the high conductance through these channels of Na and Li and to the low conductance of K, Rb and Cs. A restriction in the size of the pore at its narrowest point probably accounts for the low conductance of organic cations as well as the possible exclusion of water molecules. The outer mouth of the channel appears to be negatively charged and may control access to the region of highest selectivity and may serve as a preliminary selectivity filter, attracting cations over anions. These conclusions are illustrated by the cartoon of the channel in Fig. 3. This picture is obviously both fanciful and simplified, but its general points will hopefully be testable. It leaves open a number of important questions, including: does amiloride block the channel by binding within the outer mouth? what does the inner mouth of the channel look like, and does this part of the channel contribute to selectivity? and what, if any, are the interactions between the features of the channel that impart selectivity and those that control the regulation of the channel by hormonal and other factors?

Recent advances in the characterization of epithelial ionic channels

Physiologists have long recognized the importance of channels in the functioning of neurons and excitable membranes. This brief review has been an attempt to illustrate how channel properties are also essential to an understanding of epithelial transport physiology. Among their more important functions, channels influence membrane potentials and serve as conduits for ion movements. As the need to understand the molecular basis for ion transport continues to develop, it is crucial to be able to distinguish between different channel properties. For example, apparent voltage-dependent properties can arise because of a voltage-dependent gating process, or alternatively, because of a rectification of channel conductance. Voltage-dependent effects can also be only indirect, mediated by changes in cell volume, intracellular ion levels, the levels of secondary intracellular messengers such as Ca2+ (perhaps through voltage-dependent membrane Ca2+ channels), or possibly even by morphological changes. An important area for future research is to differentiate mechanisms which modulate the activity of open channels. For example, a decrease in channel number, a reduction in open-channel conductance or a decline in the probability of channel opening can all underlie changes in macroscopic permeability. The factors which mediate hormonal activation of epithelial channels particularly need to be understood. Specifically, the mechanisms of aldosterone and anti-diuretic hormone activation of apical membrane Na+ channels need to be identified. In conclusion, we are witnessing a new era in epithelial electrophysiology which promises to resolve many issues concerning the cellular regulation of ion transport and open new, unanticipated avenues of inquiry.

Sodium ion influx in proliferating lymphocytes: an early component of the mitogenic signal

Stimulation of pig peripheral blood lymphocytes with concanavalin A (Con A) provoked a rapid increase (two- to threefold) in the rate of ouabain-inhibitable K+ uptake observable within 3-10 min of stimulation with mitogen. At least two phases can be distinguished in the activation of the Na+/K+ pump: the early phase (till 3 h) is characterized by an unaltered number of ouabain binding sites and the later phase (noted at 5 h) by an increased number of such sites. Both K+ efflux and influx increased to the same extent, thereby maintaining [K+]i at the same level as in resting cells (120 mM). Within 3 min of addition of mitogen, the rates of total and amiloride-inhibitable Na+ uptake went up two- and fourfold, respectively, thus resulting in rapid increase in [Na+]i from 20 to about 50 mM. Activation of the Na+/K+ pump was not observed when the cells were stimulated with Con A in low Na+ medium (9 mM), nor did the usual rise in [Na+]i occur. When monensin (30 microM), a Na+/H+ ionophore, was added to resting cells, an increase in both [Na+]i and active K+ uptake occurred in normal medium but not when cells were suspended in low Na+ isotonic buffer. Amiloride (500 microM), on the other hand, prevented both the Con A-induced increase in [Na+]i and the activation of the Na+/K+ pump. Despite complete inhibition of the Na+,K+-ATPase in the presence of ouabain (1 mM), Con A activated the amiloride-inhibitable Na+ uptake in the usual way. In mouse splenocytes stimulated with Con A, there was also a parallel rise in both [Na+]i and active K+ uptake but this took considerably longer to occur than was the case in pig peripheral blood lymphocytes. Increase in both ionic fluxes, the former passive and the latter active, is essential to the entry and maintenance of the cells in proliferative cycle.

Effect of amiloride on bulk flow and iontophoretic taste stimuli in the hamster

This investigation demonstrates the effect of amiloride on various taste responses in the hamster, and tests the hypothesis that its action on iontophoretic application of taste stimuli parallels its action on bulk flow delivery. Amiloride has not previously been tested in the hamster nor has its effect on iontophoretic stimuli (so-called 'electric taste'), which is thought to behave similarly to bulk flow stimuli, been examined. Amiloride treatment (4 min of 0.0001 M) of the hamster's tongue effectively inhibited chorda tympani responses to NaCl and LiCl solutions. Bulk flow (0.1 M) and iontophoretic (+ 7 microA through 0.001 M) presentations of NaCl and LiCl, which had unequal response magnitudes pre-treatment, were inhibited to the same residual response magnitude post-treatment. Recovery then proceeded along two distinct curves asymptotically returning to pre-treatment response levels. These curves could be adequately described by a simple exponential relationship. KCl responses were unaffected when presented via bulk flow techniques but significantly reduced when presented iontophoretically. HCl responses via either method were only slightly diminished. No decrement in response level was observed for the sweet stimuli sucrose (0.5 M) or saccharin (-9 microA through 0.001 M Na-saccharin) nor for potassium picrate, a bitter stimulus, (0.01 M or -10 microA through 0.001 M). Amiloride treatment of the hamster tongue was as specific in its action for sodium and lithium as reported in other species, and with the exception of KCl the action of amiloride on iontophoretic stimulation paralleled its action on bulk flow stimulation.

Purification and characterization of the amiloride-sensitive sodium channel from A6 cultured cells and bovine renal papilla

The amiloride-binding Na+ channel protein of high electrical resistance epithelia was solubilized and purified from cultured A6 toad kidney cells and bovine renal papilla. Purification was assessed by enrichment in [3H]methylbromoamiloride specific binding. Chromatography of 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS)-solubilized plasma membrane vesicles on agarose-immobilized wheat-germ agglutinin provided a 130-fold enrichment of the amiloride-binding component compared to the cell homogenate. Further purification was achieved by either amiloride-affinity chromatography or size-exclusion HPLC. When the HPLC and amiloride affinity-purified material was injected into a second higher molecular weight exclusion HPLC column, only a single peak with Mr 800,000 was found. Further HPLC separation of the Mr 800,000 material at low ionic strength resolved two peaks with apparent Mrs 800,000 and 700,000. Only the 700-kDa component displayed specific [3H]methylbromoamiloride binding activity. The final binding specific activity achieved was 1300 pmol/mg of protein, corresponding to 91% homogeneity of the protein.